- 17.F17-1: FI7-1. The cart and its load have a total mass of 100 kg. Determine...
- 17.F17-2: FI7-2. If the 80-kg cabinet is allowed to roll down the inclined pl...
- 17.F17-3: F17-3. The 20-lb link AB is pinned to a moving frame at A and held ...
- 17.F17-4: FI7-4. Determine the maximum acceleration of the truck without caus...
- 17.F17-5: F17-5. At the instant shown both rods of negligible mass swing with...
- 17.F17-6: FI7-6. At the instant shown, link CD rotates with an angular veloci...
- 17.F17-7: FI7-7. The 100-kg wheel has a radius of gyration about its center O...
- 17.F17-8: FI7-8. The 50-kg disk is subjected to the couple moment of M = (9/)...
- 17.F17-9: F17-9. At the instant shown, the uniform 30-kg slender rod has a co...
- 17.F17-10: F17-10. At the instant shown, the 30-kg disk has a counterclockwise...
- 17.F17-11: FI7-11. The uniform slender rod has a mass of 15 kg. Determine the ...
- 17.F17-12: FI7-12. The uniform 30-kg slender rod is being pulled by the cord t...
- 17.F17-13: F17-13. The uniform 60-kg slender bar is initially at rest on a smo...
- 17.F17-14: FI7-14. The 100-kg cylinder rolls without slipping on the horizonta...
- 17.F17-15: F17-15. The 20-kg wheel has a radius of gyration about its center O...
- 17.F17-16: FI7-16. The 20-kg sphere rolls down the inclined plane without slip...
- 17.F17-17: FI7-17. The 200-kg spool has a radius of gyration about its mass ce...
- 17.F17-18: FI 7-18. The 12-kg slender rod is pinned to a small roller A that s...
- 17.17-1: 17-1. Determine the moment of inertia /v for the slender rod. The r...
- 17.17-2: 17-2. The solid cylinder has an outer radius R, height h. and is ma...
- 17.17-3: 17-3. Determine the moment of inertia of the thin ring about the z ...
- 17.17-4: *17-4. Determine the moment of inertia of the semiellipsoid with re...
- 17.17-5: 17-5. The sphere is formed by revolving the shaded area around the ...
- 17.17-6: 17-6. Determine the mass moment of inertia /, of the cone formed by...
- 17.17-7: 17-7. The solid is formed by revolving the shaded area around the y...
- 17.17-8: *17-8. The concrete shape is formed by rotating the shaded area abo...
- 17.17-9: 17-9. Determine the moment of inertia /- of the torus.The mass of t...
- 17.17-10: 17-10. Determine the mass moment of inertia of the pendulum about a...
- 17.17-11: 17-11. The slender rods have a weight of 3 Ib/ft. Determine the mom...
- 17.17-12: *17-12. Determine the moment of inertia of the solid steel assembly...
- 17.17-13: 17-13. The wheel consists of a thin ring having a mass of 10 kg and...
- 17.17-14: 17-14. If the large ring, small ring and each of the spokes weigh 1...
- 17.17-15: 17-15. Determine the moment of inertia about an axis perpendicular ...
- 17.17-16: *17-16. Determine the mass moment of inertia of the thin plate abou...
- 17.17-17: 17-17. The assembly consists of a disk having a mass of 6 kg and sl...
- 17.17-18: 17-18. The assembly consists of a disk having a mass of 6 kg and sl...
- 17.17-19: 17-19. The pendulum consists of two slender rods AB and OC which ha...
- 17.17-20: *17-20. The pendulum consists of two slender rods AB and OC which h...
- 17.17-21: 17-21. The pendulum consists of the 3-kg slender rod and the 5-kg t...
- 17.17-22: *17-22. Determine the moment of inertia of the overhung crank about...
- 17.17-23: 17-23. Determine the moment of inertia of the overhung crank about ...
- 17.17-24: 17-24. The door has a weight of 200 lb and a center of gravity at G...
- 17.17-25: 17-25. The door has a weight of 200 lb and a center of gravity at G...
- 17.17-26: 17-26. The uniform pipe has a weight of 500 lb/ft and diameter of 2...
- 17.17-27: 17-27. The drum truck supports the 600-lb drum that has a center of...
- 17.17-28: *17-28. If the cart is given a constant acceleration of a = 6 ft/s2...
- 17.17-29: 17-29. If the strut AC can withstand a maximum compression force of...
- 17.17-30: 17-30. The drop gate at the end of the trailer has a mass of 1.25 M...
- 17.17-31: 17-31. The pipe has a length of 3 m and a mass of 500 kg. It is att...
- 17.17-32: *17-32. The mountain bike has a mass of 40 kg with center of mass a...
- 17.17-33: 17-33. The mountain bike has a mass of 40 kg with center of mass at...
- 17.17-34: 17-34. The trailer with its load has a mass of 150 kg and a center ...
- 17.17-35: 17-35. At the start of a race, the rear drive wheels B of the 1550-...
- 17.17-36: *17-36. Determine the maximum acceleration that can be achieved by ...
- 17.17-37: 17-37. If the 4500-lb van has front-wheel drive, and the coefficien...
- 17.17-38: 17-38. If the 4500-lb van has rear-wheel drive, and the coefficient...
- 17.17-39: 17-39. The uniform bar of mass m is pin connected to the collar, wh...
- 17.17-40: *17-40. The lift truck has a mass of 70 kg and mass center at G. If...
- 17.17-41: 17-41. The lift truck has a mass of 70 kg and mass center at G. Det...
- 17.17-42: 17-42. The uniform crate has a mass of 50 kg and rests on the cart ...
- 17.17-43: 17-43. Determine the acceleration of the 150-lb cabinet and the nor...
- 17.17-44: *17-44. The assembly has a mass of 8 Mg and is hoisted using the bo...
- 17.17-45: 17-45. The 2-Mg truck achieves a speed of 15 m/s with a constant ac...
- 17.17-46: 17-46. Determine the shortest time possible for the rear-wheel driv...
- 17.17-47: 17-47. Tlie snowmobile has a weight of 250 lb. centered at G|, whil...
- 17.17-48: *17-48. The snowmobile has a weight of 250 lb, centered at G|. whil...
- 17.17-49: 17-49. If the carts mass is 30 kg and it is subjected to a horizont...
- 17.17-50: 17-50. If the carts mass is 30 kg. determine the horizontal force P...
- 17.17-51: 17-51. The pipe has a mass of 800 kg and is being towed behind the ...
- 17.17-52: *17-52. The pipe has a mass of 800 kg and is being towed behind a t...
- 17.17-53: 17-53. The arched pipe has a mass of 80 kg and rests on the surface...
- 17.17-54: 17-54. The arched pipe has a mass of 80 kg and rests on the surface...
- 17.17-55: 17-55. At the instant shown, link CD rotates with an angular veloci...
- 17.17-56: *17-56. Determine the force developed in the links and the accelera...
- 17.17-57: 17-57. The 10-kg wheel has a radius of gyration kA = 200 inm. If th...
- 17.17-58: 17-58. The 80-kg disk is supported by a pin at A. If it is released...
- 17.17-59: 17-59. The uniform slender rod has a mass m. If it is released from...
- 17.17-60: *17-60. The drum has a weight of 80 lb and a radius of gyration kG ...
- 17.17-61: 17-61. Cable is unwound from a spool supported on small rollers at ...
- 17.17-62: 17-62. The 10-lb bar is pinned at its center O and connected to a t...
- 17.17-63: 17-63. The 10-lb bar is pinned at its center O and connected to a t...
- 17.17-64: 17-64. If shaft BC is subjected to a torque of M=(0A5t\/2) N m. whe...
- 17.17-65: 17-65. Determine the vertical and horizontal components of reaction...
- 17.17-66: 17-66. The kinetic diagram representing the general rotational moti...
- 17.17-67: 17-67. Determine the position rP of the center of percussion P of t...
- 17.17-68: *17-68. The disk has a mass M and a radius R. If a block of mass m ...
- 17.17-69: 17-69. The door will close automatically using torsional springs mo...
- 17.17-70: 17-70. The door will close automatically using torsional springs mo...
- 17.17-71: 17-71. The pendulum consists of a 10-kg uniform slender rod and a 1...
- 17.17-72: *17-72. The disk has a mass of 20 kg and is originally spinning at ...
- 17.17-73: 17-73. The slender rod of length L and mass m is released from rest...
- 17.17-74: 17-74. Tie 5-kg cylinder is initially at rest when it is placed in ...
- 17.17-75: 17-75. The wheel has a mass of 25 kg and a radius of gyration kR = ...
- 17.17-76: 17-76. A 40-kg boy sits on top of the large wheel which has a mass ...
- 17.17-77: 17-77. Gears A and B have a mass of 50 kg and 15 kg, respectively. ...
- 17.17-78: 17-78. Block A has a mass m and rests on a surface having a coeffic...
- 17.17-79: 17-79. The two blocks A and B have a mass of 5 kg and 10 kg. respec...
- 17.17-80: *17-80. The two blocks A and B have a mass mA and m#. respectively,...
- 17.17-81: 17-81. Determine the angular acceleration of the 25-kg diving board...
- 17.17-82: 17-82. The lightweight turbine consists of a rotor which is powered...
- 17.17-83: 17-83. The two-bar assembly is released from rest in the position s...
- 17.17-84: *17-84. The armature (slender rod) AB has a mass of 0.2 kg and can ...
- 17.17-85: 17-85. The bar has a weight per length of w. If it is rotating in t...
- 17.17-86: 1786. A force F = 2 lb is applied perpendicular to the axis of the ...
- 17.17-87: 17-87. The 15-kg block A and 20-kg cylinder B are connected by a li...
- 17.17-88: *17-88. The 15-kg block A and 20-kg cylinder B are connected by a l...
- 17.17-89: 17-89. The Catherine wheel" is a firework that consists of a coiled...
- 17.17-90: 17-90. If the disk in Fig. 17-20 rolls w ithout slipping, show that...
- 17.17-91: 17-91. The 20-kg punching bag has a radius of gyration about its ce...
- 17.17-92: 17-92. The uniform 150-lb beam is initially at rest when the forces...
- 17.17-93: 17-93. The rocket has a weight of 20 000 lb. mass center at G. and ...
- 17.17-94: 17-94. The tire has a weight of 30 lb and a radius of gyration of k...
- 17.17-95: 17-95. The tire has a weight of 30 lb and a radius of gyration of k...
- 17.17-96: *17-96. The spool has a mass of 100 kg and a radius of gyration of ...
- 17.17-97: 17-97. Solve Prob. 17-96 if the cord and force P = 50 N are directe...
- 17.17-98: 17-98. The spool has a mass of 100 kg and a radius of gyration kG =...
- 17.17-99: 17-99. The upper body of the crash dummy has a mass of 75 lb. a cen...
- 17.17-100: *17-100. A uniform rod having a weight of 10 lb is pin supported at...
- 17.17-101: 17-101. Solve Prob. 17-100 assuming that the roller at A is replace...
- 17.17-102: 17-102. The 2-kg slender bar is supported by cord UC and then relea...
- 17.17-103: 17-103. If the truck accelerates at a constant rate of 6 m/s2. star...
- 17.17-104: *17-104. If P = 30 lb, determine the angular acceleration of the 50...
- 17.17-105: 17-105. If the coefficient of static friction between the 50-lb rol...
- 17.17-106: 17-106. The spool has a mass of 500 kg and a radius of gyration kG ...
- 17.17-107: 17107. The spool has a mass of 500 kg and a radius of gyration ka =...
- 17.17-108: *17-108. The semicircular disk having a mass of 10 kg is rotating a...
- 17.17-109: 17-109. The 500-kg concrete culvert has a mean radius of 0.5 m. If ...
- 17.17-110: 17-110. The 10-lb hoop or thin ring is given an initial angular vel...
- 17.17-111: 17-111. A long strip of paper is wrapped into two rolls, each havin...
- 17.17-112: 17-112. The circular concrete culvert rolls with an angular velocit...
- 17.17-113: 17-113. The uniform disk of mass m is rotating with an angular velo...
- 17.17-114: 17-114. The uniform disk of mass m is rotating with an angular velo...
- 17.17-115: 17-115. The 16-lb bowling ball is cast horizontally onto a lane suc...
- 17.17-116: *17-116. The uniform beam has a weight W. If it is originally at re...
- 17.17-117: 17-117. A cord C is wrapped around each of the two 10-kg disks. If ...
- 17.17-118: 17-118. The 500-lb beam is supported at A and B when it is subjecte...
- 17.17-119: 17-119. The 30-kg uniform slender rod AB rests in the position show...
- 17.17-120: *17-120. The 30-kg slender rod AB rests in the position shown when ...
- 17.P17-1: PI7-1. The truck is used to pull the heavy container.To be most eff...
- 17.P17-2: P17-2. The tractor is about to tow the plane to the right. Is it po...
- 17.P17-3: P17-3. How can you tell the driver is accelerating this SUV? To exp...
- 17.P17-4: PI7-4. Here is something you should not try at home, at least not w...

# Solutions for Chapter 17: Engineering Mechanics: Dynamics 13th Edition

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ISBN: 9780132911276

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