calculate the theoretical stress using the flexure or bending stress formula. The experimental se is shown in Figure 1: ● ● L Take a few minutes to solve the following pre-lab exercise problems before continuing with the background unit: LB 10 inches w 1.5 inches t = 0.25 inches W Problem 1: An experiment was set up according to Figure 1 with the following: L = 12 inches LB Q Search Figure 1: Simple cantilever beam with single longitudinal strain gage P = 4 lbs With the load applied, the longitudinal strain gage reading was recorded as 83 μs (microstrain). Determine the elastic modulus of the beam material. What material is it?

calculate the theoretical stress using the flexure or bending stress formula. The experimental se is shown in Figure 1: ● ● L Take a few minutes to solve the following pre-lab exercise problems before continuing with the background unit: LB 10 inches w 1.5 inches t = 0.25 inches W Problem 1: An experiment was set up according to Figure 1 with the following: L = 12 inches LB Q Search Figure 1: Simple cantilever beam with single longitudinal strain gage P = 4 lbs With the load applied, the longitudinal strain gage reading was recorded as 83 μs (microstrain). Determine the elastic modulus of the beam material. What material is it?

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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F1=603N F2 =818N show a detailed solution please
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