Explanation Given information: The effective length of the steel column is L e = 24 ft . The magnitude of the axial load is P = 120 kips . The eccentricity of the load in steel column is e = 8 in . . The allowable yield stress of the steel column is σ Y = 50 ksi . The modulus of elasticity of the steel column is E = 29 × 10 6 psi . The allowable stress in bending is ( σ all ) bending = 30 ksi . Calculation: Consider the W shaped section of W 14 × 53 ; Refer to Appendix C “Properties of Rolled-Steel Shapes” in the textbook. For W 14 × 53 shape; The cross sectional area is A = 15.6 in . 2 . The section modulus in x -axis is S x = 77.8 in . 3 . The minimum radius of gyration is r = r y = 1.92 in . . Find the slenderness ratio L r using the equation. L r = 4.71 E σ Y Here, the modulus of elasticity of the material is E and the allowable yield strength is σ Y Substitute 29 × 10 6 psi for E and 50 ksi for σ Y : L r = 4.71 29 × 10 6 50 ksi × 1,000 psi 1 ksi = 113.43 Find the ratio of the effective length to the minimum radius of gyration. L e r = 24 ft × 12 in . 1 ft 1.92 = 150 ≥ L r = 113.43 Find the effective stress ( σ e ) using the equation. σ e = π 2 E ( L e / r ) 2 Substitute 29 × 10 6 psi for E and 150 for L e / r . σ e = π 2 × 29 × 10 6 psi × 1 ksi 1,000 psi ( 150 ) 2 = 12.721 ksi Find the critical stress ( σ cr ) using the relation. σ cr = 0.877 σ e Substitute 12.72 ksi for σ e . σ cr = 0.877 × 12.72 = 11.156 ksi Find the allowable stress ( σ all ) centric due to centric load using the relation. ( σ all ) centric = σ cr 1.67 Substitute 11.156 ksi for σ cr . ( σ all ) centric = 11.156 1.67 = 6.68 ksi Find the maximum moment ( M ) using the relation. M = P e Here, the allowable load is P and the eccentricity of the load is e . Substitute 120 kips for P and 8 in. for e . M = 120 × 8 = 960 kips-in . Check the allowable stress using the centric and bending equation. P / A ( σ all ) centric + M / S x ( σ all ) bending ≤ 1 Substitute 120 kips for P , 15.6 in . 2 for A , 6.68 ksi for ( σ all ) centric , 960 kips-in. for M , 77.8 in . 3 for S x , and 30 ksi for ( σ all ) bending . ( 120 15

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Author: BEER

Publisher: YUZU

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Buckling of columns

The column is described as a vertical member of the structure that carries an axial compressive load, and buckling is a lateral deformation of the column under the application of load.

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Chapter 10.4, Problem 114P

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Choose the wide-flange shape of 14 in. nominal depth.

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Chapter 10.4, Problem 113P

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Chapter 10 Solutions

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Choose the wide-flange shape of 14 in. nominal depth.

Solution Summary: The author analyzes the W shaped section of W14times 53.

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