Mechanics of Materials, 7th Edition
Mechanics of Materials, 7th Edition
7th Edition
ISBN: 9780073398235
Author: Ferdinand P. Beer, E. Russell Johnston Jr., John T. DeWolf, David F. Mazurek
Publisher: McGraw-Hill Education
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Chapter 10, Problem 117RP

Determine (a) the critical load for the steel strut, (b) the dimension d for which the aluminum strut will have the same critical load. (c) Express the weight of the aluminum strut as a percent of the weight of the steel strut.

Fig. P10.117

Chapter 10, Problem 117RP, Determine (a) the critical load for the steel strut, (b) the dimension d for which the aluminum

(a)

Expert Solution
Check Mark
To determine

Find the critical load for the steel strut.

Answer to Problem 117RP

The critical load of the steel strut is 647lb_.

Explanation of Solution

The modulus of elasticity of the steel strut is Est=29×106psi.

The size of the steel strut is ast=12in..

The length of the steel strut is Lst=4ft.

Determine the moment of inertia of the steel strut (Ist) using the relation.

Ist=(ast)412

Here, the size of the steel strut is ast.

Substitute 12in. for ast.

Ist=(12)412=5.2083×103in.4

The effective length (Le) of the column is equal to the length of the column.

Le=Lst=4ft

Determine the critical load (Pcr,st) of the steel strut using the equation.

Pcr,st=π2EstIst(Le)2

Here, the modulus of elasticity of the steel strut is Est and the effective length of the steel strut is Le.

Substitute 29×103psi for Est, 5.2083×103in.4 for Ist, and 4 ft for Le.

Pcr,st=π2×29×106×5.2083×103(4ft×12in.1ft)2=647lb

Therefore, the critical load of the steel strut is 647lb_.

(b)

Expert Solution
Check Mark
To determine

Find the dimension d for the condition that the critical load is same for steel strut and aluminum strut.

Answer to Problem 117RP

The dimension d of the aluminum strut for the given condition is 0.651in._.

Explanation of Solution

The modulus of elasticity of the aluminium strut is Eal=10.1×106psi.

The length of the aluminium strut is Lst=4ft.

The critical load of the steel strut and the aluminum strut is equal.

Pcr,st=Pcr,al=647lb.

The effective length (Le) of the column is equal to the length of the column.

Le=Lal=4ft

Determine the moment of inertia of the aluminium strut (Ial) using the equation.

Pcr,al=π2EalIal(Le)2

Here, the critical load in the aluminium strut is Pcr,al, the modulus of elasticity of the aluminium strut is Eal, and the effective length of the aluminium strut is Le.

Substitute 647 lb for Pcr,al, 10.1×106psi for Eal, and 4 ft for Le.

647=π2×10.1×106×Ial(4ft×12in.1ft)2Ial=149.543×104in.4

Determine the dimension of the aluminum strut (d) using the relation.

Ial=d412

Substitute 149.543×104in.4 for Ial.

149.543×104=d412d=0.651in.

Therefore, the dimension d of the aluminum strut for the given condition is 0.651in._.

(c)

Expert Solution
Check Mark
To determine

Find the percentage weight of aluminum strut to the steel strut.

Answer to Problem 117RP

The percentage weight of aluminum strut to the steel strut is 58.8%_.

Explanation of Solution

The weight density of the aluminium strut is γal=170lb/ft3.

The weight density of the steel strut is γst=490lb/ft3.

The length of the steel strut is Lst=4ft.

The length of the aluminium strut is Lal=4ft.

The dimension of the aluminium strut is d=0.651in..

The size of the steel strut is ast=12in..

In general,

The weight density (γ) of a material is defined as follows;

γ=WV=WALW=γAL

Here, the weight of the material is W, the volume of the material is V, the cross sectional area of the material is A, and the length of the material is L.

Write the expression as percentage weight of aluminium strut (Wal) to the steel strut (Wst) as follows;

WalWst×100%=γalAalLalγstAstLst×100%=γald2Lalγst(ast)2Lst×100%

Substitute 170lb/ft3 for γal, 0.651 in. for d, 4 ft for Lal, 490lb/ft3 for γst, 12in. for ast, 4 ft for Lst.

WalWst×100%=170×0.6512×4490×(12)2×4×100%=58.8%

Therefore, the percentage weight of aluminum strut to the steel strut is 58.8%_.

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Chapter 10 Solutions

Mechanics of Materials, 7th Edition

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