- 6.6-1: Draw the shear and moment diagrams for the shaft and determine the ...
- 6.6-2: Draw the shear and moment diagrams for the beam, and determine the ...
- 6.6-3: Draw the shear and moment diagrams for the beam, and determine the ...
- 6.6-4: Express the shear and moment in terms of x for 0 6 x 6 3 m and 3 m ...
- 6.6-5: Express the internal shear and moment in the cantilevered beam as a...
- 6.6-6: Draw the shear and moment diagrams for the shaft. The bearings at A...
- 6.6-7: Express the internal shear and moment in terms of x for 0 x 6 L>2, ...
- 6.6-8: Draw the shear and moment diagrams for the beam, and determine the ...
- 6.6-9: If the force applied to the handle of the load binder is 50 lb, det...
- 6.6-10: Draw the shear and moment diagrams for the shaft. The bearings at A...
- 6.6-11: The crane is used to support the engine, which has a weight of 1200...
- 6.6-12: Draw the shear and moment diagrams for the beam.
- 6.6-13: Draw the shear and moment diagrams for the beam.
- 6.6-14: Draw the shear and moment diagrams for the beam.
- 6.6-15: Members ABC and BD of the counter chair are rigidly connected at B ...
- 6.6-16: A reinforced concrete pier is used to support the stringers for a b...
- 6.6-17: Draw the shear and moment diagrams for the beam and determine the s...
- 6.6-18: The industrial robot is held in the stationary position shown. Draw...
- 6.6-19: Determine the placement distance a of the roller support so that th...
- 6.6-20: Draw the shear and moment diagrams for the beam.
- 6.6-21: Draw the shear and moment diagrams for the beam.
- 6.6-22: Draw the shear and moment diagrams for the overhanging beam.
- 6.6-23: The 150-lb man sits in the center of the boat, which has a uniform ...
- 6.6-24: Draw the shear and moment diagrams for the beam.
- 6.6-25: The footing supports the load transmitted by the two columns. Draw ...
- 6.6-26: Draw the shear and moment diagrams for the beam.
- 6.6-27: Draw the shear and moment diagrams for the beam.
- 6.6-28: Draw the shear and moment diagrams for the beam.
- 6.6-29: Draw the shear and moment diagrams for the beam.
- 6.6-30: Draw the shear and moment diagrams for the beam.
- 6.6-31: The support at A allows the beam to slide freely along the vertical...
- 6.6-32: The smooth pin is supported by two leaves A and B and subjected to ...
- 6.6-33: The shaft is supported by a smooth thrust bearing at A and smooth j...
- 6.6-34: Draw the shear and moment diagrams for the cantilever beam.
- 6.6-35: Draw the shear and moment diagrams for the beam.
- 6.6-36: Draw the shear and moment diagrams for the rod. Only vertical react...
- 6.6-37: Draw the shear and moment diagrams for the beam.
- 6.6-38: The beam is used to support a uniform load along CD due to the 6-kN...
- 6.6-39: Draw the shear and moment diagrams for the double overhanging beam.
- 6.6-40: Draw the shear and moment diagrams for the simply supported beam.
- 6.6-41: The compound beam is fixed at A, pin connected at B, and supported ...
- 6.6-42: Draw the shear and moment diagrams for the compound beam.
- 6.6-43: The compound beam is fixed at A, pin connected at B, and supported ...
- 6.6-44: Draw the shear and moment diagrams for the beam.
- 6.6-45: A short link at B is used to connect beams AB and BC to form the co...
- 6.6-46: The truck is to be used to transport the concrete column. If the co...
- 6.6-47: An A-36 steel strip has an allowable bending stress of 165 MPa. If ...
- 6.6-48: Determine the moment M that will produce a maximum stress of 10 ksi...
- 6.6-49: Determine the maximum tensile and compressive bending stress in the...
- 6.6-50: The beam is constructed from four pieces of wood, glued together as...
- 6.6-51: The beam is constructed from four pieces of wood, glued together as...
- 6.6-52: The beam is made from three boards nailed together as shown. If the...
- 6.6-53: The beam is made from three boards nailed together as shown. If the...
- 6.6-54: If the built-up beam is subjected to an internal moment of M = 75 k...
- 6.6-55: If the built-up beam is subjected to an internal moment of M = 75 k...
- 6.6-56: The beam is subjected to a moment M. Determine the percentage of th...
- 6.6-57: Determine the moment M that should be applied to the beam in order ...
- 6.6-58: The beam is made from three boards nailed together as shown. If the...
- 6.6-59: If M = 1 kip # ft, determine the resultant force the bending stress...
- 6.6-60: The beam is subjected to a moment of 15 kip # ft. Determine the res...
- 6.6-61: The beam is subjected to a moment of 15 kip # ft. Determine the per...
- 6.6-62: The beam is subjected to a moment of M = 40 kN # m. Determine the b...
- 6.6-63: The steel shaft has a diameter of 2 in. It is supported on smooth j...
- 6.6-64: The beam is made of steel that has an allowable stress of sallow = ...
- 6.6-65: A shaft is made of a polymer having an elliptical cross section. If...
- 6.6-66: Solve Prob. 665 if the moment M = 50 N # m is applied about the y a...
- 6.6-67: The shaft is supported by smooth journal bearings at A and B that o...
- 6.6-68: The shaft is supported by smooth journal bearings at A and B that o...
- 6.6-69: The axle of the freight car is subjected to a wheel loading of 20 k...
- 6.6-70: The strut on the utility pole supports the cable having a weight of...
- 6.6-71: The boat has a weight of 2300 lb and a center of gravity at G. If i...
- 6.6-72: Determine the absolute maximum bending stress in the 1.5-in.-diamet...
- 6.6-73: Determine the smallest allowable diameter of the shaft. The shaft i...
- 6.6-74: The pin is used to connect the three links together. Due to wear, t...
- 6.6-75: The shaft is supported by a thrust bearing at A and journal bearing...
- 6.6-76: A timber beam has a cross section which is originally square. If it...
- 6.6-77: If the beam is subjected to an internal moment of M = 2 kip # ft, d...
- 6.6-78: If the allowable tensile and compressive stress for the beam are (s...
- 6.6-79: If the beam is subjected to an internal moment of M = 2 kip # ft, d...
- 6.6-80: If the beam is subjected to a moment of M = 100 kN # m, determine t...
- 6.6-81: If the beam is made of material having an allowable tensile and com...
- 6.6-82: The shaft is supported by a smooth thrust bearing at A and smooth j...
- 6.6-83: The shaft is supported by a thrust bearing at A and journal bearing...
- 6.6-84: If the intensity of the load w = 15 kN>m, determine the absolute ma...
- 6.6-85: If the allowable bending stress is sallow = 150 MPa, determine the ...
- 6.6-86: The beam is subjected to the triangular distributed load with a max...
- 6.6-87: The beam has a rectangular cross section with b = 4 in. Determine t...
- 6.6-88: Determine the absolute maximum bending stress in the beam. Each seg...
- 6.6-89: If the compound beam in Prob. 642 has a square cross section of sid...
- 6.6-90: If the beam in Prob. 628 has a rectangular cross section with a wid...
- 6.6-91: Determine the absolute maximum bending stress in the 80-mm-diameter...
- 6.6-92: Determine, to the nearest millimeter, the smallest allowable diamet...
- 6.6-93: Determine the absolute maximum bending stress in the beam, assuming...
- 6.6-94: Determine the absolute maximum bending stress in the 2-in.-diameter...
- 6.6-95: Determine the smallest diameter of the shaft to the nearest 1 8 in....
- 6.6-96: A log that is 2 ft in diameter is to be cut into a rectangular sect...
- 6.6-97: A log that is 2 ft in diameter is to be cut into a rectangular sect...
- 6.6-98: If the beam in Prob. 63 has a rectangular cross section with a widt...
- 6.6-99: The simply supported truss is subjected to the central distributed ...
- 6.6-100: If d = 450 mm, determine the absolute maximum bending stress in the...
- 6.6-101: If the allowable bending stress is sallow = 6 MPa, determine the mi...
- 6.6-102: The beam has a rectangular cross section as shown. Determine the la...
- 6.6-103: The beam has the rectangular cross section shown. If w = 1 kN>m, de...
- 6.6-104: The member has a square cross section and is subjected to the momen...
- 6.6-105: The member has a square cross section and is subjected to the momen...
- 6.6-106: Consider the general case of a prismatic beam subjected to bending-...
- 6.6-107: Determine the bending stress at point A of the beam, and the orient...
- 6.6-108: Determine the bending stress at point A of the beam using the resul...
- 6.6-109: The steel shaft is subjected to the two loads. If the journal beari...
- 6.6-110: The 65-mm-diameter steel shaft is subjected to the two loads. If th...
- 6.6-111: For the section, Iz = 31.7(106) m4, Iy = 114(106) m4, Iyz = 15.8(10...
- 6.6-112: Solve Prob. 6111 using the equation developed in Prob. 6106.
- 6.6-113: The box beam is subjected to a moment of M = 15 kip # ft. Determine...
- 6.6-114: Determine the maximum magnitude of the bending moment M so that the...
- 6.6-115: The shaft is subjected to the vertical and horizontal loadings of t...
- 6.6-116: For the section, Iy= 31.7(10-6 ) m4 , Iz= 114(10-6 ) m4 , Iyz = 15....
- 6.6-117: Solve Prob. 6116 using the equation developed in Prob. 6106.
- 6.6-118: If the applied distributed loading of w = 4 kN>m can be assumed to ...
- 6.6-119: Determine the maximum allowable intensity w of the uniform distribu...
- 6.6-120: The composite beam is made of steel (A) bonded to brass (B) and has...
- 6.6-121: The composite beam is made of steel (A) bonded to brass (B) and has...
- 6.6-122: Segment A of the composite beam is made from 2014-T6 aluminum alloy...
- 6.6-123: Segment A of the composite beam is made from 2014-T6 aluminum alloy...
- 6.6-124: The white spruce beam is reinforced with A-992 steel straps at its ...
- 6.6-125: The wooden section of the beam is reinforced with two steel plates ...
- 6.6-126: The wooden section of the beam is reinforced with two steel plates ...
- 6.6-127: The Douglas Fir beam is reinforced with A-992 steel straps at its s...
- 6.6-128: The steel channel is used to reinforce the wood beam. Determine the...
- 6.6-129: A wood beam is reinforced with steel straps at its top and bottom a...
- 6.6-130: A bimetallic strip is made from pieces of 2014-T6 aluminum and C834...
- 6.6-131: Determine the maximum uniform distributed load w0 that can be suppo...
- 6.6-132: The composite beam is made of A-36 steel (A) bonded to C83400 red b...
- 6.6-133: The composite beam is made of A-36 steel (A) bonded to C83400 red b...
- 6.6-134: If the beam is subjected to a moment of M= 45 kN # m, determine the...
- 6.6-135: The Douglas Fir beam is reinforced with A-36 steel straps at its si...
- 6.6-136: For the curved beam in Fig. 640a, show that when the radius of curv...
- 6.6-137: The curved member is subjected to the moment of M = 50 kN # m. Dete...
- 6.6-138: The curved member is made from material having an allowable bending...
- 6.6-139: The curved beam is subjected to a moment of M = 40 lb # ft. Determi...
- 6.6-140: The curved beam is made from material having an allowable bending s...
- 6.6-141: If P = 3 kN, determine the bending stress at points A, B, and C of ...
- 6.6-142: If the maximum bending stress at section aa is not allowed to excee...
- 6.6-143: The elbow of the pipe has an outer radius of 0.75 in. and an inner ...
- 6.6-144: The curved bar used on a machine has a rectangular cross section. I...
- 6.6-145: The curved bar used on a machine has a rectangular cross section. I...
- 6.6-146: The steel rod has a circular cross section. If it is gripped at its...
- 6.6-147: The member has a circular cross section. If it is subjected to a mo...
- 6.6-148: The member has a circular cross section. If the allowable bending s...
- 6.6-149: The curved bar used on a machine has a rectangular cross section. I...
- 6.6-150: The bar is subjected to a moment of M = 100 N # m. Determine the ma...
- 6.6-151: The allowable bending stress for the bar is sallow = 200 MPa. Deter...
- 6.6-152: The bar has a thickness of 1 in. and the allowable bending stress i...
- 6.6-153: The bar has a thickness of 1 in. and is subjected to a moment of 3 ...
- 6.6-154: The bar has a thickness of 0.5 in. and the allowable bending stress...
- 6.6-155: If the radius of each notch on the plate is r = 10 mm, determine th...
- 6.6-156: The stepped bar has a thickness of 10 mm. Determine the maximum mom...
- 6.6-157: The bar has a thickness of 0.5 in. and is subjected to a moment of ...
- 6.6-158: Determine the shape factor for the wide-flange beam.
- 6.6-159: The wide-flange member is made from an elastic perfectly plastic ma...
- 6.6-160: The rod has a circular cross section. If it is made of an elastic p...
- 6.6-161: The rod has a circular cross section. If it is made of an elastic p...
- 6.6-162: The beam is made of an elastic perfectly plastic material. Determin...
- 6.6-163: Determine the plastic moment Mp that can be supported by a beam hav...
- 6.6-164: Determine the shape factor for the beam.
- 6.6-165: The beam is made of elastic perfectly plastic material. Determine t...
- 6.6-166: Determine the shape factor for the beam.
- 6.6-167: The beam is made of an elastic perfectly plastic material for which...
- 6.6-168: The beam is made of elastic perfectly plastic material for which sY...
- 6.6-169: Determine the shape factor of the cross section.
- 6.6-170: The rod has a circular cross section. If it is made of an elastic p...
- 6.6-171: The rod has a circular cross section. If it is made of an elastic p...
- 6.6-172: Determine the shape factor of the cross section.
- 6.6-173: The beam is made of elastic perfectly plastic material. Determine t...
- 6.6-174: Determine the shape factor for the member having the tubular cross ...
- 6.6-175: Determine the shape factor of the cross section.
- 6.6-176: The box beam is made of an elastic perfectly plastic material for w...
- 6.6-177: The beam is made of an elastic perfectly plastic material for which...
- 6.6-178: The plexiglass bar has a stressstrain curve that can be approximate...
- 6.6-179: The stressstrain diagram for a titanium alloy can be approximated b...
- 6.6-180: A beam is made from polypropylene plastic and has a stressstrain di...
- 6.6-181: The bar is made of an aluminum alloy having a stressstrain diagram ...
- 6.6-182: The beam is made of phenolic, a structural plastic, that has the st...

# Solutions for Chapter 6: Bending

## Full solutions for Mechanics of Materials | 10th Edition

ISBN: 9780134319650

Solutions for Chapter 6: Bending

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