1) For a point on the rim of the flywheel, the distance from the center of the motion is equal to the radius of the wheel: [tex]r=0.700 m[/tex].
The tangential acceleration for a point on the rim is given by
[tex]a_t = \alpha r[/tex]
where [tex]\alpha=0.800 rad/s^2[/tex] is the angular acceleration while r is the radius. Substituting the numbers, we get
[tex]a_t = (0.800 rad/s^2)(0.700 m)=0.560 m/s^2[/tex]
2) The radial acceleration for a point on the rim (r=0.700 m) at time t=0 is given by:
[tex]a_r = \frac{v_t^2}{r} [/tex]
where [tex]v_t[/tex] is the tangential velocity at time t=0.
The tangential velocity is given by
[tex]v_t = \omega r[/tex]
where [tex]\omega[/tex] is the angular speed; however, at the start of the motion (t=0) the flywheel is at rest, so [tex]\omega=0[/tex] and [tex]v_t=0[/tex], so the radial acceleration is [tex]a_r = 0[/tex].
3) The magnitude of the acceleration at time t=0 is given by:
[tex]|a| = \sqrt{a_t^2 + a_r^2}= \sqrt{(0.560 m/s^2)^2+(0)^2} =0.560 m/s^2 [/tex]
4) As we said at point 1), the tangential acceleration is given by
[tex]a_t = \alpha r[/tex]
but [tex]\alpha[/tex], the angular acceleration, is constant, so the tangential acceleration after an angle of [tex]\theta=60.0^{\circ} [/tex] is just equal to the tangential acceleration at the beginning of the motion:
[tex]a_t = (0.800 rad/s^2)(0.700 m)=0.560 m/s^2[/tex]
