Explanation Given information: The yield stress for steel is σ Y = 36 ksi . The components of plane stress at a critical point in a steel machine bracket are σ x = 20 ksi, σ y = − 12 ksi , and τ x y = 18 ksi . Calculation: Find the principal stresses in complex system as shown below. σ 1 , 2 = σ x + σ y 2 ± ( σ x − σ y 2 ) 2 + τ x y 2 (1) Here, σ x is the normal stress in x direction, σ y is the normal stress in y direction, and τ x y is the shear stress. Substitute 20 ksi for σ x , − 12 ksi for σ y , and 18ksi for τ x y in Equation (1). σ 1 , 2 = 20 + ( − 12 ) 2 ± ( 20 − ( − 12 ) 2 ) 2 + 18 2 = 8 2 ± 580 = 4 ± 24

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Chapter 10.7, Problem 10.82P

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The yielding occurs using the maximum distortion energy theory.

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Chapter 10.7, Problem 10.81P

Chapter 10.7, Problem 10.83P

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180- Dimensions in mm 100 100 D E Steel B Brass 60 kN 40 kN 40-mm diam. 30-mm diam. PROBLEM 2.40 Solve Prob. 2.39, assuming that rod AC is made of brass and rod CE is made of steel. PROBLEM 2.39 Two cylindrical rods, one of steel and the other of brass, are joined at C and restrained by rigid supports at A and E. For the loading shown and knowing that E = 200 GPa and E, 105 GPa, determine (a) the reactions at A and E, (b) the deflection of point C. = R = 45.5 kN ← A

Dimensions in mm 100 100 -180- -120-+- C D Steel B Brass 60 kN 40 kN 40-mm diam. 30-mm diam. E PROBLEM 2.39 Two cylindrical rods, one of steel and the other of brass, are joined at Cand restrained by rigid supports at A and E. For the loading shown and knowing that E = 200 GPa and E₁ = 105 GPa, determine (a) the reactions at A and E, (b) the deflection of point C.

(read image) (Answer: vE = 0.514 m/s)

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The yielding occurs using the maximum distortion energy theory.

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Chapter 10 Solutions