A thin solid disk of 1 kg is rotating along its diameter axis at the speed of 1800 rpm. By applying an external torque of $25\pi$ Nm for 40s, the speed increases to 2100 rpm. The diameter of the disk is ______ m.
Show Hint
Correct Answer: 40
Approach Solution - 1
The given equation is:
\( \tau \, dt = I \Delta w \)
Substitute the given values:
\( 25\pi \times 40 = I(300) \times \frac{2\pi}{60} \)
Simplify to find \( I \):
\( I = \frac{25 \times 60 \times 40}{300 \times 2} = 100 = \frac{M R^2}{4} \)
Now, solving for \( R^2 \):
\( R^2 = 400 \)
Thus, the value of \( R \) is:
\( R = 20 \, \text{m} \)
And the distance \( D \) is:
\( D = 40 \, \text{m} \)
Approach Solution -2
Step 1: Convert initial and final angular speeds from rpm to rad/s.
- Initial speed, \(\omega_0 = 1800 \, \text{rpm} = \frac{1800 \times 2\pi}{60} = 60\pi \, \text{rad/s}\).
- Final speed, \(\omega = 2100 \, \text{rpm} = \frac{2100 \times 2\pi}{60} = 70\pi \, \text{rad/s}\).
Step 2: Calculate angular acceleration (\(\alpha\)) using torque and moment of inertia.
- Torque, \(\tau = 25\pi \, \text{Nm}\).
- Moment of inertia for a thin disk rotating about its diameter: \( I = \frac{1}{4}MR^2 = \frac{1}{4} \times 1 \times R^2 = \frac{R^2}{4}\).
- Angular acceleration: \( \tau = I\alpha \quad \Rightarrow \quad 25\pi = \frac{R^2}{4} \alpha \quad \Rightarrow \quad \alpha = \frac{100\pi}{R^2}\).
Step 3: Relate angular acceleration to the change in angular velocity.
\( \omega = \omega_0 + \alpha t \quad \Rightarrow \quad 70\pi = 60\pi + \left(\frac{100\pi}{R^2}\right) \times 40\).
Simplify: \( 10\pi = \frac{4000\pi}{R^2} \quad \Rightarrow \quad R^2 = 400 \quad \Rightarrow \quad R = 20 \, \text{m}\).
- Diameter, \(D = 2R = 40 \, \text{m}\).
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