Dynamics: Angular Acceleration of Rods Connected to Disk

vercingortix
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Homework Statement


Bars BC and AB and dish OA are attached by a pin like in the picture. The dish has a constant angular velocity \omega\_{0}. Find the angular acceleration of bars BC and AB.

Homework Equations


Relative Motion Equations:
v_{b}=v_{A}+v_{A/B}
a_{B}=a_{A}+\alpha_{A}Xr_{B/A}-\omega^{2}r_{B/A}

The Attempt at a Solution


So far, I have this written down:

V_{A}=\omegar
a_{A}=V_{A}^{2}/r=\omega^{2}r

a_{B}=\alpha_{BC}Xr_{BC}-\omega_{BC}^{2}r_{BC}

Still just fumbling over these equations. Any help is appreciated.
 

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welcome to pf!

hi vercingortix! welcome to pf! :smile:

(have a theta: θ and an omega: ω :wink:)

(centripetal acceleration is irrelevant)

ω = (vP - vQ)/PQ

so find vB as a function of θ :wink:
 
That equation looks foreign to me. What I'm currently trying to do is solve for angular acceleration of the bar by knowing the omega and accelerations of both A & B. Something like the second equation in my original post. I'm very lost.
 
hi vercingortix! :wink:

ω = |vP - vQ]/PQ

and

α = |aP - aQ|/PQ

are the definitions of angular speed and acceleration

so find the x,y components of B as a function of θ, and differentiate to get vB and aB :smile:
 

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