Mechanics of Materials (10th Edition)
Mechanics of Materials (10th Edition)
10th Edition
ISBN: 9780134319650
Author: Russell C. Hibbeler
Publisher: PEARSON
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Chapter 6, Problem 6.1CP

Using appropriate measurements and data, explain how to determine the bending stress in the blade.

Chapter 6, Problem 6.1CP, Using appropriate measurements and data, explain how to determine the bending stress in the blade.

C6–1

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To determine
The bending stress in the blade.

Answer to Problem 6.1CP

The bending stress in the blade is σ=34w(πr)2bd2_.

Explanation of Solution

Given information:

  • The steel saw blade passes over the drive wheel of the band saw.
  • Use appropriate measurements and data.

Explanation:

The contact area of the cable is upper half portion of the drive wheel. The, the upper half portion of the wheel will undergo stress.

Show the free-body diagram of the drive wheel as in Figure 1.

Mechanics of Materials (10th Edition), Chapter 6, Problem 6.1CP , additional homework tip  1

The force induced in the drive wheel will be uniformly distributed.

The circumferential distance of the circular section is 2πr. Here, r is the radius of the circular section.

Convert the semi-circular section into beam section as in Figure 2.

Mechanics of Materials (10th Edition), Chapter 6, Problem 6.1CP , additional homework tip  2

Determine the tension in the cable:

Moment about point A:

Determine the tension in the cable at point B by taking moment about point A.

MA=0(w×πr×πr2)TB(πr)=0 (1)

Along the vertical direction:

Determine the tension in the cable at point A by resolving the vertical component of forces.

Fy=0(w×πr)TATB=0 (2)

Show the calculation of values as follows:

Solve Equation (1).

TB(πr)=w×πr×πr2TB=wπr2

Substitute wπr2 for TB in Equation (2).

w×πrTAwπr2=0TA=wπr2

Maximum Bending moment:

The maximum bending moment will occur where the shear force changes sign

Consider a section at a distance x from left end of the beam.

Show the free body diagram of the section as in Figure 3.

Mechanics of Materials (10th Edition), Chapter 6, Problem 6.1CP , additional homework tip  3

Along the vertical direction:

Determine the shear force at the section by resolving the vertical component of forces.

Fy=0V+(w×xTA)=0 (3)

Moment about the section:

Determine the moment at the section by taking moment about the section.

Mx=0M+TA(x)w×x×x2=0 (4)

Substitute 0 for V and wπr2 for TA in Equation (3).

0+w×xwπr2=0wx=wπr2x=πr2

Thus, the maximum bending moment will occur at a distance πr2 from left end.

Substitute wπr2 for TA and πr2 for x in Equation (4).

Mmax+wπr2(πr2)w×πr2×πr4=0Mmax+w(πr)24w(πr)28=0Mmax=w(πr)28

Bending stress:

Calculate the bending stress in the blade using the flexure formula.

σ=MmaxcI (5)

Here, c is the distance between the centroid and the extreme fibre and I is moment of inertia of the band saw.

Consider the band saw is in rectangular cross section.

The value of c is c=d2.

The moment of inertia of the band saw is I=bd312.

Here, b is width of the section and d is depth of the section.

Substitute w(πr)28 for Mmax, d2 for c, and bd312 for I in Equation (5).

σ=w(πr)28×d2bd312=w(πr)28×d2×12bd3=34w(πr)2bd2

Thus, the bending stress in the blade is σ=34w(πr)2bd2_.

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Chapter 6 Solutions

Mechanics of Materials (10th Edition)

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If it is...Ch. 6.10 - The beam is made of an elastic perfectly plastic...Ch. 6.10 - Determine the plastic moment Mp that can be...Ch. 6.10 - Determine the shape factor for the beam. Prob....Ch. 6.10 - The beam is made of elastic perfectly plastic...Ch. 6.10 - Determine the shape factor for the beam. Prob....Ch. 6.10 - The beam is made of an elastic perfectly plastic...Ch. 6.10 - Prob. 6.168PCh. 6.10 - Prob. 6.169PCh. 6.10 - Prob. 6.170PCh. 6.10 - The rod has a circular cross section. If it is...Ch. 6.10 - Determine the shape factor of the cross section....Ch. 6.10 - The beam is made of elastic perfectly plastic...Ch. 6.10 - Determine the shape factor for the member having...Ch. 6.10 - Determine the shape factor of the cross section....Ch. 6.10 - The box beam is made of an elastic perfectly...Ch. 6.10 - The beam is made of an elastic perfectly plastic...Ch. 6.10 - The plexiglass bar has a stress-strain curve that...Ch. 6.10 - The stress-strain diagram for a titanium alloy can...Ch. 6.10 - A beam is made from polypropylene plastic and has...Ch. 6.10 - The bar is made of an aluminum alloy having a...Ch. 6.10 - The beam is made of phenolic, a structural...Ch. 6 - Using appropriate measurements and data, explain...Ch. 6 - Determine the shape factor for the wide-flange...Ch. 6 - The compound beam consists of two segments that...Ch. 6 - The composite beam consists of a wood core and two...Ch. 6 - If it resists a moment of M = 125 N m, determine...Ch. 6 - Determine the maximum bending stress in the handle...Ch. 6 - The curved beam is subjected to a bending moment...Ch. 6 - Determine the shear and moment in the beam as...Ch. 6 - A wooden beam has a square cross section as shown...Ch. 6 - Draw the shear and moment diagrams for the shaft...Ch. 6 - The strut has a square cross section a by a and is...
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