The bell-crank mechanism is in equilibrium for an applied load of P = 48 kN. Assume that a = 290 mm, b = 240 mm, and 8 = 52°. The pin at B has a diameter of d = 27 mm, and the bell crank has a thickness of t = 15 mm. Calculate the bearing stress in the bell crank at pin B.

The bell-crank mechanism is in equilibrium for an applied load of P = 48 kN. Assume that a = 290 mm, b = 240 mm, and 8 = 52°. The pin at B has a diameter of d = 27 mm, and the bell crank has a thickness of t = 15 mm. Calculate the bearing stress in the bell crank at pin B.

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 11.2.4P: Repeat Problem 11.2-3 assuming that R= 10 kN · m/rad and L = 2 m.

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The bell-crank mechanism is in equilibrium for an applied load of P = 48 kN. Assume that a = 290 mm, b = 240 mm, and 0 = 52º. The pin
at B has a diameter of d = 27 mm, and the bell crank has a thickness of t = 15 mm. Calculate the bearing stress in the bell crank at pin B.
P
Answer:
0 = i
Bell crank-
a
C
MPa
B
Support bracket -
b
B
F₁
IF

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