The extruded plastic shape has dimensions of D = 40 mm, d = 38 mm, a = 90 mm, and t = 6 mm. (a) Determine the magnitude of the horizontal shear stress at point A for a shear force of V = 380 N.(b) If the allowable shear stress for the plastic material is 1450 kPa, what is the magnitude of the maximum shear force V that can be applied to the extrusion? The extruded plastic shape has dimensions of D = 40 mm, d = 38 mm, a = 90 mm, and t = 6 mm.(a) Determine the magnitude of the horizontal shear stress at point A for a shear force of V = 380 N.(b) If the allowable shear stress for the plastic material is 1450 kPa, what is the magnitude of the maximumshear force V that can be applied to the extrusion?HO+ZAnswer:(a) TA =(b) V=dikSave for LaterakPaN

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The extruded plastic shape has dimensions of D = 40 mm, d = 38 mm, a = 90 mm, and t = 6 mm. (a) Determine the magnitude of the horizontal shear stress at point A for a shear force of V = 380 N. (b) If the allowable shear stress for the plastic material is 1450 kPa, what is the magnitude of the maximum shear force V that can be applied to the extrusion? HG N a

The extruded plastic shape has dimensions of D = 40 mm, d = 38 mm, a = 90 mm, and t = 6 mm. (a) Determine the magnitude of the horizontal shear stress at point A for a shear force of V = 380 N. (b) If the allowable shear stress for the plastic material is 1450 kPa, what is the magnitude of the maximum shear force V that can be applied to the extrusion? HG N a

Principles of Foundation Engineering (MindTap Course List)

9th Edition

ISBN:9781337705028

Author:Braja M. Das, Nagaratnam Sivakugan

Publisher:Braja M. Das, Nagaratnam Sivakugan

Chapter8: Vertical Stress Increase In Soil

Section: Chapter Questions

Problem 8.7P: A 9 ft wide and infinitely long flexible strip load of 800 lb/ft2 is placed on an elastic medium as...

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