- 11.4.P11-2: Determine the moment of inertia of the cross section about the neut...
- 11.4.P11-3: Determine the location of the centroid, y , and the moment of inert...
- 11.4.P11-4: In each case, show how the bending stress acts on a differential vo...
- 11.4.P11-5: Sketch the bending stress distribution over each cross section.
- 11.4.F11-9: If the beam is subjected to a bending moment of M = 20 kN m, determ...
- 11.4.F11-10: If the beam is subjected to a bending moment of M = 50 kN m, sketch...
- 11.4.F11-11: If the beam is subjected to a bending moment of M = 50 kN m, determ...
- 11.4.F11-12: If the beam is subjected to a bending moment of M = 10 kN m, determ...
- 11.4.F11-13: If the beam is subjected to a bending moment of M = 5 kN m, determi...
- 11.4.11-47: An A-36 steel strip has an allowable bending stress of 165 MPa. If ...
- 11.4.11-48: Determine the moment M that will produce a maximum stress of 10 ksi...
- 11.4.11-49: Determine the maximum tensile and compressive bending stress in the...
- 11.4.11-50: The beam is constructed from four pieces of wood, glued together as...
- 11.4.11-51: The beam is constructed from four pieces of wood, glued together as...
- 11.4.11-52: The beam is made from three boards nailed together as shown. If the...
- 11.4.11-53: The beam is made from three boards nailed together as shown. If the...
- 11.4.11-54: If the built-up beam is subjected to an internal moment of M = 75 k...
- 11.4.11-55: If the built-up beam is subjected to an internal moment of M = 75 k...
- 11.4.11-56: The beam is subjected to a moment M. Determine the percentage of th...
- 11.4.11-57: Determine the moment M that should be applied to the beam in order ...
- 11.4.11-58: The beam is made from three boards nailed together as shown. If the...
- 11.4.11-59: If M = I kip ft, determine the resultant force the bending stresses...
- 11.4.11-60: The beam is subjected to a moment of IS kip ft. Determine the resul...
- 11.4.11-61: The beam is subjected to a moment of 15 kip ft. Determine the perce...
- 11.4.11-62: The beam is subjected to a moment of M = 40 kN m. Determine the ben...
- 11.4.11-63: The steel shaft bas a diameter of2 in. It is supported on smooth jo...
- 11.4.11-64: The beam is made of steel that has an allowable stress of Uauow = 2...
- 11.4.11-65: A shaft is made of a polymer having an elliptical cross section. If...
- 11.4.11-66: Solve Prob. 11-65 if the moment M = 50 N m is applied about the y a...
- 11.4.11-67: The shaft is supported by smooth journal bearings at A and 8 that o...
- 11.4.11-68: The shaft is supported by smooth journal bearings at A and 8 that o...
- 11.4.11-69: The axle of the freight car is subjected to a wheel loading of 20 k...
- 11.4.11-70: The strut on the utility pole supports the cable having a weight of...
- 11.4.11-71: The boat has a weight of 2300 lb and a center of gravity at G. If i...
- 11.4.11-72: Determine the absolute maximum bending stress in the LS-in.-diamete...
- 11.4.11-73: Determine the smallest allowable diameter of the shaft. The shaft i...
- 11.4.11-74: The pin is used 10 connect the three links together. Due to wear, t...
- 11.4.11-75: The shaft is supported by a thrust bearing at A and journal bearing...
- 11.4.11-76: If the intensity of the load w = 15 kN /m, determine the absolute m...
- 11.4.11-77: If the allowable bending stress is u allow = 150 MPa, determine the...
- 11.4.11-78: The beam is subjected to the triangular distributed load with a max...
- 11.4.11-79: The beam has a rectangular cross section with b =4 in. Determine th...
- 11.4.11-80: Determine the absolute maximum bending stress in the beam. Each seg...
- 11.4.11-81: If the compound beam in Prob. 11-42 has a square cross section of s...
- 11.4.11-82: If t he beam in Prob. 11-28 has a rectangular cross section with a ...
- 11.4.11-83: Determine the absolute maximum bending stress in the SO-mm-diameter...
- 11.4.11-84: Determine, to the nearest millimeter, the smallest allowable diamet...
- 11.4.11-85: Determine the absolute maximum bending stress in the beam, assuming...
- 11.4.11-86: Determine the absolute maximum bending stress in the 2-in.-diameter...
- 11.4.11-87: Determine the smallest diameter of the shaft to the nearest kin. Th...
- 11.4.11-88: A log that is 2 ft in diameter is to be cut into a rectangular sect...
- 11.4.11-89: A log that is 2 ft in diameter is to be cut into a rectangular sect...
- 11.4.11-90: If the beam in Prob. 11-19 has a rectangular cross section with a w...
- 11.4.11-91: The simply supported truss is subjected to the central distributed ...
- 11.4.11-92: If d = 450 mm, determine the absolute maximum bending stress in the...
- 11.4.11-93: If the allowable bending stress is u allow = 6 MPa, determine the m...
- 11.4.11-94: The beam has a rectangular cross section as shown. Determine the la...
- 11.4.11-95: The beam has the rectangular cross section shown. If w = 1 kN/m, de...

# Solutions for Chapter 11.4: The Flexure Formula

## Full solutions for Statics and Mechanics of Materials | 5th Edition

ISBN: 9780134382593

Solutions for Chapter 11.4: The Flexure Formula

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Solutions for Chapter 11.4

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Chapter 11.4: The Flexure Formula includes 58 full step-by-step solutions. Statics and Mechanics of Materials was written by and is associated to the ISBN: 9780134382593. This expansive textbook survival guide covers the following chapters and their solutions. This textbook survival guide was created for the textbook: Statics and Mechanics of Materials, edition: 5. Since 58 problems in chapter 11.4: The Flexure Formula have been answered, more than 172018 students have viewed full step-by-step solutions from this chapter.

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