For the following cantilever beam and loading, a. Find the beam's maximum shear stress. Indicate precisely where this maximum shear stress occurs on the beam and in the cross-section. b. Determine the minimum shear capacity of each fastener in kN if the beam is constructed from a single structural tee and a plate with fasteners at point A (as indicated in the cross-section) and the spacing of fasteners along the beam is s = 100 mm. c. Determine the state of stress at point B (on the web slightly below the flange), on the cross-sectional cut to the support's left: draw the result d. The principal stresses, the maximum in-plane shear stress, and their orientation (all at point B): sketch the result e. Considering the material is ductile and ov|= 200 MPa, determine if the material is yielded at point B Fixed Connection 50 kN 노100-> B -0.5 m 200

For the following cantilever beam and loading, a. Find the beam's maximum shear stress. Indicate precisely where this maximum shear stress occurs on the beam and in the cross-section. b. Determine the minimum shear capacity of each fastener in kN if the beam is constructed from a single structural tee and a plate with fasteners at point A (as indicated in the cross-section) and the spacing of fasteners along the beam is s = 100 mm. c. Determine the state of stress at point B (on the web slightly below the flange), on the cross-sectional cut to the support's left: draw the result d. The principal stresses, the maximum in-plane shear stress, and their orientation (all at point B): sketch the result e. Considering the material is ductile and ov|= 200 MPa, determine if the material is yielded at point B Fixed Connection 50 kN 노100-> B -0.5 m 200

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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