EBK MECHANICS OF MATERIALS
EBK MECHANICS OF MATERIALS
7th Edition
ISBN: 8220100257063
Author: BEER
Publisher: YUZU
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Chapter 3.1, Problem 28P

Chapter 3.1, Problem 28P, Fig. P3.27 and P3.28 3.28 A torque T = 900 N m is applied to shaft AB of the gear train shown.

Fig. P3.27 and P3.28

3.28 A torque T = 900 N m is applied to shaft AB of the gear train shown. Knowing that the allowable shearing stress is 80 MPa, determine the required diameter of (a) shaft AB, (b) shaft CD, (c) shaft EF.

(a)

Expert Solution
Check Mark
To determine

The required diameter of the shaft AB.

Answer to Problem 28P

The required diameter of the shaft AB is 38.6mm_.

Explanation of Solution

Given information:

The torque applied to the shaft AB is T=900Nm.

The allowable shear stress is 80 MPa.

Calculation:

The torsion formula for maximum shear stress in the solid shaft AB (τmax) is expressed as shown below:

τmax=TABcJ (1)

Here, T is the applied internal torque in the shaft AB, J is the polar moment of inertia of the shaft, and c is the radius of the shaft AB.

The polar moment of inertia for a solid shaft AB (J) of radius c is J=π2c4.

Substitute π2c4 for J in Equation (1).

τmax=TABcπ2c4=2TABπc3 (2)

The torque in the shaft AB is TAB=T=900Nm.

Substitute 80MPa for τmax and 900Nm for TAB in Equation (2).

80MPa=2(900Nm)π(c)380Nmm2=2(900Nm×103mm1m)π(c)3c3=7,161.9724c=19.2757mm

Diameter of the shaft AB is twice the radius of the shaft AB.

dAB=2(19.2757mm)=38.6mm

Therefore, the required diameter of the shaft AB is 38.6mm_.

(b)

Expert Solution
Check Mark
To determine

The required diameter of the shaft CD.

Answer to Problem 28P

The required diameter of the shaft CD is 52.3mm_.

Explanation of Solution

Given information:

The torque applied to the shaft AB is T=900Nm.

The allowable shear stress is 80 MPa.

Calculation:

The torsion formula for maximum shear stress in the solid shaft CD (τmax) is expressed as shown below:

τmax=TCDcJ (3)

Here, T is the applied internal torque in the shaft CD, J is the polar moment of inertia of the shaft, and c is the radius of the shaft CD.

The polar moment of inertia for a solid shaft CD (J) of radius c is J=π2c4.

Substitute π2c4 for J in Equation (3).

τmax=TCDcπ2c4=2TCDπc3 (4)

The torque in the shaft CD is expressed as follows:

TCDrC=TABrB (5)

Here, rC is radius at C and rB is radius at B.

Substitute 75 mm for rC, 30 mm for rB, and T for TAB in Equation (5).

TCD75mm=T30mmTCD=2.5T=2.5(900Nm)=2,250Nm (6)

Substitute 80MPa for τmax and 2,250Nm for TCD in Equation (4).

80MPa=2(2,250Nm)π(c)380Nmm2=2(2,250Nm×103mm1m)π(c)3c3=17,904.9311c=26.161mm

Diameter of the shaft CD is twice the radius of the shaft CD.

dCD=2(26.161mm)=52.3mm

Therefore, the required diameter of the shaft CD is 52.3mm_.

(c)

Expert Solution
Check Mark
To determine

The required diameter of the shaft EF.

Answer to Problem 28P

The required diameter of the shaft EF is 75.5mm_.

Explanation of Solution

Given information:

The torque applied to the shaft AB is T=900Nm.

Allowable shear stress is 80 MPa.

Calculation:

The torsion formula for maximum shear stress in the solid shaft EF (τmax) is expressed as shown below:

τmax=TEFcJ (7)

Here, T is the applied internal torque in the shaft EF, J is the polar moment of inertia of the shaft, and c is the radius of the shaft EF.

The polar moment of inertia for a solid shaft EF (J) of radius c is J=π2c4.

Substitute π2c4 for J in Equation (7).

τmax=TEFcπ2c4=2TEFπc3 (8)

The torque in the shaft EF is expressed as follows:

TEFrF=TCDrD (9)

Here, rF is radius at F and rD is radius at D.

Substitute 90 mm for rF, 30 mm for rD, and 2.5T for TCD in Equation (9).

TEF90mm=2.5T30mmTEF=7.5T=7.5(900Nm)=6,750Nm (10)

Substitute 80MPa for τmax and 6,750Nm for TEF in Equation (8).

80MPa=2(6,750Nm)π(c)380Nmm2=2(6,750Nm×103mm1m)π(c)3c3=53,714.7933c=37.731mm

Diameter of the shaft EF is twice the radius of the shaft EF.

dEF=2(37.731mm)=75.5mm

Therefore, the required diameter of the shaft EF is 75.5mm_.

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Chapter 3 Solutions

EBK MECHANICS OF MATERIALS

Ch. 3.1 - Fig. P3.11 and P3.12 3.12 Knowing that an...Ch. 3.1 - Under normal operating conditions, the electric...Ch. 3.1 - In order to reduce the total mass of the assembly...Ch. 3.1 - The allowable shearing stress is 15 ksi in the...Ch. 3.1 - The allowable shearing stress is 15 ksi in the...Ch. 3.1 - The solid shaft shown is formed of a brass for...Ch. 3.1 - Solve Prob. 3.17 assuming that the direction of Tc...Ch. 3.1 - The solid rod AB has a diameter dAB= 60 mm and is...Ch. 3.1 - Fig. P3.19 and P3.20 3.20 The solid rod AB has a...Ch. 3.1 - A torque of magnitude T = 1000 N m is applied at D...Ch. 3.1 - Fig. P3.21 and P3.22 3.22 A torque of magnitude T...Ch. 3.1 - Under normal operating conditions a motor exerts a...Ch. 3.1 - Fig P3.23 and P3.24 3.24 Under normal operating...Ch. 3.1 - Prob. 25PCh. 3.1 - Fig. P3.25 and P3.26 3.26 The two solid shafts are...Ch. 3.1 - For the gear train shown, the diameters of the...Ch. 3.1 - Fig. P3.27 and P3.28 3.28 A torque T = 900 N m is...Ch. 3.1 - Fig. P3.29 3.29 While the exact distribution of...Ch. 3.1 - Fig. P3.30 3.30 (a) For a given allowable shearing...Ch. 3.3 - Determine the largest allowable diameter of a...Ch. 3.3 - The ship at A has just started to drill for oil on...Ch. 3.3 - (a) For the solid steel shaft shown, determine the...Ch. 3.3 - (a) For the aluminum pipe shown (G = 27 GPa),...Ch. 3.3 - The electric motor exerts a 500 N m-torque on the...Ch. 3.3 - The torques shown are exerted on pulleys and B....Ch. 3.3 - The aluminum rod BC (G = 26 GPa) is bonded to the...Ch. 3.3 - The aluminum rod AB (G = 27 GPa) is bonded to the...Ch. 3.3 - The solid spindle AB has a diameter ds = 1.75 in....Ch. 3.3 - Fig. p3.39 and p3.40 3.40 The solid spindle AB has...Ch. 3.3 - Two shafts, each of 78in. diameter, are connected...Ch. 3.3 - Two solid steel shafts each of 30-mm diameter, are...Ch. 3.3 - A coder F, used to record in digital form the...Ch. 3.3 - Fig. p3.43 3.44 For the gear train described in...Ch. 3.3 - The design specifications of a 1.2-m-long solid...Ch. 3.3 - 3.46 and 3.47 The solid cylindrical rod BC of...Ch. 3.3 - 3.46 and 3.47 The solid cylindrical rod BC of...Ch. 3.3 - The design of the gear-and-shaft system shown...Ch. 3.3 - The electric motor exerts a torque of 900 Nm on...Ch. 3.3 - A hole is punched at A in a plastic sheet by...Ch. 3.3 - The solid cylinders AB and BC are bonded together...Ch. 3.3 - Solve Prob. 3.51, assuming that cylinder AB is...Ch. 3.3 - The composite shaft shown consists of a...Ch. 3.3 - Fig. p3.53 and p3.54 3.54 The composite shaft...Ch. 3.3 - Two solid steel shafts (G = 77.2 GPa) are...Ch. 3.3 - Solve Prob. 3.55, assuming that the shaft AB is...Ch. 3.3 - 3.57 and 3.58 Two solid steel shafts are fitted...Ch. 3.3 - 3.57 and 3.58 Two solid steel shafts are fitted...Ch. 3.3 - The steel jacket CD has been attached to the...Ch. 3.3 - A torque T is applied as shown to a solid tapered...Ch. 3.3 - Prob. 61PCh. 3.3 - A solid shaft and a hollow shaft are made of the...Ch. 3.3 - An annular plate of thickness t and modulus G is...Ch. 3.5 - Determine the maximum shearing stress in a solid...Ch. 3.5 - Determine the maximum shearing stress in a solid...Ch. 3.5 - Using an allowable shearing stress of 4.5 ksi,...Ch. 3.5 - Using an allowable shearing stress of 50 MPa,...Ch. 3.5 - While a steel shaft of the cross section shown...Ch. 3.5 - Determine the required thickness of the 50-mm...Ch. 3.5 - A steel drive shaft is 6 ft long and its outer and...Ch. 3.5 - The hollow steel shaft shown (G = 77.2 GPa, all =...Ch. 3.5 - A steel pipe of 3.5-in. outer diameter is to be...Ch. 3.5 - 3.73 The design of a machine element calls for a...Ch. 3.5 - Three shafts and four gears are used to form a...Ch. 3.5 - Three shafts and four gears are used to form a...Ch. 3.5 - The two solid shafts and gears shown are used to...Ch. 3.5 - Fig. P3.76 and P3.77 3.77 The two solid shafts and...Ch. 3.5 - The shaft-disk-belt arrangement shown is used to...Ch. 3.5 - A 5-ft-long solid steel shaft of 0.875-in....Ch. 3.5 - A 2.5-m-long steel shaft of 30-mm diameter rotates...Ch. 3.5 - The design specifications of a 1.2-m-long solid...Ch. 3.5 - A 1.5-m-long tubular steel shaft (G = 77.2 GPa) of...Ch. 3.5 - Fig. P3.82 and P3.83 3.83 A 1.5-m-long tubular...Ch. 3.5 - The stepped shaft shown must transmit 40 kW at a...Ch. 3.5 - The stepped shaft shown rotates at 450 rpm....Ch. 3.5 - Knowing that the stepped shaft shown transmits a...Ch. 3.5 - The stepped shaft shown must rotate at a frequency...Ch. 3.5 - Fig. P3.87 and P3.88 3.88 The stepped shaft shown...Ch. 3.5 - A torque of magnitude T = 200 lbin. is applied to...Ch. 3.5 - Fig. P3.89, P3.90 and P3.91 3.90 In the stepped...Ch. 3.5 - In the stepped shaft shown, which has a full...Ch. 3.8 - The solid circular shaft shown is made of a steel...Ch. 3.8 - Prob. 93PCh. 3.8 - Prob. 94PCh. 3.8 - Prob. 95PCh. 3.8 - Fig. P3.95 and P3.96 3.96 The solid shaft shown is...Ch. 3.8 - It is observed that a straightened paper clip can...Ch. 3.8 - The solid shaft shown is made of a mild steel that...Ch. 3.8 - Prob. 99PCh. 3.8 - Prob. 100PCh. 3.8 - Prob. 101PCh. 3.8 - Prob. 102PCh. 3.8 - Prob. 103PCh. 3.8 - Prob. 104PCh. 3.8 - A solid circular rod is made of a material that is...Ch. 3.8 - Prob. 106PCh. 3.8 - Prob. 107PCh. 3.8 - Prob. 108PCh. 3.8 - Prob. 109PCh. 3.8 - Prob. 110PCh. 3.8 - Prob. 111PCh. 3.8 - A 50-mm diameter cylinder is made of a brass for...Ch. 3.8 - Prob. 113PCh. 3.8 - The solid circular drill rod AB is made of a steel...Ch. 3.8 - Prob. 115PCh. 3.8 - Prob. 116PCh. 3.8 - After the solid shaft of Prob. 3.116 has been...Ch. 3.8 - The hollow shaft shown is made of a steel that is...Ch. 3.8 - Prob. 119PCh. 3.8 - Prob. 120PCh. 3.10 - Determine the smallest allowable square cross...Ch. 3.10 - Prob. 122PCh. 3.10 - Using all = 70 MPa and G = 27 GPa, determine for...Ch. 3.10 - Prob. 124PCh. 3.10 - Determine the largest torque T that can be applied...Ch. 3.10 - Each of the two brass bars shown is subjected to a...Ch. 3.10 - Prob. 127PCh. 3.10 - Prob. 128PCh. 3.10 - Prob. 129PCh. 3.10 - Shafts A and B are made of the same material and...Ch. 3.10 - Prob. 131PCh. 3.10 - Shafts A and B are made of the same material and...Ch. 3.10 - Prob. 133PCh. 3.10 - Prob. 134PCh. 3.10 - Prob. 135PCh. 3.10 - A 36-kipin. torque is applied to a 10-ft-long...Ch. 3.10 - A 4-m-long steel member has a W310 60 cross...Ch. 3.10 - Prob. 138PCh. 3.10 - A 5-kipft torque is applied to a hollow aluminum...Ch. 3.10 - A torque T = 750 kNm is applied to the hollow...Ch. 3.10 - A 750-Nm torque is applied to a hollow shaft...Ch. 3.10 - 3.142 and 3.143 A hollow member having the cross...Ch. 3.10 - A hollow member having the cross section shown is...Ch. 3.10 - A 90-Nm torque is applied to a hollow shaft having...Ch. 3.10 - 3.145 and 3.146 A hollow member having the cross...Ch. 3.10 - 3.145 and 3.146 A hollow member having the cross...Ch. 3.10 - A cooling tube having the cross section shown is...Ch. 3.10 - A hollow cylindrical shaft was designed to have a...Ch. 3.10 - Equal torques are applied to thin-walled tubes of...Ch. 3.10 - A hollow cylindrical shaft of length L, mean...Ch. 3 - A steel pipe of 12-in. outer diameter is...Ch. 3 - A torque of magnitude T = 120 Nm is applied to...Ch. 3 - Fig. P3.152 3.153 Two solid shafts are connected...Ch. 3 - Prob. 154RPCh. 3 - Prob. 155RPCh. 3 - A torque of magnitude T = 4 kNm is applied at end...Ch. 3 - Ends A and D of the two solid steel shafts AB and...Ch. 3 - As the hollow steel shaft shown rotates at 180...Ch. 3 - Prob. 159RPCh. 3 - Prob. 160RPCh. 3 - Prob. 161RPCh. 3 - The shaft AB is made of a material that is...
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