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A wheel rotates without friction about a stationary horizontal axis at the center of the wheel. A constant tangential force equal to 73.0 N is applied to the rim of the wheel. The wheel has radius 0.110 m. Starting from rest, the wheel has an angular speed of 14.9 rev/s after 3.41 s. What is the moment of inertia of the wheel?

User Shrembo
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1 Answer

21 votes
21 votes

Answer:

Approximately
0.293\; {\rm kg \cdot m^(2)}.

Step-by-step explanation:

Since the wheel started from rest, initial angular velocity will be
\omega_(0) = 0\; {\rm rad \cdot s^(-1)}. It is given that the angular velocity
\omega_(1) is
14.9\; {\rm rev \cdot s^(-1)} after
t = 3.41\; {\rm s}. Apply unit conversion and ensure that all angular velocity are measured in radians-per-second:


\begin{aligned} \omega_(1) &= 14.9\; {\rm rev \cdot s^(-1)} * \frac{2\, \pi \; {\rm rad}}{1\; {\rm rev}} \\ &\approx 93.620\; {\rm rad \cdot s^(-1)}\end{aligned}.

Change in angular velocity:


\begin{aligned} \Delta \omega = \omega_(1) - \omega_(0) \approx 93.620\; {\rm rad \cdot s^(-1)}\end{aligned}.

Since the tangential force is constant and there is no friction on the wheel, the angular acceleration
\alpha of this wheel will be constant. Since the change in velocity
\Delta \omega \approx 93.620\; {\rm rad \cdot s^(-1)} was achieved within
t = 3.41\; {\rm s}, the average angular acceleration will be:


\begin{aligned} \alpha &= (\Delta \omega)/(t) \\ &\approx \frac{93.620\; {\rm rad \cdot s^(-1)}}{3.41\; {\rm s}} \\ &\approx 27.45\; {\rm rad \cdot s^(-2)}\end{aligned}.

At a distance of
r = 0.110\; {\rm m} from the axis of rotation, the tangential force
F = 73.0\; {\rm N} will exert on the wheel a torque
\tau of magnitude:


\begin{aligned} \tau &= F\, r \\ &= (73.0\; {\rm N})\, (0.110\; {\rm m}) \\ &\approx 8.030\; {\rm N \cdot m}\end{aligned}.

Let
I denote the moment of inertia of this wheel. The equation
\alpha = (\tau / I) relates angular acceleration
\alpha to moment of inertia
I\! and net torque
\tau. Rearrange this equation to find the moment of inertia:


\begin{aligned}I &= (\tau)/(\alpha) \\ &\approx \frac{8.030\; {\rm N\cdot m}}{27.45\; {\rm rad \cdot s^(-2)}} \\ &\approx 0.293\; {\rm N \cdot m \cdot s^(2)} \\ &= 0.293 \; {\rm kg \cdot m^(2)}\end{aligned}.

Note that the unit "radians" is typically ignored. Additionally,
1\; {\rm N} = 1\; {\rm kg \cdot m \cdot s^(-2)}.

Hence, the moment of inertia of this wheel is approximately
0.293\; {\rm kg \cdot m^(2)}.

User Quetzalcoatl
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