Explanation Given information: The magnitude force P is 98 kips . Refer to Problem 2.119. 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 ) of 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 ) of 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 ( A ) 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 Calculate the total force to yield ( P Y ) using the relation as follows: σ Y 1 = P Y A P Y = A σ Y 1 (4) Here, σ Y 1 is yield strength. Substitute 1.75 in 2 for A and 50 ksi for σ Y 1 in Equation (4). P Y = 1.75 × ( 50 ksi × 10 3 psi 1 ksi ) = 1.75 × 50 , 000 = 87.50 × 10 3 lb The condition is P > P Y . The mild steel yields. So the tempered steel is elastic. Find the value of force ( P 1 ) as follows: P 1 = A 1 σ Y 1 (5) Here, P 1 is force carried by mild steel. Substitute 1.00 in 2 for A 1 and 50 ksi for σ Y 1 in Equation (5). P 1 = 1 × 50 ksi ( 10 3 psi 1 ksi ) = 50 × 10 3 lb Find the value of force ( P 2 ) using the relation as follows: P = P 1 + P 2 P 2 = P − P 1 (6) Here, P 1 is force steel bar and P 2 is mild steel bar

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ISBN: 9780100257061

Author: BEER

Publisher: YUZU

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Chapter 2.13, Problem 119P

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Find the residual stresses in the tempered steel bar.

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Chapter 2.13, Problem 118P

Chapter 2.13, Problem 120P

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Chapter 2 Solutions

EBK MECHANICS OF MATERIALS

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Find the residual stresses in the tempered steel bar.

Solution Summary: The author calculates the residual stresses in the tempered steel bar using the relation: underset_8.00ksi.

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