The bell-crank mechanism is in equilibrium for an applied load of F1 = 12 kN applied at A. Assume a = 330mm, b = 140mm, c = 80mm, and e = 35°. Pin Bis in a double-shear connection and has a diameter of 32 mm. The bell crank has a thickness of 23 mm. Determine (a) the shear stress in pin B. (b) the bearing stress in the bell crank at B. Bell crank F2 Support bracket

The bell-crank mechanism is in equilibrium for an applied load of F1 = 12 kN applied at A. Assume a = 330mm, b = 140mm, c = 80mm, and e = 35°. Pin Bis in a double-shear connection and has a diameter of 32 mm. The bell crank has a thickness of 23 mm. Determine (a) the shear stress in pin B. (b) the bearing stress in the bell crank at B. Bell crank F2 Support bracket

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter11: Columns

Section: Chapter Questions

Problem 11.6.1P: A steel bar has a square cross section of width b = 2.0 in. (sec figure). The bar has pinned...

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