The steel bar AB with the length 6 m has a rectangular cross-section, which is fixed at A and pin connected at B. The Young's modulus of steel is Et = 200 GPa and its yield stress oy = 360 MPa.Click here to see all formulaswC5 mL30 mm20 mm20 mmPart A - The critical load to initiate buckling on bar AB iskN.O 0.560O 2.24О 3.13O 1.12O 4.48SubmitRequest AnswerPart B - The maximum allowable intensity ww of the distributed load that can be applied to BC without causing AB to buckle iskN/m. Part B - The maximum allowable intensity ww of the distributed load that can be applied to BC without causing AB to buckle iskN/m.O 0.224O 0.895O 0.448O 1.79O 1.34SubmitRequest AnswerPart C - The maximum allowable intensity w of the distributed load that can be applied to BC without causing AB to yield is_kN/m.O 86.4O 173O 259O 216O 43.2SubmitRequest AnswerO O O o OO O O O O

Given:- L=6m Es=200 GPa σy=360 MPa BC=5m To find:- Part A- Critical load to initiate buckling on bar…

Answered: The steel bar AB with the length 6 m…

The steel bar AB with the length 6 m has a rectangular cross-section, which is fixed at A and pin connected at B. The Young's modulus of steel is E = 200 GPa and its yield stress oy = 360 MPa.

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

Power Transmission Elements

It is defined as the energy transfer from one location to another location. The energy will start moving from the energy generation source to the energy applied position to obtain the work output. From this method, a large amount of electric energy moves from the power station to various electrical substations.

Question

The steel bar AB with the length 6 m has a rectangular cross-section, which is fixed at A and pin connected at B. The Young's modulus of steel is Et = 200 GPa and its yield stress oy = 360 MPa.
Click here to see all formulas
w
C
5 m
L
30 mm
20 mm
20 mm
Part A - The critical load to initiate buckling on bar AB is
kN.
O 0.560
O 2.24
О 3.13
O 1.12
O 4.48
Submit
Request Answer
Part B - The maximum allowable intensity ww of the distributed load that can be applied to BC without causing AB to buckle is
kN/m.

Part B - The maximum allowable intensity ww of the distributed load that can be applied to BC without causing AB to buckle is
kN/m.
O 0.224
O 0.895
O 0.448
O 1.79
O 1.34
Submit
Request Answer
Part C - The maximum allowable intensity w of the distributed load that can be applied to BC without causing AB to yield is
_kN/m.
O 86.4
O 173
O 259
O 216
O 43.2
Submit
Request Answer
O O O o O
O O O O O

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