Chapter 4 Solutions

CHAPTER 4 20 40 20 PROBLEM 4.1 20 A M 5 15 kN · m Knowing that the couple shown acts in a vertical plane, determine the stress at (a) point A, (b) point B. 80 20 B Dimensions in mm SOLUTION For rectangle: I  Outside rectangle: I1  1 3 bh 12 1 (80)(120)3 12 I1  11.52  106 mm 4  11.52  106 m 4 Cutout: I2  1 (40)(80)3 12 I 2  1.70667  106 mm 4  1.70667  106 m 4 Section: (a) (b) I  I1  I 2  9.81333  106 m 4 y A  40 mm  0.040 m yB  60 mm  0.060 m A   My A (15  103 )(0.040)   61.6  106 Pa 6 I 9.81333  10 B   MyB (15  103 )(0.060)   91.7  106 Pa I 9.81333  106  A  61.6 MPa   B  91.7 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 447 2 in. 2 in. 2 in. PROBLEM 4.2 M 25 kip · in. A B Knowing that the couple shown acts in a vertical plane, determine the stress at (a) point A, (b) point B. 2 in. 1.5 in. 2 in. SOLUTION For rectangle: I 1 3 bh 12 For cross sectional area: I  I1  I 2  I 3  1 1 1 (2)(1.5)3  (2)(5.5)3  (2)(1.5)3  28.854 in 4 12 12 12 (a) y A  2.75 in. A   My A (25)(2.75)  I 28.854 (b) yB  0.75 in. B   (25)(0.75) MyB  28.854 I  A  2.38 ksi   B  0.650 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 448 200 mm PROBLEM 4.3 12 mm y C x Using an allowable stress of 155 MPa, determine the largest bending moment M that can be applied to the wide-flange beam shown. Neglect the effect of fillets. 220 mm M 8 mm 12 mm SOLUTION Moment of inertia about x-axis: I1  1 (200)(12)3  (200)(12)(104)2 12 I2  1 (8)(196)3  5.0197  106 mm 4 12  25.9872  106 mm 4 I 3  I1  25.9872  106 mm 4 I  I1  I 2  I 3  56.944  106 mm 4  56.944  106 m 4   Mc 1 with c  (220)  110 mm  0.110 m I 2 I M  with   155  106 Pa c Mx  (56.944  106 )(155  106 )  80.2  103 N  m 0.110 M x  80.2 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 449 200 mm PROBLEM 4.4 12 mm y Solve Prob. 4.3, assuming that the wide-flange beam is bent about the y axis by a couple of moment My. C x 220 mm PROBLEM 4.3. Using an allowable stress of 155 MPa, determine the largest bending moment M that can be applied to the wide-flange beam shown. Neglect the effect of fillets. M 8 mm 12 mm SOLUTION Moment of inertia about y axis: I1  1 (12)(200)3  8  106 mm 4 12 1 (196)(8)3  8.3627  103 mm 4 I2  12 I 3  I1  8  106 mm 4 I  I1  I 2  I 3  16.0084  106 mm 4  16.0084  106 m 4   1 Mc with c  (200)  100 mm  0.100 m 2 I I with   155  106 Pa My  c My  (16.0084  106 )(155  106 )  24.8  103 N  m 0.100 M y  24.8 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 450 0.1 in. PROBLEM 4.5 0.5 in. Using an allowable stress of 16 ksi, determine the largest couple that can be applied to each pipe. M1 (a) 0.2 in. 0.5 in. M2 (b) SOLUTION (a) I  4 o c  0.6 in.   (b) r 4  I  Mc : I   ri4   M  4 (0.64  0.54 )  52.7  103 in 4 I c  (16)(52.7  103 ) 0.6 M  1.405 kip  in.   (0.74  0.54 )  139.49  103 in 4 4 c  0.7 in.   Mc : I M  I c  (16)(139.49  103 ) 0.7 M  3.19 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 451 r 5 20 mm A PROBLEM 4.6 M = 2.8 kN · m 30 mm B 30 mm Knowing that the couple shown acts in a vertical plane, determine the stress at (a) point A, (b) point B. 120 mm SOLUTION I  1 1   (0.120 m)(0.06 m)3  2   (0.02 m) 4  12 12 4    2.1391  106 mm 4 (a) (b) A   B  (2.8  103 N  m)(0.03 m) M yA  I 2.1391  106 mm 4  A  39.3 MPa  (2.8  103 N  m)(0.02 m) M yB  I 2.1391  106 m 4  B  26.2 MPa   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 452 PROBLEM 4.7 y Two W4  13 rolled sections are welded together as shown. Knowing that for the steel alloy used  Y  36 ksi and  U  58 ksi and using a factor of safety of 3.0, determine the largest couple that can be applied when the assembly is bent about the z axis. z C SOLUTION Properties of W4  13 rolled section. (See Appendix C.) Area  3.83 in 2 Width  4.060 in. I y  3.86 in 4 For one rolled section, moment of inertia about axis b-b is I b  I y  Ad 2  3.86  (3.83)(2.030)2  19.643 in 4 For both sections, I z  2 I b  39.286 in 4 c  width  4.060 in.  all  M all U  58  19.333 ksi F .S . 3.0  I (19.333)(39.286)  all  4.060 c  Mc I M all  187.1 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 453 y PROBLEM 4.8 C Two W4  13 rolled sections are welded together as shown. Knowing that for the steel alloy used  U  58 ksi and using a factor of safety of 3.0, determine the largest couple that can be applied when the assembly is bent about the z axis. z SOLUTION Properties of W4  13 rolled section. (See Appendix C.) Area  3.83 in 2 Depth  4.16 in. I x  11.3 in 4 For one rolled section, moment of inertia about axis a-a is I a  I x  Ad 2  11.3  (3.83)(2.08)2  27.87 in 4 For both sections, I z  2 I a  55.74 in 4 c  depth  4.16 in.  all  M all U  58  19.333 ksi F .S . 3.0  I (19.333)(55.74)  all  4.16 c  Mc I M all  259 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 454 PROBLEM 4.9 3 in. 3 in. 3 in. Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam. 6 in. 2 in. A 15 kips 15 kips B C 40 in. 60 in. D 40 in. SOLUTION    A y0 A y0 18 5 90 18 1 18 36 Y0  108 108  3 in. 36 Neutral axis lies 3 in. above the base. I1  1 1 b1h13  A1d12  (3)(6)3  (18)(2) 2  126 in 4 12 12 1 1 3 2 I 2  b2 h2  A2 d 2  (9)(2)3  (18)(2) 2  78 in 4 12 12 I  I1  I 2  126  78  204 in 4 ytop  5 in. ybot  3 in. M  Pa  0 M  Pa  (15)(40)  600 kip  in.  top   M ytop  bot   M ybot (600)(3)  I 204 I   top  14.71 ksi (compression)  (600)(5) 204  bot  8.82 ksi (tension)  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 455 PROBLEM 4.10 8 in. 1 in. Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam. 6 in. 1 in. 1 in. 4 in. A 25 kips 25 kips B C 20 in. 60 in. D 20 in. SOLUTION     A y0 A y0 8 7.5 60 6 4 24 4 0.5 18 Yo  2 86 86  4.778 in. 18 Neutral axis lies 4.778 in. above the base. I1  1 1 b1h13  A1d12  (8)(1)3  (8)(2.772) 2  59.94 in 4 12 12 1 1 I 2  b2 h23  A2 d 22  (1)(6)3  (6)(0.778)2  21.63 in 4 12 12 1 1 3 2 I 3  b3 h3  A3 d3  (4)(1)3  (4)(4.278)2  73.54 in 4 12 12 I  I1  I 2  I 3  59.94  21.63  73.57  155.16 in 4 ytop  3.222 in. ybot  4.778 in. M  Pa  0 M  Pa  (25)(20)  500 kip  in.  top    bot   Mytop I  (500)(3.222) 155.16 Mybot (500)(4.778)  I 155.16  top  10.38 ksi (compression)   bot  15.40 ksi (tension)  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 456 10 mm PROBLEM 4.11 10 mm 10 kN 10 kN B 50 mm C A D Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam. 10 mm 50 mm 150 mm 250 mm 150 mm SOLUTION     A, mm 2 y0 , mm A y0 , mm3 600 30 600 30 18  103 300 5 1500 Y0  37.5  103  25mm 1500 18  103 1.5  103 37.5  103 Neutral axis lies 25 mm above the base. I1  1 (10)(60)3  (600)(5)2  195  103 mm 4 I 2  I1  195 mm 4 12 1 I 3  (30)(10)3  (300)(20) 2  122.5  103 mm 4 12 I  I1  I 2  I 3  512.5  103 mm 4  512.5  109 m 4 ytop  35 mm  0.035 m ybot  25 mm  0.025 m a  150 mm  0.150 m P  10  103 N M  Pa  (10  103 )(0.150)  1.5 103 N  m (1.5  103 )(0.035)  102.4  106 Pa 512.5  109  top   Mytop  bot   M ybot (1.5  103 )(0.025)   73.2  106 Pa I 512.5  109 I   top  102.4 MPa (compression)   bot  73.2 MPa (tension)  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 457 216 mm y 36 mm 54 mm z PROBLEM 4.12 C 108 mm Knowing that a beam of the cross section shown is bent about a horizontal axis and that the bending moment is 6 kN  m, determine the total force acting on the shaded portion of the web. 72 mm SOLUTION The stress distribution over the entire cross section is given by the bending stress formula: x   My I where y is a coordinate with its origin on the neutral axis and I is the moment of inertia of the entire cross sectional area. The force on the shaded portion is calculated from this stress distribution. Over an area element dA, the force is dF   x dA    The total force on the shaded area is then F  dF    My M dA   I I My dA I  y dA   M * * y A I where y * is the centroidal coordinate of the shaded portion and A* is its area. d1  54  18  36 mm d 2  54  36  54  36 mm PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 458 PROBLEM 4.12 (Continued) Moment of inertia of entire cross section: I1  1 1 b1h13  A1d12  (216)(36)3  (216)(36)(36)2  10.9175  106 mm 4 12 12 1 1 I 2  b2 h23  A2 d 22  (72)(108)3  (72)(108)(36)2  17.6360  106 mm 4 12 12 I  I1  I 2  28.5535  106 mm 4  28.5535  106 m 4 For the shaded area, A*  (72)(90)  6480 mm 2 y *  45 mm A* y *  291.6  103 mm3  291.6  106 m F MA* y * (6  103 )(291.6  106 )  I 28.5535  106  61.3  103 N F  61.3 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 459 20 mm 12 mm PROBLEM 4.13 20 mm y 12 mm 24 mm Knowing that a beam of the cross section shown is bent about a horizontal axis and that the bending moment is 4 kN  m, determine the total force acting on the shaded portion of the beam. 20 mm z C 20 mm 24 mm SOLUTION Dimensions in mm: Iz  1 1 (12  12)(88)3  (40)(40)3 12 12  1.3629  106  0.213  106  1.5763  106 mm 4  1.5763  106 m 4 For use in Prob. 4.14, Iy  1 1 (88)(64)3  (24  24)(40)3 12 12 6  1.9224  10  0.256  106  1.6664  106 mm 4  1.6664  106 m 4 Bending about horizontal axis. M z  4 kN  m M z c (4 kN  m)(0.044 m)   111.654 MPa Iz 1.5763  10 6 m 4 M c (4 kN  m)(0.020 m) B  z   50.752 MPa Iz 1.5763  10 6 m 4 A  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 460 PROBLEM 4.13 (Continued) A  (44)(12)  528 mm 2  528  10 6 m 2 Portion (1):  avg   A  (111.654)  55.83 MPa 1 2 1 2 Force1   avg A  (55.83 MPa)(528  106 m 2 )  29.477 kN A  (20)(20)  400 mm 2  400  10 6 m 2 Portion (2):  avg  1 1  B  (50.752)  25.376 MPa 2 2 Force2   avg A  (25.376 MPa)(400  106 m 2 )  10.150 kN Total force on shaded area  29.477  10.150  39.6 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 461 20 mm 12 mm PROBLEM 4.14 20 mm y 12 mm Solve Prob. 4.13, assuming that the beam is bent about a vertical axis by a couple of moment 4 kN  m. 24 mm PROBLEM 4.13. Knowing that a beam of the cross section shown is bent about a horizontal axis and that the bending moment is 4 kN  m, determine the total force acting on the shaded portion of the beam. 20 mm z C 20 mm 24 mm SOLUTION M y  4 kN  m Bending about vertical axis. See Prob. 4.13 for sketch and D  E  I y  1.6664  106 m 4 Mc (4 kN  m)(0.032 m)   76.81 MPa Iy 1.6664  106 m 4 Mc (4 kN  m)(0.020 m)   48.01 MPa Iy 1.6664  106 m 4 A  (44)(12)  528 mm 2  528  10 6 m 2 Portion (1):  avg  ( D   E )  (76.81  48.01)  62.41 MPa 1 2 1 2 Force1   avg A  (62.41 MPa)(528  106 m 2 )  32.952 kN A  (20)(20)  400 mm 2  400  106 m 2 Portion (2):  avg  1 1  E  (48.01)  24.005 MPa 2 2 Force2   avg A  (24.005 MPa)(400  106 m 2 )  9.602 kN Total force on shaded area  32.952  9.602  42.6 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 462 0.5 in. 0.5 in. 0.5 in. PROBLEM 4.15 1.5 in. 1.5 in. Knowing that for the extruded beam shown the allowable stress is 12 ksi in tension and 16 ksi in compression, determine the largest couple M that can be applied. 1.5 in. 0.5 in. M SOLUTION   Ay0 A y0 2.25 1.25 2.8125 2.25 0.25 0.5625 4.50 Y The neutral axis lies 0.75 in. above bottom. ytop  2.0  0.75  1.25 in., I1  3.375 3.375  0.75 in. 4.50 ybot  0.75 in. 1 1 b1h13  A1d12  (1.5)(1.5)3  (2.25)(0.5)2  0.984375 in 4 12 12 1 1 2 2 I 2  b2 h2  A2 d 2  (4.5)(0.5)3  (2.25)(0.5)2  0.609375 in 4 12 12 I  I1  I 2  1.59375 in 4   My I M  I y Top: (compression) M  (16)(1.59375)  20.4 kip  in. 1.25 Bottom: (tension) M  (12)(1.59375)  25.5 kip  in. 0.75 Choose the smaller as Mall. M all  20.4 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 463 PROBLEM 4.16 40 mm The beam shown is made of a nylon for which the allowable stress is 24 MPa in tension and 30 MPa in compression. Determine the largest couple M that can be applied to the beam. 15 mm d 30 mm 20 mm M SOLUTION   Σ Y0  A, mm2 y0 , mm A y0 , mm3 600 22.5 300 7.5 2.25  103 13.5  103 15.75  103 900 15.5  103  17.5 mm 900 The neutral axis lies 17.5 mm above the bottom. ytop  30  17.5  12.5 mm  0.0125 m ybot  17.5 mm  0.0175 m I1  1 1 b1h13  A1d12  (40)(15)3  (600)(5)2  26.25  103 mm 4 12 12 1 1 I 2  b2 h23  A2 d 22  (20)(15)3  (300)(10)2  35.625  103 mm 4 12 12 I  I1  I 2  61.875  103 mm 4  61.875  109 m 4 | |  My I Top: (tension side) M Bottom: (compression) M M I y (24  106 )(61.875  109 )  118.8 N  m 0.0125 (30  106 )(61.875  109 )  106.1 N  m 0.0175 Choose smaller value. M  106.1 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 464 PROBLEM 4.17 40 mm Solve Prob. 4.16, assuming that d  40 mm. 15 mm d 30 mm PROBLEM 4.16 The beam shown is made of a nylon for which the allowable stress is 24 MPa in tension and 30 MPa in compression. Determine the largest couple M that can be applied to the beam. 20 mm M SOLUTION A, mm2 y0 , mm A y0 , mm3 600 32.5 500 12.5 6.25  103   Σ Y0  25.75  103 1100 25.75  103  23.41 mm 1100 19.5  103 The neutral axis lies 23.41 mm above the bottom. ytop  40  23.41  16.59 mm  0.01659 m ybot  23.41 mm  0.02341 m I1  1 1 b1h13  A1d12  (40)(15)3  (600)(9.09) 2  60.827  103 mm 4 12 12 1 1 I 2  b2 h22  A2 d 22  (20)(25)3  (500)(10.91) 2  85.556  103 mm 4 12 12 I  I1  I 2  146.383  103 mm 4  146.383  109 m 4 | |  M My I Top: (tension side) M Bottom: (compression) M I y (24  106 )(146.383  109 )  212 N  m 0.01659 (30  106 )(146.383  109 )  187.6 N  m 0.02341 Choose smaller value. M  187.6 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 465 PROBLEM 4.18 2.4 in. 0.75 in. 1.2 in. Knowing that for the beam shown the allowable stress is 12 ksi in tension and 16 ksi in compression, determine the largest couple M that can be applied. M SOLUTION   rectangle   semi-circular cutout A1  (2.4)(1.2)  2.88 in 2 A2   2 (0.75)2  0.8836 in 2 A  2.88  0.8836  1.9964 in 2 y1  0.6 in. y2  4r (4)(0.75)   0.3183 in. 3 3 (2.88)(0.6)  (0.8836)(0.3183) A y   0.7247 in. Y  1.9964 A Neutral axis lies 0.7247 in. above the bottom. Moment of inertia about the base: 1 1   I b  bh3  r 4  (2.4)(1.2)3  (0.75) 4  1.25815 in 4 3 8 3 8 Centroidal moment of inertia: I  I b  AY 2  1.25815  (1.9964)(0.7247) 2  0.2097 in 4 ytop  1.2  0.7247  0.4753 in., ybot  0.7247 in. | |  M My I I y Top: (tension side) M (12)(0.2097)  5.29 kip  in. 0.4753 Bottom: (compression) M (16)(0.2097)  4.63 kip  in. 0.7247 Choose the smaller value. M  4.63 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 466 PROBLEM 4.19 80 mm Knowing that for the extruded beam shown the allowable stress is 120 MPa in tension and 150 MPa in compression, determine the largest couple M that can be applied. 54 mm 40 mm M SOLUTION   Σ Y  A, mm2 y0 , mm 2160 27 58,320 3 1080 36 38,880 3 A y0 , mm3 3240 97, 200  30 mm 3240 d, mm 97,200 The neutral axis lies 30 mm above the bottom. ytop  54  30  24 mm  0.024 m I1  ybot  30 mm  0.030 m 1 1 b1h13  A1d12  (40)(54)3  (40)(54)(3)2  544.32  103 mm 4 12 12 1 1 1 I 2  b2 h22  A2 d 22  (40)(54)3  (40)(54)(6)2  213.84  103 mm 4 36 36 2 3 4 I  I1  I 2  758.16  10 mm  758.16  109 m 4 | |  My I |M |  I y Top: (tension side) M Bottom: (compression) M Choose the smaller as Mall. (120  106 )(758.16  109 )  3.7908  103 N  m 0.024 (150  106 )(758.16  109 )  3.7908  103 N  m 0.030 M all  3.7908  103 N  m M all  3.79 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 467 PROBLEM 4.20 48 mm Knowing that for the extruded beam shown the allowable stress is 120 MPa in tension and 150 MPa in compression, determine the largest couple M that can be applied. 48 mm 36 mm 48 mm 36 mm M SOLUTION  Solid rectangle  Square cutout Σ Y  A, mm2 y0 , mm 4608 48 221,184 –1296 30 –38,880 3312 182,304  55.04 mm 3312 A y0 , mm3 182,304 Neutral axis lies 55.04 mm above bottom. ytop  96  55.04  40.96 mm  0.04096 m ybot  55.04 mm  0.05504 m I1  1 1 b1h13  A1d12  (48)(96)3  (48)(96)(7.04)2  3.7673  106 mm 4 12 12 1 1 I 2  b2 h32  A2 d 22  (36)(36)3  (36)(36)(25.04) 2  0.9526  106 mm 4 12 12 I  I1  I 2  2.8147  106 mm 4  2.8147  106 m 4 | |  My I  M  I y (120  106 )(2.8147  106 )  8.25  103 N  m 0.04096 Top: (tension side) M Bottom: (compression) M Mall is the smaller value. M  7.67  103 N  m (150  106 )(2.8147  106 )  7.67  103 N  m 0.05504 7.67 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 468 PROBLEM 4.21 Straight rods of 6-mm diameter and 30-m length are stored by coiling the rods inside a drum of 1.25-m inside diameter. Assuming that the yield strength is not exceeded, determine (a) the maximum stress in a coiled rod, (b) the corresponding bending moment in the rod. Use E  200 GPa. SOLUTION D  inside diameter of the drum, Let d  diameter of rod, c 1 d, 2   radius of curvature of center line of rods when bent.  I (a)  max  (b) M    Ec EI   1 1 1 1 D  d  (1.25)  (6  103 )  0.622 m 2 2 2 2  4 c4   4 (0.003) 4  63.617  1012 m 4 (200  109 )(0.003)  965  106 Pa 0.622   965 MPa  (200  109 )(63.617  1012 )  20.5 N  m 0.622 M  20.5 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 469 M' PROBLEM 4.22 M 8 mm A 900-mm strip of steel is bent into a full circle by two couples applied as shown. Determine (a) the maximum thickness t of the strip if the allowable stress of the steel is 420 MPa, (b) the corresponding moment M of the couples. Use E  200 GPa. t r 900 mm SOLUTION When the rod is bent into a full circle, the circumference is 900 mm. Since the circumference is equal to 2 times , the radius of curvature, we get   900 mm  143.24 mm  0.14324 m 2   E  Stress:  Ec or c For   420 MPa and E  200 GPa, c (a)  E (0.14324)(420  106 )  0.3008  103 m 200  109 Maximum thickness: t  2c  0.6016  103 m t  0.602 mm  Moment of inertia for a rectangular section. I  (b) bt 3 (8  103 )(0.6016  103 )3   145.16  1015 m 4 12 12 Bending moment: M M   EI (200  109 )(145.16  1015 )  0.203 N  m 0.14324 M  0.203 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 470 PROBLEM 4.23 5 ft Straight rods of 0.30-in. diameter and 200-ft length are sometimes used to clear underground conduits of obstructions or to thread wires through a new conduit. The rods are made of high-strength steel and, for storage and transportation, are wrapped on spools of 5-ft diameter. Assuming that the yield strength is not exceeded, determine (a) the maximum stress in a rod, when the rod, which is initially straight, is wrapped on a spool, (b) the corresponding bending moment in the rod. Use E  29  106 psi . SOLUTION Radius of cross section: r  Moment of inertia: I  D  5 ft  60 in. c  r  0.15 in. (a)  max  (b) M   EI  Ec     1 1 d  (0.30)  0.15 in. 2 2  4 r4   4 (0.15) 4  397.61  106 in 4 1 D  30 in. 2 (29  106 )(0.15)  145.0  103 psi 30 (29  106 )(397.61  106 ) 30  max  145.0 ksi  M  384 lb  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 471 PROBLEM 4.24 12 mm y 60 N · m A 60-N  m couple is applied to the steel bar shown. (a) Assuming that the couple is applied about the z axis as shown, determine the maximum stress and the radius of curvature of the bar. (b) Solve part a, assuming that the couple is applied about the y axis. Use E  200 GPa. 20 mm z SOLUTION (a) Bending about z-axis. I 1 3 1 bh  (12)(20)3  8  103 mm 4  8  109 m 4 12 12 20 c  10 mm  0.010 m 2   1 (b)  Mc (60)(0.010)   75.0  106 Pa 9 I 8  10 60 M   37.5  103 m 1 EI (200  109 )(8  109 )   75.0 MPa    26.7 m  Bending about y-axis. I 1 3 1 bh  (20)(12)3  2.88  103 mm 4  2.88  109 m 4 12 12 12  6 mm  0.006 m c 2 Mc (60)(0.006)    125.0  106 Pa 9 I 2.88  10  1  60 M   104.17  103 m 1 9 EI (200  10 )(2.88  109 )   125.0 MPa    9.60 m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 472 10 mm M (a) Using an allowable stress of 120 MPa, determine the largest couple M that can be applied to a beam of the cross section shown. (b) Solve part a, assuming that the cross section of the beam is an 80-mm square. 80 mm C PROBLEM 4.25 10 mm 80 mm 5 mm 5 mm SOLUTION (a) I  I1  4 I 2 , where I1 is the moment of inertia of an 80-mm square and I2 is the moment of inertia of one of the four protruding ears. I1  1 3 1 bh  (80)(80)3  3.4133  106 mm 4 12 12 I2  1 3 1 bh  Ad 2  (5)(10)3  (5)(10)(45)2  101.667  103 mm 4 12 12 I  I1  4 I 2  3.82  106 mm 4  3.82  106 mm 4 , c  50 mm  0.050 m  (b) Without the ears: Mc I M I c   9.168  103 N  m I  I1  3.4133  106 m 2 , M I c  (120  106 )(3.82  106 ) 0.050  9.17 kN  m  c  40 mm  0.040 m (120  106 )(3.4133  106 )  10.24  103 N  m 0.040  10.24 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 473 0.1 in. PROBLEM 4.26 0.2 in. A thick-walled pipe is bent about a horizontal axis by a couple M. The pipe may be designed with or without four fins. (a) Using an allowable stress of 20 ksi, determine the largest couple that may be applied if the pipe is designed with four fins as shown. (b) Solve part a, assuming that the pipe is designed with no fins. 1.5 in. M 0.75 in. SOLUTION I x of hollow pipe: I x of fins: Ix   (1.5 in.) 4  (0.75 in.) 4   3.7276 in 4 4  1  1  I x  2  (0.1)(0.2)3  (0.1  0.2)(1.6)2   2  (0.2)(0.1)3  12 12      0.1026 in 4 (a) Pipe as designed, with fins: I x  3.8302 in 4 ,  all  20 ksi, (b) Pipe with no fins:  all  20 ksi, M   all c  1.7 in. M   all Ix 3.8302 in 4  (20 ksi) 1.7 in. c I x  3.7276 in 4 , Ix 3.7276 in 4  (20 ksi) 1.5 in. c M  45.1 kip  in.  c  1.5 in. M  49.7 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 474 PROBLEM 4.27 A couple M will be applied to a beam of rectangular cross section that is to be sawed from a log of circular cross section. Determine the ratio d/b for which (a) the maximum stress m will be as small as possible, (b) the radius of curvature of the beam will be maximum. M M' d b SOLUTION Let D be the diameter of the log. D 2  b2  d 2 I  (a) 1 bd 3 12 c m is the minimum when d 2  D 2  b2 I is maximum. c I 1  b( D 2  b 2 ) 6 c d I 1 2   D  db  c  6 d  (b)   I 1  bd 2 c 6 1 d 2 D2   1 2 1 D b  b3 6 6 3 2 b 0 6 1 2 D  3 b 1 D 3 2 D 3 d  b 2  d  b 3  EI M  is maximum when I is maximum, 1 bd 3 is maximum, or b2d 6 is maximum. 12 ( D 2  d 2 )d 6 is maximum. 6D2d 5  8d 7  0 b D2  d  3 2 1 D  D 4 2 3 D 2 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 475 PROBLEM 4.28 h0 M h C h0 SOLUTION h A portion of a square bar is removed by milling, so that its cross section is as shown. The bar is then bent about its horizontal axis by a couple M. Considering the case where h  0.9h0, express the maximum stress in the bar in the form  m  k 0 , where  0 is the maximum stress that would have occurred if the original square bar had been bent by the same couple M, and determine the value of k. I  4 I1  2 I 2  1  1  (4)   h h3  (2)   (2h0  2h)(h3 )  12  3 1 4 4 4  h 4  h 0 h3  h h3  h 0 h3  h 4 3 3 3 3 ch Mc Mh 3M    4 h h3  h 4 (4h 0  3h) h 2 I 3 0 For the original square, h  h0 , c  h0 . 0  3M 3M  3 2 h0 (4h0  3h0 )h0 h03 h03     0.950  0 (4h0  3h)h 2 (4h0  (3)(0.9)h0 )(0.9 h02 )   0.950  0 k  0.950  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 476 PROBLEM 4.29 h0 M In Prob. 4.28, determine (a) the value of h for which the maximum stress  m is as small as possible, (b) the corresponding value of k. h PROBLEM 4.28 A portion of a square bar is removed by milling, so that its cross section is as shown. The bar is then bent about its horizontal axis by a couple M. Considering the case where h  0.9h0, express the maximum stress in the bar in the form  m  k 0 , where  0 is the maximum stress that would have occurred if the original square bar had been bent by the same couple M, and determine the value of k. C h h0 SOLUTION I  4 I1  2 I 2  1  1  (4)   hh3  (2)   (2h0  2h) h3 12   3 1 4 4 4  h 4  h 0 h3  h3  h 0 h 3  h 4 3 3 3 3 I 4 2 3 ch  h0 h  h c 3 d 4 I  is maximum at h 0 h 2  h3   0.  c dh  3  8 h 0 h  3h 2  0 3  256 3 I 4 8  8   h0  h0    h0   h0 729 c 3 9  9  For the original square, 2 h  h0 3 c  h0 0  h  Mc 729M   I 256h03 8 h 0  9 I0 1 3  h0 c0 3 Mc0 3M  2 I0 h0  729 1 729     0.949  0 256 3 768 k  0.949  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 477 PROBLEM 4.30 For the bar and loading of Concept Application 4.1, determine (a) the radius of curvature  , (b) the radius of curvature   of a transverse cross section, (c) the angle between the sides of the bar that were originally vertical. Use E  29  106 psi and v  0.29. SOLUTION M  30 kip  in. From Example 4.01, (a) (b)  1  (30  103 ) M   993  106 in.1 EI (29  106 )(1.042)  1  v   vc v I  1.042 in 4   1007 in.   c 1 1  v  (0.29)(993  106 )in.1  288  106 in.1   (c)  length of arc b 0.8    230  106 rad   3470 radius    3470 in.    0.01320  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 478 PROBLEM 4.31 y A z M A W200  31.3 rolled-steel beam is subjected to 45 kN  m. Knowing that E  200 GPa and v  radius of curvature  , (b) the radius of curvature section. a couple M of moment 0.29, determine (a) the   of a transverse cross C x SOLUTION For W 200  31.3 rolled steel section, I  31.3  106 mm 4  31.3  10 6 m 4 (a) (b)  1  45  103 M   7.1885  103 m 1 EI (200  109 )(31.3  106 ) 1 1  v  (0.29)(7.1885  103 )  2.0847  103 m 1     139.1 m     480 m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 479 PROBLEM 4.32 y ␪ 2 y ⫽ ⫹c ␴y It was assumed in Sec. 4.1B that the normal stresses  y in a member in pure bending are negligible. For an initially straight elastic member of rectangular cross section, (a) derive an approximate expression for  y as a function of y, (b) show that ( y )max  (c /2  )( x ) max and, thus, that  y can be neglected in all practical situations. (Hint: Consider the free-body diagram of the portion of beam located below the surface of ordinate y and assume that the distribution of the stress  x is still linear.) ␪ 2 ␴y ␴x ␴x ␪ 2 ␪ 2 y ⫽ ⫺c SOLUTION Denote the width of the beam by b and the length by L.  cos Using the free body diagram above, with Fy  0 : y   But, (a) y  ( x )max c   y bL  2 2  sin 2 L  x  ( x )max y c y dy  ( x )max y 2 c 2  y c   2 y c  L 1  x b dy sin  x dy   L   2 y c 0  x dy    1 y c  x dy y c y  y c The maximum value  y occurs at y  0 . ( y )max   (b) ( x ) max 2 ( y  c 2 )  2 c ( x )max c 2 ( ) c   x max  2c 2 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 480 PROBLEM 4.33 Brass 6 mm A bar having the cross section shown has been formed by securely bonding brass and aluminum stock. Using the data given below, determine the largest permissible bending moment when the composite bar is bent about a horizontal axis. Aluminum 30 mm 6 mm Aluminum Brass 70 GPa 105 GPa 100 MPa 160 MPa Modulus of elasticity 30 mm Allowable stress SOLUTION Use aluminum as the reference material. n  1.0 in aluminum n  Eb /Ea  105/70  1.5 in brass For the transformed section, I1  n1 b1h13  n1 A1d 12 12 1.5  (30)(6)3  (1.5)(30)(6)(18)3  88.29  103 mm 4 12 I2  n2 1.0 b2h23  (30)(30)3  67.5  103 mm 4 12 12 I 3  I1  88.29  103 mm 4 I  I1  I 2  I 3  244.08  103 mm 4   Aluminum: M  I ny y  15 mm  0.015 m,   100  106 Pa (100  106 )(244.08  10 9 )  1.627  103 N  m (1.0)(0.015) n  1.5, M Choose the smaller value nMy I n  1.0, M Brass:  244.08  109 m4 y  21 mm  0.021 m,   160  106 Pa (160  106 )(244.08  10 9 )  1.240  103 N  m (1.5)(0.021) M  1.240  103 N  m 1.240 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 481 PROBLEM 4.34 8 mm 8 mm 32 mm 8 mm 32 mm A bar having the cross section shown has been formed by securely bonding brass and aluminum stock. Using the data given below, determine the largest permissible bending moment when the composite bar is bent about a horizontal axis. 8 mm Brass Aluminum Brass 70 GPa 105 GPa 100 MPa 160 MPa Modulus of elasticity Aluminum Allowable stress SOLUTION Use aluminum as the reference material. For aluminum, n  1.0 For brass, n  Eb /Ea  105/70  1.5 Values of n are shown on the sketch. For the transformed section, I1  n1 1.5 b1h13  (8)(32)3  32.768  103 mm 4 12 12 n2 1.0 I 2  b2 H 23  h23  (32)(323  163 )  76.459  103 mm 4 12 12 I 3  I1  32.768  103 mm 4   I  I1  I 2  I 3  141.995  103 mm 4  141.995  109 m 4 | |  Aluminum: M I ny n  1.0, | y |  16 mm  0.016 m,   100  106 Pa M Brass: nMy I (100  106 )(141.995  109 )  887.47 N  m (1.0)(0.016) n  1.5, | y |  16 mm  0.016 m,   160  106 Pa M (160  106 )(141.995  109 )  946.63 N  m (1.5)(0.016) Choose the smaller value. M  887 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 482 PROBLEM 4.35 Brass 6 mm For the composite bar indicated, determine the largest permissible bending moment when the bar is bent about a vertical axis. 30 mm PROBLEM 4.35. Bar of Prob. 4.33. Aluminum Modulus of elasticity 6 mm Allowable stress 30 mm Aluminum Brass 70 GPa 105 GPa 100 MPa 160 MPa SOLUTION Use aluminum as reference material. n  1.0 in aluminum n  Eb /Ea  105/70  1.5 in brass For transformed section, I1  n1 b1h13 12 1.5 (6)(30)3  20.25  103 mm 4  12 I2  n2 b2h23 12 1.0 (30)(30)3  67.5  103 mm 4  12 I3  I1  20.25  103 mm 4 I  I1  I 2  I 3  108  103 mm 4  108  10 9 m 4   Aluminum: n  1.0, M Brass: nMy I I ny y  15 mm  0.015 m,   100  106 Pa (100  106 )(108  10 9 )  720 N  m (1.0)(0.015) n  1.5, M  M  y  15 mm  0.015 m,   160  106 Pa (160  106 )(108  109 )  768 N  m (1.5)(0.015) Choose the smaller value. M  720 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 483 PROBLEM 4.36 8 mm 8 mm 32 mm 8 mm For the composite bar indicated, determine the largest permissible bending moment when the bar is bent about a vertical axis. PROBLEM 4.36 Bar of Prob. 4.34. 32 mm 8 mm Brass Modulus of elasticity Allowable stress Aluminum Aluminum 70 GPa 100 MPa Brass 105 GPa 160 MPa SOLUTION Use aluminum as the reference material. For aluminum, n  1.0 For brass, n  Eb /Ea  105/70  1.5 Values of n are shown on the sketch.  For the transformed section, I1   n1 1.5 (32)(483  323 )  311.296  103 mm 4 h1 B13  b13  12 12 n2 1.0 I 2  h2b23  (8)(32)3  21.8453  103 mm 4 12 12 I 3  I 2  21.8453  103 mm 4 I  I1  I 2  I 3  354.99  103 mm 4  354.99  109 m 4 | |  Aluminum: I ny (100  106 )(354.99  109 )  2.2187  103 N  m (1.0)(0.016) n  1.5 | y |  24 mm  0.024 m   160  106 Pa M Choose the smaller value. M n  1.0, | y |  16 mm  0.016 m,   100  106 Pa M Brass: nMy I (160  106 )(354.99  109 )  1.57773  103 N  m (1.5)(0.024) M  1.57773  103 N  m M  1.578 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 484 PROBLEM 4.37 1 5 3 2 in. Wooden beams and steel plates are securely bolted together to form the composite member shown. Using the data given below, determine the largest permissible bending moment when the member is bent about a horizontal axis. 10 in. Wood 1 5 3 2 in. Modulus of elasticity: 6 in. Allowable stress: Steel 2  106 psi 29  106 psi 2000 psi 22 ksi SOLUTION Use wood as the reference material. n  1.0 in wood n  Es /Ew  29/2  14.5 in steel For the transformed section, I1  n1 b1h13  n1 A1d12 12 14.5  1  1 (5)    (14.5)(5)   (5.25)2  999.36 in 4 12 2   2 n 1.0 (6)(10)3  500 in 4 I 2  2 b2 h22  12 12 I 3  I1  999.36 in 4  3 I  I1  I 2  I 3  2498.7 in 4   Wood: Steel: nMy I  M  n  1.0, M  ny y  5 in.,   2000 psi (2000)(2499)  999.5  103 lb  in. (1.0)(5) n  14.5, M  I y  5.5 in.,   22 ksi  22  103 psi (22  103 )(2499)  689.3  103 lb  in. (14.5)(5.5) Choose the smaller value. M  689  103 lb  in. M  689 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 485 PROBLEM 4.38 10 in. Wooden beams and steel plates are securely bolted together to form the composite member shown. Using the data given below, determine the largest permissible bending moment when the member is bent about a horizontal axis. Wood 3 in. 1 2 3 in. Modulus of elasticity: in. Allowable stress: Steel 2  106 psi 29  106 psi 2000 psi 22 ksi SOLUTION Use wood as the reference material. n  1.0 in wood n  Es /Ew  29/2  14.5 in steel For the transformed section, I1  n1 1.0 (3)(10)3  250 in 4 b1h13  12 12 n 14.5  1  I 2  2 b2 h23  (10)3  604.17 in 4   12 12  2  I 3  I1  250 in 4   Wood: Steel: nMy I  M  n  1.0, M  ny y  5 in.,   2000 psi (2000)(1104.2)  441.7  103 lb  in. (1.0)(5) n  14.5, M  I I  I1  I 2  I 3  1104.2 in 4 y  5 in.,   22 ksi  22  103 psi (22  103 )(1104.2)  335.1  103 lb  in. (14.5)(5) Choose the smaller value. M  335  103 lb  in. M  335 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 486 PROBLEM 4.39 A copper strip (Ec = 105 GPa) and an aluminum strip (Ea = 75 GPa) are bonded together to form the composite beam shown. Knowing that the beam is bent about a horizontal axis by a couple of moment M = 35 N  m, determine the maximum stress in (a) the aluminum strip, (b) the copper strip. SOLUTION Use aluminum as the reference material. n  1.0 in aluminum n  Ec /Ea  105/75  1.4 in copper Transformed section:   A, mm2 nA, mm 2 y0 , mm nAy0 , mm3 144 144 9 1296 144 201.6 3 Σ Y0  345.6 604.8 1900.8 1900.8  5.50 mm 345.6 The neutral axis lies 5.50 mm above the bottom. I1  n1 1.0 b1h13  n1 A1d12  (24)(6)3  (1.0)(24)(6)(3.5) 2  2196 mm 4 12 12 n 1.4 (24)(6)3  (1.4)(24)(6)(2.5)2  1864.8 mm 4 I 2  2 b2 h23  n2 A2 d 22  12 12 I  I1  I 2  4060.8 mm 4  4.0608  109 m 4 (a) (b) Aluminum: Copper: n  1.0,   nMy (1.0)(35)(0.0065)   56.0  106 Pa  56.0 MPa 9 I 4.0608  10 n  1.4,   y  12  5.5  6.5 mm  0.0065 m y  5.5 mm  0.0055 m   56.0 MPa  nMy (1.4)(35)(0.0055)   66.4  106 Pa  66.4 MPa I 4.0608  109   66.4 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 487 PROBLEM 4.40 A copper strip (Ec = 105 GPa) and an aluminum strip (Ea = 75 GPa) are bonded together to form the composite beam shown. Knowing that the beam is bent about a horizontal axis by a couple of moment M = 35 N  m, determine the maximum stress in (a) the aluminum strip, (b) the copper strip. SOLUTION Use aluminum as the reference material. n  1.0 in aluminum n  Ec /Ea  105/75  1.4 in copper Transformed section:   A, mm2 nA, mm 2 Ay0 , mm nAy0 , mm3 216 216 7.5 1620 72 100.8 1.5 Σ Y0  316.8 151.8 1771.2 1771.2  5.5909 mm 316.8 The neutral axis lies 5.5909 mm above the bottom. I1  n1 1.0 b1h13  n1 A1d12  (24)(9)3  (1.0)(24)(9)(1.9091) 2  2245.2 mm 4 12 12 n 1.4 I 2  2 b2 h23  n2 A2 d 22  (24)(3)3  (1.4)(24)(3)(4.0909)2  1762.5 mm 4 12 12 I  I1  I 2  4839 mm 4  4.008  109 m 4 (a) (b)  Aluminum: Copper:  n  1.0,   y  12  5.5909  6.4091 mm  0.0064091 nMy (1.0)(35)(0.0064091)   56.0  106 Pa I 4.008  109  56.0 MPa n  1.4, y  5.5909 mm  0.0055909 m  nMy (1.4)(35)(0.0055909)   68.4  106 Pa   9 I 4.008  10  68.4 MPa   56.0 MPa     68.4 MPa   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 488 PROBLEM 4.41 6 in. M 12 in. 53 1 2 The 6  12-in. timber beam has been strengthened by bolting to it the steel reinforcement shown. The modulus of elasticity for wood is 1.8  106 psi and for steel, 29  106 psi. Knowing that the beam is bent about a horizontal axis by a couple of moment M  450 kip  in., determine the maximum stress in (a) the wood, (b) the steel. in. SOLUTION Use wood as the reference material. For wood, For steel, Transformed section: 421.931 Yo  112.278  3.758 in. n 1 n  Es /Ew  29 / 1.8  16.1111   wood    steel A, in 2 nA, in 2 72 72  2.5 40.278 y0 6 0.25 112.278 nA y0 , in 3 432 10.069 421.931 The neutral axis lies 3.758 in. above the wood-steel interface. I1  n1 1 b1h13  n1 A1d12  (6)(12)3  (72)(6  3.758) 2  1225.91 in 4 12 12 n2 16.1111 I 2  b2 h23  n2 A2 d 22  (5)(0.5)3  (40.278)(3.578  0.25)2  647.87 in 4 12 12 I  I1  I 2  1873.77 in 4 M  450 kip  in. (a) Wood: n  1,   y  12  3.758  8.242 in. w   (b) Steel: (1)(450)(8.242)  1.979 ksi 1873.77 n  16.1111, s   nMy I y  3.758  0.5  4.258 in. (16.1111)(450)(4.258)  16.48 ksi 1873.77  w  1.979 ksi   s  16.48 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 489 PROBLEM 4.42 6 in. M 12 in. The 6  12-in. timber beam has been strengthened by bolting to it the steel reinforcement shown. The modulus of elasticity for wood is 1.8  106 psi and for steel, 29  106 psi. Knowing that the beam is bent about a horizontal axis by a couple of moment M  450 kip  in., determine the maximum stress in (a) the wood, (b) the steel. C8 11.5 SOLUTION For wood, Use wood as the reference material. For steel, n 1 n Es 29  106   16.1111 Ew 1.8  106 For C8  11.5 channel section, A  3.38 in 2 , tw  0.220 in., x  0.571 in., I y  1.32 in 4 For the composite section, the centroid of the channel (part 1) lies 0.571 in. above the bottom of the section. The centroid of the wood (part 2) lies 0.220  6.00  6.22 in. above the bottom. Transformed section: A, in2 3.38 Part 1 72 2  Y0  nA, in2 54.456 y , in. 0.571 nAy , in 3 31.091 d, in. 3.216 72 6.22 447.84 2.433 478.93 126.456 d  y0  Y0 478.93 in 3  3.787 in. 126.456 in 2 The neutral axis lies 3.787 in. above the bottom of the section. I1  n1 I1  n1 A1d12  (16.1111)(1.32)  (54.456)(3.216) 2  584.49 in 4 I2  n2 1 b2 h23  n2 A2 d 22  (6)(12)3  (72)(2.433) 2  1290.20 in 4 12 12 I  I1  I 2  1874.69 in 4 M  450 kip  in (a) (b) Wood: Steel: n  1, w     n My I y  12  0.220  3.787  8.433 in. (1)(450)(8.433)  2.02 ksi 1874.69 n  16.1111, y  3.787 in. s   (16.1111)(450)(3.787)  14.65 ksi 1874.67  w  2.02 ksi   s  14.65 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 490 PROBLEM 4.43 Aluminum Copper 6 mm 6 mm For the composite beam indicated, determine the radius of curvature caused by the couple of moment 35 N  m. Beam of Prob. 4.39. 24 mm SOLUTION See solution to Prob. 4.39 for the calculation of I.  1  35 M   0.1149 m 1 9 Ea I (75  10 )(4.0608  109 )   8.70 m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 491 PROBLEM 4.44 Aluminum 9 mm Copper 3 mm For the composite beam indicated, determine the radius of curvature caused by the couple of moment 35 N  m. Beam of Prob. 4.40. 24 mm SOLUTION See solution to Prob. 4.40 for the calculation of I.  1  M 35   0.1164 m 1 Ea I (75  109 )(4.008  109 )   8.59 m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 492 6 in. PROBLEM 4.45 M 12 in. For the composite beam indicated, determine the radius of curvature caused by the couple of moment 450 kip  in. Beam of Prob. 4.41. 53 1 2 in. SOLUTION See solution to Prob. 4.41 for calculation of I. I  1873.77 in 4 Ew  1.8  106 psi M  450 kip  in  450  103 lb  in.  1  M 450  103   133.421  106 in.1 6 EI (1.8  10 )(1873.77)   7495 in.  625 ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 493 6 in. PROBLEM 4.46 M 12 in. For the composite beam indicated, determine the radius of curvature caused by the couple of moment 450 kip  in. Beam of Prob. 4.42. C8 11.5 SOLUTION See solution to Prob. 4.42 for calculation of I. I  1874.69 in 4 Ew  1.8  106 psi M  450 kip  in.  450  103 lb  in.  1  M 450  103   133.355  106 in.1 EI (1.8  106 )(1874.69)   7499 in.  625 ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 494 PROBLEM 4.47 5 8 -in. diameter 4 in. 5.5 in. 5.5 in. A concrete slab is reinforced by 85 -in.-diameter steel rods placed on 5.5-in. centers as shown. The modulus of elasticity is 3  106 psi for the concrete and 29  106 psi for the steel. Using an allowable stress of 1400 psi for the concrete and 20 ksi for the steel, determine the largest bending moment in a portion of slab 1 ft wide. 5.5 in. 6 in. 5.5 in. SOLUTION n Es 29  106   9.6667 Ec 3  106 Consider a section 5.5 in. wide. As   4 d s2   5  0.3068 in 2 4  8  2 nAs  2.9657 in 2 Locate the natural axis. 5.5 x x  (4  x )(2.9657)  0 2 2.75 x 2  2.9657 x  11.8628  0 Solve for x. x  1.6066 in. 4  x  2.3934 in. 1 I  (5.5) x3  (2.9657)(4  x)2 3 1  (5.5)(1.6066)3  (2.9657)(2.3934) 2  24.591 in 4 3   nMy I Concrete: n  1, M  M  I ny y  1.6066 in.,   1400 psi (24.591)(1400)  21.429  103 lb  in. (1.0)(1.6066) PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 495 PROBLEM 4.47 (Continued) Steel: n  9.6667, M  y  2.3934 in.,   20 ksi=20  103 psi (24.591)(20  103 )  21.258  103 lb  in. (9.6667)(2.3934) Choose the smaller value as the allowable moment for a 5.5 in. width. M  21.258  103 lb  in. For a 1 ft = 12 in. width, M  12 (21.258  103 )  46.38  103 lb  in. 5.5 M  46.38 kip  in. 3.87 kip  ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 496 PROBLEM 4.48 5 8 -in. diameter Solve Prob. 4.47, assuming that the spacing of the 85 -in.-diameter steel rods is increased to 7.5 in. 4 in. PROBLEM 4.47 A concrete slab is reinforced by 85 -in.-diameter steel rods placed on 5.5-in. centers as shown. The modulus of elasticity is 3 × 106 psi for the concrete and 29  106 psi for the steel. Using an allowable stress of 1400 psi for the concrete and 20 ksi for the steel, determine the largest bending moment in a portion of slab 1 ft wide. 5.5 in. 5.5 in. 5.5 in. 6 in. 5.5 in. SOLUTION n Number of rails per foot:  Es 29  106 psi   9.667 Ec 3  106 psi 12 in.  1.6 7.5 in. 5  5 Area of -in.-diameter bars per foot: 1.6   4 8 8 As  0.4909 in 2 2 Transformed section, all concrete. First moment of area: x 12 x    4.745(4  x)  0 2 x  1.4266 in. nAs  9.667(0.4909)  4.745 in 2 1 I NA  (12)(1.4266)3  4.745(4  1.4266)2  43.037 in 4 3 For concrete:  all  1400 psi c  x  1.4266 in. M  For steel: 43.037 in 4 1.4266 in.  all  20 ksi c  4  x  4  1.4266  2.5734 in. M We choose the smaller M. I  (1400 psi) c  steel I n  c  20 ksi 43.042 in 4  9.667 2.5734 in. M  34.60 kip  in. M  42.24 kip.in.  M  34.60 kip  in.  M  2.88 kip  ft  Steel controls. PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 497 PROBLEM 4.49 540 mm The reinforced concrete beam shown is subjected to a positive bending moment of 175 kN  m. Knowing that the modulus of elasticity is 25 GPa for the concrete and 200 GPa for the steel, determine (a) the stress in the steel, (b) the maximum stress in the concrete. 25-mm diameter 60 mm 300 mm SOLUTION n Es 200 GPa   8.0 25 GPa Ec As  4   4   d 2  (4)   (25) 2  1.9635  103 mm 2 4 nAs  15.708  103 mm 2 Locate the neutral axis. x  (15.708  103 )(480  x)  0 2 150 x 2  15.708  103 x  7.5398  106  0 300 x Solve for x. 15.708  103  (15.708  103 ) 2  (4)(150)(7.5398  106 ) (2)(150) x  177.87 mm, 480  x  302.13 mm x 1 I  (300) x3  (15.708  103 )(480  x) 2 3 1  (300)(177.87)3  (15.708  103 )(302.13) 2 3  1.9966  109 mm 4  1.9966  103 m 4   (a) Steel: y  302.45 mm  0.30245 m   (b) Concrete: nMy I (8.0)(175  103 )(0.30245)  212  106 Pa 3 1.9966  10   212 MPa  y  177.87 mm  0.17787 m   (1.0)(175  103 )(0.17787)  15.59  106 Pa 1.9966  103   15.59 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 498 PROBLEM 4.50 540 mm 25-mm diameter 60 mm 300 mm Solve Prob. 4.49, assuming that the 300-mm width is increased to 350 mm. PROBLEM 4.49 The reinforced concrete beam shown is subjected to a positive bending moment of 175 kN  m. Knowing that the modulus of elasticity is 25 GPa for the concrete and 200 GPa for the steel, determine (a) the stress in the steel, (b) the maximum stress in the concrete. SOLUTION n Es 200 GPa   8.0 25 GPa Ec As  4  4   d 2  (4)   (25) 2 4  1.9635  103 mm 2 nAs  15.708  103 mm 2 Locate the neutral axis. x  (15.708  103 )(480  x)  0 2 175 x 2  15.708  103 x  7.5398  106  0 350 x Solve for x. 15.708  103  (15.708  103 ) 2  (4)(175)(7.5398  106 ) (2)(175) x  167.48 mm, 480  x  312.52 mm x 1 I  (350) x3  (15.708  103 )(480  x)2 3 1  (350)(167.48)3  (15.708  103 )(312.52) 2 3  2.0823  109 mm 4  2.0823  103 m 4 nMy   I (a) Steel: y  312.52 mm  0.31252 m   (b) Concrete: (8.0)(175  103 )(0.31252)  210  106 Pa 3 2.0823  10   210 MPa  y  167.48 mm  0.16748 m   (1.0)(175  103 )(0.16748)  14.08  106 Pa 2.0823  103   14.08 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 499 4 in. 24 in. PROBLEM 4.51 Knowing that the bending moment in the reinforced concrete beam is 100 kip  ft and that the modulus of elasticity is 3.625  106 psi for the concrete and 29  106 psi for the steel, determine (a) the stress in the steel, (b) the maximum stress in the concrete. 20 in. 1-in. diameter 2.5 in. 12 in. SOLUTION n 29  106 Es   8.0 Ec 3.625  106   As  (4)   (1)2  3.1416 in 2 4 nAs  25.133 in  2 Locate the neutral axis.  x (24)(4)( x  2)  (12 x)    (25.133)(17.5  4  x)  0 2 96 x  192  6 x 2  339.3  25.133x  0 x Solve for x. or 6 x 2  121.133x  147.3  0 121.133  (121.133)2  (4)(6)(147.3)  1.150 in. (2)(6) d3  17.5  4  x  12.350 in. I1  1 1 b1h13  A1d12  (24)(4)3  (24)(4)(3.150) 2  1080.6 in 4 12 12 1 3 1 I 2  b2 x  (12)(1.150)3  6.1 in 4 3 3 I 3  nA3d32  (25.133)(12.350) 2  3833.3 in 4 I  I1  I 2  I 3  4920 in 4   nMy I (a) Steel: n  8.0 (b) Concrete: n  1.0, c   where M  100 kip  ft  1200 kip  in. s   y  12.350 in. (8.0)(1200)(12.350) 4920  s  24.1 ksi  y  4  1.150  5.150 in. (1.0)(1200)(5.150) 4920  c  1.256 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 500 PROBLEM 4.52 7 8 16 in. -in. diameter 2 in. A concrete beam is reinforced by three steel rods placed as shown. The modulus of elasticity is 3  106 psi for the concrete and 29  106 psi for the steel. Using an allowable stress of 1350 psi for the concrete and 20 ksi for the steel, determine the largest allowable positive bending moment in the beam. 8 in. SOLUTION n Es 29  10 6   9.67 Ec 3  106 As  3     7  d 2  (3)     1.8040 in 2 4  4  8  2 nAs  17.438 in 2 x  (17.438)(14  x)  0 2 4 x 2  17.438 x  244.14  0 8x Locate the neutral axis: Solve for x. x 17.438  17.4382  (4)(4)(244.14)  5.6326 in. (2)(4) 14  x  8.3674 in. I    1 3 1 8 x  nAs (14  x)2  (8)(5.6326)3  (17.438)(8.3674)2  1697.45 in 4 3 3 nMy I  M I ny Concrete: n  1.0, M  M  Choose the smaller value.   1350 psi (1350)(1697.45)  406.835  103 lb  in.  407 kip  in. (1.0)(5.6326) n  9.67, Steel: y  5.6326 in., y  8.3674 in.,   20  103 psi (20  103 )(1697.45)  419.72 lb  in.  420 kip  in. (9.67)(8.3674) M  407 kip  in. M  33.9 kip  ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 501 PROBLEM 4.53 d The design of a reinforced concrete beam is said to be balanced if the maximum stresses in the steel and concrete are equal, respectively, to the allowable stresses  s and  c . Show that to achieve a balanced design the distance x from the top of the beam to the neutral axis must be x b 1  s Ec  c Es d where Ec and Es are the moduli of elasticity of concrete and steel, respectively, and d is the distance from the top of the beam to the reinforcing steel. SOLUTION nM (d  x) Mx c  I I  s n(d  x) d  n n x x c s  E d 1 s 1 1 c s x n c Es  c x  d Ec s 1 Es  c PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 502 PROBLEM 4.54 d For the concrete beam shown, the modulus of elasticity is 25 GPa for the concrete and 200 GPa for the steel. Knowing that b = 200 mm and d = 450 mm, and using an allowable stress of 12.5 MPa for the concrete and 140 MPa for the steel, determine (a) the required area As of the steel reinforcement if the beam is to be balanced, (b) the largest allowable bending moment. (See Prob. 4.53 for definition of a balanced beam.) b SOLUTION Es 200  109   8.0 Ec 25  109 nM (d  x) Mx s  c  I I  s n( d  x ) d  n n x x c n d 1 s 1 140  106 1 1   2.40 x n c 8.0 12.5  106 x  0.41667d  (0.41667)(450)  187.5 mm bx Locate neutral axis. As  (a) x  nAs (d  x) 2 bx 2 (200)(187.5) 2   1674 mm 2 2n(d  x) (2)(8.0)(262.5) As  1674 mm 2  1 1 I  bx3  nAs (d  x)2  (200)(187.5)3  (8.0)(1674)(262.5) 2 3 3 9 4  1.3623  10 mm  1.3623  103 m 4 nMy I M  I ny (b) n  1.0 Concrete: M M   12.5  106 Pa y  262.5 mm  0.2625 m   140  106 Pa (1.3623  103 )(12.5  106 )  90.8  103 N  m (1.0)(0.1875) n  8.0 Steel: y  187.5 mm  0.1875 m (1.3623  103 )(140  106 )  90.8  103 N  m (8.0)(0.2625) Note that both values are the same for balanced design. M  90.8 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 503 Aluminum 0.5 in. Brass 0.5 in. Steel 0.5 in. Brass 0.5 in. Aluminum 0.5 in. 1.5 in. PROBLEM 4.55 Five metal strips, each a 0.5 × 1.5-in. cross section, are bonded together to form the composite beam shown. The modulus of elasticity is 30 × 106 psi for the steel, 15 × 106 psi for the brass, and 10 × 106 psi for the aluminum. Knowing that the beam is bent about a horizontal axis by a couple of moment 12 kip  in., determine (a) the maximum stress in each of the three metals, (b) the radius of curvature of the composite beam. SOLUTION Use aluminum as the reference material. n Es 30  106   3.0 in steel Ea 10  106 Eb 15  106   1.5 in brass Ea 10  106 n  1.0 in aluminum n For the transformed section, I1  n1 1 b1h13  n1 A1d12  (1.5)(0.5)3  (0.75)(1.0) 2 12 12 4  0.7656 in I2  n2 1.5 (1.5)(0.5)3  (1.5)(0.75)(0.5)2  0.3047 in 4 b2 h23  n2 A2 d 22  12 12 n 3.0 (1.5)(0.5)3  0.0469 in 4 I 3  3 b3 h33  12 12 I 4  I 2  0.3047 in 4 I 5  I1  0.7656 in 4 I (a) i  2.1875 in 4 1 Aluminum:  nMy (1.0)(12)(1.25)   6.86 ksi I 2.1875  Brass:  nMy (1.5)(12)(0.75)   6.17 ksi I 2.1875  Steel:  nMy (3.0)(12)(0.25)   4.11 ksi I 2.1875   1 (b)  I 5   12  103 M   548.57  106 in.1 Ea I (10  106 )(2.1875)   1823 in. = 151.9 ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 504 Steel 0.5 in. Aluminum 0.5 in. Brass 0.5 in. Aluminum 0.5 in. Steel 0.5 in. 1.5 in. PROBLEM 4.56 Five metal strips, each a 0.5 × 1.5-in. cross section, are bonded together to form the composite beam shown. The modulus of elasticity is 30 × 106 psi for the steel, 15 × 106 psi for the brass, and 10 × 106 psi for the aluminum. Knowing that the beam is bent about a horizontal axis by a couple of moment 12 kip · in., determine (a) the maximum stress in each of the three metals, (b) the radius of curvature of the composite beam. SOLUTION Use aluminum as the reference material. n Es 30  106   3.0 in steel Ea 10  106 Eb 15  106   1.5 in brass Ea 10  106 n  1.0 in aluminum n For the transformed section, I1  n1 b1h13  n1 A1d12 12 3.0  (1.5)(0.5)3  (3.0)(0.75)(1.0)2 12  2.2969 in 4 I2  n2 1.0 (1.5)(0.5)3  (1.0)(0.75)(0.5) 2  0.2031 in 4 b2 h23  n2 A2 d 22  12 12 n 1.5 (1.5)(0.5)3  0.0234 in 4 I 3  3 b3 h33  12 12 I 4  I 2  0.2031 in 4 I 5  I1  2.2969 in 4 I (a) 5 i  5.0234 in 4 1 Steel:  nMy (3.0)(12)(1.25)   8.96 ksi I 5.0234  Aluminum:  nMy (1.0)(12)(0.75)   1.792 ksi I 5.0234  Brass:  nMy (1.5)(12)(0.25)   0.896 ksi I 5.0234   1 (b)  I   12  103 M   238.89  106 in.1 Ea I (10  106 )(5.0234)   4186 in.  349 ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 505 PROBLEM 4.57 Brass 0.8 in. Aluminum The composite beam shown is formed by bonding together a brass rod and an aluminum rod of semicircular cross sections. The modulus of elasticity is 15  106 psi for the brass and 10  106 psi for the aluminum. Knowing that the composite beam is bent about a horizontal axis by couples of moment 8 kip  in., determine the maximum stress (a) in the brass, (b) in the aluminum. SOLUTION For each semicircle, y0  r  0.8 in.  A 2 4r (4)(0.8)   0.33953 in. 3 3 r 2  1.00531 in 2 , I base   8 r 4  0.160850 in 4 I  I base  Ay02  0.160850  (1.00531)(0.33953) 2  0.044953 in 4 Use aluminum as the reference material. n  1.0 in aluminum n Eb 15  106   1.5 in brass Ea 10  106 Locate the neutral axis.    A, in2 nA, in2 1.00531 1.50796 1.00531 1.00531 Y0  nAy0 , in 3 y0 , in. 0.33953 0.51200 0.33953 0.34133 2.51327 0.17067  0.06791 in. 2.51327 The neutral axis lies 0.06791 in. above the material interface. 0.17067 d1  0.33953  0.06791  0.27162 in., d 2  0.33953  0.06791  0.40744 in. I1  n1I  n1 Ad12  (1.5)(0.044957)  (1.5)(1.00531)(0.27162) 2  0.17869 in 4 I 2  n2 I  n2 Ad 22  (1.0)(0.044957)  (1.0)(1.00531)(0.40744)2  0.21185 in 4 I  I1  I 2  0.39054 in 4 (a) Brass: n  1.5, y  0.8  0.06791  0.73209 in.   (b) Aluminium: n  1.0, nMy (1.5)(8)(0.73209)  I 0.39054   22.5 ksi  nMy (1.0)(8)(0.86791)  I 0.39054   17.78 ksi  y  0.8  0.06791  0.86791 in.   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 506 y Aluminum PROBLEM 4.58 3 mm A steel pipe and an aluminum pipe are securely bonded together to form the composite beam shown. The modulus of elasticity is 200 GPa for the steel and 70 GPa for the aluminum. Knowing that the composite beam is bent by a couple of moment 500 N  m, determine the maximum stress (a) in the aluminum, (b) in the steel. Steel 6 mm z 10 mm 38 mm SOLUTION Use aluminum as the reference material. n  1.0 in aluminum n  Es / Ea  200 / 70  2.857 in steel For the transformed section, Steel: I s  ns Aluminium: I a  na r 4  4 o r 4  4 o     ri4  (2.857)   (164  104 )  124.62  103 mm 4 4     ri4  (1.0)   (194  164 )  50.88  103 mm 4 4 I  I s  I a  175.50  103 mm 4  175.5  109 m 4 (a) Aluminum: c  19 mm  0.019 m a  (b) Steel: na Mc (1.0)(500)(0.019)   54.1  106 Pa 9 I 175.5  10 c  16 mm  0.016 m s  ns Mc (2.857)(500)(0.016)   130.2  106 Pa 9 I 175.5  10  a  54.1 MPa   s  130.2 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 507 M PROBLEM 4.59 Et 100 mm 1 2 Ec 50 mm Ec The rectangular beam shown is made of a plastic for which the value of the modulus of elasticity in tension is one-half of its value in compression. For a bending moment M  600 N  m, determine the maximum (a) tensile stress, (b) compressive stress. SOLUTION n 1 on the tension side of neutral axis 2 n  1 on the compression side Locate neutral axis. n1bx x hx  n2 b(h  x) 0 2 2 1 2 1 bx  b(h  x) 2  0 2 4 x2  1 1 (h  x) 2 x  (h  x) 2 2 1 x h  0.41421 h  41.421 mm 2 1 h  x  58.579 mm 1 1 I1  n1 bx3  (1)   (50)(41.421)3  1.1844  106 mm 4 3  3 1  1  1  I 2  n2 b(h  x)3     (50)(58.579)3  1.6751  106 mm 4 3  2  3  I  I1  I 2  2.8595  106 mm 4  2.8595  106 m 4 (a) Tensile stress: n 1 , 2   (b) Compressive stress: n  1,   y  58.579 mm  0.058579 m nMy (0.5)(600)(0.058579)   6.15  106 Pa 6 I 2.8595  10  t  6.15 MPa  nMy (1.0)(600)(0.041421)   8.69  106 Pa 6 I 2.8595  10  c  8.69 MPa  y  41.421 mm  0.041421 m PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 508 PROBLEM 4.60* A rectangular beam is made of material for which the modulus of elasticity is Et in tension and Ec in compression. Show that the curvature of the beam in pure bending is  1  M Er I where Er  4 Et Ec ( Et  Ec ) 2 SOLUTION Use Et as the reference modulus. Then Ec  nEt . Locate neutral axis. x hx  b( h  x ) 0 2 2 nx 2  (h  x) 2  0 nx  (h  x) nbx x I trans  1 h n 1 hx nh n 1 3  h  1 3    3 n 3 1 n 3  bx  b(h  x)      bh    3  n  1   n  1   3 3      1 n  n3/ 2 1 n 1 n 1 3  bh bh3   3 3 3 n 1 3 n 1 3  M M  Et I trans Er I    where I  Er I  Et I trans Er   Et I trans 12  3  Et  I bh 3  4 Et Ec /Et   Ec /Et  1 2     n 1 2 bh3 1 3 bh 12 n  n 1 4 Et Ec  n Ec  Et  2 bh3 2 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 509 8 mm PROBLEM 4.61 Knowing that M  250 N  m, determine the maximum stress in the beam shown when the radius r of the fillets is (a) 4 mm, (b) 8 mm. r M 80 mm 40 mm SOLUTION I  1 3 1 bh  (8)(40)3  42.667  103 mm 4  42.667  109 m 4 12 12 c  20 mm  0.020 m D 80 mm   2.00 d 40 mm (a) 4 mm r   0.10 d 40 mm  max  K (b) Mc (1.87)(250)(0.020)   219  106 Pa I 42.667  109 8 mm r   0.20 d 40 mm  max  K K  1.87 From Fig. 4.27,  max  219 MPa  K  1.50 From Fig. 4.27, Mc (1.50)(250)(0.020)   176.0  106 Pa I 42.667  109  max  176.0 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 510 8 mm PROBLEM 4.62 r M 80 mm Knowing that the allowable stress for the beam shown is 90 MPa, determine the allowable bending moment M when the radius r of the fillets is (a) 8 mm, (b) 12 mm. 40 mm SOLUTION I  1 3 1 (8)(40)3  42.667  103 mm 4  42.667  109 m 4 bh  12 12 c  20 mm  0.020 m D 80 mm   2.00 d 40 mm (a) 8 mm r   0.2 d 40 mm  max  K (b) Mc I 12 mm r   0.3 d 40 mm K  1.50 From Fig. 4.27, M   max I Kc  (90  106 )(42.667  109 ) (1.50)(0.020) K  1.35 From Fig. 4.27, M  (90  106 )(42.667  109 ) (1.35)(0.020) M  128.0 N  m  M  142.0 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 511 r 4.5 in. 3 4 M in. PROBLEM 4.63 Semicircular grooves of radius r must be milled as shown in the sides of a steel member. Using an allowable stress of 8 ksi, determine the largest bending moment that can be applied to the member when (a) r = 83 in., (b) r = 34 in. SOLUTION (a) 3 d  D  2r  4.5  (2)    3.75 in. 8 D r 4.5 0.375   1.20   0.10 d d 3.75 3.75 From Fig. 4.28, K  2.07 1 3 1 3 1 3 4 bh  c   1.875 in.   (3.75)  3.296 in 12 12  4  2 (8)(3.296) I Mc  K  M    6.79 kip  in. I Kc (2.07)(1.875) I  (b) 3 d  D  2r  4.5  (2)    3.0 4 From Fig. 4.28, K  1.61 c D 4.5   1.5 d 3.0 I  1 d  1.5 in. 2   6.79 kip  in.  r 0.75   0.25 d 3.0 1 3 1 3 3 4 bh    (3.0)  1.6875 in 12 12  4  M  I Kc  (8)(1.6875)  5.59 kip  in. (1.61)(1.5)  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 512 3 4 r in. Semicircular grooves of radius r must be milled as shown in the sides of a steel member. Knowing that M = 4 kip · in., determine the maximum stress in the member when the radius r of the semicircular grooves is (a) r = 83 in., (b) r = 34 in. M 4.5 in. PROBLEM 4.64 SOLUTION 3 d  D  2r  4.5  (2)    3.75 in. 8 4.5 0.375 D r   1.20   0.10 3.75 3.75 d d (a) From Fig. 4.28, K  2.07 1 3 1 3 3 4 bh    (3.75)  3.296 in 12 12  4  Mc (2.07)(4)(1.875)   4.71 ksi  K I 3.296 I  (b) 3 d  D  2r  4.5  (2)    3.00 in. 4 From Fig. 4.28, K  1.61 I  D 4.5   1.50 d 3.00 1 3 1 3 3 4 bh    (3.00)  1.6875 in 12 12  4   K c Mc (1.61)(4)(1.5)   5.72 ksi I 1.6875 c 1  1.875 in. 2   4.71 ksi  r 0.75   0.25 d 3.0 1 d  1.5 in. 2   5.72 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 513 M PROBLEM 4.65 M 100 mm 100 mm 150 mm 150 mm 18 mm 18 mm (a) A couple of moment M = 2 kN · m is to be applied to the end of a steel bar. Determine the maximum stress in the bar (a) if the bar is designed with grooves having semicircular portions of radius r = 10 mm, as shown in Fig. a, (b) if the bar is redesigned by removing the material to the left and right of the dashed lines as shown in Fig. b. (b) SOLUTION For both configurations, D  150 mm d  100 mm r  10 mm D 150   1.50 100 d 10 r   0.10 d 100 For configuration (a), Fig. 4.28 gives For configuration (b), K a  2.21. Fig. 4.27 gives K b  1.79. I  1 3 1 (18)(100)3  1.5  106 mm 4  1.5  106 m 4 bh  12 12 1 c  d  50 mm  0.05 m 2 (a) (b)   KMc (2.21)(2  103 )(0.05)   147.0  106 Pa  147.0 MPa 6 I 1.5  10   KMc (1.79)(2  103 )(0.05)   119.0  106 Pa  119.0 MPa I 1.5  106   147.0 MPa    119.0 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 514 M PROBLEM 4.66 M 100 mm The allowable stress used in the design of a steel bar is 80 MPa. Determine the largest couple M that can be applied to the bar (a) if the bar is designed with grooves having semicircular portions of radius r  15 mm, as shown in Fig. a, (b) if the bar is redesigned by removing the material to the left and right of the dashed lines as shown in Fig. b. 100 mm 150 mm 150 mm 18 mm 18 mm (a) (b) SOLUTION For both configurations, D  150 mm r  15 mm d  100 mm D 150   1.50 d 100 r 15   0.15 d 100 For configuration (a), Fig. 4.28 gives K a  1.92. For configuration (b), Fig. 4.27 gives Kb  1.57. I  1 3 1 (18)(100)3  1.5  106 mm 4  1.5  106 m 4 bh  12 12 1 c  d  50 mm  0.050 m 2 (a) (a)   M  KMc  I I Kc  M  I Kc  (80  106 )(1.5  106 )  1.250  103 N  m (1.92)  (0.05)  1.250 kN  m (80  106 )(1.5  106 )  1.530  103 N  m  1.530 kN  m (1.57)(0.050)   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 515 M PROBLEM 4.67 The prismatic bar shown is made of a steel that is assumed to be elastoplastic with  Y  300 MPa and is subjected to a couple M parallel to the x axis. Determine the moment M of the couple for which (a) yield first occurs, (b) the elastic core of the bar is 4 mm thick. x z 12 mm 8 mm SOLUTION (a) I 1 3 1 bh  (12)(8)3  512 mm 4 12 12  512  1012 m 4 1 c  h  4 mm  0.004 m 2 Y I (300  106 )(512  1012 ) c 0.004  38.4 N  m MY  (b) yY  1 (4)  2 mm 2  yY 2   0.5 4 c  1  y 2  3 M  M Y 1   Y   2  3  c   3  1   (38.4) 1  (0.5) 2  2  3   52.8 N  m M Y  38.4 N  m  M  52.8 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 516 M PROBLEM 4.68 Solve Prob. 4.67, assuming that the couple M is parallel to the z axis. PROBLEM 4.67 The prismatic bar shown is made of a steel that is assumed to be elastoplastic with  Y  300 MPa and is subjected to a couple M parallel to the x axis. Determine the moment M of the couple for which (a) yield first occurs, (b) the elastic core of the bar is 4 mm thick. x z 12 mm 8 mm SOLUTION (a) I 1 3 1 bh  (8)(12)3  1.152  103 mm 4 12 12  1.152  109 m 4 1 c  h  6 mm  0.006 m 2 Y I (300  106 )(1.152  109 ) c 0.006  57.6 N  m MY  (b) yY  1 (4)  2 mm 2  yY 2 1   6 3 c M  3 MY 2 M Y  57.6 N  m   1  y 2  1   Y    3  c    1  1 2  3 (57.6) 1     2  3  3    83.2 N  m M  83.2 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 517 PROBLEM 4.69 A solid square rod of side 0.6 in. is made of a steel that is assumed to be elastoplastic with E = 29 × 106 psi and  Y  48 ksi. Knowing that a couple M is applied and maintained about an axis parallel to a side of the cross section, determine the moment M of the couple for which the radius of curvature is 6 ft. SOLUTION I  MY   max  1 (0.6)(0.6)3  10.8  103 in 4 12 c 1 h  0.3 in. 2 I Y (10.8  103 )(48  103 )   1728 lb  in. c 0.3  c  0.3  4.16667  103 72 Y  yY  1.65517  103  Y   0.39724 c M 4.16667  103 Y E    6 ft  72 in. 48  103  1.65517  103 29  106 2  1  YY   3 1 3   M  M Y 1      (1728) 1  (0.39724)2  3 c   2 3 2    M  2460 lb  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 518 PROBLEM 4.70 For the solid square rod of Prob. 4.69, determine the moment M for which the radius of curvature is 3 ft. PROBLEM 4.69. A solid square rod of side 0.6 in. is made of a steel that is assumed to be elastoplastic with E = 29 × 106 psi and  Y  48 ksi. Knowing that a couple M is applied and maintained about an axis parallel to a side of the cross section, determine the moment M of the couple for which the radius of curvature is 6 ft. SOLUTION I  MY   max  1 (0.6)(0.6)3  10.8  103 in 4 12 1 h  0.3 in. 2 (10.8  103 )(48  103 ) I Y   1728 lb  in. 0.3 c  c  0.3  8.3333  103 36 Y  1.65517  10 yY   Y   0.19862 c  max 8.3333  103 M  c 3 Y E    3 ft  36 in. 48  103  1.65517  103 29  106 2  3 1Y   3 1   M Y 1   Y    (1728) 1  (0.19862)2  2 3 2 3 c       M  2560 lb  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 519 y PROBLEM 4.71 18 mm The prismatic rod shown is made of a steel that is assumed to be elastoplastic with E  200 GPa and  Y  280 MPa . Knowing that couples M and M of moment 525 N · m are applied and maintained about axes parallel to the y axis, determine (a) the thickness of the elastic core, (b) the radius of curvature of the bar. M 24 mm M⬘ x SOLUTION I  1 3 1 bh  (24)(18)3  11.664  103 mm 4  11.664  103 m 4 12 12 1 c  h  9 mm  0.009 m 2 MY  M  yY  c Y I c Y  (280  106 )(11.664  109 )  362.88 N  m 0.009  3 1 yY 2  M Y 1   2 3 c2   3 (a) (b)   yY  yY  c or (2)(525)  0.32632 362.88 Y E    Y EyY 32 M MY yY  0.32632c  2.9368 mm  (200  109 )(2.9368  103 )  2.09 m 280  106 tcore  2 yY  5.87 mm   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 520 y PROBLEM 4.72 Solve Prob. 4.71, assuming that the couples M and M are applied and maintained about axes parallel to the x axis. 18 mm M 24 mm M⬘ x PROBLEM 4.71 The prismatic rod shown is made of a steel that is assumed to be elastoplastic with E  200 GPa and  Y  280 MPa . Knowing that couples M and M of moment 525 N · m are applied and maintained about axes parallel to the y axis, determine (a) the thickness of the elastic core, (b) the radius of curvature of the bar. SOLUTION I  1 3 1 (18)(24)3  20.736  103 mm 4  20.736  109 m 4 bh  12 12 1 c  h  12 mm  0.012 m 2 MY  M  yY  c Y I c Y  (280  106 )(20.736  109 )  483.84 N  m 0.012  3 1 yY 2  M Y 1   2 3 c2   3 (a) (b)   yY  yY  c or (2)(525)  0.91097 483.84 Y E    Y EyY 32 M MY yY  0.91097  c  10.932 mm (200  109 )(10.932  103 )  7.81 m 280  106 tcore  2 yY  21.9 mm   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 521 y z PROBLEM 4.73 C 90 mm A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E  200 GPa and  Y  240 MPa. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 30 mm thick. 60 mm SOLUTION (a) I 1 3 1 bh  (60)(90)3  3.645  106 mm 4  3.645  106 m 4 12 12 1 c  h  45 mm  0.045 m 2  I (240  106 )(3.645  106 )  19.44  10 N  m MY  Y  0.045 c M Y  19.44 kN  m  R1   Y A1  (240  106 )(0.060)(0.030)  432  103 N y1  15 mm  15 mm  0.030 m 1 1 R2   Y A2    (240  106 )(0.060)(0.015) 2 2  108  103 N y2  (b) 2 (15 mm)  10 mm  0.010 m 3 M  2( R1 y1  R2 y2 )  2[(432  103 )(0.030)  (108  103 )(0.010)]  28.08  103 N  m M  28.1 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 522 y PROBLEM 4.74 30 mm 30 mm C z A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E  200 GPa and  Y  240 MPa. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 30 mm thick. 30 mm 15 mm 15 mm 30 mm SOLUTION (a) I rect  1 3 1 bh  (60)(90)3  3.645  106 mm 4 12 12 1 1 I cutout  bh3  (30)(30)3  67.5  103 mm 4 12 12 I  3.645  106  67.5  103  3.5775  106 mm 4  3.5775  106 mm 4 c 1 h  45 mm  0.045 m 2  I (240  106 )(3.5775  106 ) MY  Y  0.045 c 3  19.08  10 N  m M Y  19.08 kN  m  R1   Y A1  (240  106 )(0.060)(0.030)  432  103 N y1  15 mm  15 mm  30 mm  0.030 m 1 1  Y A2  (240  106 )(0.030)(0.015)  54  103 N 2 2 2 y2  (15 mm)  10 mm  0.010 m 3 R2  (b) M  2( R1 y1  R2 y2 )  2[(432  103 )(0.030)  (54  103 )(0.010)]  27.00  103 N  m M  27.0 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 523 PROBLEM 4.75 y 3 in. C z 3 in. A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E  29  106 psi and  Y  42 ksi. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 3 in. thick. 3 in. 1.5 in. 1.5 in. 3 in. SOLUTION (a) I1  1 1 b1h13  A1d12  (3)(3)3  (3)(3)(3) 2  87.75 in 4 12 12 1 1 I 2  b2 h23  (6)(3)3  13.5 in 4 12 12 I 3  I1  87.75 in 4 I  I1  I 2  I 3  188.5 in 4 c  4.5 in.  I (42)(188.5) MY  Y  c 4.5 M Y  1759 kip  in.  R1   Y A1  (42)(3)(3)  378 kip y1  1.5  1.5  3.0 in. 1 1 R2   Y A2  (42)(6)(1.5) 2 2  189 kip 2 y2  (1.5)  1.0 in. 3 (b) M  2( R1 y1  R2 y2 )  2[(378)(3.0)  (189)(1.0)]  2646 kip  in. M  2650 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 524 PROBLEM 4.76 y 3 in. 3 in. C z A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E  29  106 psi and  Y  42 ksi. For bending about the z axis, determine the bending moment at which (a) yield first occurs, (b) the plastic zones at the top and bottom of the bar are 3 in. thick. 3 in. 1.5 in. 3 in. 1.5 in. SOLUTION (a) I1  1 1 b1h13  A1d12  (6)(3)3  (6)(3)(3) 2  175.5 in 4 12 12 1 1 3 I 2  b2 h2  (3)(3)3  6.75 in 4 12 12 I 3  I1  175.5 in 4 I  I1  I 2  I 3  357.75 in 4 c  4.5 in. MY  Y I c  (42)(357.75)  3339 kip  in. 4.5 M Y  3340 kip  in.  R1   Y A1  (42)(6)(3)  756 kip y1  1.5  1.5  3 in. 1 1 R2   Y A2  (42)(3)(1.5) 2 2  94.5 kip y2  (b) M  2( R1 y1  R2 y2 )  2[(756)(3)  (94.5)(1.0)]  4725 kip  in. 2 (1.5)  1.0 in. 3 M  4730 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 525 PROBLEM 4.77 y For the beam indicated (of Prob. 4.73), determine (a) the fully plastic moment M p , (b) the shape factor of the cross section. z 90 mm C 60 mm SOLUTION E  200 GPa and  Y  240 MPa From Problem 4.73, A1  (60)(45)  2700 mm 2  2700  106 m 2 R   Y A1  (240  106 )(2700  106 )  648  103 N d  45 mm  0.045 m (a) M p  Rd  (648  103 )(0.045)  29.16  103 N  m (b) I M p  29.2 kN  m  1 3 1 bh  (60)(90)3  3.645  106 mm 4  3.645  106 m 4 12 12 c  45 mm  0.045 m MY  Y I c  (240  106 )(3.645  106 )  19.44  103 N  m 0.045 k Mp MY  29.16 19.44 k  1.500  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 526 y PROBLEM 4.78 30 mm 30 mm C z For the beam indicated (of Prob. 4.74), determine (a) the fully plastic moment M p , (b) the shape factor of the cross section. 30 mm 15 mm 15 mm 30 mm SOLUTION From Problem 4.74, (a) R1   Y A1 E  200 GPa and  Y  240 MPa  (240  106 )(0.060)(0.030)  432  103 N y1  15 mm  15 mm  30 mm  0.030 m R2   Y A2  (240  106 )(0.030)(0.015)  108  103 N 1 y2  (15)  7.5 mm  0.0075 m 2 M p  2( R1 y1  R2 y2 )  2[( 432 103 )(0.030)  (108 103 )(0.0075)]  27.54  103 N  m (b) M p  27.5 kN  m  I rect  1 3 1 bh  (60)(90)3  3.645  106 mm 4 12 12 1 3 1 I cutout  bh  (30)(30)3  67.5  103 mm 4 12 12 I  I rect  I cutout  3.645  106  67.5  103  3.5775  103 mm 4 c  3.5775  109 m 4 1 h  45 mm  0.045 m 2  I (240  106 )(3.5775  109 )  19.08  103 N  m MY  Y  0.045 c M p 27.54 k  MY 19.08 k  1.443  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 527 PROBLEM 4.79 y 3 in. 3 in. C z For the beam indicated (of Prob. 4.75), determine (a) the fully plastic moment M p , (b) the shape factor of the cross section. 3 in. 1.5 in. 1.5 in. 3 in. SOLUTION From Problem 4.75, (a) E  29  106 psi and  Y  42 ksi. R1   Y A1  (42)(3)(3)  378 kip y1  1.5  1.5  3.0 in. R2   Y A2  (42)(6)(1.5)  378 kip y2  1 (1.5)  0.75 in. 2 M p  2( R1 y1  R2 y2 )  2[( 378)( 3.0)  ( 378)(0. 75)] (b) M p  2840 kip  in.  I1  1 1 b1h13  A1d12  (3)(3)3  (3)(3)(3) 2  87.75 in 4 12 12 1 1 I 2  b2 h23  (6)(3)3  13.5 in 4 12 12 I 3  I1  87.75 in 4 I  I1  I 2  I 3  188.5 in 4 c  4.5 in. MY  Y I (42)(188.5)  1759.3 kip  in 4.5 2835  k MY 1759.3 c Mp  k  1.611  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 528 PROBLEM 4.80 y 3 in. C z For the beam indicated (of Prob. 4.76), determine (a) the fully plastic moment M p , (b) the shape factor of the cross section. 3 in. 3 in. 1.5 in. 3 in. 1.5 in. SOLUTION From Problem 4.76, (a) E  29  106 and  Y  42 ksi R1   Y A1  (42)(6)(3)  756 kip y1  1.5  1.5  3.0 in. R2   Y A2  (42)(3)(1.5)  189 kip y2  1 (1.5)  0.75 in. 2 M p  2( R1 y1  R2 y2 )  2[( 756)( 3.0)  (189)(0. 75)] (b) M p  4820 kip  in.  I1  1 1 b1h13  A1d12  (6)(3)3  (6)(3)(3) 2  175.5 in 4 12 12 1 1 3 I 2  b2 h2  (3)(3)3  6.75 in 4 12 12 I 3  I1  175.5 in 4 I  I1  I 2  I 3  357.75 in 4 c  4.5 in. MY  Y I  (42)(357.75)  3339 kip  in. c 4.5 M p 4819.5 k  MY 3339 k  1.443  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 529 PROBLEM 4.81 r 18 mm Determine the plastic moment M p of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa. SOLUTION A For a semicircle, Resultant force on semicircular section:  2 r 2; r  R  Y A 4r 3 Resultant moment on entire cross section: M p  2 Rr  Data: 4 Y r3 3  Y  240 MPa  240  106 Pa, Mp  r  18 mm  0.018 m 4 (240  106 )(0.018)3  1866 N  m 3 M p  1.866 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 530 PROBLEM 4.82 50 mm 30 mm Determine the plastic moment M p of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa. 10 mm 10 mm 10 mm 30 mm SOLUTION A  (50)(90)  (30)(30)  3600 mm 2 Total area: 1 A  1800 mm 2 2 1 A 1800 x 2   36 mm 50 b A1  (50)(36)  1800 mm 2 , y1  18 mm, A1 y1  32.4  103 mm3 A2  (50)(14)  700 mm 2 , y2  7 mm, A2 y2  4.9  103 mm3 A4  (50)(10)  500 mm 2 , y4  49 mm, A4 y4  24.5  103 mm3 A3  (20)(30)  600 mm 2 , y3  29 mm, A3 y3  17.4  103 mm3 A1 y1  A2 y2  A3 y3  A4 y4  79.2  103 mm3  79.2  106 m3 M p   Y Ai yi  (240  106 )(79.2  106 )  19.008  103 N  m M p  19.01 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 531 PROBLEM 4.83 36 mm Determine the plastic moment M p of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa. 30 mm SOLUTION Total area: A 1 (30)(36)  540 mm 2 2 By similar triangles, Since b 30  y 36 A1  y b Half area: 1 A  270 mm 2  A1 2 5 y 6 1 5 2 by  y , 2 12 y2  12 A1 5 12 (270)  25.4558 mm 5 b  21.2132 mm 1 A1  (21.2132)(25.4558)  270 mm 2  270  106 m 2 2 A2  (21.2132)(36  25.4558)  223.676 mm 2  223.676  106 m 2 A3  A  A1  A2  46.324 mm 2  46.324  106 m 2 Ri   Y Ai  240  106 Ai R1  64.8  103 N, R2  53.6822  103 N, R3  11.1178  103 N 1 y1  y  8.4853 mm  8.4853  103 m 3 1 y2  (36  25.4558)  5.2721 mm  5.2721  103 m 2 2 y3  (36  25.4558)  7.0295 mm  7.0295  103 m 3 M p  R1 y1  R2 y2  R3 y3  911 N  m M p  911 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 532 0.4 in. PROBLEM 4.84 1.0 in. Determine the plastic moment Mp of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 42 ksi. 1.0 in. 0.4 in. 0.4 in. SOLUTION A  (1.0 in.)(0.4 in.)  2(1.4 in.)(0.4 in.)  1.52 in 2 x 1 2 (1.52) 2(0.4)  0.95 in. R1  (1.0)(0.4)  0.4 in 2 y1  1.2  0.95  0.25 in. R2  2(0.4)(1.4  0.95)  0.36 in 2 y2  1 (1.4  0.95)  0.225 in. 2 R3  2(0.4)(0.95)  0.760 in 2 y3  1 (0.95)  0.475 in. 2 M p  ( R1 y1  R2 y 2  R3 y 3 )( y )  [(0.4)(0.25)  (0.36)(0.225)  (0.760)(0.475)](42) M p  22.8 kip  in .  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 533 5 mm PROBLEM 4.85 5 mm 80 mm t = 5 mm 120 mm Determine the plastic moment Mp of the cross section shown when the beam is bent about a horizontal axis. Assume the material to be elastoplastic with a yield strength of 175 MPa. SOLUTION For M p , the neutral axis divides the area into two equal parts. Total area  (100  100  120)t  320t Shaded area  2at  1 (320)t 2 a  80 mm 80 (80 mm)  64 mm b 100 A1  2at  2(0.08 m)(0.005 m)  800  106 m 2 A2  2(100  a )t  2(0.02 m)(0.005 m)  200  106 m 2 A3  (120 mm)t  (0.120 m)(0.005 m)  600  106 m 2 R1   Y A1  (175 MPa)(800  106 m 2 )  140 kN R2   Y A2  (175 MPa)(200  106 m 2 )  35 kN R3   Y A3  (175 MPa)(600  106 m 2 )  105 kN  M z : M p  R1 (32 mm)  R2 (8 mm)  R3 (16 mm)  (140 kN)(0.032 m)  (35 kN)(0.008 m)  (105 kN)(0.016 m) M p = 6.44 k N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 534 PROBLEM 4.86 4 in. 1 2 1 2 in. in. 3 in. 1 2 in. Determine the plastic moment M p of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 36 ksi. 2 in. SOLUTION Total area: 1 1 1 A  (4)      (3)  (2)    4.5 in 2 2 2 2 1 A  2.25 in 2 2 A1  2.00 in 2 , y1  0.75, A2  0.25 in 2 , y2  0.25, A4  1.00 in 2 , y4  2.75, A3  1.25 in 2 , y3  1.25, A1 y1  1.50 in 3 A2 y2  0.0625 in 3 A3 y3  1.5625 in 3 A4 y4  2.75 in 3 M p   Y ( A1 y1  A2 y2  A3 y3  A4 y4 )  (36)(1.50  0.0625  1.5625  2.75) M p  212 kip  in .  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 535 PROBLEM 4.87 y z C 90 mm For the beam indicated (of Prob. 4.73), a couple of moment equal to the full plastic moment M p is applied and then removed. Using a yield strength of 240 MPa, determine the residual stress at y  45mm . 60 mm SOLUTION M p  29.16  103 N  m See solutions to Problems 4.73 and 4.77. I  3.645  106 m 4 c  0.045 m   LOADING Mp c M max y  I I UNLOADING   at y  c  45 mm RESIDUAL STRESSES (29.16  103 )(0.045)  360  106 Pa 6 3.645  10  res      Y  360  106  240  106  120  106 Pa  res  120.0 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 536 y PROBLEM 4.88 30 mm z 30 mm C For the beam indicated (of Prob. 4.74), a couple of moment equal to the full plastic moment M p is applied and then removed. Using a yield strength of 240 MPa, determine the residual stress at y  45mm . 30 mm 15 mm 15 mm 30 mm SOLUTION M p  27.54  103 N  m (See solutions to Problems 4.74 and 4.78.) I  3.5775  106 m 4 ,     LOADING Mp c M max y  I I c  0.045 m at y c (27.54  103 )(0.045)  346.4  106 Pa 6 3.5775  10 UNLOADING RESIDUAL STRESSES  res      Y  346.4  106  240  106  106.4  106 Pa  res  106.4 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 537 PROBLEM 4.89 y A bending couple is applied to the bar indicated, causing plastic zones 3 in. thick to develop at the top and bottom of the bar. After the couple has been removed, determine (a) the residual stress at y  4.5 in., (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the bar. 3 in. 3 in. C z Beam of Prob. 4.75. 3 in. 1.5 in. 1.5 in. 3 in. SOLUTION See solution to Problem 4.75 for bending couple and stress distribution during loading. M  2646 kip  in. (a)  Y  42 ksi   I  188.5 in 4 At c  4.5 in. y  c,  res      Y  63.167  42  21.167 ksi y  yY ,  res      Y  21.056  42  20.944 ksi UNLOADING LOADING (c) E  29  106 psi  29  103 ksi Mc (2646)(4.5)   63.167 ksi I 188.5 MyY (2646)(1.5)      21.056 ksi I 188.5 At (b) yY  1.5 in. My0  Y I (188.5)(42) I Y y0    2.99 in. 2646 M  res  20.9 ksi  RESIDUAL STRESSES  res  0  At   y  yY ,  Ey Answer: y0  2.99 in., 0, 2.99 in.   res  20.944 ksi     Ey  (29  103 )(1.5)  2077 in. 20.944   173.1 ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 538 PROBLEM 4.90 y A bending couple is applied to the bar indicated, causing plastic zones 3 in. thick to develop at the top and bottom of the bar. After the couple has been removed, determine (a) the residual stress at y  4.5 in., (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the bar. 3 in. 3 in. C z Beam of Prob. 4.76. 3 in. 1.5 in. 3 in. 1.5 in. SOLUTION See solution to Problem 4.76 for bending couple and stress distribution. M  4725 kip  in.  Y  42 ksi (a) yY  1.5 in. I  357.75 in 4      59.4 ksi  y  yY ,  res      Y  19.8113  42  22.189 ksi UNLOADING LOADING  res  0  y0  (c) c  4.5 in. Mc (4725)(4.5)   59.434 ksi 357.75 I (4725)(1.5) MyY      19.8113 ksi 357.75 I At y  c,  res      Y  59.434  42  17.4340 ksi At (b) E  29  106 psi  29  103 ksi At RESIDUAL STRESSES My0  Y  0 I (357.75)(42) I Y   3.18 in. 4725 M Answer: y0  3.18 in., 0, 3.18 in.  y  yY ,  res  22.189 ksi    Ey     Ey  (29  103 )(1.5)  1960.43 in. 22.189   163.4 ft.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 539 PROBLEM 4.91 y z 90 mm C A bending couple is applied to the beam of Prob. 4.73, causing plastic zones 30 mm thick to develop at the top and bottom of the beam. After the couple has been removed, determine (a) the residual stress at y  45 mm, (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the beam. 60 mm SOLUTION See solution to Problem 4.73 for bending couple and stress distribution during loading. M  28.08  103 N  m  Y  240 MPa (a)      yY  15 mm  0.015 m I  3.645  106 m 4 E  200 GPa c  0.045 m Mc (28.08  103 )(0.045)   346.67  106 Pa  346.67 MPa I 3.645  106 (28.08  103 )(0.015) M yY   115.556  106 Pa  115.556 MPa I 3.645  106 At y  c,  res      Y  346.67  240  106.670 MPa At y  yY ,  res      Y  115.556  240  124.444 MPa LOADING (b)  res  0  y0  (c) At UNLOADING  res  106.7 MPa   res  124.4 MPa RESIDUAL STRESSES My0  Y  0 I (3.645  106 )(240  106 ) I Y   31.15  103 m  31.15 mm M 28.08  103 Answer: y0  31.2 mm, 0, 31.2 mm  y  yY ,  res  124.444  106 Pa    Ey     Ey  (200  109 )(0.015) 124.444  106   24.1 m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 540 PROBLEM 4.92 y A beam of the cross section shown is made of a steel that is assumed to be elastoplastic with E  29 × 106 psi and  Y = 42 ksi. A bending couple is applied to the beam about the z axis, causing plastic zones 2 in. thick to develop at the top and bottom of the beam. After the couple has been removed, determine (a) the residual stress at y  2 in., (b) the points where the residual stress is zero, (c) the radius of curvature corresponding to the permanent deformation of the beam. 1 in. z C 2 in. 1 in. 1 in. 1 in. 1 in. SOLUTION Flange: I1  Web: I2  1 1 b1h13  A1d12  (3)(1)3  (3)(1)(1.5)2  7.0 in 4 12 12 1 1 b2 h23  (1)(2)3  0.6667 in 4 12 12 4 I 3  I1  7.0 in I  I1  I 2  I 3  14.6667 in 4 c  2 in. MY  Y I c  (42)(14.6667) 2 MY  308 kip  in .  R1   Y A1  (42)(3)(1)  126 kips y1  1.0  0.5  1.5 in. 1 1 R2   Y A2  (42)(1)(1) 2 2  21 kips y2  2 (1.0)  0.6667 in. 3 M  2( R1 y1  R2 y 2 )  2[(126)(1.5)  (21)(0.6667)] M  406 kip  in. yY  1.0 in. E  29  106  29  103 ksi  Y  42 ksi (a) M  406 kip  in .  I  14.6667 in 4 c  2 in.  Mc (406)(2)  55.364 I 14.6667    MyY (406)(1.0)  27.682 I 14.662  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 541 PROBLEM 4.92 (Continued) At y  c,  res      Y  55.364  42  13.3640 ksi At y  yY ,  res      Y  27.682  42  14.3180 ksi (b) (c) My0  Y  0 I I (14.667)(42) y0  Y   1.517 in M 406  res  13.36 k si   res  14.32 k si   res  0  At y  yY ,    Ey Answer : y0  1.517 in., 0, 1.517 in.   res  14.3180 ksi     Ey  (29  103 )(1.0)  2025.42 in. 14.3180   168.8 ft  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 542 PROBLEM 4.93* A rectangular bar that is straight and unstressed is bent into an arc of circle of radius by two couples of moment M. After the couples are removed, it is observed that the radius of curvature of the bar is  R . Denoting by Y the radius of curvature of the bar at the onset of yield, show that the radii of curvature satisfy the following relation: R 1  2   1 3   1      1 1       2 Y  3  Y        SOLUTION Y 1 Let m denote M . MY  MY , EI M   3 1 2  M Y 1  , 2 3 Y2   3 2  2 M  1  2    32m 2 MY Y  Y2 1 1 M 1 mM Y 1 m       R  EI   Y EI m  1 1  2     1  3       1 1 1 m      3 Y2    Y    2 Y   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 543 PROBLEM 4.94 A solid bar of rectangular cross section is made of a material that is assumed to be elastoplastic. Denoting by M Y and Y , respectively, the bending moment and radius of curvature at the onset of yield, determine (a) the radius of curvature when a couple of moment M  1.25 M Y is applied to the bar, (b) the radius of curvature after the couple is removed. Check the results obtained by using the relation derived in Prob. 4.93. SOLUTION (a) Y 1  m (b) R 1   M  MY , EI  3 1 2  M Y 1   2 3 Y2   3 1 2  M  1   2 3 Y2  MY  1  Let m  M  1.25 MY   3  2m  0.70711 Y M m 1 mM Y 1 1 1.25       EI  EI  Y Y 0.70711Y Y 0.16421   0.707Y   R  6.09Y  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 544 PROBLEM 4.95 M The prismatic bar AB is made of a steel that is assumed to be elastoplastic and for which E  200 GPa . Knowing that the radius of curvature of the bar is 2.4 m when a couple of moment M  350 N  m is applied as shown, determine (a) the yield strength of the steel, (b) the thickness of the elastic core of the bar. B A 20 mm 16 mm SOLUTION M    (a)   2 Y2  bc 2 Y 1  M 3E 2c 2   Data:  3 1 2  M Y 1   2 3 Y2   3 Y I 2 c  1  2 Y2  1   3 E 2c 2   3  Y b(2c)3  1  2 Y2  1   2 12c  3 E 2c 2   1  2 Y2    Y bc 2 1   3 E 2c 2   Cubic equation for  Y E  200  109 Pa M  420 N  m   2.4 m b  20 mm  0.020 m c 1 h  8 mm  0.008 m 2 (1.28  106 )  Y 1  750  1021 Y2   350  Y 1  750  1021 Y2   273.44  106 Solving by trial, (b) yY  Y  E   Y  292  106 Pa (292  106 )(2.4)  3.504  103 m  3.504 mm 9 200  10  Y  292 MPa  thickness of elastic core  2 yY  7.01 mm  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 545 PROBLEM 4.96 (MPa) 300 The prismatic bar AB is made of an aluminum alloy for which the tensile stress-strain diagram is as shown. Assuming that the  - diagram is the same in compression as in tension, determine (a) the radius of curvature of the bar when the maximum stress is 250 MPa, (b) the corresponding value of the bending moment. (Hint: For part b, plot  versus y and use an approximate method of integration.) B 40 mm M' 200 M 60 mm A 100 0 0.005 0.010 ⑀ SOLUTION (a)  m  250 MPa  250  106 Pa  m  0.0064 from curve c 1 h  30 mm  0.030 m 2 b  40 mm  0.040 m  1 (b)  m c    4.69 m  0.0064  0.21333 m 1 0.030    m Strain distribution: y   mu c u  where  y M    c y b dy  2b 0 y | | dy  2bc 2  0 u | | du  2bc 2 J c Bending couple: c 1 where the integral J is given by  0 u | | du 1 Evaluate J using a method of numerial integration. If Simpson’s rule is used, the integration formula is J  u wu | | 3 where w is a weighting factor. Using u  0.25, we get the values given in the table below: u 0 0.25 0.5 0.75 1.00 | | 0 0.0016 0.0032 0.0048 0.0064 J  | |, (MPa) 0 110 180 225 250 u | |, (MPa) 0 27.5 90 168.75 250 w 1 4 2 4 1 wu | |, (MPa) 0 110 180 675 250 1215  wu | | (0.25)(1215)  101.25 MPa  101.25  106 Pa 3 M  (2)(0.040)(0.030)2 (101.25  106 )  7.29  103 N  m M  7.29 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 546 PROBLEM 4.97 0.8 in. The prismatic bar AB is made of a bronze alloy for which the tensile stress-strain diagram is as shown. Assuming that the  - diagram is the same in compression as in tension, determine (a) the maximum stress in the bar when the radius of curvature of the bar is 100 in., (b) the corresponding value of the bending moment. (See hint given in Prob. 4.96.) B M ␴ (ksi) 1.2 in. A 50 40 30 20 10 0 0.004 ⑀ 0.008 SOLUTION (a)   100 in., b  0.8 in., c  0.6 in. m  (b)  c  0.6  0.006 100 Strain distribution: Bending couple: From the curve,    m M   y   mu c c c where u   m  43.0 ksi   y y  b dy  2b  y | | dy  2bc 2  0 u | | du  2bc 2 J c 0 where the integral J is given by  0 u | | du 1 1 Evaluate J using a method of numerial integration. If Simpson’s rule is used, the integration formula is J  u wu| | 3 where w is a weighting factor. Using u  0.25, we get the values given the table below: u | | 0 0.25 0.5 0.75 1.00 0 0.0015 0.003 0.0045 0.006 | |, ksi 0 25 36 40 43 u | |, ksi 0 6.25 18 30 43 w 1 4 2 4 1 J  (0.25)(224)  18.67 ksi 3 M  (2)(0.8)(0.6) 2 (18.67) wu | |, ksi 0 25 36 120 43 224  wu | | M  10.75 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 547 PROBLEM 4.98 ␴ A prismatic bar of rectangular cross section is made of an alloy for which the stress-strain diagram can be represented by the relation   k n for   0 and    k n for   0 . If a couple M is applied to the bar, show that the maximum stress is ⑀ m  M 1  2n Mc 3n I SOLUTION Strain distribution: Bending couple:    m y   mu c where u  y c M    c y  b dy  2b  0 y | | dy  2bc 2  0 c c c  2 bc 2  0 u | | du y dy | | c c 1 For Then   K n ,  m  K m     u   m  m   n 2 1 m  1 1 1n du 1 1 u n  2bc  m 2  1n Then 1 M  2bc 2  0 u mu n du  2bc 2 m  0 u 2 Recall that | |   mu n 2n  1 M 2 bc 2  0  2n  1 bc  m 1 2n 2 I 1 b(2c)3 2 1 2 c   bc 2   2 c 12 c 3 3 I bc m  2n  1 Mc 3n I PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 548 PROBLEM 4.99 30 mm Knowing that the magnitude of the horizontal force P is 8 kN, determine the stress at (a) point A, (b) point B. B 24 mm A D P 45 mm 15 mm SOLUTION A  (30)(24)  720 mm 2  720  106 m 2 e  45  12  33 mm  0.033 m I  1 3 1 bh  (30)(24)3  34.56  103 mm 4  34.56  109 m 4 12 12 1 c  (24 mm)  12 mm  0.012 m P  8  103 N 2 (a) (b) M  Pe  (8  103 )(0.033)  264 N  m A   P Mc 8  103 (264)(0.012)     102.8  106 Pa 6 A I 720  10 34.56  109 B   P Mc 8  103 (264)(0.012)     80.6  106 Pa 6 A I 720  10 34.56  109  A  102.8 MPa   B  80.6 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 549 PROBLEM 4.100 y b 3 in. 6 kips A short wooden post supports a 6-kip axial load as shown. Determine the stress at point A when (a) b  0, (b) b  1.5 in., (c) b  3 in. C A z x SOLUTION A   r 2   (3) 2  28.27 in 2 I  (a) (b) b0    r 4  (3) 4  63.62 in 4 4 4 I 63.62 S    21.206 in 3 c 3 P  6 kips M  Pb P 6   0.212 ksi A 28.27   212 psi  b  1.5 in. M  (6)(1.5)  9 kip  in.   (c) M 0  6 9 P M     0.637 ksi A S 28.27 21.206 b  3 in.   M  (6)(3)  18 kip  in. 6 18 P M     1.061 ksi A S 28.27 21.206   637 psi    1061 psi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 550 P P r PROBLEM 4.101 r Two forces P can be applied separately or at the same time to a plate that is welded to a solid circular bar of radius r. Determine the largest compressive stress in the circular bar, (a) when both forces are applied, (b) when only one of the forces is applied. SOLUTION For a solid section, Compressive stress (a) Both forces applied. (b) One force applied. A   r 2, I   4 F Mc    A I F 4M  2  3 r r r 4, c  r F  2 P, M  0 F  P, M  Pr F 4P    2  r2 r r   2P   r2   5P   r2 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 551 30 mm PROBLEM 4.102 y 60 mm A short 120 × 180-mm column supports the three axial loads shown. Knowing that section ABD is sufficiently far from the loads to remain plane, determine the stress at (a) corner A, (b) corner B. 30 kN 20 kN 100 kN C z x A D 90 mm 90 mm B 120 mm SOLUTION A  (0.120 m)(0.180 m)  21.6  103 m 2 1 S  (0.120 m)(0.180 m)2  6.48  104 m 2 6 M  (30 kN)(0.03 m)  (100 kN)(0.06 m)  5.10 kN  m (a) A   P M 150  103 N 5.10  103 N  m    A S 21.6  103 m 2 6.48  104 m3 (b) B   P M 150  10 N 5.10  10 N  m    2 3 A S 21.6  10 m 6.48  104 m3 3  A  0.926 MPa  3  B  14.81 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 552 80 mm 80 mm P P P C 1 2 3 PROBLEM 4.103 As many as three axial loads, each of magnitude P  50 kN, can be applied to the end of a W200 × 31.1 rolled-steel shape. Determine the stress at point A (a) for the loading shown, (b) if loads are applied at points 1 and 2 only. A SOLUTION For W200  31.3 rolled-steel shape. A  3970 mm 2  4.000  103 m 2 c 1 1 d  (210)  105 mm  0.105 m 2 2 I  31.3  106 mm 4  31.3  106 m 4 (a) Centric load: 3P  50  50  50  150 kN  150  103 N   (b) Ececentric loading: 3P 150  103   37.783  106 Pa  37.8 MPa 3 A 3.970  10 e  80 mm  0.080 m  2 P  50  50  100 kN  100  103 N M  Pe  (50  103 )(0.080)  4.0  103 N  m A   2P Mc 100  103 (4.0  103 )(0.105)     38.607  106 Pa  38.6 MPa A I 3.970  103 31.3  106  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 553 PROBLEM 4.104 y 10 mm 10 mm Two 10-kN forces are applied to a 20 × 60-mm rectangular bar as shown. Determine the stress at point A when (a) b  0, (b) b  15 mm, (c) b  25 mm. A 30 mm z 30 mm 10 kN C b 10 kN x 25 mm SOLUTION A  (0.060 m)(0.020 m)  1.2  103 m 2 S  (a) 1 (0.020 m)(0.060 m)2  12  106 m3 6 b  0, M  (10 kN)(0.025 m)  250 N  m  A  (20 kN)/(1.2  103 m 2 )  (250 N  m)/(12  106 m3 )  16.667 MPa  20.833 MPa (b) b  15 mm, M  (10 kN)(0.025 m  0.015 m)  100 N  m  A  (20 kN)/(1.2  103 m 2 )  (100 N  m)/(12  106 m3 )  16.667 MPa  8.333 MPa (c)  A  4.17 MPa  b  25 mm, M  0:  A  (20 kN)/(1.2  103 m 2 )  A  8.33 MPa   A  16.67 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 554 P P' P PROBLEM 4.105 P' Portions of a 12  12 -in. square bar have been bent to form the two machine components shown. Knowing that the allowable stress is 15 ksi, determine the maximum load that can be applied to each component. 1 in. (a) (b) SOLUTION The maximum stress occurs at point B.  B  15 ksi  15  103 psi B   K  where 1 ec  A I P Mc P Pec      KP A I A I e  1.0 in. A  (0.5)(0.5)  0.25 in 2 I  1 (0.5)(0.5)3  5.2083  103 in 4 for all centroidal axes. 12 (a) (a) c  0.25 in. K  1 (1.0)(0.25)   52 in 2 0.25 5.2083  103 P (b) (b) c B K  (15  103 ) 52 P  288 lb  0.5  0.35355 in. 2 K  1 (1.0)(0.35355)   71.882 in 2 0.25 5.2083  103 P B K  (15  103 ) 71.882 P  209 lb  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 555 PROBLEM 4.106 P Knowing that the allowable stress in section ABD is 80 MPa, determine the largest force P that can be applied to the bracket shown. A D B 18 mm 40 mm 12 mm 12 mm SOLUTION A  (24)(18)  432 mm 2  432  106 m 2 I  1 (24)(18)3  11.664  103 mm 4  11.664  109 m 4 12 1 c  (18)  9 mm  0.009 m 2 1 e  (18)  40  49 mm  0.049 m 2 On line BD, both axial and bending stresses are compressive. Therefore Solving for P gives  max  P Mc  A I  P Pec  A I P P  max  1 ec     I  A 80  106 Pa  1 (0.049 m)(0.009 m)     6 2 11.664  109 m 4   432  10 m P  1.994 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 556 PROBLEM 4.107 P' a d P a A milling operation was used to remove a portion of a solid bar of square cross section. Knowing that a  30 mm, d  20 mm, and  all  60 MPa, determine the magnitude P of the largest forces that can be safely applied at the centers of the ends of the bar. SOLUTION A  ad , e I  1 ad 3 , 12 c a d  2 2 P Mc P 6 Ped      A I ad ad 3 3P (a  d ) P   KP   ad ad 2 Data: a  30 mm  0.030 m K  P 1 d 2 where K  1 3(a  d )  ad ad 2 d  20 mm  0.020 m 1 (3)(0.010)   4.1667  103 m 2 (0.030)(0.020) (0.030)(0.020)2  K  60  106  14.40  103 N 4.1667  103 P  14.40 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 557 PROBLEM 4.108 P' A milling operation was used to remove a portion of a solid bar of square cross section. Forces of magnitude P  18 kN are applied at the centers of the ends of the bar. Knowing that a  30 mm and  all  135 MPa, determine the smallest allowable depth d of the milled portion of the bar. a d P a SOLUTION A  ad , e I  a d  2 2 1 ad 3 , 12 c 1 d 2 P 1 (a  d ) 1 d P Mc P Pec P 2  P  3P(a  d )      2 1 A I ad I ad ad ad 2 ad 3 12 P 3P 2P 2   2  d  3P  0 or  d 2  ad a d   2   1   2P  2P  P   12      a  2   a    Solving for d, d  Data: a  0.030 m, P  18  103 N,   135  106 Pa 2   1 (2)(18  103 )    (2)(18  103 )  3 6 d       12(18  10 )(135  10 )  0.030 0.030 (2)(135  106 )        16.04  103 m d  16.04 mm  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 558 12 kips 5 in. P PROBLEM 4.109 The two forces shown are applied to a rigid plate supported by a steel pipe of 8-in. outer diameter and 7-in. inner diameter. Determine the value of P for which the maximum compressive stress in the pipe is 15 ksi. SOLUTION  all  15 ksi I NA   4 (4 in.)4   4 (3.5 in.)4  83.2 in 4 A   (4 in.) 2   (3.5 in.)2  11.78 in 2 Max. compressive stress is at point B. B   12  P (5P)(4.0 in.) Q Mc    2 A I 11.78 in 83.2 in 4 15 ksi  1.019  0.085P  0.240 P 13.981  0.325P P  43.0 kips  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 559 PROBLEM 4.110 d P' P An offset h must be introduced into a solid circular rod of diameter d. Knowing that the maximum stress after the offset is introduced must not exceed 5 times the stress in the rod when it is straight, determine the largest offset that can be used. h P' P d SOLUTION For centric loading, c  For eccentric loading, e  Given P A P Phc  A I  e  5 c P Phc P  5 A I A Phc P 4 I A    (4)  d 4  4I 1 64     d h  d 2 cA   2   d   2  4  h  0.500 d  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 560 PROBLEM 4.111 d P' P h P' P An offset h must be introduced into a metal tube of 0.75-in. outer diameter and 0.08-in. wall thickness. Knowing that the maximum stress after the offset is introduced must not exceed 4 times the stress in the tube when it is straight, determine the largest offset that can be used. d SOLUTION c 1 d  0.375 in. 2 c1  c  t  0.375  0.08  0.295 in.   A   c 2  c12   (0.3752  0.2952 )  0.168389 in 2 I  c 4  4   c14   4  9.5835  103 in 4 For centric loading,  cen  For eccentric loading,  ecc  (0.3754  0.2954 ) P A P Phc  A I  ecc  4  cen 3 hc  I A or h P Phc P  4 A I A 3I (3)(9.5835  103 )  Ac (0.168389)(0.375) h  0.455 in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 561 PROBLEM 4.112 16 kips 2 4 1 A short column is made by nailing four 1 × 4-in. planks to a 4 × 4-in. timber. Using an allowable stress of 600 psi, determine the largest compressive load P that can be applied at the center of the top section of the timber column as shown if (a) the column is as described, (b) plank 1 is removed, (c) planks 1 and 2 are removed, (d) planks 1, 2, and 3 are removed, (e) all planks are removed. 3 SOLUTION (a) M 0 Centric loading:   P A A  (4  4)  4(1)(4)  32 in 2   (b) P A  P  (0.600 ksi)(32 in 2 )  19.20 kips  Eccentric loading: M  Pe   P Pec  A I A  (4)(4)  (3)(1)(3)  28 in 2 y  e y  Ay (1)(4)(2.5)   0.35714 in. A 28 I  ( I  Ad 2 )  1 1 (6)(4)3  (6)(4)(0.35714)2  (4)(1)3  (4)(1)(2.14286)2  53.762 in 4 12 12  1 ec    I  A   P (c) Centric loading:  P M 0 (0.600 ksi)  11.68 kips 1 (0.35714)(2.35714)     28  53.762    P A A  (6)(4)  24 in 2 P  (0.600 ksi)(24)  14.40 kips  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 562 PROBLEM 4.112 (Continued) (d) Eccentric loading: M  Pe   P Pec  A I A  (4)(4)  (1)(4)(1)  20 in 2 x  2.5  2  0.5 in. I  P (e) Centric loading: e x 1 (4)(5)3  41.667 in 4 12 (0.600 ksi)  7.50 kips (0.5)(2.5)  1  20  41.667  M 0   P A A  (4)(4)  16 in 2   P  (0.600 ksi)(16.0 in 2 )  9.60 kips  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 563 1 in. a 1.5 in. PROBLEM 4.113 3 in. a 0.75 in. 1.5 in. A 3 in. 0.75 in. B Section a–a SOLUTION A vertical rod is attached at point A to the cast iron hanger shown. Knowing that the allowable stresses in the hanger are  all  5 ksi and  all  12 ksi , determine the largest downward force and the largest upward force that can be exerted by the rod. (1  3)(0.5)  2(3  0.25)(2.5) Ay  X   (1  3)  2(3  0.75) A X  12.75 in 3  1.700 in. 7.5 in 2 A  7.5 in 2  all  5 ksi  all  12 ksi  1  I c    bh3  Ad 2   12  1 1  (3)(1)3  (3  1)(1.70  0.5)2  (1.5)(3)3  (1.5  3)(2.5  1.70)2 12 12 I c  10.825 in 4 Downward force. M  P(1.5 in.+1.70 in.)  (3.20 in.) P At D:  D   P Mc  A I  5 ksi  P (3.20) P(1.70)  7.5 10.825  5  P(0.6359) At E:  E   P  7.86 kips  P Mc  A I  12 ksi  P (3.20) P(2.30)  7.5 10.825  12  P(0.5466) We choose the smaller value. P  21.95 kips  P  7.86 kips   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 564 PROBLEM 4.113 (Continued) Upward force. M  P(1.5 in.  1.70 in.)  (3.20 in.) P At D:  D   P Mc  A I 12 ksi   P (3.20) P(1.70)  7.5 10.825 12  P(0.6359) At E:  E   P  18.87 kips  P Mc  A I 5 ksi  P (3.20) P(2.30)  7.5 10.825 5  P(0.5466) We choose the smaller value. P  9.15 kips  P  9.15 kips   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 565 PROBLEM 4.114 1 in. a 1.5 in. 3 in. a 1.5 in. A Solve Prob. 4.113, assuming that the vertical rod is attached at point B instead of point A. 0.75 in. 3 in. 0.75 in. B Section a–a SOLUTION PROBLEM 4.113 A vertical rod is attached at point A to the cast iron hanger shown. Knowing that the allowable stresses in the hanger are  all  5 ksi and  all  12 ksi, determine the largest downward force and the largest upward force that can be exerted by the rod. (1  3)(0.5)  2(3  0.25)(2.5) Ay  X   (1  3)  2(3  0.75) A  X  12.75 in 3  1.700 in. 7.5 in 2 A  7.5 in 2  all  5 ksi  all  12 ksi  1  I c    bh3  Ad 2  12   1 1  (3)(1)3  (3  1)(1.70  0.5)2  (1.5)(3)3  (1.5  3)(2.5  1.70)2 12 12 I c  10.825 in 4 Downward force.  all  5 ksi  all  12 ksi M  (2.30 in.  1.5 in.)  (3.80 in.) P At D:  D   P Mc  A I 12 ksi   P (3.80) P(1.70)  7.5 10.825  12  P(0.4634) At E:  E   P  25.9 kips  P Mc  A I 5 ksi   P (3.80) P(2.30)  7.5 10.825 5  P(0.9407) We choose the smaller value. P  5.32 kips   P  5.32 kips   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 566 PROBLEM 4.114 (Continued) Upward force.   all  5 ksi  M  (2.30 in.  1.5 in.)P  (3.80 in.)P     all  12 ksi  At D:  D   P Mc   A I 5 ksi   P (3.80) P(1.70)  7.5 10.825 5  P(0.4634)   At E:  E   P  10.79 kips  P Mc  A I 12 ksi   P (3.80) P(2.30)  7.5 10.825 12  P(0.9407) We choose the smaller value. P  12.76 kips  P  10.79 kips   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 567 2 mm radius A P PROBLEM 4.115 P' 32 mm 20 mm a B a Knowing that the clamp shown has been tightened until P  400 N, determine (a) the stress at point A, (b) the stress at point B, (c) the location of the neutral axis of section a  a. 4 mm Section a–a SOLUTION Cross section: Rectangle   Circle  A1  (20 mm)(4 mm)  80 mm 2 y1  1 (20 mm)  10 mm 2 A2   (2 mm)2  4 mm 2 y2  20  2  18 mm Ay (80)(10)  (4 )(18) cB  y     11.086 mm 80  4 A c A  20  y  8.914 mm d1  11.086  10  1.086 mm d 2  18  11.086  6.914 mm I1  I1  A1d12  I 2  I 2  A2d 22  1 (4)(20)3  (80)(1.086) 2  2.761  103 mm 4 12  4 (2) 4  (4 )(6.914)2  0.613  103 mm 4 I  I1  I 2  3.374  103 mm 4  3.374  109 m 4 A  A1  A2  92.566 mm 2  92.566  106 m 2 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 568 PROBLEM 4.115 (Continued) e  32  8.914  40.914 mm  0.040914 m M  Pe  (400 N)(0.040914 m)  16.3656 N  m (a) Point A: A  400 (16.3656)(8.914  103 ) P Mc    6 A I 92.566  10 3.374  109  4.321  106  43.23  106  47.55  106 Pa (b) Point B: B  400 (16.3656)(11.086) P Mc    A I 92.566  106 3.374  109  4.321  106  53.72  106  49.45  106 Pa (c)  A  47.6 MPa  Neutral axis:  B  49.4 MPa  By proportions, a 20  47.55 47.55  49.45 a  9.80 mm 9.80 mm below top of section  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 569 PROBLEM 4.116 P a a The shape shown was formed by bending a thin steel plate. Assuming that the thickness t is small compared to the length a of a side of the shape, determine the stress (a) at A, (b) at B, (c) at C. 90⬚ t B C A P' SOLUTION Moment of inertia about centroid:    a  1 2 2t   12  2 1  ta3 12 I Area: (a) (b) (c)  3   a  a A  2 2t    2at , c  2 2  2 A  P P Pec P    2at A I P P Pec P B     2at A I    a 2 2 a 2 2 3 A   P  2at a 2 B   2P  at C   P  2at    1 ta 12 a 2 1 ta3 12 C   A PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 570 PROBLEM 4.117 P Three steel plates, each of 25  150-mm cross section, are welded together to form a short H-shaped column. Later, for architectural reasons, a 25-mm strip is removed from each side of one of the flanges. Knowing that the load remains centric with respect to the original cross section, and that the allowable stress is 100 MPa, determine the largest force P (a) that could be applied to the original column, (b) that can be applied to the modified column. 50 mm 50 mm SOLUTION (a) Centric loading:   P A A  (3)(150)(25)  11.25  103 mm 2  11.25  103 m 2 P   A  (100  106 )(11.25  103 )  1.125  106 N (b) P  1125 kN  Eccentric loading (reduced cross section): A, 103 mm 2 y , mm 3.75 87.5 328.125 76.5625 3.75 0 0 10.9375     A y (103 mm3 ) 87.5 2.50 10.00 218.75 d , mm 98.4375 109.375 Y  A y 109.375  103   10.9375 mm A 10.00  103 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 571 PROBLEM 4.117 (Continued) The centroid lies 10.9375 mm from the midpoint of the web. I1  1 1 (150)(25)3  (3.75  103 )(76.5625)2  22.177  106 mm 4 b1h13  A1d12  12 12 1 1 I2  b2h23  A2d 22  (25)(150)3  (3.75  103 )(10.9375)2  7.480  106 mm 4 12 12 1 1 (100)(25)3  (2.50  103 )(98.4375) 2  24.355  106 mm 4 I3  b3h33  A3d32  12 12 I  I1  I 2  I 3  54.012  106 mm 4  54.012  106 m 4 c  10.9375  75  25  110.9375 mm  0.1109375 m M  Pe   K  where e  10.4375 mm  10.4375  103 m P Mc P Pec      KP A I A I A  10.00  103 m 2 1 ec 1 (101.9375  103 )(0.1109375)  122.465 m 2    A I 10.00  103 54.012  106 P  K  (100  106 )  817  103 N 122.465 P  817 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 572 y P y B 3 in. y x PROBLEM 4.118 3 in. B A vertical force P of magnitude 20 kips is applied at point C located on the axis of symmetry of the cross section of a short column. Knowing that y  5 in., determine (a) the stress at point A, (b) the stress at point B, (c) the location of the neutral axis. 2 in. C A 4 in. A 2 in. x 2 in. 1 in. (a) (b) SOLUTION Locate centroid. Part A, in 2 y , in.  12 5  8 2  20 Eccentricity of load: e  5  3.8  1.2 in. I1  1 (6)(2)3  (12)(1.2) 2  21.28 in 4 12 I  I1  I 2  57.867 in 4 (a) 1 (2)(4)3  (8)(1.8)2  36.587 in 4 12 P Pec A 20 20(1.2)(3.8)    A I 20 57.867  A  0.576 ksi  P PecB 20 20(1.2)(2.2)    A I 20 57.867  B  1.912 ksi  Stress at B : cB  6  3.8  2.2 in. B   (c) I2  Ay 76   3.8 in. A 20 Stress at A : c A  3.8 in. A   (b) y  Ay , in 3 60 16 76 Location of neutral axis:   0   P Pea ea 1  0   A I I A I 57.867 a   2.411 in. Ae (20)(1.2) Neutral axis lies 2.411 in. below centroid or 3.8  2.411  1.389 in. above point A. Answer: 1.389 in. from point A  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 573 y P y B 3 in. y x PROBLEM 4.119 3 in. B A vertical force P is applied at point C located on the axis of symmetry of the cross section of a short column. Determine the range of values of y for which tensile stresses do not occur in the column. 2 in. C A 4 in. A 2 in. x 2 in. 1 in. (a) (b) SOLUTION Locate centroid.    Eccentricity of load: A, in 2 12 8 20 e  y  3.8 in. I1  y , in. Ay , in 3 5 2 60 16 76 y  e  3.8 in. 1 (6)(2)3  (12)(1.2) 2  21.28 in 4 12 I  I1  I 2  57.867 in 4 If stress at A equals zero, Ai yi 76   3.8 in. 20 Ai 1 (2)(4)3  (8)(1.8) 2  36.587 in 4 12 c A  3.8 in. A   e If stress at B equals zero, I2  y  P Pec A  0 A I  ec A 1  I A I 57.867   0.761 in. Ac A (20)(3.8) y  0.761  3.8  4.561 in. cB  6  3.8  2.2 in. B   1 P PecB ecB  0   A I I A 57.867 I   1.315 in. e (20)(2.2) AcB y  1.315  3.8  2.485 in. Answer: 2.49 in.  y  4.56 in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 574 PROBLEM 4.120 P P P P The four bars shown have the same cross-sectional area. For the given loadings, show that (a) the maximum compressive stresses are in the ratio 4:5:7:9, (b) the maximum tensile stresses are in the ratio 2:3:5:3. (Note: the cross section of the triangular bar is an equilateral triangle.) SOLUTION Stresses: At A, A   At B, B   Aec A  P Pec A P    1  A I A I  P PecB P  AecB      1 A I A I  1 4 1 1  2  A1  a , I1  12 a , c A  cB  2 a, e  2 a     1  1   (a 2 )  a  a     P  2  2    A   1  1 2   A  a    12      2  1  1     (a )  a  a   P  2  2   1     B A 1 2  a    12     4 a  2 2  A2   c  a  c   , I 2  4 c , e  c      P  ( c 2 )(c)(c)   A   1     4 A2   c   4        P  ( c 2 )(c)(c)   B   1   4 A2    c   4    A  4 P  A1 B  2 P  A1  A  5 P  A2 B  3 P  A2 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 575 PROBLEM 4.120 (Continued)  2 1 2 a I3  a4 e  c  A3  a c  2 12     2  2    a  a   (a 2 )  2  2    P    A   1   1 4 A3  a   12          2  2    a  a   (a 2 )    2  2   P   1  B  1 4 A3   a    12      A4   A  7 P  A3  B  5 P  A3  A  9 P  A4 B  3 P  A4 1  3  3 2 (s)  s  s 2  2  4 1  3  3 4 I4  s s  s   36  2  96 3 cA  2 3 s e s 3 2 3 cB  s   3 2   s  s   s       P   4  3  3     A   1   A4 3 4   s   96     3 2   s  s   s       P   4  3  2 3     1 B   A4 3 4   s   96   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 576 PROBLEM 4.121 25 mm An eccentric force P is applied as shown to a steel bar of 25  90-mm cross section. The strains at A and B have been measured and found to be 30 mm  A  350  A 90 mm B 45 mm  B  70  Knowing that E  200 GPa, determine (a) the distance d, (b) the magnitude of the force P. P d 15 mm SOLUTION h  15  45  30  90 mm b  25 mm c 1 h  45 mm  0.045 m 2 A  bh  (25)(90)  2.25  103 mm 2  2.25  103 m 2 I 1 3 1 bh  (25)(90)3  1.51875  106 mm 4  1.51875  106 m 4 12 12 y A  60  45  15 mm  0.015 m yB  15  45  30 mm  0.030 m Stresses from strain gages at A and B: Subtracting,  A B   M   A  E A  (200  109 )(350  106 )  70  106 Pa  B  E B  (200  109 )(70  106 )  14  106 Pa A  P MyA  A I (1) B  P MyB  A I (2) M ( y A  yB ) I I ( A   B ) (1.51875  106 )(84  106 )   2835 N  m y A  yB 0.045 Multiplying (2) by y A and (1) by yB and subtracting, P (a) y A B  yB A  ( y A  yB ) P A A( y A B  yB A ) (2.25  103 )[(0.015)(14  106 )  (0.030)(70  106 )]   94.5  103 N y A  yB 0.045 M   Pd  d   M 2835   0.030 m P 94.5  103 (b) d  30.0 mm  P  94.5 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 577 PROBLEM 4.122 25 mm Solve Prob. 4.121, assuming that the measured strains are  A  600  30 mm PROBLEM 4.121 An eccentric force P is applied as shown to a steel bar of 25  90-mm cross section. The strains at A and B have been measured and found to be A 90 mm B 45 mm  B  420  P  A  350 d  B  70 Knowing that E  200 GPa, determine (a) the distance d, (b) the magnitude of the force P. 15 mm SOLUTION h  15  45  30  90 mm b  25 mm c 1 h  45 mm  0.045 m 2 A  bh  (25)(90)  2.25  103 mm 2  2.25  103 m 2 I 1 3 1 bh  (25)(90)3  1.51875  106 mm 4  1.51875  106 m 4 12 12 y A  60  45  15 mm  0.015 m yB  15  45  30 mm  0.030 m Stresses from strain gages at A and B: A  P My A  A I B  P MyB  A I Subtracting,  A  E A  (200  109 )(600  106 )  120  106 Pa  B  E B  (200  109 )(420  106 )  84  106 Pa (1) (2)  A B   M  M ( y A  yB ) I I ( A   B ) (1.51875  106 )(36  106 )   1215 N  m y A  yB 0.045 Multiplying (2) by y A and (1) by yB and subtracting, P A A( y A B  yB A ) (2.25  103 )[(0.015)(84  106 )  (0.030)(120  106 )]   243  103 N 0.045 y A  yB M 1215 d  5.00 mm    5  103 m M   Pd  d   3 P 243  10 P (a) y A B  yB A  ( y A  yB ) P  243 kN  (b) PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 578 P' PROBLEM 4.123 The C-shaped steel bar is used as a dynamometer to determine the magnitude P of the forces shown. Knowing that the cross section of the bar is a square of side 40 mm and that strain on the inner edge was measured and found to be 450, determine the magnitude P of the forces. Use E  200 GPa. 40 mm 80 mm P SOLUTION At the strain gage location,   E  (200  109 )(450  106 )  90  106 Pa A  (40)(40)  1600 mm 2  1600  106 m 2 I  1 (40)(40)3  213.33  103 mm 4  213.33  109 m 4 12 e  80  20  100 mm  0.100 m c  20 mm  0.020 m   P Mc P Pec     KP A I A I K  1 ec 1 (0.100)(0.020)     10.00  103 m 2 6 A I 1600  10 213.33  109 P  K  90  106  9.00  103 N 10.00  103 P  9.00 kN  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 579 P y 6 in. PROBLEM 4.124 6 in. 10 in. Q B A x x z A z A = 10.0 in2 Iz = 273 in4 A short length of a rolled-steel column supports a rigid plate on which two loads P and Q are applied as shown. The strains at two points A and B on the centerline of the outer faces of the flanges have been measured and found to be  A  400  106 in./in.  B  300  106 in./in. Knowing that E  29  106 psi, determine the magnitude of each load. SOLUTION Stresses at A and B from strain gages:  A  E A  (29  106 )(400  106 )  11.6  103 psi  B  E B  (29  106 )(300  106 )  8.7  103 psi F  PQ Centric force: M  6 P  6Q Bending couple: c  5 in. A   F Mc P  Q (6 P  6Q)(5)    10.0 273 A I 11.6  103  0.00989 P  0.20989Q B   F Mc P  Q (6 P  6Q )(5)    10.0 273 A I 8.7  103  0.20989 P  0.00989Q Solving (1) and (2) simultaneously, P  44.2  103 lb  44.2 kips Q  57.3  103 lb  57.3 kips (1) (2)   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 580 PROBLEM 4.125 y P A single vertical force P is applied to a short steel post as shown. Gages located at A, B, and C indicate the following strains: z  A  500 x  C  200 Knowing that E  29  106 psi, determine (a) the magnitude of P, (b) the line of action of P, (c) the corresponding strain at the hidden edge of the post, where x  2.5 in. and z  1.5 in. C A  B  1000 B 3 in. 5 in. SOLUTION Ix  1 (5)(3)3  11.25 in 4 12 M x  Pz M z   Px Iz  1 (3)(5)3  31.25 in 4 12 A  (5)(3)  15 in 2 x A  2.5 in., xB  2.5 in., xC  2.5 in., xD  2.5 in. z A  1.5 in., z B  1.5 in., zC  1.5 in., z D  1.5 in.  A  E A  (29  106 )(500  106 )  14,500 psi  14.5 ksi  B  E B  (29  106 )(1000  106 )  29, 000 psi  29 ksi  C  E C  (29  106 )(200  106 )  5800 psi  5.8 ksi A   B   C   P M x z A M z xA    0.06667 P  0.13333M x  0.08M z A Ix Iz (1) P M x z B M z xB    0.06667 P  0.13333M x  0.08M z A Ix Iz P M x zC M x   z C  0.06667 P  0.13333M x  0.08M z A Ix Iz (2) (3) Substituting the values for  A ,  B , and  C into (1), (2), and (3) and solving the simultaneous equations gives M x  87 kip  in.  x  z  (c) (a) P  152.3 kips  Mz 90.625   152.25 P (b) x  0.595 in.  Mx 87   152.25 P D    M z  90.625 kip  in. z  0.571 in.  P M x z D M z xD    0.06667 P  0.13333M x  0.08M z A Ix Iz  (0.06667)(152.25)  (0.13333)(87)  (0.08)(90.625)  8.70 ksi Strain at hidden edge:   D E  8.70  103 29  106     300  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 581 PROBLEM 4.126 b ⫽ 40 mm A a ⫽ 25 mm D d B P The eccentric axial force P acts at point D, which must be located 25 mm below the top surface of the steel bar shown. For P  60 kN, determine (a) the depth d of the bar for which the tensile stress at point A is maximum, (b) the corresponding stress at point A. C 20 mm SOLUTION A  bd I 1 bd 3 12 1 1 c d e d a 2 2 P Pec A   A I  1 1  P  1 12 2 d  a 2 d  P  4 6a  A       2 b d d3  b d d     (a) (b)   Depth d for maximum  A : Differentiate with respect to d. A  60  103 40  103 d A P  4 12a    2  3   0 dd b d d  d  3a  4 (6)(25  103 )    40  106 Pa  3 3 2  75 10 (75 10 )     d  75 mm   A  40 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 582 PROBLEM 4.127 y M 300 N · m 60 A z B 16 mm The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. C 16 mm D 40 mm 40 mm SOLUTION Iz  1 (80)(32)3  218.45  103 mm 4  218.45  109 m 4 12 1 I y  (32)(80)3  1.36533  106 mm 4  1.36533  106 m 4 12 y A  yB   yD  16 mm z A   z B   z D  40 mm M y  300cos 30  259.81 N  m (a) (b) (c) A   B   D   M z  300sin 30  150 N  m M z yA M y zA (150)(16  103 ) (259.81)(40  103 )    Iz Iy 218.45  109 1.36533  106  3.37  106 Pa  A  3.37 MPa   18.60  106 Pa  B  18.60 MPa  M z yB M y z B (150)(16  103 ) (259.81)(40  103 )    Iz Iy 218.45  109 1.36533  106 M z yD M y z D (150)(16  103 ) (259.81)(40  103 )    Iz Iy 218.45  109 1.36533  106  3.37  106 Pa  D  3.37 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 583 PROBLEM 4.128 y ␤ ⫽ 30⬚ A The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. B M ⫽ 400 lb · m 0.6 in. z C 0.6 in. D 0.4 in. SOLUTION Iz  1 (0.4)(1.2)3  57.6  10 3 in 4 12 1 I y  (1.2)(0.4)3  6.40  103 in 4 12 y A  yB   yD  0.6 in. 1 z A   z B   z D    (0.4)  0.2 in. 2 M y  400 cos 60  200 lb  in., (a) (b) (c) A   B   D   M z  400 sin 60  346.41 lb  in. M z yA M y zA (346.41)(0.6) (200)(0.2)    Iz Iy 57.6  103 6.40  103  9.86  103 psi  9.86 ksi   2.64  103 psi  2.64 ksi   9.86  103 psi  9.86 ksi  M z yB M y zB (346.41)(0.6) (200)(0.2)    Iz Iy 57.6  106 6.4  103 M z yD M y z D (346.41)(0.6) (200)(0.2)    Iz Iy 57.6  103 6.40  103 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 584 y PROBLEM 4.129 15 A The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. B M 25 kN · m 80 mm C z 20 mm 80 mm D 30 mm SOLUTION M y  25sin 15  6.4705 kN  m M z  25cos15  24.148 kN  m Iy  1 1 (80)(90)3  (80)(30)3  5.04  106 mm 4 12 12 6 4 I y  5.04  10 m 1 1 1 I z  (90)(60)3  (60)(20)3  (30)(100)3  16.64  106 mm 4  16.64  106 m 4 3 3 3 Stress: (a) A    M yz Iy  Mzy Iz (6.4705 kN  m)(0.045 m) (24.148 kN  m)(0.060 m)  5.04  106 m 4 16.64  106 m 4  57.772 MPa  87.072 MPa (b) B  (6.4705 kN  m)(0.045 m) (24.148 kN  m)(0.060 m)  5.04  106 m 4 16.64  106 m 4  57.772 MPa  87.072 MPa (c) D  (6.4705 kN  m)(0.015 m) (24.148 kN  m)(0.100 m)  5.04  106 m 4 16.64  106 m 4  19.257 MPa  145.12 MPa  A  29.3 MPa   B  144.8 MPa   D  125.9 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 585 y PROBLEM 4.130 20 M 10 kip · in. A z 3 in. The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. 2 in. C B 3 in. D 2 in. 4 in. SOLUTION Locate centroid. A, in 2   Σ The centroid lies at point C. z , in. 16 1 Az , in 3 8 2 16 16 24 0 Iz  1 1 (2)(8)3  (4)(2)3  88 in 4 12 12 1 1 I y  (8)(2)3  (2)(4)3  64 in 4 3 3 y A   yB  1 in., yD  4 in. z A  z B  4 in., zD  0 M z  10 cos 20  9.3969 kip  in. M y  10 sin 20  3.4202 kip  in. (a) A   (b) B   (c) D   M z yA M y zA (9.3969)(1) (3.4202)(4)    88 64 Iz Iy M z yB M y z B (9.3969)( 1) (3.4202)( 4)    88 64 Iz Iy M z yD M y z D (9.3969)(4) (3.4202)(0)    88 64 Iz Iy  A  0.321 ksi   B  0.107 ksi   D  0.427 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 586 PROBLEM 4.131 y M 5 60 kip · in. b 5 508 A B 3 in. The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. C z 3 in. D 1 in. 1 in. 2.5 in. 2.5 in. 5 in. 5 in. SOLUTION M z  60 sin 40  38.567 kip  in. M y  60 cos 40  45.963 kip  in. y A  yB   yD  3 in. z A   z B   z D  5 in. Iz  Iy  (a) A   1   (10)(6)3  2  (1) 2   178.429 in 4 12 4  1   (6)(10)3  2  (1) 4   (1) 2 (2.5) 2   459.16 in 4 12 4   M z yA M y zA (38.567)(3) (45.963)(5)    Iz Iy 178.429 459.16  1.149 ksi (b) (c) B   D   M z yB M y z B (38.567)(3) (45.963)(5)    Iz Iy 178.429 459.16  A  1.149 ksi   0.1479  B  0.1479 ksi   1.149 ksi  D  1.149 ksi  M z yD M y z D (38.567)(3) (45.963)(5)    178.429 459.16 Iz Iy PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 587 y PROBLEM 4.132 M 5 75 kip · in. b 5 758 A 2.4 in. B 1.6 in. z The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. C D 4 in. 4.8 in. SOLUTION Iz  1 1 (4.8)(2.4)3  (4)(1.6)3  4.1643 in 4 12 12 1 1 I y  (2.4)(4.8)3  (1.6)(4)3  13.5851 in 4 12 12 y A  yB   yD  1.2 in. z A   z B   z D  2.4 in. M z  75sin15  19.4114 kip  in. M y  75cos15  72.444 kip  in. (a) A   (b) B   (c) D   M z yA M y zA (19.4114)(1.2) (72.444)(2.4)    Iz Iy 4.1643 13.5851 M z yB M y z B (19.4114)(1.2) (72.444)(2.4)    4.1643 13.5851 Iz Iy M z yD M y z D (19.4114)(1.2) (72.444)(2.4)    4.1643 13.5851 Iz Iy  A  7.20 ksi   B  18.39 ksi   D  7.20 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 588 y PROBLEM 4.133 ␤ ⫽ 30⬚ M ⫽ 100 N · m The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. B z C D A r ⫽ 20 mm SOLUTION Iz   8    4r      r 4   r 2   8  2  3   8 9 2  4 r   (0.109757)(20) 4  17.5611  103 mm 4  17.5611  109 m 4 Iy   8 r4  y A  yD    (20) 4 8  62.832  103 mm 4  62.832  109 m 4 4r (4)(20)   8.4883 mm 3 3 yB  20  8.4883  11.5117 mm z A   z D  20 mm zB  0 M z  100 cos30  86.603 N  m M y  100sin 30  50 N  m (a) (b) (c) A   B   D   (86.603)(8.4883  103 ) (50)(20  103 ) M z yA M y zA    Iz Iy 17.5611  109 62.832  109  57.8  106 Pa (86.603)(11.5117  10 ) (50)(0) M z yB M y z B    9 Iz Iy 17.5611  10 62.832  109 3  56.8  106 Pa (86.603)(8.4883  10 ) (50)(20  10 ) M z yD M y z D    Iz Iy 17.5611  109 62.832  109 3  25.9  106 Pa  A  57.8 MPa   B  56.8 MPa  3  D  25.9 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 589 W310 ⫻ 38.7 15 PROBLEM 4.134 B A C 310 mm The couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Determine the stress at (a) point A, (b) point B, (c) point D. M ⫽ 16 kN · m D E 165 mm SOLUTION For W310  38.7 rolled steel shape, I z  84.9  106 mm 4  84.9  106 m 4 I y  7.20  106 mm 4  7.20  106 m 4 1 1 yD   yE    (310)  155 mm 2 2 1 z A  z E   z B   z D    (165)  82.5 mm 2 y A  yB  M z  (16  103 ) cos 15  15.455  103 N  m M y  (16  103 ) sin 15  4.1411  103 N  m (a) tan   Iz 84.9  106 tan   tan 15  3.1596 I 7.20  106   72.4   72.4  15  57.4 (b)  Maximum tensile stress occurs at point E. E   M z yE M y z E (15.455  103 )(155  103 ) (4.1411  103 )(82.5  103 )    Iz Iy 84.9  106 7.20  106  75.7  106 Pa  75.7 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 590 PROBLEM 4.135 208 S6 3 12.5 A M 5 15 kip · in. B C E The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam. 3.33 in. 6 in. D SOLUTION For S6  12.5 rolled steel shape, I z  22.0 in 4 I y  1.80 in 4 zE   z A   zB  zD  1 (3.33)  1.665 in. 2 1 y A  yB   yD   yE  (6)  3 in. 2 M z  15 sin 20  5.1303 kip  in. M y  15 cos 20  14.095 kip  in. (a) tan   Iz 22.0 tan   tan (90  20)  33.58 Iy 1.80   88.29   88.29  70  18.29 (b)  Maximum tensile stress occurs at point D. D   M z yD M y z D (5.1303)(3) (14.095)(1.665)     13.74 ksi Iz Iy 22.0 1.80  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 591 PROBLEM 4.136 5⬚ C150 ⫻ 12.2 B A M ⫽ 6 kN · m 152 mm C The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam. 13 mm E D 48.8 mm SOLUTION M y  6 sin 5  0.52293 kN  m M z   6 cos 5  5.9772 kN  m C150  12.2 I y  0.286  106 m 4 I z   5.45  106 m 4 (a) Neutral axis: tan   I z 5.45  106 m 4 tan   tan 5 I y 0.286  106 m 4 tan   1.66718   59.044     5 (b)   54.0 Maximum tensile stress at E: y E  76 mm, zE  13 mm E   M y zE I y  M z  yE (0.52293 kN  m)(0.013 m) (5.9772 kN  m)(0.076 m)   I z 0.286  106 m 4 5.45  106 m 4   E  107.1 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 592 y' PROBLEM 4.137 30⬚ B 50 mm A 5 mm 5 mm C M 400 N · m z' The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam. D E 18.57 mm 5 mm 50 mm Iy' ⫽ 281 ⫻ 103 mm4 Iz' ⫽ 176.9 ⫻ 103 mm4 SOLUTION I z  176.9  103 mm 4  176.9  109 m 4 I y  281  103 mm 4  281  109 m 4 yE  18.57 mm, z E  25 mm M z  400 cos 30  346.41 N  m M y  400sin 30  200 N  m (a) tan   I z 176.9  109 tan    tan 30  0.36346 I y 281  109   19.97   30  19.97 (b)   10.03  Maximum tensile stress occurs at point E. E   (346.41)(18.57  103 ) (200)(25  103 ) M z  yE M y zE    I z I y 176.9  109 281  109  36.36  106  17.79  106  54.2  106 Pa  E  54.2 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 593 458 PROBLEM 4.138 y' B z' 0.859 in. M 5 15 kip · in. C A 1 2 in. 4 in. D The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam. 4 in. 4 in. Iy' 5 6.74 in4 Iz' 5 21.4 in4 SOLUTION I z  21.4 in 4 I y  6.74 in 4 z A  z B  0.859 in. y A  4 in. z D  4  0.859 in.  3.141 in. yB  4 in. yD  0.25 in. M y  15 sin 45  10.6066 kip  in. M z  15 cos 45  10.6066 kip  in. (a) Angle of neutral axis: tan   I z 21.4 tan   tan (45)  3.1751 6.74 I y   72.5   72.5  45    27.5    (b) The maximum tensile stress occurs at point D. D   M z yD M y z D (10.6066)(0.25) (10.6066)(3.141)    Iz Iy 21.4 6.74  0.12391  4.9429  D  5.07 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 594 y' 20⬚ PROBLEM 4.139 B 10 mm A The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam. 6 mm M 120 N · m C z' 10 mm D 6 mm E Iy' ⫽ 14.77 ⫻ 103 mm4 Iz' ⫽ 53.6 ⫻ 103 mm4 10 mm 10 mm SOLUTION I z  53.6  103 mm 4  53.6  109 m 4 I y  14.77  103 mm 4  14.77  109 m 4 M z  120 sin 70  112.763 N  m M y  120 cos 70  41.042 N  m (a) Angle of neutral axis:   20 tan   I z 53.6  109 tan   tan 20  1.32084 I y 14.77  109   52.871   52.871  20 (b)   32.9  The maximum tensile stress occurs at point E. yE  16 mm  0.016 m z E  10 mm  0.010 m M y  M y z E  E   z E  I z I y  (112.763)(0.016) (41.042)(0.010)  53.6  109 14.77  109  61.448  106 Pa  E  61.4 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 595 PROBLEM 4.140 208 A 90 mm M 5 750 N · m C The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine (a) the angle that the neutral axis forms with the horizontal, (b) the maximum tensile stress in the beam. B 30 mm 25 mm 25 mm SOLUTION M y  750 sin 20 M y  256.5 N  m M z   750 cos 20 M z   704.8 N  m 1  I y  2  (90)(25)3   0.2344  106 mm 4 12   I y  0.2344  106 m 4 I z  (a) Neutral axis: tan   1 (50)(90)3  1.0125  106 mm 4  1.0125  106 m 4 36 I z 1.0125  106 m 4 tan   tan 20 I y 0.2344  106 m 4 tan   1.5724   57.5      20  57.5  30  37.5 (b) Maximum tensile stress, at D: yD  30 mm D  M y zD I y  z  25 mm M z  yD (256.5 N  m)(0.030 m) (704.8 N  m)(0.025 m)   I z 0.2344  106 m 4 1.0125  106 m 4  32.83 MPa  17.40 MPa  50.23 MPa   37.5   D  50.2 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 596 A PROBLEM 4.141 y 40 mm z 10 mm C M 1.2 kN · m 10 mm 40 mm 70 mm The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine the stress at point A. 10 mm Iy 1.894 ⫻ 106 mm4 Iz ⫽ 0.614 ⫻ 106 mm4 Iyz ⫽ ⫹0.800 ⫻ 106 mm4 SOLUTION Using Mohr’s circle, determine the principal axes and principal moments of inertia. Y : (1.894, 0.800)  106 mm 4 Z : (0.614, 0.800)  106 mm 4 E : (1.254, 0)  106 mm 4 R  EF  FZ  0.6402  0.8002  106  1.0245  106 mm 4 2 2 I v  (1.254  1.0245)  106 mm 4  0.2295  106 mm 4  0.2295  106 m 4 I u  (1.254  1.0245)  106 mm 4  2.2785  106 mm 4  2.2785  106 m 4 FZ 0.800  106   1.25  m  25.67 FE 0.640  106 M v  M cos  m  (1.2  103 ) cos 25.67  1.0816  103 N  m tan 2 m  M u   M sin  m  (1.2  103 ) sin 25.67  0.5198  103 N  m u A  y A cos  m  z A sin  m  45 cos 25.67  45 sin 25.67  21.07 mm v A  z A cos  m  y A sin  m  45 cos 25.67  45 sin 25.67  60.05 mm A   M v u A M u vA (1.0816  103 )(21.07  103 ) ( 0.5198  103 )(60.05  103 )    Iu Iv 0.2295  106 2.2785  106  A  113.0 MPa   113.0  106 Pa PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 597 y PROBLEM 4.142 A 2.4 in. The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine the stress at point A. 2.4 in. z M 125 kip · in. C 2.4 in. 2.4 in. 2.4 in. 2.4 in. SOLUTION 1  I y  2  (7.2)(2.4)3   66.355 in 4 3  1  I z  2  (2.4)(7.2)3  (2.4)(7.2)(1.2) 2   199.066 in 4 12  I yz  2 (2.4)(7.2)(1.2)(1.2)  49.766 in 4 Using Mohr’s circle, determine the principal axes and principal moments of inertia. Y : (66.355 in 4 , 49.766 in 4 ) Z : (199.066 in 4 ,  49.766 in 4 ) E : (132.710 in 4 , 0) PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 598 PROBLEM 4.142 (Continued) tan 2 m  DY 49.766  DE 66.355 2 m  36.87  m  18.435 R  DE  DY  82.944 in 4 2 2 I u  132.710  82.944  49.766 in 4 I v  132.710  82.944  215.654 in 4 M u  125sin18.435  39.529 kip  in. M v  125cos18.435  118.585 kip  in. u A  4.8 cos 18.435  2.4 sin 18.435  5.3126 in.  A  4.8 sin 18.435  2.4 cos 18.435  0.7589 in. M u M A    A  u A  I Iu (118.585)(5.3126) (39.529)(0.7589)  215.654 49.766  2.32 ksi  A  2.32 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 599 y PROBLEM 4.143 1.08 in. 0.75 in. The couple M acts in a vertical plane and is applied to a beam oriented as shown. Determine the stress at point A. 2.08 in. z C M 5 60 kip · in. 6 in. 0.75 in. A 4 in. Iy 5 8.7 in4 Iz 5 24.5 in4 Iyz 5 18.3 in4 SOLUTION Using Mohr’s circle, determine the principal axes and principal moments of inertia. Y : (8.7, 8.3) in 4 Z : (24.5,  8.3) in 4 E : (16.6, 0) in 4 EF  7.9 in 4 FZ  8.3 in 4 R  7.92  8.32  11.46 in 4 tan 2 m   m  23.2 I u  16.6  11.46  5.14 in 4 FZ 8.3   1.0506 EF 7.9 I v  16.6  11.46  28.06 in 4 M u  M sin  m  (60) sin 23.2  23.64 kip  in. M v  M cos  m  (60) cos 23.2  55.15 kip  in. u A  y A cos  m  z A sin  m  3.92cos 23.2  1.08 sin 23.2  4.03 in. v A  z A cos  m  y A sin  m  1.08cos 23.2  3.92 sin 23.2  0.552 in. A   M vu A M u vA (55.15)(4.03) (23.64)(0.552)    28.06 5.14 Iv Iu  A  10.46 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 600 PROBLEM 4.144 D H 14 kN B The tube shown has a uniform wall thickness of 12 mm. For the loading given, determine (a) the stress at points A and B, (b) the point where the neutral axis intersects line ABD. G 28 kN 125 mm E A F 28 kN 75 mm SOLUTION Add y- and z-axes as shown. Cross section is a 75 mm  125-mm rectangle with a 51 mm  101-mm rectangular cutout. Iz  1 1 (75)(125)3  (51)(101)3  7.8283  106 mm 4  7.8283  106 m 4 12 12 1 1 I y  (125)(75)3  (101)(51)3  3.2781  103 mm 4  3.2781  106 m 4 12 12 A  (75)(125)  (51)(101)  4.224  103 mm 2  4.224  103 m 2 Resultant force and bending couples: P  14  28  28  70 kN  70  103 N M z  (62.5 mm)(14 kN)  (62.5 mm)(28kN)  (62.5 mm)(28 kN)  2625 N  m M y  (37.5 mm)(14 kN)  (37.5 mm)(28 kN)  (37.5 mm)(28 kN)  525 N  m (a) A  P M z yA M y zA 70  103 (2625)(0.0625) ( 525)(0.0375)      3 A Iz Iy 4.224  10 7.8283  106 3.2781  106  A  31.5 MPa   31.524  106 Pa B  P M z yB M y z B 70  103 (2625)(0.0625) (525)(0.0375)      3 A Iz Iy 4.224  10 7.8283  106 3.2781  106  10.39  106 Pa (b)  B  10.39 MPa  Let point H be the point where the neutral axis intersects AB. z H  0.0375 m, 0 yH  ?,  H  0 P M z yH M y z H   A Iz Iy  P Mz H  7.8283  106  70  103 (525)(0.0375)         3 A I y  2625 3.2781  106   4.224  10   0.03151 m  31.51 mm yH  Iz Mz 31.51  62.5  94.0 mm Answer: 94.0 mm above point A.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 601 PROBLEM 4.145 A horizontal load P of magnitude 100 kN is applied to the beam shown. Determine the largest distance a for which the maximum tensile stress in the beam does not exceed 75 MPa. y 20 mm a 20 mm O z x P 20 mm 60 mm 20 mm SOLUTION Locate the centroid.   ∑ Move coordinate origin to the centroid. Coordinates of load point: Bending couples: Ix  X P  a, M x  yP P A, mm2 y , mm 2000 10 1200 3200 –10 Ay , mm3 20  103 12  103 8  103 Ay Y  A 8  103 3200  2.5 mm  yP  2.5 mm M y  aP 1 1 (100)(20)3  (2000)(7.5) 2  (60)(20)3  (1200)(12.5) 2  0.40667  106 mm 4 12 12  0.40667  106 m 4 Iy  1 1 (20)(100)3  (20)(60)3  2.0267  106 mm 4  2.0267  106 m 4 12 12 P M y M x    x  y  A  75  106 Pa, P  100  103 N A Ix Iy PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 602 PROBLEM 4.145 (Continued) My  My   Iy P Mxy     x A Ix  For point A, x  50 mm, y  2.5 mm 2.0267  106  100  103 (2.5)(100  103 )(2.5  103 )    75  106   3 6 6 50  10 0.40667  10  3200  10  2.0267  106 {31.25  1.537  75}  106  1.7111  103 N  m 50  103 a My P  (1.7111  103 )  17.11  103 m 3 100  10 a  17.11 mm  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 603 1 in. PROBLEM 4.146 1 in. 4 in. Knowing that P  90 kips, determine the largest distance a for which the maximum compressive stress dose not exceed 18 ksi. 5 in. P 1 in. a 2.5 in. SOLUTION A  (5 in.)(6 in.)  2(2 in.)(4 in.)  14 in 2 Ix  1 1 (5 in.)(6 in.)3  2 (2 in.)(4 in.)3  68.67 in 4 12 12 1 1 (4 in.)(1 in.)3  21.17 in 4 I z  2 (1 in.)(5 in.)3  12 12 Force-couple system at C: For P  90 kips: P P 18 ksi   M z  Pa P  90 kips M x  (90 kips)(2.5 in.)  225 kip  in. Maximum compressive stress at B: B   M x  P(2.5 in.)  B  18 ksi M z  (90 kips) a P M x (3 in.) M z (2.5 in.)   A Ix Iz 90 kips (225 kip  in.)(3 in.) (90 kips) a (2.5 in.)   14 in 2 68.67 in 4 21.17 in 4 18  6.429  9.830  10.628a 1.741  10.628 a a  0.1638 in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 604 1 in. PROBLEM 4.147 1 in. 4 in. Knowing that a  1.25 in., determine the largest value of P that can be applied without exceeding either of the following allowable stresses: 5 in. P 1 in.  ten  10 ksi a 2.5 in.  comp  18 ksi SOLUTION A  (5 in.)(6 in.)  (2)(2 in.)(4 in.)  14 in 2 Ix  1 1 (5 in.)(6 in.)3  2 (2 in.)(4 in.)3  68.67 in 4 12 12 1 1 (4 in.)(1 in.)3  21.17 in 4 I z  2 (1 in.)(5 in.)3  12 12 Force-couple system at C: P  P M x  P(2.5 in.) For a  1.25 in., M y  Pa  (1.25 in.) Maximum compressive stress at B: B   18 ksi    B  18 ksi P M x (3 in.) M z (2.5 in.)   A Ix Iz P P(2.5 in.)(3 in.) P(1.25 in.)(2.5 in.)   2 14 in 68.67 in 4 21.17 in 4 18   0.0714P  0.1092 P  0.1476 P 18  0.3282P P  54.8 kips Maximum tensile stress at D:  D  10 ksi D   P M x (3 in.) M z (2.5 in.)   A Ix Iz 10 ksi   0.0714 P  0.1092 P  0.1476 P 10  0.1854 P The smaller value of P is the largest allowable value. P  53.9 kips P  53.9 kips  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 605 y R 125 mm C z P 4 kN PROBLEM 4.148 E A rigid circular plate of 125-mm radius is attached to a solid 150  200-mm rectangular post, with the center of the plate directly above the center of the post. If a 4-kN force P is applied at E with   30, determine (a) the stress at point A, (b) the stress at point B, (c) the point where the neutral axis intersects line ABD. x A D B 200 mm 150 mm SOLUTION P  4  103 N (compression) M x   PR sin 30  (4  103 )(125  103 )sin 30  250 N  m M z   PR cos 30  (4  103 )(125  103 ) cos 30  433 N  m Ix  1 (200)(150)3  56.25  106 mm 4  56.25  106 m 4 12 1 (150)(200)3  100  106 mm 4  100  106 m 4 Iz  12  x A  xB  100 mm z A  z B  75 mm A  (200)(150)  30  103 mm 2  30  103 m 2 (a) A   P M x z A M z xA 4  103 (250)(75  103 ) (433)(100  103 )      A Ix Iz 30  103 56.25  106 100  106  A  633  103 Pa  633 kPa  (b) B   P M x z B M z xB 4  103 (250)(75  103 ) (433)(100  103 )      A Ix Iz 30  103 56.25  106 100  106  B  233  103 Pa  233 kPa  (c) Let G be the point on AB where the neutral axis intersects. G  0 G   xG  zG  75 mm P M x zG M z xG   0 A Ix Iz xG  ? I z  P M x zG  100  106  4  103 (250)(75  103 )        Mz  A Ix  433  30  103 56.25  106   46.2  103 m  46.2 mm Point G lies 146.2 mm from point A.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 606 y R 125 mm C z P 4 kN PROBLEM 4.149 E In Prob. 4.148, determine (a) the value of θ for which the stress at D reaches it largest value, (b) the corresponding values of the stress at A, B, C, and D. x A D B 200 mm 150 mm PROBLEM 4.148 A rigid circular plate of 125-mm radius is attached to a solid 150  200-mm rectangular post, with the center of the plate directly above the center of the post. If a 4-kN force P is applied at E with   30, determine (a) the stress at point A, (b) the stress at point B, (c) the point where the neutral axis intersects line ABD. SOLUTION P  4  103 N (a) PR  (4  103 )(125  103 )  500 N  m M x   PR sin   500sin  Ix  M x   PR cos   500 cos  1 (200)(150)3  56.25  106 mm 4  56.25  106 m 4 2 1 I z  (150)(200)3  100  106 mm 4  100  106 m 4 2 xD  100 mm z D  75 mm   A  (200)(150)  30  103 mm 2  30  103 m 2  1 Rz sin  P M xz M zx Rx cos      P     A Ix Iz Ix Iz  A For  to be a maximum, d 0 d with z  z D , x  xD  d D Rz cos  RxD sin     P 0  D  0 d Ix IZ   sin  (100  106 )(75  103 ) 4 I z  tan    z D    6 3 cos  I x xD (56.25  10 )(100  10 ) 3 (b) A   sin   0.8, cos   0.6   53.1  P M x z A M z xA 4  103 (500)(0.8)(75  103 ) (500)(0.6)(100  103 )      A Ix Iz 30  103 56.25  106 100  106  (0.13333  0.53333  0.300)  106 Pa  0.700  106 Pa  B  (0.13333  0.53333  0.300)  106 Pa  0.100  106 Pa  C  (0.13333  0  0)  106 Pa  D  (0.13333  0.53333  0.300)  106 Pa   0.967  106 Pa  A  700 kPa   B  100 kPa   C  133.3 kPa   D  967 kPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 607 y PROBLEM 4.150 0.5 in. 1.43 in. z M0 C 5 in. 0.5 in. 1.43 in. A beam having the cross section shown is subjected to a couple M 0 that acts in a vertical plane. Determine the largest permissible value of the moment M 0 of the couple if the maximum stress in the beam is not to exceed 12 ksi. Given: I y  I z  11.3 in 4 , A  4.75 in 2 , kmin  0.983 in. (Hint: By reason of symmetry, the principal axes form 2 an angle of 45 with the coordinate axes. Use the relations I min  Akmin and I min  I max  I y  I z .) 5 in. SOLUTION M u  M 0 sin 45  0.70711M 0 M v  M 0 cos 45  0.70711M 0 2  (4.75)(0.983)2  4.59 in 4 I min  Akmin I max  I y  I z  I min  11.3  11.3  4.59  18.01 in 4 u B  yB cos 45  z B sin 45  3.57 cos 45  0.93 sin 45  1.866 in. vB  z B cos 45  yB sin 45  0.93 cos 45  (3.57) sin 45  3.182 in. B    u M vu B M u vB v    0.70711M 0   B  B  Iv Iu I max   I min  (1.866) 3.182   0.70711M 0     0.4124M 0 4.59 18.01   M0  B 0.4124  12 0.4124 M 0  29.1 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 608 PROBLEM 4.151 y 0.5 in. Solve Prob. 4.150, assuming that the couple M 0 acts in a horizontal plane. 1.43 in. z M0 C 5 in. 0.5 in. 1.43 in. 5 in. SOLUTION PROBLEM 4.150 A beam having the cross section shown is subjected to a couple M 0 that acts in a vertical plane. Determine the largest permissible value of the moment M 0 of the couple if the maximum stress in the beam is not to exceed 12 ksi. Given: I y  I z  11.3 in 4, A  4.75 in 2, kmin  0.983 in. (Hint: By reason of symmetry, the principal axes form an angle of 45 with the coordinate axes. Use the 2 relations I min  Akmin and I min  I max  I y  I z .) M u  M 0 cos 45  0.70711M 0 M v  M 0 sin 45   0.70711M 0 2  (4.75)(0.983)2  4.59 in 4 I min  Akmin I max  I y  I z  I min  11.3  11.3  4.59  18.01 in 4 uD  yD cos 45  z D sin 45  0.93 cos 45  (3.57 sin 45)  1.866 in. vD  z D cos 45  yD sin 45  (3.57) cos 45  (0.93) sin 45  3.182 in. D    u M v u D M u vD v    0.70711M 0   D  D  Iv Iu I max   I min  (1.866) 3.182   0.70711M 0     0.4124M 0 4.59 18.01   M0  D 0.4124  12 0.4124 M 0  29.1 kip  in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 609 PROBLEM 4.152 y z M0 40 mm 10 mm C 10 mm 40 mm 70 mm 10 mm The Z section shown is subjected to a couple M 0 acting in a vertical plane. Determine the largest permissible value of the moment M 0 of the couple if the maximum stress is not to exceed 80 MPa. Given: I max  2.28  106 mm 4 , I min  0.23  106 mm 4 , principal axes 25.7 and 64.3 . SOLUTION I v  I max  2.28  106 mm 4  2.28  106 m 4 I u  I min  0.23  106 mm 4  0.23  106 m 4 M v  M 0 cos 64.3 M u  M 0 sin 64.3   64.3 tan   Iv tan  Iu 2.28  106 tan 64.3 0.23  106  20.597    87.22 Points A and B are farthest from the neutral axis. uB  yB cos 64.3  z B sin 64.3  (45) cos 64.3  (35) sin 64.3  51.05 mm vB  z B cos 64.3  yB sin 64.3  (35) cos 64.3  (45) sin 64.3  25.37 mm B   80  106   M v u B M u vB  Iv Iu (M 0 cos 64.3)(51.05  103 ) (M 0 sin 64.3)(25.37  103 )  0.23  106 2.28  106  109.1  103 M 0 M0  80  106 109.1  103 M 0  733 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 610 PROBLEM 4.153 y z M0 40 mm 10 mm C 10 mm 40 mm 70 mm 10 mm Solve Prob. 4.152 assuming that the couple M 0 acts in a horizontal plane. PROBLEM 4.152 The Z section shown is subjected to a couple M 0 acting in a vertical plane. Determine the largest permissible value of the moment M 0 of the couple if the maximum stress is not to exceed 80 MPa. Given: I max  2.28  106 mm 4 , I min  0.23  106 mm 4 , principal axes and 64.3 . 25.7 SOLUTION I v  I min  0.23  106 mm 4  0.23  106 m 4 I u  I max  2.28  106 mm 4  2.28  106 m 4 M v  M 0 cos 64.3 M u  M 0 sin 64.3   64.3 tan   Iv tan  Iu 0.23  106 tan 64.3 2.28  106  0.20961    11.84 Points D and E are farthest from the neutral axis. u D  yD cos 25.7  z D sin 25.7  (5) cos 25.7  45 sin 25.7  24.02 mm vD  z D cos 25.7  yD sin 25.7  45cos 25.7  (5) sin 25.7  38.38 mm D   (M D cos 64.3)(24.02  103 ) M vu D M u vD   Iv Iu 0.23  106  (M 0 sin 64.3)(38.38  103 ) 2.28  106 80  106  60.48  103 M 0 M 0  1.323 kN  m  M 0  1.323  103 N  m PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 611 PROBLEM 4.154 y 0.3 in. M0 C z 0.3 in. 1.5 in. 0.6 in. 1.5 in. 0.6 in. An extruded aluminum member having the cross section shown is subjected to a couple acting in a vertical plane. Determine the largest permissible value of the moment M 0 of the couple if the maximum stress is not to exceed 12 ksi. Given: I max  0.957 in 4 , I min  0.427 in 4 , principal axes 29.4 and 60.6  SOLUTION I u  I max  0.957 in 4 I v  I min  0.427 in 4 M u  M 0 sin 29.4, M v  M 0 cos 29.4   29.4 tan   0.427 Iv tan   tan 29.4 Iu 0.957  0.2514   14.11 Point A is farthest from the neutral axis. y A  0.75 in., z A  0.75 in. u A  y A cos 29.4  z A sin 29.4  1.0216 in. v A  z A cos 29.4  y A sin 29.4  0.2852 in. A   M0  (M cos 29.4)(1.0216) (M 0 sin 29.4)(0.2852) M vu A MV  u A  0  0.427 0.957 Iv Iu A 1.9381  1.9381 M 0  M 0  6.19 kip  in.  12 1.9381 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 612 PROBLEM 4.155 y 20 mm z A beam having the cross section shown is subjected to a couple M0 acting in a vertical plane. Determine the largest permissible value of the moment M0 of the couple if the maximum stress is not to exceed 100 MPa. Given: I y  I z  b 4 /36 and I yz  b 4 /72. M0 C b = 60 mm 20 mm b = 60 mm SOLUTION I y  Iz  I yz b 4 604   0.360  106 mm 4 36 36 b 4 604    0.180  106 mm 4 72 72 Principal axes are symmetry axes. Using Mohr’s circle, determine the principal moments of inertia. R  I yz  0.180  106 mm 4 Iv  I y  Iz R 2  0.540  106 mm 4  0.540  106 m 4 I y  Iz R Iu  2  0.180  106 mm 4  0.180  106 m 4 M u  M 0 sin 45  0.70711M 0 ,   45   71.56 Point A: uA  0 A   M0   tan   M v  M 0 cos 45  0.70711M 0 Iv 0.540  106 tan   tan 45  3 Iu 0.180  106 v A  20 2 mm M vu A M u vA (0.70711M 0 )(20 2  103 )  0  11.11  103 M 0 Iv Iu 0.180  106 A 111.11  103  100  106  900 N  m 111.11  103 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 613 PROBLEM 4.155 (Continued) Point B: uB   60 2 mm, vB  20 2  mm   (0.70711M 0 )  602  103 (0.70711M 0 ) 202  103 M v u B M u vB    B   Iv Iu 0.540  106 0.180  106   111.11  103 M 0 M0  B 111.11  103  100  106  900 N  m 111.11  103 Choose the smaller value. M 0  900 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 614 b PROBLEM 4.156 B A Show that, if a solid rectangular beam is bent by a couple applied in a plane containing one diagonal of a rectangular cross section, the neutral axis will lie along the other diagonal. h M C D E SOLUTION tan   b h M z  M cos  , M z  M sin  Iz  1 3 bh 12 Iy  1 3 hb 12 1 3 bh b Iz h   tan   tan   12 1 Iy b hb3 h 12 The neutral axis passes through corner A of the diagonal AD.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 615 PROBLEM 4.157 y D A A D P B x z C h 6 x z (a) Show that the stress at corner A of the prismatic member shown in part a of the figure will be zero if the vertical force P is applied at a point located on the line x z  1 b /6 h /6 h B b (a) (b) C b 6 (b) Further show that, if no tensile stress is to occur in the member, the force P must be applied at a point located within the area bounded by the line found in part a and three similar lines corresponding to the condition of zero stress at B, C, and D, respectively. This area, shown in part b of the figure, is known as the kern of the cross section. SOLUTION Iz  1 3 1 3 hb Ix  bh 12 12 h b zA   xA   2 2 Let P be the load point. M z   PxP A      A  0, (a) For (b) At point E: At point F: 1 x z  0 b/6 h/6 z  0  xE  b /6 A  bh M x  Pz P P M z xA M x z A   A Iz Ix   ( PxP )  b2 ( Pz P  h2 ) P   3 1 hb 1 bh3 bh 12 12 P  x z  1 P  P   bh  b /6 h/6  x z  1 b/6 h/6 x  0  z F  h/6 If the line of action ( xP , z P ) lies within the portion marked TA , a tensile stress will occur at corner A. By considering  B  0,  C  0, and  D  0, the other portions producing tensile stresses are identified. PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 616 PROBLEM 4.158 y A beam of unsymmetric cross section is subjected to a couple M 0 acting in the horizontal plane xz. Show that the stress at point A, of coordinates y and z, is z A  A y C z zI z  yI yz 2 I y I z  I yz My x where Iy, Iz, and Iyz denote the moments and product of inertia of the cross section with respect to the coordinate axes, and My the moment of the couple. SOLUTION The stress  A varies linearly with the coordinates y and z. Since the axial force is zero, the y- and z-axes are centroidal axes:  A  C1 y  C2 z where C1 and C2 are constants. M z    y AdA  C1 y 2dA  C2  yz dA   I zC1  I yzC2  0 C1   I yz Iz C2 M y   z AdA  C1 yz dA  C2  z 2dA  I yzC1  I yC2  I yz  I yz Iz C2  I y C2  2 I z M y  I y I z  I yz C2 C2  IzM y 2 I y I z  I yz C1   A  I yz M y 2 I y I z  I yz I z z  I yz y 2 I y I z  I yz My  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 617 PROBLEM 4.159 y A beam of unsymmetric cross section is subjected to a couple M 0 acting in the vertical plane xy. Show that the stress at point A, of coordinates y and z, is z A  A y C z yI y  zI yz 2 I y I z  I yz Mz x where I y , I z , and I yz denote the moments and product of inertia of the cross section with respect to the coordinate axes, and M z the moment of the couple. SOLUTION The stress  A varies linearly with the coordinates y and z. Since the axial force is zero, the y- and z-axes are centroidal axes:  A  C1 y  C2 z where C1 and C2 are constants. M y   z AdA  C1  yz dA  C2  z 2dA  I yzC1  I yC2  0 C2   I yz Iy C1 M z   y Adz  C1 y 2dA  C2  yz dA   I z C1  I yz  I yz  Iy C1 2 I y M z   I y I z  I yz C1 C1   C2   A   I yM z 2 I y I z  I yz I yz M z 2 I y I z  I yz I y y  I yz 2 2 I y I z  I yz Mz  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 618 PROBLEM 4.160 y (a) Show that, if a vertical force P is applied at point A of the section shown, the equation of the neutral axis BD is D B P C A z zA xA  zA   xA   2  x   2  z  1  rz   rx  x where rz and rx denote the radius of gyration of the cross section with respect to the z axis and the x axis, respectively. (b) Further show that, if a vertical force Q is applied at any point located on line BD, the stress at point A will be zero. SOLUTION Definitions: rx2  (a) M x  Pz A E    M z   Px A P M z xE M x z E P Px A xE Pz A z E      A Iz Ix A Arz2 Arx2 z   P   xA  1   2  xE   A2  z E   0 A   rz   rx   if E lies on neutral axis. (b) M x  Pz E A   Ix I , rz2  z A A z  x  1   A2  x   A2  z  0,  rz   rx  M z   PxE  zA   xA   2  x   2  z  1  rz   rx  P M z xA M x z A P Px x Pz z      E 2 A  E 2A A Iz Iy A Arz Arx  0 by equation from part (a).   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 619 24 mm B PROBLEM 4.161 B For the curved bar shown, determine the stress at point A when (a) h  50 mm, (b) h  60 mm. h A 600 N · m C A 50 mm 600 N · m SOLUTION (a) h  50 mm, r1  50 mm, A  (24)(50)  1.200  103 mm R  r  r2  100 mm h 50   72.13475 mm r2 ln 100 50 ln r1 1 (r1  r2 )  75 mm 2 e  r  R  2.8652 mm y A  72.13475  50  22.13475 mm A   (b) (600)(22.13475  103 ) My A   77.3  106 Pa AerA (1.200  103 )(2.8652  103 )(50  103 ) h  60 mm, R rA  50 mm r1  50 mm, r2  110 mm, h 60   76.09796 mm 110 r2 ln 50 ln r 1 A  (24)(60)  1.440  103 mm 2 77.3 MPa  r  1 e  r  R  3.90204 mm (r1  r2 )  80 mm 2 y A  76.09796  50  26.09796 mm rA  50 mm A   M yA (600)(26.09796  103 )   55.7  106 Pa 3 3 3 AerA (1.440  10 )(3.90204  10 )(50  10 ) 55.7 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 620 24 mm B B A A PROBLEM 4.162 For the curved bar shown, determine the stress at points A and B when h  55 mm. h 600 N · m C 50 mm 600 N · m SOLUTION h  55 mm, r1  50 mm, A  (24)(55)  1.320  10 mm 3 r2  105 mm 2 R 50 h   74.13025 mm 105 r2 ln ln 50 r1 1 r  (r1  r2 )  77.5 mm 2 e  r  R  3.36975 mm y A  74.13025  50  24.13025 mm A   (600)(24.13025  103 ) M yA   65.1  106 Pa AerA (1.320  103 )(3.36975  103 )(50  103 ) yB  74.13025  105  30.86975 mm B  rA  50 mm rB  105 mm (600)(30.8697  103 ) MyB   39.7  106 Pa AerB (1.320  103 )(3.36975  103 )(105  103 ) 65.1 MPa  39.7 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 621 4 kip · in. 4 kip · in. PROBLEM 4.163 C 3 in. For the machine component and loading shown, determine the stress at point A when (a) h  2 in., (b) h  2.6 in. h A 0.75 in. B SOLUTION M  4 kip  in. Rectangular cross section: r  (a) A  bh r2  3 in. r1  r2  h 1 h (r1  r2 ), R  , er R r 2 ln 2 r1 h  2 in. A  (0.75)(2)  1.5 in 2 r  r1  3  2  1 in. R  2  1.8205 in. ln 13 (b) e  2  1.8205  0.1795 in. r  r1  1 in. At point A: A  M (r  R) (4)(1  1.8205)   12.19 ksi (1.5)(0.1795)(1) Aer h  2.6 in. A  (0.75)(2.6)  1.95 in 2 r  r1  3  2.6  0.4 in. R  2.6  1.2904 in. 3 ln 0.4 At point A: A  1 (3  1)  2 in. 2  A  12.19 ksi  1 (3  0.4)  1.7 in. 2 e  1.7  1.2904  0.4906 in. r  r1  0.4 in. M (r  R ) (4)(0.4  1.2904)   11.15 ksi (1.95)(0.4096)(0.4) Aer  A  11.15 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 622 4 kip · in. 4 kip · in. PROBLEM 4.164 C 0.75 in. 3 in. For the machine component and loading shown, determine the stress at points A and B when h  2.5 in. h A B SOLUTION M  4 kip  in. Rectangular cross section: h  2.5 in. b  0.75 in. A  1.875 in.2 r2  3 in. r1  r2  h  0.5 in. r  1 1 (r1  r2 )  (0.5  3.0)  1.75 in. 2 2 h 2.5 R  r  3.0  1.3953 in. ln 0.5 ln r2 e  r  R  1.75  1.3953  0.3547 in. 1 At point A: r  r1  0.5 in. A  At point B: M (r  R) (4 kip  in.)(0.5 in.  1.3953 in.)  Aer (0.75 in.)(2.5 in.)(0.3547 in.)(0.5 in.)  A  10.77 ksi  M (r  R ) (4 kip  in.)(3 in.  1.3953 in.)  Aer (0.75 in.  2.5 in.)(0.3547 in.)(3 in.)  B  3.22 ksi  r  r2  3 in. B  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 623 PROBLEM 4.165 r1 40 mm The curved bar shown has a cross section of 40  60 mm and an inner radius r1  15 mm. For the loading shown, determine the largest tensile and compressive stresses. 60 mm 120 N · m SOLUTION h  40 mm, r1  15 mm, r2  55 mm A  (60)(40)  2400 mm 2  2400  106 m 2 R r  40 h   30.786 mm 55 r2 ln ln r1 40 1 (r1  r2 )  35 mm 2 e  r  R  4.214 mm At r  15 mm,   y  30.786  15  15.756 mm My Aer (120)(15.786  103 )  12.49  10 6 Pa (2400  10 6 )(4.214  103 )(15  103 ) At r  55 mm,     y  30.786  55  24.214 mm (120)(24.214  103 )  5.22  106 Pa (2400  106 )(4.214  103 )(55  103 )   12.49 MPa    5.22 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 624 PROBLEM 4.166 r1 40 mm For the curved bar and loading shown, determine the percent error introduced in the computation of the maximum stress by assuming that the bar is straight. Consider the case when (a) r1  20 mm, (b) r1  200 mm, (c) r1  2 m. 60 mm 120 N · m SOLUTION h  40 mm, A  (60)(40)  2400 mm 2  2400  106 m 2 , M  120 N  m I  1 3 1 (60)(40)3  0.32  106 mm 4  0.32  106 mm 4 , bh  12 12 c 1 h  20 mm 2 Assuming that the bar is straight, s   (a) Mc (120)(20  108 )   7.5  106 Pa  7.5 MPa I (0.32  106 ) r1  20 mm r2  60 mm R 40 h   36.4096 mm 60 r2 ln ln r1 20 r  1 (r1  r2 )  40 mm 2 a  r1  R  16.4096 mm e  r  R  3.5904 mm (120)(16.4096  103 ) M (r1  R)   11.426  106 Pa  11.426 MPa 6 3 3 Aer (2400  10 )(3.5904  10 )(20  10 ) % error  11.426  (7.5)  100%  34.4% 11.426  For parts (b) and (c), we get the values in the table below: (a) (b) (c) r1, mm r2 , mm 20 200 2000 60 240 2040 R, mm 36.4096 219.3926 2019.9340 r , mm 40 220 2020 e, mm 3.5904 0.6074 0.0660  , MPa 11.426 7.982 7.546 % error 34.4 % 6.0 %  0.6 %  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 625 0.3 in. B 0.4 in. P9 PROBLEM 4.167 B P 0.4 in. Steel links having the cross section shown are available with different central angles  . Knowing that the allowable stress is 12 ksi, determine the largest force P that can be applied to a link for which   90. 0.8 in. A A 0.8 in. b 1.2 in. C C SOLUTION Reduce section force to a force-couple system at G, the centroid of the cross section AB.   a  r 1  cos  2  The bending couple is M   Pa. For the rectangular section, the neutral axis for bending couple only lies at R Also, e  r  R h ln r2 r1 At point A, the tensile stress is A  K 1 where P Data: . P My A P Pay A P ay  P     1  A   K A Aer1 A Aer1 A er1  A ay A er1 A A K y A  R  r1 and r  1.2 in., r1  0.8 in., r2  1.6 in., h  0.8 in., b  0.3 in. 0.8 A  (0.3)(0.8)  0.24 in 2 R  1.6  1.154156 in. ln 0.8 e  1.2  1.154156  0.045844 in., y A  1.154156  0.8  0.35416 in. a  1.2(1  cos 45)  0.35147 in. K 1 P (0.35147)(0.35416)  4.3940 (0.045844)(0.8) P  655 lb  (0.24)(12)  0.65544 kips 4.3940 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 626 PROBLEM 4.168 0.3 in. B 0.4 in. P9 Solve Prob. 4.167, assuming that   60. B 0.8 in. P 0.4 in. A PROBLEM 4.167 Steel links having the cross section shown are available with different central angles . Knowing that the allowable stress is 12 ksi, determine the largest force P that can be applied to a link for which   90. A 0.8 in. b 1.2 in. C C SOLUTION Reduce section force to a force-couple system at G, the centroid of the cross section AB. The bending couple is M   Pa.   a  r 1  cos  2  For the rectangular section, the neutral axis for bending couple only lies at R Also, e  r  R At point A, the tensile stress is A  ln P r2 r1 . P My A P Pay A P ay  P     1  A   K A Aer1 A Aer1 A er1  A K 1 where Data: h ay A er1 A A K and y A  R  r1 r  1.2 in., r1  0.8 in., r2  1.6 in., h  0.8 in., b  0.3 in. 0.8 A  (0.3)(0.8)  0.24 in 2 R  1.6  1.154156 in. ln 0.8 e  1.2  1.154156  0.045844 in. y A  1.154156  0.8  0.35416 in. a  (1.2)(1  cos 30)  0.160770 in. K 1 P (0.160770)(0.35416)  2.5525 (0.045844)(0.8) P  1128 lb  (0.24)(12)  1.128 kips 2.5525 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 627 5 kN PROBLEM 4.169 a The curved bar shown has a cross section of 30  30 mm. Knowing that the allowable compressive stress is 175 MPa, determine the largest allowable distance a. 30 mm B A 20 mm 20 mm C 30 mm 5 kN SOLUTION Reduce the internal forces transmitted across section AB to a force-couple system at the centroid of the section. The bending couple is M  P(a  r ) For the rectangular section, the neutral axis for bending couple only lies at R  Also, e  r  R h . r2 ln r1 The maximum compressive stress occurs at point A . It is given by A   P My A P P (a  r ) y A    A Aer1 A Aer1  K P with y A  R  r1 A (a  r )( R  r1) Thus, K  1  er1 h  30 mm, r1  20 mm, r2  50 mm, r  35 mm, R  Data: (1) 30  32.7407 mm ln 50 20 e  35  32.7407  2.2593 mm, b  30 mm, R  r1  12.7407 mm, a  ?  A  175 MPa  175  106 Pa, P  5 kN  5  103 N K  Solving (1) for ar  (900  106 )(175  106 ) A A   31.5 P 5  103 a  r, ar  ( K  1)er1 R  r1 (30.5)(2.2593)(20)  108.17 mm 12.7407 a  108.17 mm  35 mm a  73.2 mm  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 628 PROBLEM 4.170 2500 N For the split ring shown, determine the stress at (a) point A, (b) point B. 90 mm 40 mm B A 14 mm SOLUTION r1  1 40  20 mm, 2 r2  A  (14)(25)  350 mm 2 1 r  (r1  r2 )  32.5 mm 2 1 (90)  45 mm h  r2  r1  25 mm 2 25 h R  r  45  30.8288 mm 2 ln r ln 20 e  r  R  1.6712 mm 1 Reduce the internal forces transmitted across section AB to a force-couple system at the centroid of the cross section. The bending couple is M  Pa  P r  (2500)(32.5  103 )  81.25 N  m (a) Point A: rA  20 mm y A  30.8288  20  10.8288 mm P My A 2500 (81.25)(10.8288  103 )    A AeR 350  106 (350  106 )(1.6712  103 )(20  103 )  82.4  106 Pa A   (b) Point B: rB  45 mm yB  30.8288  45  14.1712 mm P MyB 2500 (81.25)(14.1712  103 )    A AerB 350  106 (350  106 )(1.6712  103 )(45  103 )  36.6  106 Pa B    A  82.4 MPa   B  36.6 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 629 2 in. PROBLEM 4.171 B 0.5 in. 0.5 in. Three plates are welded together to form the curved beam shown. For M  8 kip  in., determine the stress at (a) point A, (b) point B, (c) the centroid of the cross section. 2 in. 0.5 in. A 3 in. M M' 3 in. C SOLUTION R r  r 3 3.5 5.5 6 Part     b A bi hi A   r   1r dA b ln ri 1 bi ln i 1 i ri ri Ari A Ar 0.462452 3.25 4.875 1.0 0.225993 4.5 4.5 1.0 0.174023 5.75 5.75 3.5 0.862468 A 3 0.5 1.5 0.5 2 2 0.5 b ln R 3.5  4.05812 in., 0.862468 e  r  R  0.26331 in. (a) y A  R  r1  4.05812  3  1.05812 in. A   My A (8)(1.05812)  Aer1 (3.5)(0.26331)(3) 15.125 r  15.125  4.32143 in. 3.5 M  8 kip  in.  A  3.06 ksi  (b) yB  R  r2  4.05812  6  1.94188 in.   B   (c) yC  R  r  e C   ri 1 ri r h MyB (8)(1.94188)   Aer2 (3.5)(0.26331)(6)  B  2.81 ksi   8 MyC Me M    (3.5)(4.32143) Aer Aer Ar  C  0.529 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 630 2 in. PROBLEM 4.172 B 0.5 in. 0.5 in. 2 in. 0.5 in. A 3 in. M M' 3 in. Three plates are welded together to form the curved beam shown. For the given loading, determine the distance e between the neutral axis and the centroid of the cross section. C SOLUTION R r  r 3 3.5 5.5 6 Part A bi hi A   r   1r dA b ln ri 1 bi ln i 1 i ri ri Ari A b     ri 1 ri r Ar 0.462452 3.25 4.875 1.0 0.225993 4.5 4.5 1.0 0.174023 5.75 5.75 3.5 0.862468 h A 3 0.5 1.5 0.5 2 2 0.5 b ln R 15.125 3.5 15.125  4.05812 in., r   4.32143 in. 0.862468 3.5 e  r  R  0.26331 in. e  0.263 in.  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 631 C M PROBLEM 4.173 Mʹ A 150 mm A Knowing that the maximum allowable stress is 45 MPa, determine the magnitude of the largest moment M that can be applied to the components shown. 45 mm 135 mm B B 36 mm SOLUTION R r  A bi hi Ai   1 r r   r dA b 2 ln i 1 bi ln i 1 i ri ri Ai ri Ai r, mm 150 Part bi , mm h, mm   195 330 bi ln A, mm 2 ri 1 , mm ri r , mm Ar , mm3 838.35  103 108 45 4860 28.3353 172.5 36 135 4860 18.9394 262.5 9720 47.2747 ∑ R 9720  205.606 mm 47.2747 e  r  R  11.894 mm r  1275.75  103 2114.1  103 2114.1  103  217.5 mm 9720 y A  R  r1  205.606  150  55.606 mm A   M   My A Aer1  A Aer1 yA (45  106 )(9720  106 )(11.894  103 )(150  103 )  14.03 kN  m (55.606  103 ) yB  R  r2  205.606  330  124.394 mm B   M   MyB Aer2  B Aer2 yB (45  106 )(9720  106 )(11.894  103 )(330  103 ) (124.394  103 )  13.80 kN  m M  13.80 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 632 C M PROBLEM 4.174 Mʹ A 150 mm A Knowing that the maximum allowable stress is 45 MPa, determine the magnitude of the largest moment M that can be applied to the components shown. 135 mm 45 mm B B 36 mm SOLUTION R r  A bi hi Ai   r   1r dA b ln ri 1 bi ln i 1 i ri ri Ai ri Ai r, mm 150  285  330 ∑ R bi , mm h, mm A, mm 2 bi ln ri 1 , mm ri2 r , mm 36 135 4860 23.1067 217.5 108 45 4860 15.8332 307.5 9720 38.9399 9720  249.615 mm, 38.9399 e  r  R  12.885 mm, r  2.5515  106  262.5 mm 9720 Ar , mm3 1.05705  106 1.49445  106 2.5515  106 M  20  103 N  m y A  R  r1  249.615  150  99.615 mm A   M   My A Aer1  A Aer1 yA (45  106 )(9720  106 )(12.885  103 )(150  103 )  8.49 kN  m (99.615  103 ) yB  R  r2  249.615  330  80.385 mm B   M   MyB Aer2  B Aer2 yB (45  106 )(9720  106 )(12.885  103 )(330  103 ) (80.385  103 )  23.1 kN  m M  8.49 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 633 120 lb 120 lb The split ring shown has an inner radius r1  0.8 in. and a circular cross section of diameter d  0.6 in. Knowing that each of the 120-lb forces is applied at the centroid of the cross section, determine the stress (a) at point A, (b) at point B. r1 A PROBLEM 4.175 d B SOLUTION rA  r1  0.8 in. rB  rA  d  0.8  0.6  1.4 in. r  1 (rA  rB )  1.1 in. 2 c A   c 2   (0.3)2  0.28274 in 2 1 d  0.3 in. 2 for solid circular section 1 1 r  r 2  c 2   1.1  (1.1)2  (0.3)2   1.079150 in.  2   2  e  r  R  1.1  1.0791503  0.020850 in. R Q  120 lb   Fx  0: P  Q  0  M 0  0: 2rQ  M  0 (a) (b) r  rA  0.8 in. A  P  120 lb M  2rQ  (2)(1.1)(120)  264 lb  in. P M (rA  R) 120 (264)(0.8  1.079150)     16.05  103 psi A AerA 0.28274 (0.28274)(0.020850)(0.8) r  rB  1.4 in. B   A  16.05 ksi  120 (264)(1.4  1.079150) P M (rB  R)    0.28274 (0.28274)(0.020850)(1.4) A AerB  9.84  103 psi  B  9.84 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 634 120 lb 120 lb PROBLEM 4.176 Solve Prob. 4.175, assuming that the ring has an inner radius r1 = 0.6 in. and a cross-sectional diameter d  0.8 in. r1 A PROBLEM 4.175 The split ring shown has an inner radius r1  0.8 in. and a circular cross section of diameter d  0.6 in. Knowing that each of the 120-lb forces is applied at the centroid of the cross section, determine the stress (a) at point A, (b) at point B. d B SOLUTION rA  r1  0.6 in. rB  rA  d  0.6  0.8  1.4 in. r  1 (rA  rB )  1.0 in. 2 c A   c 2   (0.4)2  0.50265 in 2 1 d  0.4 in. 2 for solid circular section. 1 1 r  r 2  c 2   1.0  (1.0) 2  (0.4)2   0.958258 in.     2  2 e  r  R  1.0  0.958258  0.041742 in. R Q  120 lb  M 0  0: (a)   Fx  0 2rQ  M  0 r  rA  0.6 in. A  PQ  0 P  120 lb M  2rQ  (2)(1.0)(120)  240 lb  in. 120 (240)(0.6  0.958258) P M (rA  R)    0.50265 (0.50265)(0.041742)(0.6) A AerA  7.069  103 psi (b) r  rB  1.4 in. B  120 (240)(1.4  0.958258) P M (rB  R)    0.50265 (0.50265)(0.041742)(1.4) A AerB  3.37  103 psi  A  7.07 ksi   B  3.37 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 635 220 N B PROBLEM 4.177 The bar shown has a circular cross section of 14-mm diameter. Knowing that a  32 mm, determine the stress at (a) point A, (b) point B. A C 220 N a 16 mm 12 mm SOLUTION c 1 d  8 mm r  12  8  20 mm 2 1 1 R   r  r 2  c 2    20  202  82   19.1652 mm     2  2 e  r  R  20  19.1652  0.83485 mm A   r 2   (8) 2  201.06 mm 2 P  220 N M   P(a  r )  220(0.032  0.020)  11.44 N  m y A  R  r1  19.1652  12  7.1652 mm yb  R  r2  19.1652  28  8.8348 mm (a) A   (b) B   P My A  A Aer1 220 (11.44)(7.1652  103 )  201.06  106 (201.06  106 )(0.83485  103 )(12  103 )  A  41.8 MPa  P MyB  A Aer2 220 (11.44)(8.8348  103 )  201.06  106 (201.06  106 )(0.83485  103 )(28  103 )  B  20.4 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 636 220 N B PROBLEM 4.178 The bar shown has a circular cross section of 14-mm diameter. Knowing that the allowable stress is 38 MPa, determine the largest permissible distance a from the line of action of the 220-N forces to the plane containing the center of curvature of the bar. A C 220 N a 16 mm 12 mm SOLUTION c 1 d  8 mm r  12  8  20 mm 2 1 1 R   r  r 2  c 2    20  202  82   19.1652 mm     2  2 e  r  R  20  19.1652  0.83485 mm A   r 2   (8) 2  201.06 mm 2 P  220 N M   P (a  r ) y A  R  r1  19.1652  12  7.1652 mm (a  r ) y A  P My A P P(a  r ) y A P     1   A Aer1 A Aer1 A er1  (a  r ) y A KP where  K 1 A er1 A   AA (38  106 )(201.06  106 )  34.729 P 220 ( K  1)er1 ar  yA K    (34.729  1)(0.83485  103 )(12  103 ) (7.1652  103 )  0.047158 m a  0.047158  0.020  0.027158 a  27.2 mm  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 637 C M PROBLEM 4.179 16 mm The curved bar shown has a circular cross section of 32-mm diameter. Determine the largest couple M that can be applied to the bar about a horizontal axis if the maximum stress is not to exceed 60 MPa. 12 mm SOLUTION c  16 mm r  12  16  28 mm 1 r  r 2  c2     2 1   28  282  162   25.4891 mm  2  R e  r  R  28  25.4891  2.5109 mm  max occurs at A, which lies at the inner radius. It is given by  max  My A from which Aer1 M  Aer1  max yA A   c 2   (16)2  804.25 mm 2 Also, . y A  R  r1  25.4891  12  13.4891 mm Data: M  (804.25  106 )(2.5109  103 )(12  103 )(60  106 ) 13.4891  103 M  107.8 N  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 638 P PROBLEM 4.180 90 mm Knowing that P  10 kN, determine the stress at (a) point A, (b) point B. 80 mm B A 100 mm SOLUTION Locate the centroid D of the cross section. r  100 mm  90 mm  130 mm 3 Force-couple system at D. P  10 kN M  Pr  (10 kN)(130 mm)  1300 N  m Triangular cross section. A 1 1 bh  (90 mm)(80 mm) 2 2  3600 mm 2  3600  106 m 2 1 1 h (90) 45 mm 2 2 R   190 190 r2 r2 ln  1 ln  1 0.355025 90 100 h r1 R  126.752 mm e  r  R  130 mm  126.752 mm  3.248 mm (a) Point A: A   rA  100 mm  0.100 m P M (rA  R) 10 kN (1300 N  m)(0.100 m  0.126752 m)    6 2 A AerA 3600  10 m (3600  106 m 2 )(3248  103 m)(0.100 m)  A  32.5 MPa   2.778 MPa  29.743 MPa (b) Point B: B   rB  190 mm  0.190 m P M (rB  R) 10 kN (1300 N  m)(0.190 m  0.126752 m)    A AerB 3600  106 m 2 (3600  106 m 2 )(3.248  103 m)(0.190 m)  B  34.2 MPa   2.778 MPa  37.01 MPa PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 639 M 2.5 in. A PROBLEM 4.181 B M Knowing that M  5 kip  in., determine the stress at (a) point A, (b) point B. C 3 in. 2 in. 2 in. 3 in. SOLUTION A 1 1 bh  (2.5)(3)  3.75 in 2 2 2 r  2  1  3.00000 in. b1  2.5 in., r1  2 in., b2  0, r2  5 in. Use formula for trapezoid with b2  0. 1 h 2 (b  b ) 1 2 2 R r2 (b1r2  b2r1) ln  h(b1  b2 ) r1  (a) (b) y A  R  r1  0.84548 in. A   (0.5)(3)2 (2.5  0)  2.84548 in. [(2.5)(5)  (0)(2)] ln 52  (3)(2.5  0) e  r  R  0.15452 in. My A (5)(0.84548)  Aer1 (3.75)(0.15452)(2)  A  3.65 ksi  MyB (5)(2.15452)  Aer2 (3.75)(0.15452)(5)  B  3.72 ksi  yB  R  r2  2.15452 in. B   M  5 kip  in. PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 640 M PROBLEM 4.182 B Knowing that M  5 kip  in., determine the stress at (a) point A, (b) point B. 2.5 in. A 3 in. M C 2 in. 2 in. 3 in. SOLUTION A  1 (2.5)(3)  3.75 in 2 2 r  2  2  4.00000 in. b1  0, r1  2 in., Use formula for trapezoid with b1  0. b2  2.5 in., r2  5 in. 1 h 2 (b  b ) 1 2 2 R r2 (b1r2  b2r1) ln  h (b1  b2 ) r1 (0.5)(3) 2 (0  2.5)  3.85466 in. [(0)(5)  (2.5)(2)] ln 5  (3)(0  2.5) 2 e  r  R  0.14534 in. M  5 kip  in.  (a) (b) y A  R  r1  1.85466 in. A   My A (5)(1.85466)  Aer1 (3.75)(0.14534)(2)  A  8.51 ksi  MyB (5)(1.14534)  Aer2 (3.75)(0.14534)(5)  B  2.10 ksi  yB  R  r2  1.14534 in. B   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 641 80 kip · in. b B A B A PROBLEM 4.183 Knowing that the machine component shown has a trapezoidal cross section with a  3.5 in. and b  2.5 in., determine the stress at (a) point A, (b) point B. C a 6 in. 4 in. SOLUTION Locate centroid. A, in 2 r , in. Ar , in 3 10.5 6 63 7.5 8 60    18 r  R  123 123  6.8333 in. 18 1 2 h (b1  b2 ) 2 (b1r2  b2 r1 ) ln r2 r1  h(b1  b2 ) (0.5)(6)2 (3.5  2.5)  6.3878 in. [(3.5)(10)  (2.5)(4)]ln 104  (6)(3.5  2.5) e  r  R  0.4452 in. (a) (b) y A  R  r1  6.3878  4  2.3878 in. My (80)(2.3878) A   A   (18)(0.4452)(4) Aer1 M  80 kip  in.  A  5.96 ksi  yB  R  r2  6.3878  10  3.6122 in. My (80)(3.6122) B   B   (18)(0.4452)(10) Aer2  B  3.61 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 642 80 kip · in. b B A B A PROBLEM 4.184 Knowing that the machine component shown has a trapezoidal cross section with a  2.5 in. and b  3.5 in., determine the stress at (a) point A, (b) point B. C a 6 in. 4 in. SOLUTION Locate centroid.    A, in 2 r , in. Ar , in 3 7.5 6 45 10.5 8 84 18 r  R  129 129  7.1667 in. 18 1 2 h (b1  b2 ) 2 (b1r2  b2 r1 ) ln r2 r1  h(b1  b2 ) (0.5)(6) 2 (2.5  3.5)  6.7168 in. [(2.5)(10)  (3.5)(4)]ln 104  (6)(2.5  3.5) e  r  R  0.4499 in. (a) (b) M  80 kip  in. y A  R  r1  2.7168 in. A    A  6.71 ksi  My A (80)(2.7168)  (18)(0.4499)(4) Aer1 yB  R  r2  3.2832 in. B   MyB (80)(3.2832)  (18)(0.4499)(10) Aer2  B  3.24 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 643 B a 20 mm PROBLEM 4.185 B A For the curved beam and loading shown, determine the stress at (a) point A, (b) point B. 30 mm a A 250 N · m 250 N · m 35 mm 40 mm Section a–a SOLUTION Locate centroid.    A, mm 2 r , mm Ar , mm3 600 45 300 55 16.5  103 900 r  R  43.5  103  48.333 mm 900 1 2 (b1r2  b2r1) ln r2 r1  h(b2  b1) (0.5)(30) 2 (40  20)  46.8608 mm 65  (30)(40  20) [(40)(65)  (20)(35)]ln 35 (b) y A  R  r1  11.8608 mm A   M  250 N  m (250)(11.8608  103 ) My A   63.9  106 Pa Aer1 (900  106 )(1.4725  103 )(35  103 ) yB  R  r2  18.1392 mm B   43.5  103 h 2 (b1  b2 ) e  r  R  1.4725 mm (a) 27  103 MyB (250)(18.1392  103 )   52.6  106 Pa Aer2 (900  106 )(1.4725  103 )(65  103 )  A  63.9 MPa   B  52.6 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 644 PROBLEM 4.186 For the crane hook shown, determine the largest tensile stress in section a-a. 35 mm 25 mm 60 mm 40 mm a a 60 mm Section a–a 15 kN SOLUTION Locate centroid.    A, mm 2 r , mm Ar , mm3 1050 60 750 80 60  103 63  103 103  103 1800 r Force-couple system at centroid: 103  103  63.333 mm 1800 P  15  103 N M   Pr  (15  103 )(68.333  103 )  1.025  103 N  m R  1 2 h 2 (b1  b2 ) (b1r2  b2 r1 ) ln r2 r1  h(b1  b2 ) (0.5)(60)2 (35  25)  63.878 mm  (60)(35  25) [(35)(100)  (25)(40)]ln 100 40 e  r  R  4.452 mm Maximum tensile stress occurs at point A. y A  R  r1  23.878 mm A   P My A  A Aer1 (1.025  103 )(23.878  103 ) 15  103  1800  106 (1800  106 )(4.452  103 )(40  103 )  84.7  106 Pa  A  84.7 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 645 PROBLEM 4.187 Using Eq. (4.66), derive the expression for R given in Fig. 4.61 for a circular cross section. SOLUTION Use polar coordinate  as shown. Let w be the width as a function of  w  2c sin  r  r  c cos  dr  c sin  d  dA  w dr  2c 2 sin 2  d    dA  r   0  dA  r 2 2   0  2c 2 sin  d r  c cos  c 2 (1  cos 2  ) d r  c cos  r 2  c 2 cos 2   (r 2  c 2 ) d r  c cos   0  0 (r  c cos  ) d   2(r 2  c 2 )  2r   0  2c sin   2(r  c ) 2 2  0 2 r c 2 2 tan 1   0 dr r  c cos    r 2  c 2 tan 1  2 r c    2r (  0)  2c(0  0)  4 r 2  c 2    0  2    1  2 0  2 r  2 r 2  c 2 A   c2 R  A c2 r  r 2  c2 1  c2    dA 2 r  2 r 2  c 2 2 r  r 2  c 2 r  r 2  c 2 r  c2 r  r 2  c2 r  (r  c ) 2 2 2   1 c r  r 2  c2 2 2 c 2 1 r 2  r 2  c2   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 646 PROBLEM 4.188 Using Eq. (4.66), derive the expression for R given in Fig. 4.73 for a trapezoidal cross section. SOLUTION The section width w varies linearly with r. w  c0  c1r w  b1 at r  r1 and w  b2 at r  r2 b1  c0  c1r1 b2  c0  c1r2 b1  b2  c1 (r1  r2 )  c1h b b c1   1 2 h r2b1  r1b2  (r2  r1 )c0  hc0 r b  rb c0  2 1 1 2 h r2 w r2 c  c r dA 0 1 dr  dr  r1 r r1 r r r2 r2  c0 ln r  c1 r    r1 r1 r  c0 ln 2  c1 (r2  r1 ) r1 r2 b1  r1b2 r2 b1  b2 h ln   h r1 h r b  rb r  2 1 1 2 ln 2  (b1  b2 ) h r1 1 A  (b1  b2 ) h 2 1 2 h (b1  b2 ) A 2  R r dA ( r2b1  r1b2 ) ln r2  h(b1  b2 ) r   1 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 647 PROBLEM 4.189 Using Equation (4.66), derive the expression for R given in Fig. 4.73 for a triangular cross section. SOLUTION The section width w varies linearly with r.  w  c0  c1r w  b at r  r1 and w  0 at r  r2 b  c0  c1r1 0  c0  c1r2 b  c1 (r1  r2 )  c1h br b c1   and c0  c1r2  2 h h r2 w r2 c  c r dA 0 1  dr  dr r1 r r1 r r r2 r2  c0 ln r  c1 r   r1 r1 r  c0 ln 2  c1 (r2  r1 ) r1 br2 r2 b ln  h  h r1 h  r br r r  2 ln 2  b  b  2 ln 2  1 h r1  h r1  1 A  bh 2 1 1 bh h A R  r 2 r  r 2r 2 dA ln r2  1 b h2 ln r2  1 h r 1   1   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 648 PROBLEM 4.190 b2 b3 Show that if the cross section of a curved beam consists of two or more rectangles, the radius R of the neutral surface can be expressed as b1 R r1 r2 r3 r4 A  r b1  r b2  r b3  ln  2   3   4    r1   r2   r3     where A is the total area of the cross section. SOLUTION R  Note that for each rectangle,  A A  1  dA  b ln ri 1 i r r  A r   ln  i 1   ri   bi  i A  r b1  r b2  r b3  ln  2   3   4    r1   r2   r3      ri 1 dr 1 dA  bi ri r r ri  1 dr ri 1  bi  bi ln r2 r ri  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 649 PROBLEM 4.191 C ␪ 2 ␪ 2 r1 ␴x ␴x b ␴r ␴r R For a curved bar of rectangular cross section subjected to a bending couple M, show that the radial stress at the neutral surface is M  r1 R r  1   ln  Ae  R r1  and compute the value of  r for the curved bar of Concept Applications 4.10 and 4.11. (Hint: consider the free-body diagram of the portion of the beam located above the neutral surface.) SOLUTION M (r  R) M MR   Aer Ae Aer For portion above the neutral axis, the resultant force is r  At radial distance r,  H   r dA     R r1  r b dr  Mb R MRb R dr dr  Ae r1 Ae r1 r r1 Mb MRb R MbR  R  ( R  r1 )  ln  1   ln  Ae Ae r1 Ae  R r1  Resultant of  n :    /2  /2  Fr   r cos  dA  r cos  (bR d  )   r bR   r bR sin  For equilibrium: Fr  2 H sin 2 r bR sin  2  2  /2  /2 0 2   /2  /2  2 r bR sin  2 cos  d  r1 MbR  R  1   ln  sin  0 Ae  R r1  2 r  r1 M  R 1   ln  Ae  R r1   Using results of Examples 4.10 and 4.11 as data, M  8 kip  in., r  A  3.75 in 2 , R  5.9686 in., e  0.0314 in., r1  5.25 in. 8 5.25 5.9686    ln 1  (3.75)(0.0314)  5.9686 5.25   r  0.536 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 650 PROBLEM 4.192 25 mm 25 mm 4 kN A Two vertical forces are applied to a beam of the cross section shown. Determine the maximum tensile and compressive stresses in portion BC of the beam. 4 kN B 300 mm C 300 mm SOLUTION A1   2 r2   2 (25)2  981.7 mm 2 A2  bh  (50)(25)  1250 mm 2 y  y1  4r (4)(25)   10.610 mm 3 3 25 h  12.5 mm y2     2 2 (981.7)(10.610)  (1250)(12.5) A1 y1  A2 y2   2.334 mm 981.7  1250 A1  A2 I1  I x1  A1 y12   r 4  A1 y12   (25)4  (981.7)(10.610) 2  42.886  106 mm 4 8 8 d1  y1  y  10.610  (2.334)  12.944 mm I1  I1  A1d12  42.866  103  (981.7)(12.944) 2  207.35  103 mm 4 I2  1 3 1 bh  (50)(25)3  65.104  103 mm 4 12 12 d 2  y2  y  12.5  (2.334)  10.166 mm I 2  I 2  A2 d 22  65.104  103  (1250)(10.166) 2  194.288  103 mm 4 I  I1  I 2  401.16  103 mm 4  401.16  109 m 4 ytop  25  2.334  27.334 mm  0.027334 m ybot  25  2.334  22.666 mm  0.022666 m  top   bot   Mytop I M  Pa  0:  M  Pa  (4  103 )(300  103 )  1200 N  m (1200)(0.027334)  81.76  106 Pa 401.16  109 Mybot (1200)(0.022666)   67.80  106 Pa I 401.16  109  top  81.8 MPa   bot  67.8 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 651 PROBLEM 4.193 A steel band saw blade that was originally straight passes over 8-in.-diameter pulleys when mounted on a band saw. Determine the maximum stress in the blade, knowing that it is 0.018 in. thick and 0.625 in. wide. Use E  29  106 psi. 0.018 in. SOLUTION t  0.018 in. Band blade thickness: r Radius of pulley: 1 d  4.000 in. 2 Radius of curvature of centerline of blade:   r  t  4.009 in. c 1 2 1 t  0.009 in. 2 Maximum strain: m  Maximum stress:  m  E m  (29  106 )(0.002245)  c  0.009  0.002245 4.009  m  65.1  103 psi  m  65.1 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 652 PROBLEM 4.194 M A couple of magnitude M is applied to a square bar of side a. For each of the orientations shown, determine the maximum stress and the curvature of the bar. M a (a) (b) SOLUTION I 1 3 1 3 a4 bh  aa  12 12 12 a c 2  max  1  a Mc M 2   4 I a 12  M M  EI E a 4 12   max   1  6M  a3 12M  Ea 4 For one triangle, the moment of inertia about its base is I1  1 3 1 bh  12 12 I 2  I1   a 2 3 a4 24 I  I1  I 2  c  a  a4  2a   24  2 a4 12  max   1  Mc Ma/ 2 6 2 M  4  I a /12 a3 M M   EI E a 4 12  max   1 8.49M  a3  12M  Ea 4 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 653 40 mm 60 mm PROBLEM 4.195 Determine the plastic moment M p of a steel beam of the cross section shown, assuming the steel to be elastoplastic with a yield strength of 240 MPa. SOLUTION Let c1 be the outer radius and c2 the inner radius. A1 y1  Aa ya  Ab yb    4c     4c    c12  1    c22  2   2  3   2  3  3 2 3  c1  c2 3  A2 y2  A1 y1    2 3 c1  c 22 3  M p   Y ( A1 y1  A2 y2 )  Data:  4  Y c13  c32 3  Y  240 MPa  240  106 Pa  c1  60 mm  0.060 m c2  40 mm  0.040 m Mp  4 (240  106 )(0.0603  0.0403 ) 3  48.64  103 N  m M p  48.6 kN  m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 654 PROBLEM 4.196 M 300 N · m 26 mm 30 mm 46 mm 50 mm In order to increase corrosion resistance, a 2-mm-thick cladding of aluminum has been added to a steel bar as shown. The modulus of elasticity is 200 GPa for steel and 70 GPa for aluminum. For a bending moment of 300 N  m, determine (a) the maximum stress in the steel, (b) the maximum stress in the aluminum, (c) the radius of curvature of the bar. SOLUTION Use aluminum as the reference material. n  1 in aluminum n Es 200   2.857 in steel 70 Ea Cross section geometry: Steel: As  (46 mm)(26 mm)  1196 mm 2 Is  1 (46 mm)(26 mm)3  67,375 mm 4 12 Aluminum: Aa  (50 mm)(30 mm)  1196 mm 2  304 mm 2 Ia  1 (50 mm)(30 mm3 )  67,375 mm 4  45,125 mm 4 12 Transformed section. I  na I a  ns I s  (1)(45,125)  (2.857)(67,375)  237, 615 mm 4  237.615  109 m 4 Bending moment. (a) Maximum stress in steel: s  (b) ns  2.857 ys  13 mm  0.013 m ns Mys (2.857)(300)(0.013)   46.9  106 Pa I 237.615  109 Maximum stress in aluminum: a  (c) M  300 N  m na  1, ya  15 mm  0.015 m na Mya (1)(300)(0.015)   18.94  106 Pa I 237.615  109 Radius of curvative:   EI M    s  46.9 MPa  (70  109 )(237.615  109 ) 300  a  18.94 MPa    55.4 m  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 655 PROBLEM 4.197 t P P' a a t 60 mm A 80 mm 200 mm 80 mm The vertical portion of the press shown consists of a rectangular tube of wall thickness t  10 mm. Knowing that the press has been tightened on wooden planks being glued together until P  20 kN, determine the stress at (a) point A, (b) point B. B Section a–a SOLUTION Rectangular cutout is 60 mm  40 mm. A  (80)(60)  (60)(40)  2.4  103 mm 2  2.4  103 m 2 I  1 1 (60)(80)3  (40)(60)3  1.84  106 mm 4 12 12  1.84  106 m 4 c  40 mm  0.040 m e  200  40  240 mm  0.240 m P  20  103 N M  Pe  (20  103 )(0.240)  4.8  103 N  m (a) A  (b) B  P Mc 20  103 (4.8  103 )(0.040)     112.7  106 Pa A I 2.4  103 1.84  106 P Mc 20  103 (4.8  103 )(0.040)     96.0  106 Pa 3 6 A I 2.4  10 1.84  10  A  112.7 MPa   B  96.0 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 656 P y PROBLEM 4.198 P P P B C a A D x z The four forces shown are applied to a rigid plate supported by a solid steel post of radius a. Knowing that P  24 kips and a  1.6 in., determine the maximum stress in the post when (a) the force at D is removed, (b) the forces at C and D are removed. SOLUTION For a solid circular section of radius a, A   a2 Centric force: (a) Force at D is removed.   M x   Pa, Mz  0 F 4P  2 A a M x   Pa, M z   Pa F M xz 3P ( Pa)(a) 7P   2   2 2  A I a a a 4 M  F Mc 2P   2  A I a M x2  M z2  2 Pa 2 Paa 24 2 P   2.437 P/a 2 2 2  a a 4  P  24.0 kips, Numerical data: Answers: a4 F  3P, F  2P,   4 Mx  Mz  0 Forces at C and D are removed. Resultant bending couple:  F  4P,   (b) I  (a)   (b)   a  1.6 in. (7)(24.0)  (1.6)2 (2.437)(24.0) (1.6)2   20.9 ksi    22.8 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 657 a r 20 mm PROBLEM 4.199 P 3 kN The curved portion of the bar shown has an inner radius of 20 mm. Knowing that the allowable stress in the bar is 150 MPa, determine the largest permissible distance a from the line of action of the 3-kN force to the vertical plane containing the center of curvature of the bar. 25 mm 25 mm SOLUTION Reduce the internal forces transmitted across section AB to a force-couple system at the centroid of the section. The bending couple is M  P(a  r ) For the rectangular section, the neutral axis for bending couple only lies at R Also, e  r  R h r2 r1 ln The maximum compressive stress occurs at point A. It is given by A   P My A P P (a  r ) y A P     K A Aer1 A Aer1 A with y A  R  r1 Thus, K 1 Data: (a  r )( R  r1) er1 h  25 mm, r1  20 mm, r2  45 mm, r  32.5 mm R 25  30.8288 mm, e  32.5  30.8288  1.6712 mm 45 ln 20 b  25 mm, A  bh  (25)(25)  625 mm 2  625  106 m 2 P  3  10 N  m,  A  150  10 Pa 3  AA (150  106 )(625  106 )  31.25 P 3  103 ( K  1)er1 (30.25)(1.6712)(20) ar    93.37 mm R  r1 10.8288 K  R  r1  10.8288 mm 6  a  93.37  32.5 a  60.9 mm  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 658 Dimensions in inches 400 lb PROBLEM 4.200 400 lb 400 lb 2.5 Determine the maximum stress in each of the two machine elements shown. 400 lb 2.5 3 0.5 3 r 5 0.3 r 5 0.3 1.5 0.5 0.5 1.5 0.5 SOLUTION For each case, M  (400)(2.5)  1000 lb  in. At the minimum section, I  1 (0.5)(1.5)3  0.140625 in 4 12 c  0.75 in. (a) D/d  3/1.5  2 r/d  0.3/1.5  0.2 From Fig 4.32,  max  (b) KMc (1.75)(1000)(0.75)   9.33  103 psi I 0.140625 D/d  3/1.5  2 From Fig. 4.31,  max  K  1.75  max  9.33 ksi  r/d  0.3/1.5  0.2 K  1.50 KMc (1.50)(1000)(0.75)   8.00  103 psi I 0.140625  max  8.00 ksi  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 659 120 mm PROBLEM 4.201 10 mm M 120 mm 10 mm Three 120  10-mm steel plates have been welded together to form the beam shown. Assuming that the steel is elastoplastic with E  200 GPa and  Y  300 MPa, determine (a) the bending moment for which the plastic zones at the top and bottom of the beam are 40 mm thick, (b) the corresponding radius of curvature of the beam. 10 mm SOLUTION A1  (120)(10)  1200 mm 2 R1   Y A1  (300  106 )(1200  10 6 )  360  103 N A2  (30)(10)  300 mm 2 R2   Y A2  (300  106 )(300  106 )  90  103 N A3  (30)(10)  300 mm 2 1 1 R3   Y A2  (300  106 )(300  106 )  45  103 N 2 2 y1  65 mm  65  103 m y2  45 mm  45  103 m (a) M  2( R1 y1  R2 y2  R3 y3 )  2{(360)(65)  (90)(45)  (45)(20)} (b) yY  56.7  103 N  m   Y E  Y EyY  (200  109 )(30  103 ) 300  106 y3  20 mm  20  103 m M  56.7 kN  m    20.0 mm  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 660 P 4.5 in. 4.5 in. A PROBLEM 4.202 Q A short length of a W8  31 rolled-steel shape supports a rigid plate on which two loads P and Q are applied as shown. The strains at two points A and B on the centerline of the outer faces of the flanges have been measured and found to be  A  550  106 in./in. B  B  680  106 in./in. Knowing that E  29  106 psi, determine the magnitude of each load. SOLUTION Strains:  A  550  106 in./in. C  Stresses:  B  680  106 in./in. 1 1 ( A   B )  (550  680)106  615  106 in./in. 2 2  A  E A  (29  106 psi)(550  106 in./in.)  15.95 ksi  C  E C  (29  106 psi)(615  106 in./in.)  17.835 ksi W8  31: A  9.12 in 2 M  (4.5 in.)( P  Q) At point C: At point A: C   A   PQ PQ ;  17.835 ksi   A 9.12 in 2 PQ M  A S 15.95 ksi  17.835 ksi  Solve simultaneously. S  27.5 in 3 (4.5 in.)( P  Q) ; 27.5 in 3 P  75.6 kips Q  87.1 kips P  Q  162.655 kips (1) P  Q  11.5194 kips (2) P  75.6 kips   Q  87.1 kips   PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 661 PROBLEM 4.203 ␴1 M1 A M'1 M1 M'1 ␴1 B C D ␴1 ␴1 Two thin strips of the same material and same cross section are bent by couples of the same magnitude and glued together. After the two surfaces of contact have been securely bonded, the couples are removed. Denoting by 1 the maximum stress and by 1 the radius of curvature of each strip while the couples were applied, determine (a) the final stresses at points A, B, C, and D, (b) the final radius of curvature. SOLUTION Let b  width and t  thickness of one strip. Loading one strip, M  M1 I1  1 3 1 bt , c  t 12 2 M1c  M 1  I bt 2 M 1 12 M 1  1  1 EI1 Et 3 1  After M1 is applied to each of the strips, the stresses are those given in the sketch above. They are  A  1,  B  1,  C  1,  D  1 The total bending couple is 2M1. After the strips are glued together, this couple is removed. M   2 M 1, I   1 2 b(2t )3  bt 3 12 3 ct The stresses removed are    2M y 3M1 y M y   2 13   I bt bt 2 3  A   3M1 1 3M1 1   1,  B   C  0,  D   1 2 2 2 bt bt 2 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 662 PROBLEM 4.203 (Continued) (a) Final stresses:  A   1  ( 1)  A   1  1 2 1 2  B  1   C  1   D  1  1 1 2M 3M 1 1 1 M   2 13   3 4    EI  E 3 bt Et (b) Final radius:  1  1 1  D  1 2 1 1 1 1 3 1      1 4 1 4 1    1 1  2 4 1  3 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 663 PROBLEM 4.C1 Two aluminum strips and a steel strip are to be bonded together to form a composite member of width b  60 mm and depth h  40 mm. The modulus of elasticity is 200 GPa for the steel and 75 GPa for the aluminum. Knowing that M  1500 N  m, write a computer program to calculate the maximum stress in the aluminum and in the steel for values of a from 0 to 20 mm using 2-mm increments. Using appropriate smaller increments, determine (a) the largest stress that can occur in the steel, (b) the corresponding value of a. Aluminum a Steel h ⫽ 40 mm a b ⫽ 60 mm SOLUTION Transformed section: n (all steel) I  Esteel Ealum  1 3 1  1 bh   2   (nb  b)  (h  2a )3 12 12   2   M  h2  At Point 1:  alum  At Point 2:  steel  n I M  h2  a  I PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 664 PROBLEM 4.C1 (Continued) For a  0 to 20 mm using 2-mm intervals: compute: n, I ,  alum ,  steel . b  60 mm h  40 mm M  1500 N  m Steel  200 GPa Aluminum  75 GPa Moduli of elasticity: Program Output a mm I m 4 /106 Sigma Aluminum MPa Sigma Steel MPa 0.000 0.8533 35.156 93.750 2.000 0.7088 42.325 101.580 4.000 0.5931 50.585 107.914 6.000 0.5029 59.650 111.347 8.000 0.4352 68.934 110.294 10.000 0.3867 77.586 103.448 12.000 0.3541 84.714 90.361 14.000 0.3344 89.713 71.770 16.000 0.3243 92.516 49.342 18.000 0.3205 93.594 24.958 20.000 0.3200 93.750 0.000 Find ‘a’ for max. steel stress and the corresponding aluminum stress. 6.600 0.4804 62.447 111.572083 6.610 0.4800 62.494 111.572159 6.620 0.4797 62.540 111.572113 Max. steel stress  111.6 MPa occurs when a  6.61 mm. Corresponding aluminum stress  62.5 MPa  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 665 PROBLEM 4.C2 tf y x tw d bf A beam of the cross section shown, made of a steel that is assumed to be elastoplastic with a yield strength  Y and a modulus of elasticity E, is bent about the x axis. (a) Denoting by yY the half thickness of the elastic core, write a computer program to calculate the bending moment M and the radius of curvature  for values of yY from 12 d to 16 d using decrements equal to 12 t f . Neglect the effect of fillets. (b) Use this program to solve Prob. 4.201. SOLUTION Compute moment of inertia I x . Ix  Maximum elastic moment: 1 1 b f d 3  (b f  tw )(d  2t f )3 12 12 MY  Y Ix (d/2) For yielding in the flanges, (Consider upper half of cross section.) Stress at junction of web and flange: A  c d 2 (d/2)  t f yY Y Resultant forces: Detail of stress diagram: a1  1 (c  yY ) 2 1 a2  yY   yY  (c  t f )  3 2 a3  yY  [ yY  (c  t f ) ] 3 2 a4  (c  t f ) 3 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 666 PROBLEM 4.C2 (Continued) Bending moment. M 2 R a 4 n 1 n n Radius of curvature. yY   Y   Y E ;   Y yY E (Consider upper half of cross section.) For yielding in the web, 1 a5  c  t f 2 1 a6  [ yY  (c  t f )] 2 2 a7  yY 3 R a Bending moment. M 2 Radius of curvature. yY   Y   7 n 5 n n Y E  Program: Key in expressions for an and Rn for n  1 to 7.  Y yY E For yY  c to (c  tf ) at  tf /2 decrements, compute M  2  Rn an for n  1 to 4 and   Y yY E For yY  (c  tw ) to c /3 at  tf /2 decrements, compute M  2Rn an for n  5 to 7 and   , then print. Y yY E , then print. Input numerical values and run program. PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 667 PROBLEM 4.C2 (Continued) Program Output For a beam of Problem 4.201, Depth d  140.00 mm Thickness of flange t f  10.00 mm I  0.000011600 m to the 4th Width of flange b f  120.00 mm Thickness of web tw  10.00 mm Yield strength of steel sigmaY  300 MPa Yield moment M Y  49.71 kip  in. yY (mm) M (kN  m)  (m) For yielding still in the flange, 70.000 49.71 46.67 65.000 52.59 43.33 60.000 54.00 40.00 For yielding in the web,  60.000 54.00 40.00 55.000 54.58 36.67 50.000 55.10 33.33 45.000 55.58 30.00 40.000 56.00 26.67 35.000 56.38 23.33 30.000 56.70 20.00 25.000 56.97 16.67 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 668 y ␤ PROBLEM 4.C3 0.4 0.4 A B 1.2 z C 0.4 ␤ 1.2 M D E 0.8 0.4 1.6 An 8 kip  in. couple M is applied to a beam of the cross section shown in a plane forming an angle  with the vertical. Noting that the centroid of the cross section is located at C and that the y and z axes are principal axes, write a computer program to calculate the stress at A, B, C, and D for values of  from 0 to 180° using 10° increments. (Given: I y  6.23 in 4 and I z  1.481 in 4 . ) 0.4 0.8 Dimensions in inches SOLUTION Input coordinates of A, B, C, D. z A  z (1)  2 y A  y (1)  1.4 z B  z (2)  2 yB  y (2)  1.4 z D  z (4)  1 yD  y (4)  1.4 zC  z (3)  1 Components of M. yC  y (3)  1.4 M y   M sin  M z  M cos  Equation 4.55, Page 305:  ( n)   M z y ( n) M y z ( n)  Iz Iy Program: For   0 to 180 using 10° increments. For n  1 to 4 using unit increments. Evaluate Equation 4.55 and print stresses. Return Return PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 669 PROBLEM 4.C3 (Continued) Program Output M  8.00 kip  in. Moment of couple: I y  6.23 in 4 Moments of inertia: I z  1.481 in 4 Coordinates of Points A, B, D, and E: Point A: z (1)  2: y (1)  1.4 Point B: z (2)  2: y (2)  1.4 Point D: z (3)  1: Po int E: z (4)  1: Beta   y (3)  1.4 y (4)  1.4 ---Stress at Points--A B ksi ksi D ksi E ksi 0 –7.565 –7.565 7.565 7.565 10 –7.896 –7.004 7.673 7.227 20 –7.987 –6.230 7.548 6.669 30 –7.836 –5.267 7.193 5.909 40 –7.446 –4.144 6.621 4.970 50 –6.830 –2.895 5.846 3.879 60 –6.007 –1.558 4.895 2.670 70 –5.001 –0.174 3.794 1.381 80 –3.843 1.216 2.578 0.049 90 –2.569 2.569 1.284 –1.284 100 –1.216 3.843 –0.049 –2.578 110 0.174 5.001 –1.381 –3.794 120 1.558 6.007 –2.670 –4.895 130 2.895 6.830 –3.879 –5.846 140 4.144 7.446 –4.970 –6.621 150 5.267 7.836 –5.909 –7.193 160 6.230 7.987 –6.669 –7.548 170 7.004 7.896 –7.227 –7.673 180 7.565 7.565 –7.565 –7.565 PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 670 PROBLEM 4.C4 b B B A A h M' M r1 C Couples of moment M  2 kN  m are applied as shown to a curved bar having a rectangular cross section with h  100 mm and b  25 mm. Write a computer program and use it to calculate the stresses at points A and B for values of the ratio r1/h from 10 to 1 using decrements of 1, and from 1 to 0.1 using decrements of 0.1. Using appropriate smaller increments, determine the ratio r1/h for which the maximum stress in the curved bar is 50% larger than the maximum stress in a straight bar of the same cross section. SOLUTION h  100 mm, b  25 mm, M  2 kN  m Input: For straight bar,  straight  M S 6M  2 hb  48 MPa Following notation of Section 4.15, key in the following: r2  h  r1 ; R  h /ln (r2  r1 ); r  r1  r2 : e  r  R; A  bh  2500  A  1  M (r1  R)( Aer1 ) Stresses:  B   2  M (r2  R)/(Aer2 ) Since h  100 mm, for r1/h  10, r1  1000 mm. Also, r1/h  10, r1  100 Program: (I) (II) For r1  1000 to 100 at 100 decrements, using equations of Lines I and II, evaluate r2 , R, r , e,  1 , and  2 Also evaluate ratio   1/ straight Return and repeat for r1  100 to 10 at 10 decrements. PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 671 PROBLEM 4.C4 (Continued) Program Output M  Bending moment  2 kN  m h  100.000 in. A  2500.00 mm 2 Stress in straight beam  48.00 MPa 1 2 r1 mm rbar mm R mm e mm MPa MPa r1 /h – ratio – 1000 1050 1049 0.794 –49.57 46.51 10.000 –1.033 900 950 949 0.878 –49.74 46.36 9.000 –1.036 800 850 849 0.981 –49.95 46.18 8.000 –1.041 700 750 749 1.112 –50.22 45.95 7.000 –1.046 600 650 649 1.284 –50.59 45.64 6.000 –1.054 500 550 548 1.518 –51.08 45.24 5.000 –1.064 400 450 448 1.858 –51.82 44.66 4.000 –1.080 300 350 348 2.394 –53.03 43.77 3.000 –1.105 200 250 247 3.370 –55.35 42.24 2.000 –1.153 100 150 144 5.730 –61.80 38.90 1.000 –1.288 ===================================================== 100 150 144 5.730 –61.80 38.90 1.000 –1.288 90 140 134 6.170 –63.15 38.33 0.900 –1.316 80 130 123 6.685 –64.80 37.69 0.800 –1.350 70 120 113 7.299 –66.86 36.94 0.700 –1.393 60 110 102 8.045 –69.53 36.07 0.600 –1.449 50 100 91 8.976 –73.13 35.04 0.500 –1.523 40 90 80 10.176 –78.27 33.79 0.400 –1.631 30 80 68 11.803 –86.30 32.22 0.300 –1.798 20 70 56 14.189 –100.95 30.16 0.200 –2.103 10 60 42 18.297 –138.62 27.15 0.100 –2.888 =================================================================== Find r1/h for ( max ) /( straight )  1.5 52.70 52.80 103 103 94 94 8.703 8.693 –72.036 –71.998 35.34 35.35 0.527 0.528 –1.501 –1.500 52.90 103 94 8.683 –71.959 35.36 0.529 –1.499 Ratio of stresses is 1.5 for r1  52.8 mm or r1/h  0.529. [Note: The desired ratio r1/h is valid for any beam having a rectangular cross section.] PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 672 bn PROBLEM 4.C5 hn M h2 The couple M is applied to a beam of the cross section shown. (a) Write a computer program that, for loads expressed in either SI or U.S. customary units, can be used to calculate the maximum tensile and compressive stresses in the beam. (b) Use this program to solve Probs. 4.9, 4.10, and 4.11. b2 h1 b1 SOLUTION Input: Bending moment M. For n  1 to n, Enter bn and hn Area  bn hn an  an 1  (hn 1 )/2  hn /2 (Print) [Moment of rectangle about base] m  (Area)an [For whole cross section] m  m  m; Area  Area  Area Location of centroid above base. y  m/Area (Print) Moment of inertia about horizontal centroidal axis. For n  1 to n, an  an 1  (hn 1 )/2  hn /2  I  bn hn3 /12  (bn hn )( y  an )2 I  I  I Computation of stresses. Total height: (Print) For n  1 to n, H  H  hn Stress at top: M top   M Hy I (Print) Stress at bottom: M bottom  M y I (Print) PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 673 PROBLEM 4.C5 (Continued) Problem 4.9 Summary of cross section dimensions: Width (in.) Height (in.) 9.00 2.00 3.00 6.00 Bending moment  600.000 kip  in. Centroid is 3.000 mm above lower edge. Centroidal moment of inertia is 204.000 in4. Stress at top of beam  14.706 ksi Stress at bottom of beam  8.824 ksi Problem 4.10 Summary of cross section dimensions: Width (in.) Height (in.) 4.00 1.00 1.00 6.00 8.00 1.00 Bending moment  500.000 kip  in. Centroid is 4.778 in. above lower edge. Centroidal moment of inertia is 155.111 in4. Stress at top of beam  10.387 ksi Stress at bottom of beam  15.401 ksi Problem 4.11 Summary of cross section dimensions: Width (mm) Height (mm) 50 10 20 50 Bending moment  1500.0000 N  m Centroid is 25.000 mm above lower edge. Centroidal moment of inertia is 512,500 mm4. Stress at top of beam  102.439 MPa Stress at bottom of beam  72.171 MPa PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 674 PROBLEM 4.C6 y Dy y c M z A solid rod of radius c  1.2 in. is made of a steel that is assumed to be elastoplastic with E  29,000 ksi and  Y  42 ksi. The rod is subjected to a couple of moment M that increases from zero to the maximum elastic moment M Y and then to the plastic moment M p . Denoting by yY the half thickness of the elastic core, write a computer program and use it to calculate the bending moment M and the radius of curvature  for values of yY from 1.2 in. to 0 using 0.2-in. decrements. (Hint: Divide the cross section into 80 horizontal elements of 0.03-in. height.) SOLUTION MY  Y  c3  (42 ksi)  (1.2 in.)3  57 kip  in. 4 4 4 4 M p   Y c3  (42 ksi) (1.2 in.)3  96.8 kip  in. 3 3 Consider top half of rod. Let i  Number of elements in top half. c h  Height of each element: h  L For n  0 to i  1, Step 1:   y  n(h)  z  c 2  {(n  0.5)h}2   z at midheight of element    If y  yY go to 100  (n  0.5)h   Stress in elastic core  E  Y  y   Repeat for yY  1.2 in. go to 200  to yY  0 100  Stress in plastic zone   E  Y  At 0.2-in. decrements 200 Area  2 z (h)   Force   E (Area)  Moment  Force (n  0.5)h   M  M  Moment   P  yY E / Y  Print yY , M , and  .   Next  PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 675 PROBLEM 4.C6 (Continued) Program Output Radius of rod  1.2 in. Yield point of steel  42 ksi Yield moment  57.0 kip  in. Plastic moment  96.8 kip  in. Number of elements in half of the rod  40 For yY  1.20 in., M  57.1 kip  in. For yY  0.80 in., M  76.9 kip  in. For yY  0.40 in., M  91.6 kip  in. Radius of curvature  276.19 in. For yY  0.00 in., M  infinite Radius of curvature  zero For yY  1.00 in., For yY  0.60 in., For yY  0.20 in.,  Radius of curvature  828.57 in. M  67.2 kip  in. Radius of curvature  690.48 in. M  85.2 kip  in. Radius of curvature  414.29 in. M  95.5 kip  in. Radius of curvature  552.38 in. Radius of curvature  138.10 in. PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 676 PROBLEM 4.C7 2 in. C 3 in. The machine element of Prob 4.178 is to be redesigned by removing part of the triangular cross section. It is believed that the removal of a small triangular area of width a will lower the maximum stress in the element. In order to verify this design concept, write a computer program to calculate the maximum stress in the element for values of a from 0 to 1 in. using 0.1-in. increments. Using appropriate smaller increments, determine the distance a for which the maximum stress is as small as possible and the corresponding value of the maximum stress. B A 2.5 in. a SOLUTION See Figure 4.79, Page 289. M  5 kip  in. r2  5 in. b2  2.5 in. For a  0 to 1.0 at 0.1 intervals, h  3 a r1  2  a b1  b2 (a /(h  a )) Area  (b1  b2 )(h/2) 1 1  x  a +  b1h(h/3)  b2 h  2h/3  Area 2 2  r  r2  (h  x ) R 1 2 h 2 (b1  b2 ) (b1r2  b2 r1 ) ln er R r2 r1  h(b1  b2 )  D  M (r1  R)/[Area (e)(r1 )]  B  M (r2  R) /[Area (e)(r2 )] Print and Return PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 677 PROBLEM 4.C7 (Continued) Program Output a in. R in. 0.00 3.855 0.10 3.858 0.20 3.869 0.30 3.884 0.40 3.904 0.50 3.928 0.60 3.956 0.70 3.985 0.80 4.018 0.90 4.052 1.00 4.089 D B ksi ksi b1 r e 7.7736 2.1014 0.00 4.00 0.145 2.1197 0.08 4.00 0.144 6.9260 2.1689 0.17 4.01 0.140 6.7004 2.2438 0.25 4.02 0.134 2.3423 0.33 4.03 0.127 6.5143 2.4641 0.42 4.05 0.119 2.6102 0.50 4.07 0.111 2.7828 0.58 4.09 0.103 2.9852 0.67 4.11 0.094 3.2220 0.75 4.14 0.086 3.4992 0.83 4.17 0.078 8.5071 7.2700 6.5683 6.5296 6.6098 6.7541 6.9647 Determination of the maximum compressive stress that is as small as possible. a in. R in. 0.620 3.961 0.625 3.963 0.630 3.964 D B ksi ksi b1 r e 6.51185 2.6425 0.52 4.07 0.109 2.6507 0.52 4.07 0.109 2.6591 0.52 4.07 0.109 6.51198 6.51188 Answer: When a  625 in., the compressive stress is 6.51 ksi. PROPRIETARY MATERIAL. Copyright © 2015 McGraw-Hill Education. This is proprietary material solely for authorized instructor use. Not authorized for sale or distribution in any manner. This document may not be copied, scanned, duplicated, forwarded, distributed, or posted on a website, in whole or part. 678

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