Perform a static stress analysis with linear material models on the problem shown in Figure 1 utilizing different mesh densities. Use meshes of 200, 400, 800, and 1600 elements. The thickness of the part given below is 8mm. A load of n MPa is applied on the right edge, where n is the last three digits of your UWE ID number. (for instance, for student 14020174, n is 174). The left end is fully fixed. Material is stainless steel (AISI 302) cold rolled. Assume it as a plane stress problem. Calculate stress concentration factor and compare with that of given in mechanics textbook. Write your comments in comparison with analytical solution.

Elements Of Electromagnetics
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Author:Sadiku, Matthew N. O.
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Perform a static stress analysis with linear material models on the problem shown in
Figure 1 utilizing different mesh densities. Use meshes of 200, 400, 800, and 1600
elements. The thickness of the part given below is 8mm. A load of n MPa is applied
on the right edge, where n is the last three digits of your UWE ID number. (for
instance, for student 14020174, n is 174). The left end is fully fixed. Material is
stainless steel (AISI 302) cold rolled. Assume it as a plane stress problem.
Calculate stress concentration factor and compare with that of given in mechanics
textbook. Write your comments in comparison with analytical solution.
UFMFU7-15-3
Page 2 of 6
Radius =10 mm
Fixed BC
L.
40 mm
200 mm
Figure 1
Transcribed Image Text:Perform a static stress analysis with linear material models on the problem shown in Figure 1 utilizing different mesh densities. Use meshes of 200, 400, 800, and 1600 elements. The thickness of the part given below is 8mm. A load of n MPa is applied on the right edge, where n is the last three digits of your UWE ID number. (for instance, for student 14020174, n is 174). The left end is fully fixed. Material is stainless steel (AISI 302) cold rolled. Assume it as a plane stress problem. Calculate stress concentration factor and compare with that of given in mechanics textbook. Write your comments in comparison with analytical solution. UFMFU7-15-3 Page 2 of 6 Radius =10 mm Fixed BC L. 40 mm 200 mm Figure 1
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