EBK MECHANICS OF MATERIALS
EBK MECHANICS OF MATERIALS
7th Edition
ISBN: 8220102804487
Author: BEER
Publisher: YUZU
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Chapter 3.3, Problem 58P

3.57 and 3.58 Two solid steel shafts are fitted with flanges that are then connected by bolts as shown. The bolts are slightly undersized and permit a 1.5° rotation of one flange with respect to the other before the flanges begin to rotate as a single unit. Knowing that G = 77.2 GPa, determine the maximum shearing stress in each shaft when a torque of T of magnitude 500 N·m is applied to the flange indicated.

3.57 The torque T is applied to flange B.

3.58 The torque T is applied to flange C.

Chapter 3.3, Problem 58P, 3.57 and 3.58 Two solid steel shafts are fitted with flanges that are then connected by bolts as

Expert Solution & Answer
Check Mark
To determine

The maximum shearing stress in the shaft AB.

The maximum shearing stress in the shaft CD.

Answer to Problem 58P

The maximum shearing stress in the shaft AB is 10.27MPa_.

The maximum shearing stress in the shaft CD is 48.6MPa_.

Explanation of Solution

Given information:

The modulus of rigidity of the solid shafts is 77.2GPa.

The torque applied to the flange C is 500Nm.

The rotation of one flange with respect to the other flange is 1.5°.

Calculation:

The radius of the shaft AB is c=15mm.

The polar moment of inertia of shaft AB of radius c is,

JAB=π2c4=π2(15mm)4=7.9522×104mm4=7.9522×108m4

The torque carried by the shaft AB (TAB) is expressed as shown below:

TAB=GJABLABϕB (1)

Here, G is the modulus of rigidity, ϕB is angle of twist at B, and LAB is the length of the shaft AB.

Substitute 77.2GPa for G, 7.9522×108m4 for JAB, and 2600 mm for LAB in Equation (1).

TAB=(77.2GPa)(7.9522×108m4)600mmϕB=(77.2GPa×109Pa1GPa)(7.9522×108m4)600mm×103m1mmϕB=10.2318×103ϕB (2)

The radius of the shaft CD is c=18mm.

The polar moment of inertia of shaft CD of radius c is,

JCD=π2c4=π2(18mm)4=1.64896×105mm4=1.64896×107m4

The torque carried by the shaft CD (TCD) is expressed as shown below:

TCD=GJCDLCDϕC (3)

Here, LCD is the length of the shaft CD.

Substitute 77.2GPa for G, 1.64896×107m4 for JCD, and 900 mm for LCD in Equation (3).

TCD=(77.2GPa)(1.64896×107m4)900mmϕC=(77.2GPa×109Pa1GPa)(1.64896×107m4)900mm×103m1mmϕC=14.1444×103ϕC (4)

The clearance rotation for flange C is,

ϕC'=1.5°=1.5°(πrad180°)=0.026178rad

Find the torque required to remove the clearance:

Substitute 0.026178rad for ϕC' in Equation (2).

TCD'=14.1444×103(0.026178rad)=370.27Nm

The magnitude of torque applied at the flange is 500Nm.

The torque T" required to cause additional rotation ϕ" is,

T"=500Nm370.27Nm129.73Nm

The total torque (T") is the sum of the torques TAB" and TCD". It is expressed as,

T"=TAB"+TCD"129.73Nm=10.2318×103ϕ"+14.1444×103ϕ"24.3762×103ϕ"=129.73Nmϕ"=5.322×103rad

Substitute 5.322×103rad for ϕ" in Equation (2).

TAB"=10.2318×103(5.322×103rad)=54.454Nm

Substitute 5.322×103rad for ϕ" in Equation (4).

TCD"=14.1444×103(5.322×103rad)=75.277Nm

Torque in the shaft AB is,

TAB=TAB"=54.454Nm

Torque in the shaft CD is,

TCD=TCD'+TCD"=370.27Nm+75.277Nm445.547Nm

The maximum shearing stress in the shaft AB (τAB) is expressed as shown below:

τAB=TABcJAB (5)

Substitute 54.454Nm for TAB, 15 mm for c, and 7.9522×108m4 for JAB in Equation (5).

τAB=(54.454Nm)(15mm)7.9522×108m4=(54.454Nm)(15mm×103m1mm)7.9522×108m4=10.271×106Pa10.27MPa

Therefore, the maximum shearing stress in the shaft AB is 10.27MPa_.

The maximum shearing stress in the shaft CD (τCD) is expressed as shown below:

τCD=TCDcJCD (6)

Substitute 445.547Nm for TCD, 18 mm for c, and 1.64896×107m4 for JCD in Equation (6).

τCD=(445.547Nm)(18mm)1.64896×107m4=(445.547Nm)(18mm×103m1mm)1.64896×107m4=48.636×106Pa48.6MPa

Therefore, the maximum shearing stress in the shaft CD is 48.6MPa_.

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EBK MECHANICS OF MATERIALS

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