HoneyPi
Oct8-09, 05:38 AM
1. The problem statement, all variables and given/known data
http://www.physicsforums.com/attachment.php?attachmentid=20998&stc=1&d=1254997829
A uniform beam AB, of lenth l and mass m, is free in turn in a vertical plane about a smooth hinge at A. It is supported in a static position by a light string, of the same length l, attached to the end of end B of the beam and to an anchoring point C at a height h vertically above A.
Draw a diagram showing clearly all the external forces acting on the beam.
By considering the equilibrium conditions for the beam, find an expression for the tension in the string in terms of m, l, h and g, the magnitude of the acceleration due to gravity.
2. Relevant equations
\textbf{R} = R_j \textbf{j} + R_k \textbf{k}
\textbf{W} = -mg \textbf{k}
\textbf{T} = - \textsl{T} \cos\theta \textbf{j} + \textsl{T} \sin\theta \textbf{k}
\textbf{r}_R = \textbf{0}
\textbf{r}_W = \frac{1}{2} l \cos(\frac{1}{2} \theta) \textbf{j}
\textbf{r}_T = l \cos(\frac{1}{2} \theta) \textbf{j}
3. The attempt at a solution
(i) http://www.physicsforums.com/attachment.php?attachmentid=20997&stc=1&d=1254997829
(ii) Determining the torques:
\boldsymbol{\Gamma}_R = \textbf{0}
\boldsymbol{\Gamma}_W = \frac{1}{2} l \cos(\frac{1}{2} \theta) \textbf{j} \times -mg \textbf{k} = - \frac{1}{2} l m g \cos(\frac{1}{2} \theta) \textbf{i}
\boldsymbol{\Gamma}_T = l \cos(\frac{1}{2} \theta) \textbf{j} \times \textsl{T} \sin\theta \textbf{k} = l \textsl{T} \cos(\frac{1}{2} \theta) \sin\theta \textbf{i}
Then since we consider the equilibrium conditions, we have
\boldsymbol{\Gamma}_T + \boldsymbol{\Gamma}_W + \boldsymbol{\Gamma}_R = \textbf{0}
Solving this in i-direction gives:
l \textsl{T} \cos(\frac{1}{2} \theta) \sin\theta = \frac{1}{2} l m g \cos(\frac{1}{2} \theta)
\Rightarrow \textsl{T} \sin\theta = \frac{1}{2} m g
And now I am not sure about the following:
Since
\sin(\frac{1}{2} \theta) = \frac{\frac{1}{2} h }{l}
it follows that
2 \sin(\frac{1}{2} \theta) = \sin\theta = \frac{h}{l}
And so
\textsl{T} \frac{h}{l} = \frac{1}{2} m g \qquad \Rightarrow \quad \textsl{T} = \frac{mgl}{2h}
I'd appreciate it if someone could help me out with the last part of (ii) and also checking whether I did the other parts correctly.
Thanks alot :)
Honey \pi
http://www.physicsforums.com/attachment.php?attachmentid=20998&stc=1&d=1254997829
A uniform beam AB, of lenth l and mass m, is free in turn in a vertical plane about a smooth hinge at A. It is supported in a static position by a light string, of the same length l, attached to the end of end B of the beam and to an anchoring point C at a height h vertically above A.
Draw a diagram showing clearly all the external forces acting on the beam.
By considering the equilibrium conditions for the beam, find an expression for the tension in the string in terms of m, l, h and g, the magnitude of the acceleration due to gravity.
2. Relevant equations
\textbf{R} = R_j \textbf{j} + R_k \textbf{k}
\textbf{W} = -mg \textbf{k}
\textbf{T} = - \textsl{T} \cos\theta \textbf{j} + \textsl{T} \sin\theta \textbf{k}
\textbf{r}_R = \textbf{0}
\textbf{r}_W = \frac{1}{2} l \cos(\frac{1}{2} \theta) \textbf{j}
\textbf{r}_T = l \cos(\frac{1}{2} \theta) \textbf{j}
3. The attempt at a solution
(i) http://www.physicsforums.com/attachment.php?attachmentid=20997&stc=1&d=1254997829
(ii) Determining the torques:
\boldsymbol{\Gamma}_R = \textbf{0}
\boldsymbol{\Gamma}_W = \frac{1}{2} l \cos(\frac{1}{2} \theta) \textbf{j} \times -mg \textbf{k} = - \frac{1}{2} l m g \cos(\frac{1}{2} \theta) \textbf{i}
\boldsymbol{\Gamma}_T = l \cos(\frac{1}{2} \theta) \textbf{j} \times \textsl{T} \sin\theta \textbf{k} = l \textsl{T} \cos(\frac{1}{2} \theta) \sin\theta \textbf{i}
Then since we consider the equilibrium conditions, we have
\boldsymbol{\Gamma}_T + \boldsymbol{\Gamma}_W + \boldsymbol{\Gamma}_R = \textbf{0}
Solving this in i-direction gives:
l \textsl{T} \cos(\frac{1}{2} \theta) \sin\theta = \frac{1}{2} l m g \cos(\frac{1}{2} \theta)
\Rightarrow \textsl{T} \sin\theta = \frac{1}{2} m g
And now I am not sure about the following:
Since
\sin(\frac{1}{2} \theta) = \frac{\frac{1}{2} h }{l}
it follows that
2 \sin(\frac{1}{2} \theta) = \sin\theta = \frac{h}{l}
And so
\textsl{T} \frac{h}{l} = \frac{1}{2} m g \qquad \Rightarrow \quad \textsl{T} = \frac{mgl}{2h}
I'd appreciate it if someone could help me out with the last part of (ii) and also checking whether I did the other parts correctly.
Thanks alot :)
Honey \pi