3) Figure - 2 shows a round bar (Ø 40 mm) being used as a bracket to suport equipment attached as shown. Determine stress and strain in each sectio. ) and the total dislocation of point A ,-, -). If bar diameter is increased for 0.2 [mm], find Poisson's ratio for,. Loads are applied as shown., Given: F. Z, Z, = Z, = Z3 = 400 [mm] F = 15[kN] F2 = 10[kN) F3 = 5[kN] E = 2.0 x 10° (MPa] Ø, = 40 mm Ø, = 40 mm F, Z, F,
3) Figure - 2 shows a round bar (Ø 40 mm) being used as a bracket to suport equipment attached as shown. Determine stress and strain in each sectio. ) and the total dislocation of point A ,-, -). If bar diameter is increased for 0.2 [mm], find Poisson's ratio for,. Loads are applied as shown., Given: F. Z, Z, = Z, = Z3 = 400 [mm] F = 15[kN] F2 = 10[kN) F3 = 5[kN] E = 2.0 x 10° (MPa] Ø, = 40 mm Ø, = 40 mm F, Z, F,
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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![3) Figure - 2 shows a round bar (Ø 40 mm) being used as a bracket to support equipment
attached as shown. Determine stress and strain in each sectio..
) and the total
dislocation of point A -, -). If bar diameter is increased for 0.2 [mm], find Poisson's
ratio for.
Loads are applied as shown.,
A
Given:
F,
Z,
Zz = Z2 = Z3 = 400 [mm]
F = 15[kN)
F2 = 10[kN)
F3 = 5(kN]
E = 2.0 x 10° (MPa]
Ø, = 40 mm
Ø, = 40 mm
F,
Z,
F,
Figure -](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fc71388d0-f187-4b8e-840b-91f3c593615b%2F74e90023-3398-46d2-828b-f2788c9a3ee5%2Fkamzgq_processed.jpeg&w=3840&q=75)
Transcribed Image Text:3) Figure - 2 shows a round bar (Ø 40 mm) being used as a bracket to support equipment
attached as shown. Determine stress and strain in each sectio..
) and the total
dislocation of point A -, -). If bar diameter is increased for 0.2 [mm], find Poisson's
ratio for.
Loads are applied as shown.,
A
Given:
F,
Z,
Zz = Z2 = Z3 = 400 [mm]
F = 15[kN)
F2 = 10[kN)
F3 = 5(kN]
E = 2.0 x 10° (MPa]
Ø, = 40 mm
Ø, = 40 mm
F,
Z,
F,
Figure -
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