(4) BIA 30 disk: radius = r = 0.350m r BIA = 0.300m rad: length= L = 0.90 A disk and a rod are pin-connected at B, and are arranged as shown. Given that the disk rolls without sliding to the right, with center A velocity V₁ = 3.6 m/s →, and that end I of the rod remains in contact with the wall, use the ICR method to find : (a) the angular velocity WBD of the rod (mag and direc) (b) the velocity VD of end D (mag and direc) It is also given that A and B are at the same height.

(4) BIA 30 disk: radius = r = 0.350m r BIA = 0.300m rad: length= L = 0.90 A disk and a rod are pin-connected at B, and are arranged as shown. Given that the disk rolls without sliding to the right, with center A velocity V₁ = 3.6 m/s →, and that end I of the rod remains in contact with the wall, use the ICR method to find : (a) the angular velocity WBD of the rod (mag and direc) (b) the velocity VD of end D (mag and direc) It is also given that A and B are at the same height.

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

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Question

(4)
r
A
BIA
30
disk: radius = r = 0.350m
r
B/A = 0.300m
rad: length = L = 0,90
A disk and a rod are pin-connected at B, and are arranged as shown.
Given that the disk rolls without sliding to the right, with center
velocity V₁ = 3.6 m/s →, and that end I of the rod remains in
A
)
contact with the wall, use the ICR method to find :
(a) the angular velocity WBD
(b) the velocity V of end D (mag and direc)
It is also given that A and B are at the same height.
of the rod (mag and direc)

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