Part ACalculate the safety factor for the bracket at point A using the Coulomb-Mohr theory.Express your answer to three significant figures.NCM A³SubmitPart BNMMA³Calculate the safety factor for the bracket at point A using the modified-Mohr effective-stress theory.Express your answer to three significant figurec.Submit▾ Part CNCM B=SubmitCalculate the safety factor for the bracket at point Busing the Coulomb-Mahr theory.Express your answer to three significant figurec.Part Dequaat AmerNMM =Submitque AmerProvide FeedbackCalculate the safety factor for the bracket at point using the modified-Mohr effective-stress theory.Express your answer to three significant figurec.(?AmerIdequat Amer The bracket is shown in (Figure 1). Assume that I = 160 mm,a = 280 mm, t = 5 mm, h = 25 mm, F = 850 N, ID = 19 mm.OD = 45 mm. Assume a brittle material strength of Sut = 350 MPa(50 kpsi) and Suc= 1000 MPa (150 kpsi).FigureBwalltubeodEXarmh1 of 1

Given: The force acting, F = The length, l = 160 mm= 0.16 m The length, a = 280 mm = 0.28 m The…

The bracket is shown in (Figure 1). Assume that 7 = 160 mm, a = 280 mm, t = 5 mm. h = 25 mm. F = 850 N, ID = 19 mm, OD = 45 mm. Assume a brittle material strength of Sut = 350 MPa (50 kpsi) and Suc= 1000 MPa (150 kpsi). igure B wall tube od arm h 1 of 1

The bracket is shown in (Figure 1). Assume that 7 = 160 mm, a = 280 mm, t = 5 mm. h = 25 mm. F = 850 N, ID = 19 mm, OD = 45 mm. Assume a brittle material strength of Sut = 350 MPa (50 kpsi) and Suc= 1000 MPa (150 kpsi). igure B wall tube od arm h 1 of 1

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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Concept explainers

Axial Load

When a bar of the uniform cross-section is acted by a load, such that the load acts along the longitudinal axis of the bar, such kinds of loadings are known as axial loadings. In general terms, a load is an external force acting on a component. An axial load acts perpendicular to the geometric cross-section of the component. Based on the direction of the application of the load, an axial load can be tensile or compressive. The analysis of bodies under the action of axial loads is generally studied under the branch of mechanics, known as statics.

Question

Part A
Calculate the safety factor for the bracket at point A using the Coulomb-Mohr theory.
Express your answer to three significant figures.
NCM A³
Submit
Part B
NMMA³
Calculate the safety factor for the bracket at point A using the modified-Mohr effective-stress theory.
Express your answer to three significant figurec.
Submit
▾ Part C
NCM B=
Submit
Calculate the safety factor for the bracket at point Busing the Coulomb-Mahr theory.
Express your answer to three significant figurec.
Part D
equaat Amer
NMM =
Submit
que Amer
Provide Feedback
Calculate the safety factor for the bracket at point using the modified-Mohr effective-stress theory.
Express your answer to three significant figurec.
(?
Amer
Idequat Amer

The bracket is shown in (Figure 1). Assume that I = 160 mm,
a = 280 mm, t = 5 mm, h = 25 mm, F = 850 N, ID = 19 mm.
OD = 45 mm. Assume a brittle material strength of Sut = 350 MPa
(50 kpsi) and Suc= 1000 MPa (150 kpsi).
Figure
B
wall
tube
od
E
X
arm
h
1 of 1

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