Respuesta :
Answer:
Part a)
[tex]t_1 = \frac{\omega_1}{\alpha}[/tex]
Part b)
[tex]\theta = \frac{1}{2}\alpha t_1^2[/tex]
Part c)
[tex]t = \frac{t_1}{5}[/tex]
Explanation:
Part a)
As we know that it is having constant torque so here the time taken by it to accelerate is given as
[tex]\omega_f = \omega_i + \alpha t[/tex]
[tex]\omega_1 = 0 + \alpha t_1[/tex]
[tex]t_1 = \frac{\omega_1}{\alpha}[/tex]
Part b)
angular displacement is given as
[tex]\theta = \omega_i t_1 + \frac{1}{2}(\alpha) t_1^2[/tex]
[tex]\theta = 0 + \frac{1}{2}\alpha t_1^2[/tex]
[tex]\theta = \frac{1}{2}\alpha t_1^2[/tex]
Part c)
As we know that the angular deceleration produced by the brakes is given as
[tex]\alpha_d = - 5\alpha[/tex]
now we have
[tex]\omega_f = \omega _i + \alpha t[/tex]
[tex]0 = \omega_1 - 5 \alpha_1 t[/tex]
[tex]t = \frac{\omega_1}{5 \alpha}[/tex]
As we know that
[tex]t_1 = \frac{\omega_1}{\alpha}[/tex]
so we have
[tex]t = \frac{t_1}{5}[/tex]
(A) The time taken by the flywheel for the acceleration is, [tex]\dfrac{\omega_{1}}{\alpha}[/tex].
(B) The angle turned by the flywheel is [tex]\dfrac{1}{2} \alpha t^2_{1}[/tex].
(C) The time taken by the flywheel to stop after the brake is applied is [tex]\dfrac{t_{1}}{ 5}[/tex].
Given data:
The magnitude of angular acceleration is, [tex]\alpha[/tex].
Final angular speed is, [tex]\omega_{1}[/tex].
Time taken is, [tex]t_{1}[/tex].
(A)
Apply the first rotational equation of motion as,
[tex]\omega_{1}=\omega' + \alpha t_{1}[/tex]
Since, the flywheel was initially at rest. So, [tex]\omega'=0[/tex]. Then,
[tex]\omega_{1}=0 + \alpha \times t_{1}\\t_{1}=\dfrac{\omega_{1}}{\alpha}[/tex]
Thus, the time taken for the acceleration is, [tex]\dfrac{\omega_{1}}{\alpha}[/tex].
(B)
Now apply the second rotational equation of motion to obtain the angle turned by the flywheel as,
[tex]\theta_{1}=\omega ' \times t_{1}+\dfrac{1}{2} \alpha t^2_{1}[/tex]
Substituting the values as,
[tex]\theta_{1}=0 \times t_{1}+\dfrac{1}{2} \alpha t^2_{1}\\\theta_{1}=\dfrac{1}{2} \alpha t^2_{1}[/tex]
Thus, the angle turned by the flywheel is [tex]\dfrac{1}{2} \alpha t^2_{1}[/tex].
(C) During acceleration, the expression is given as,
[tex]\omega_{1}=\omega' + \alpha t_{1}\\\omega_{1}=0 + \alpha t_{1}\\t_{1}=\dfrac{\omega_{1}}{\alpha}[/tex]
Since, brake is applied. Which means the flywheel is stopped finally. So, applying the third rotational equation of motion as,
[tex]\omega_{2}=\omega_{1}+(-5 \alpha)t'[/tex]
Here, [tex]\omega_{2}[/tex] is the final speed after brake is applied. And its value is [tex]\omega_{2} =0[/tex].
Solving as,
[tex]0=\omega_{1}-5 \alpha t\\t'=\dfrac{\omega_{1}}{5 \alpha } \\t'=\dfrac{1}{ 5} \times \dfrac{\omega_{1}}{ \alpha } \\t'=\dfrac{t_{1}}{ 5}[/tex]
Thus, the time taken by the flywheel to stop after the brake is applied is [tex]\dfrac{t_{1}}{ 5}[/tex].
Learn more about the rotational kinematics here:
https://brainly.com/question/20338754?referrer=searchResults
