A pin in a knuckle joint carrying a tensile load Fdeflects somewhat on account of this loading, making the distribution ofreaction and load as shown in part (b) of the figure. A common simplification is to assume uniform load distributions, asshown in part (c). To further simplify, designers may consider replacing the distributed loads with point loads, such as inthe two models shown in parts (d) and (e). Given: a == 0.9 in, b= 1.5 in, d= 0.9 in, and F= 3240 Ibf.(c)a+ba+b(d)(a)(e)Estimate the maximum bending stress and the maximum shear stress due to V for the three simplified models.The maximum bending stress for the model (c) iskpsi.The maximum shear stress for the model (c) iskpsi.The maximum bending stress for the model (d) iskpsi.The maximum shear stress for the model (d) iskpsi.The maximum bending stress for the model (e) iskpsi.The maximum shear stress for the model (e is!knsi

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A pin in a knuckle joint carrying a tensile load Fdeflects somewhat on account of this loading, making the distribution of reaction and load as shown in part (b) of the figure. A common simplification is to assume uniform load distributions, as shown in part (c). To further simplify, designers may consider replacing the distributed loads with point loads, such as in the two models shown in parts (d) and (e). Given: a = 0.9 in, b= 1.5 in, d= 0.9 in, and F= 3240 Ibf. b -a- (c) a+b (d) (b) (a) (e) Estimate the maximum bending stress and the maximum shear stress due to V for the three simplified models. The maximum bending stress for the model (c) is kpsi. The maximum shear stress for the model (c) is |kpsi. The maximum bending stress for the model (a) is kpsi. The maximum shear stress for the model (d) is |kpsi. The maximum bending stress for the model (e) is kpsi. The maximum shear stress for the model (e) i | 1knsi

A pin in a knuckle joint carrying a tensile load Fdeflects somewhat on account of this loading, making the distribution of reaction and load as shown in part (b) of the figure. A common simplification is to assume uniform load distributions, as shown in part (c). To further simplify, designers may consider replacing the distributed loads with point loads, such as in the two models shown in parts (d) and (e). Given: a = 0.9 in, b= 1.5 in, d= 0.9 in, and F= 3240 Ibf. b -a- (c) a+b (d) (b) (a) (e) Estimate the maximum bending stress and the maximum shear stress due to V for the three simplified models. The maximum bending stress for the model (c) is kpsi. The maximum shear stress for the model (c) is |kpsi. The maximum bending stress for the model (a) is kpsi. The maximum shear stress for the model (d) is |kpsi. The maximum bending stress for the model (e) is kpsi. The maximum shear stress for the model (e) i | 1knsi

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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