A thin strip of hard copper (E = 16,000 ksi) having length L= 90 in, and thickness t=3/32 in. is bent into a circle held with the ends just touchinga) Calculate the maximum bending stress in the stripb) By what percent does the stress increase or decrease if the thickness of the strip is increased by 1/32 in? IV. A thin strip of hard copper (E = 16,000 ksi) having length L = 90 in. and thickness t = 3/32 in. is bent into acircle held with the ends just touching (figure 4).a. Calculate the maximum bending stress omax in the strip.b. By what percent does the stress increase or decrease if the thickness of the strip is increased by1/32 in.? 332 in.

Given data:- Modulus of elasticity, E=16000ksi=110.316GPa Length of strip, l=90in=2.286m thickness,…

A thin strip of hard copper (E = 16,000 ksi) having length L= 90 in, and thickness t=3/32 in. is bent into a circle held with the ends just touching a) Calculate the maximum bending stress in the strip b) By what percent does the stress increase or decrease if the thickness of the strip is increased by 1/32 in?

A thin strip of hard copper (E = 16,000 ksi) having length L= 90 in, and thickness t=3/32 in. is bent into a circle held with the ends just touching a) Calculate the maximum bending stress in the strip b) By what percent does the stress increase or decrease if the thickness of the strip is increased by 1/32 in?

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter5: Stresses In Beams (basic Topics)

Section: Chapter Questions

Problem 5.5.9P: A seesaw weighing 3 lb/ft of length is occupied by two children, each weighing 90 lb (see figure)....

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