(a) Explanation Given information: Refer to problem 111P. The thickness ( t ) of steel bars is 3 16 in . The modulus of elasticity E is 29 × 10 6 psi . The maximum deformation δ m value is 0.04 in . Calculation: Find the area ( A 1 ) for mild steel using the relation: A 1 = b t (1) Here, b is the width of steel bar and t is thickness of steel bar. Substitute 2 in . for b and 1 2 in . for t in Equation (1). A 1 = 2 × 1 2 = 1 in 2 Find the area ( A 1 ) for tempered steel using the relation: A 2 = b ( 2 t ) (2) Substitute 2 in . for b and 3 16 in . for t in Equation (2). A 2 = 2 ( 2 3 16 ) =0 .75 in 2 Find the total area using the relation: A = A 1 + A 2 (3) Here, A 1 is area for mild steel and A 2 is area for tempered steel. Substitute 1 in 2 for A 1 and 0 .75 in 2 for A 2 in Equation (3). A = 1 + 0.75 = 1.75 in 2 Express the force at yield ( P Y ) as follows: σ Y 1 = P Y A P Y = A σ 1 (4) Substitute 1.75 in 2 for A 1 and 50 ksi for σ Y 1 in Equation (4). P 1 = 1.75 × 50 ksi ( 10 3 psi 1 ksi ) = 87.50 × 10 3 lb The condition P > P Y , thus the mild steel yields (b) To determine Find the maximum stress in the tempered steel bars. (c) To determine Find the permanent set once the load is removed.

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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 112P

(a)

To determine

Find the maximum deformation of the bar.

(b)

To determine

Find the maximum stress in the tempered steel bars.

(c)

To determine

Find the permanent set once the load is removed.

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Chapter 2.13, Problem 111P

Chapter 2.13, Problem 113P

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Chapter 2 Solutions

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Find the maximum deformation of the bar.

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Find the maximum deformation of the bar.

Find the maximum stress in the tempered steel bars.

Find the permanent set once the load is removed.

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Chapter 2 Solutions