A flanged wooden shape is used to support the loads shown on the beam. The dimensions of the shape are shown in the second figure. Assume LAB = 7 ft, LBc=2ft, LCD = 2 ft,LDE = 2 ft, Pc=1690 lb, PE = 2380 lb, WAB= 650 lb/ft, b₁ = 10 in., b₂ = 2 in., b3 = 7 in., d₁= 2 in., d₂ = 8 in., d3= 2 in. Consider the entire 13-ft length of the beam and determine: (a) the maximum tension bending stress or at any location along the beam, and (b) the maximum compression bending stress oc at any location along the beam. Answers: (a) OT = (b) o = i I WAB LAB N B Pc LBC b₁ ✪ b3 C LCD ·b₂ psi. psi. D d₁ LDE d₂ d3 PE E X

A flanged wooden shape is used to support the loads shown on the beam. The dimensions of the shape are shown in the second figure. Assume LAB = 7 ft, LBc=2ft, LCD = 2 ft,LDE = 2 ft, Pc=1690 lb, PE = 2380 lb, WAB= 650 lb/ft, b₁ = 10 in., b₂ = 2 in., b3 = 7 in., d₁= 2 in., d₂ = 8 in., d3= 2 in. Consider the entire 13-ft length of the beam and determine: (a) the maximum tension bending stress or at any location along the beam, and (b) the maximum compression bending stress oc at any location along the beam. Answers: (a) OT = (b) o = i I WAB LAB N B Pc LBC b₁ ✪ b3 C LCD ·b₂ psi. psi. D d₁ LDE d₂ d3 PE E X

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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