Explanation Given information: The magnitude of axial load is P = 105 kN . The allowable stress for compression is σ C = 8.3 MPa . The width of the cross section is b = 240 mm . The depth of the cross section is d = 180 mm . The modulus of elasticity of the material is E = 11.1 GPa . The eccentricity of the load in the column is e = 25 mm . Calculation: The parameter c for sawn lumber columns is 0.8. Find the cross sectional area ( A ) of the cross section using the equation. A = b d Here, the width of the cross section is b and the depth of the cross section is d . Substitute 240 mm for b and 180 mm for d . A = 240 × 180 = 43 , 200 mm 2 Determine the moment of inertia ( I ) of the cross section using the equation. I = d b 3 12 Substitute 180 mm for d and 240 mm for b . I = 180 × 240 3 12 = 207.36 × 10 6 mm 4 Find the distance between the neutral axis and the distance between the extreme fibre ( c ) using the relation. c = b 2 Substitute 240 mm for b . c = 240 2 = 120 mm Find the ratio of the effective length to the depth ( L d ) ; L d = L m × 1,000 mm 1 m 180 = 5.556 L Find the stress ( σ C E ) using the equation. σ C E = 0.3 E ( L d ) 2 Here, the modulus of elasticity of the material is E . Substitute 11.1 GPa for E and 5.556 L for L d . σ C E = 0.3 × 11.1 GPa × 1,000 MPa 1 GPa ( 5.556 L ) 2 = 107.875 L 2 Find the column stability factor C p using the Equation. C p = 1 + ( σ C E / σ C ) 2 c − [ 1 + ( σ C E / σ C ) 2 c ] 2 − σ C E / σ C c Here, the allowable stress for compression grain is σ C . Substitute 107.875 L 2 for σ C E , 8.3 MPa for σ C , and 0.8 for c . C p = 1 + ( ( 107.875 L 2 ) / 8.3 ) 2 × 0.8 − [ 1 + ( ( 107.875 L 2 ) / 8.3 ) 2 × 0.8 ] 2 − ( 107.875 L 2 ) / 8.3 0.8 = 1 + ( 13 L 2 ) 1.6 − [ 1 + ( 13 L 2 ) 1

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Chapter 10.4, Problem 100P

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Find the largest allowable effective length L.

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Chapter 10.4, Problem 99P

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Find the largest allowable effective length L .

Solution Summary: The author calculates the cross sectional area of a sawn lumber column using the equation.

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