Explanation Given information: The ideal column has a weight w (force/length) and is subjected to the axial load P . EI is constant. The general solution is v = C 1 sin k x + C 2 cos k x + w 2 P x 2 − w L 2 P x − w E I P 2 where k 2 = P E I . Calculation: Convert the uniformly distributed load into point load as shown below. Point Load = Intensity of loading × Length of loading Substitute w for intensity of loading and L for length of loading. Point Load = w × L = w L Sketch the Free Body Diagram of the beam as shown in Figure 1. Refer to Figure 1. Find the support reaction as shown below. Apply the Equations of Equilibrium as shown below. Summation of forces along horizontal direction is Equal to zero. ∑ F x = 0 A x − P = 0 A x = P Take moment about A is Equal to zero. ∑ M A = 0 ( B y × L ) − w L × L 2 = 0 B y − w L 2 = 0 B y = w L 2 Summation of forces along vertical direction is Equal to zero. ∑ F y = 0 A y + w L 2 − w L = 0 A y − w L 2 = 0 A y = w L 2 Sketch the Free Body Diagram of the beam at x distance from A as shown in Figure 2. Refer to Figure 2. Take moment about the section as shown below. ∑ M O = 0 w x × x 2 − M ( x ) − w L 2 x − P v = 0 w 2 ( x 2 − L x ) − P v − M ( x ) = 0 M ( x ) = w 2 ( x 2 − L x ) − P v (1) Apply the slope and elastic curve as shown below. E I d 2 v d x 2 = M ( x ) (2) Here, EI is the flexural rigidity, d 2 v d x 2 is the second derivatives of the function v , and M ( x ) is the moment at the section x . Substitute w 2 ( x 2 − L x ) − P v for M ( x ) in Equation (2). E I d 2 v d x 2 = w 2 ( x 2 − L x ) − P v d 2 v d x 2 = w 2 E I ( x 2 − L x ) − P v E I d 2 v d x 2 + P v E I = w 2 E I ( x 2 − L x ) The general solution for the differential equation. v = C 1 sin k x + C 2 cos k x + w 2 P x 2 − w L 2 P x − w E I P 2 Substitute P E I for k . v = C 1 sin P E I x + C 2 cos P E I x + w 2 P x 2 − w L 2 P x − w E I P 2 (3) Differentiate both sides of the Equation (3). d v d x = C 1 cos P E I x × ( P E I ) + C 2 ( − sin P E I x ) × ( P E I ) + w 2 P × 2 x − w L 2 P = C 1 P E I cos P E I x − C 2 P E I sin P E I x + w x P − w L 2 P (4) Apply the boundary conditions as shown below. i. The value of v = 0 at x = 0 . ii. The value of d v d x = 0 at x = L 2 . iii. The value of v = v max at x = L 2 . Apply boundary condition (i) in Equation (3). Substitute 0 for v and 0 for x in Equation (3). 0 = C 1 sin P E I ( 0 ) + C 2 cos P E I ( 0 ) + w 2 P ( 0 ) 2 − w L 2 P ( 0 ) − w E I P 2 C 2 − w E I P 2 = 0 C 2 = w E I P 2 Apply boundary condition (ii) in Equation (4)

Statics and Mechanics of Materials Plus Mastering Engineering with Pearson eText - Access Card Package (5th Edition)

5th Edition

ISBN: 9780134301006

Author: Russell C. Hibbeler

Publisher: PEARSON

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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 17.3, Problem 41P

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Find the maximum moment in the column at the midspan.

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Chapter 17.3, Problem 40P

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Chapter 17 Solutions

Statics and Mechanics of Materials Plus Mastering Engineering with Pearson eText - Access Card Package (5th Edition)

Ch. 17.3 - A 50-in.-long steel rod has a diameter of 1 in....Ch. 17.3 - A 12-ft wooden rectangular column has the...Ch. 17.3 - Prob. 3FP Ch. 17.3 - A steel pipe is fixed supported at its ends. If it...Ch. 17.3 - Determine the maximum force P that can be...Ch. 17.3 - The A992 steel rod BC has a diameter of 50 mm and...Ch. 17.3 - Determine the critical buckling load for the...Ch. 17.3 - Prob. 2P Ch. 17.3 - The aircraft link is made from an A992 steel rod....Ch. 17.3 - Rigid bars AB and BC are pin connected at B. If...

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Find the maximum moment in the column at the midspan.

Solution Summary: The author calculates the maximum moment in the column at the midspan. The ideal column has a weight w and is subjected to the axial load P.

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Chapter 17 Solutions