We will have the following:
a. We determine the tension force of T2 as follows:
We know that the system must be at equilibrium on the horizontal axis:
[tex]\sum F_x=T_1cos(42.5)+T_2cos(36.5)=0[/tex]
So:
[tex]\begin{gathered} T_2cos(36.5)=-(1235N)cos(42.5)\Rightarrow T_2=-\frac{(1235N)cos(42.5)}{cos(36.5)} \\ \\ \Rightarrow T_2=1132.711003...N\Rightarrow T_2\approx1132.7N \end{gathered}[/tex]
So, the value of T2 is approximately 1132.7 N.
b. We will determine the torques created by T1 and T2 as follows:
T1:
[tex]\tau_{T1}=(10m)(1235N)sin(42.5)\Rightarrow\tau_{T1}\approx8343.5N\ast m[/tex]
T2:
[tex]\tau_{T2}=(10m)(1132.7N)sin(36.5)\Rightarrow\tau_{T2}\approx6737.6N\ast m[/tex]
So the torques of T1 and T2 on the base are approximately 8343.5 N*m and 6737.6 N*m respectively.
c. The torques around that axis generated by the normal force and the weight are both 0 N*, since they are parallel to the axis.
d. We will determine the angular acceleration as follows:
[tex]\begin{gathered} \alpha=\frac{\tau_{T1}}{I}\Rightarrow\alpha=\frac{\tau_{T1}}{(1/3mL^2)} \\ \\ \Rightarrow\alpha=\frac{(8343.5N\ast m)}{(1/3(200kg)(10m)^2)}\Rightarrow\alpha=1.251525rad/s^2 \\ \\ \Rightarrow\alpha\approx1.25rad/s^2 \end{gathered}[/tex]
So, the angular acceleration is approximately 1.25 radians/ s^2.
