(a) Explanation Given information: Assume the cable is replaced by rod of the same cross sectional area and material. The cross sectional area of each cable is 100 mm 2 . The modulus of elasticity E is 200 GPa . The yield stress is 345 MPa . Calculation: Consider θ is rotation angle of rigid bar ABC . Calculate the rotation of the rigid bar ABC by using the formula. θ = δ B D L A B = δ C E L A C δ B D = L A B L A B δ C E = 1 2 δ C E (1) Here, δ B D is the deflection of the cable BD , L A B is the length of the cable AB , L A C is the length of the cable AC , and δ C E is deflection of cable CE . Sketch the equilibrium of bar ABC as shown in Figure 1. Refer to Figure 1. ∑ M A = 0 L A B F B D + L A C F C E − L A C Q = 0 Q = F C E + L A B L A C F B D Q = F C E + 1 2 F B D (2) Consider the cable CE is yielded. Find the corresponding force along CE using the relation as follows: F C E = A σ Y (3) Substitute 100 mm 2 for A and 345 MPa for σ Y in Equation (3). F C E = 100 mm 2 ( 1 m 10 3 mm ) 2 × 345 MPa ( 10 6 Pa 1 MPa ) = 100 × 10 − 6 × ( 345 × 10 6 ) = 34 (b) To determine Find the maximum deflection at point C . (C) To determine Find the final displacement at point C .

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Author: BEER

Publisher: YUZU

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Axial Load

When a bar of the uniform cross-section is acted by a load, such that the load acts along the longitudinal axis of the bar, such kinds of loadings are known as axial loadings. In general terms, a load is an external force acting on a component. An axial …

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Chapter 2.13, Problem 110P

(a)

To determine

Find the maximum stress occurs in cable BD.

(b)

To determine

Find the maximum deflection at point C.

(C)

To determine

Find the final displacement at point C.

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Chapter 2.13, Problem 109P

Chapter 2.13, Problem 111P

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Find the maximum stress occurs in cable BD .

Solution Summary: The author calculates the rotation angle of the rigid bar ABC by using the formula.

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Find the maximum stress occurs in cable BD.

Find the maximum deflection at point C.

Find the final displacement at point C.

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Chapter 2 Solutions