Explanation Given information: The modulus of rigidity ( G ) of hard rubber is 19 MPa . The spring constant k is P δ The deflection and load on the plate as δ and P respectively. The plate dimension as 100 × 150 × 30 mm 3 . Calculation: Write the expression of shearing strain γ as follows: γ = δ h Here, δ is deformation of plate and h is the height of section. Write the expression of τ shearing stress as follows: τ = G γ (1) Here, G is the modulus of rigidity and γ is shear strain. Substitute δ h for γ in Equation (1). τ = G ( δ h ) = G δ h Write the expression of ( P ) as follows: F = 1 2 P 1 2 P = A τ (2) Substitute G δ h for τ in Equation (2). 1 2 P = A ( G δ h ) 1 2 P = G A δ h P = 2 G A δ h Write the effective spring constant as follows: The spring constant k as P δ k = P δ (3) Substitute 2 G A δ h for P in Equation (3). k = 2 G A δ h δ = 2 G A h Find the area of plate ( A ) as shown below: A = b d (4) Here, b is the width of the section and d is the depth of the section. Substitute 150 mm for b and 10 mm for d in Equation (4)

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Author: BEER

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Chapter 2.9, Problem 82P

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Find the effective spring constant of the system.

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Chapter 2.9, Problem 81P

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Chapter 2 Solutions

EBK MECHANICS OF MATERIALS

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Find the effective spring constant of the system.

Solution Summary: The author calculates the effective spring constant of the system. The modulus of rigidity of hard rubber is 19MPa.

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Chapter 2 Solutions