Solucionario Resistencia - De Materiales Schaum William Nash

Numerical solution: Let F₁+F₂=100 kN. Deformation equality: F₁ 1.5/(500e-6 100e9) = F₂ 1.2/(400e-6 200e9) → F₁ 1.5/(5e-5 1e11) = F₂ 1.2/(4e-4 2e11) → simplify → F₁/F₂ = 0.8 → F₁=0.8F₂. Then 0.8F₂+F₂=100 → 1.8F₂=100 → F₂=55.56 kN, F₁=44.44 kN. Formula: δ_T = αΔTL, thermal force = EAαΔT (if constrained).

σ_1,2 = (σ_x+σ_y)/2 ± √[((σ_x-σ_y)/2)² + τ_xy²] = 50 ± √[(30)²+30²] = 50 ± 42.43 → σ1=92.43 MPa, σ2=7.57 MPa. τ_max=42.43 MPa. Chapter 9: Columns (Buckling) Euler’s formula: P_cr = π²EI/(KL)². solucionario resistencia de materiales schaum william nash

Let F₁ = force in bronze, F₂ = force in steel. Equilibrium: ΣM = 0 → F₁ a + F₂ b = P*c (specific distances depend on figure; assume symmetrical so F₁+F₂ = P). Compatibility: δ₁ = δ₂ → (F₁L₁)/(A₁E₁) = (F₂L₂)/(A₂E₂). Solve simultaneously. Numerical solution: Let F₁+F₂=100 kN

A steel rod 2 m long and 30 mm in diameter is subjected to a tensile load of 80 kN. E = 200 GPa. Find: (a) axial stress, (b) axial strain, (c) total elongation. Formula: δ_T = αΔTL, thermal force = EAαΔT

Cantilever beam length L=2 m, point load P=5 kN at free end. E=200 GPa, I=4×10⁻⁶ m⁴. Find tip deflection.

I = bh³/12 = 0.1 0.2³/12 = 6.667×10⁻⁵ m⁴. y_max = 0.1 m. σ_max = (20,000 0.1)/6.667e-5 = 30 MPa. Chapter 7: Beam Deflections (Double Integration and Superposition) Method: EI d²v/dx² = M(x).