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Chapter 11: Q84P (page 416)

A bicycle wheel with a heavy rim is mounted on a lightweight axle, and one end of the axle rests on top of a post. The wheel is observed to presses in the horizontal plane. With the spin direction shown in figure11.111, does the wheel process clockwise or counter wise? Explain in detail, including appropriate diagrams.

Short Answer

Expert verified

The torque points into the page and then the wheel process in clockwise direction.

Step by step solution

01

Definition of torque

Torque is defined as the force which causes the rotation of the object about an axis.

02

Find the torque point of the wheel

The direction of bicycle wheel rotation is as shown in the following figure.

The bicycle wheel on the axle behaves like a gyroscope with one of the axle on the vertical support. The wheel rotates in clockwise direction around its own axis with spin angular speed $ω$ . The rotational angular momentum $\vec{L_{r o t}}$ of the wheel points horizontally but it is changing as the gyroscope processes. The forces that are acting on the system are force exerts by support and mass, at the center of the spinning wheel.

The translational angular momentum remains constant whereas the rotational angular momentum is change as $\frac{d \vec{L}}{d t}$ .

Thus, the torque points into the page and then the wheel process in clockwise direction.

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Most popular questions from this chapter

A small rock passes a massive star, following the path shown in red on the diagram. When the rock is a distance $4.5 \times 10^{13} m$ (indicatedas in figure) from the center of the star, the magnitudeof its momentum is $1.35 \times 10^{17} k g \cdot m / s$ and the angle is $126 ° \frac{1}{2}$ . At a later time, when the rock is a distance $d_{2} = 1.3 \times 10^{13} m$ from the center of the star, it is heading in the $- y$ direction. There are no other massive objects nearby. What is the magnitude $p_{2}$ of the final momentum?

A thin metal rod of mass $1.3 kg$ and length $0.4 m$ is at rest in outer space, near a space station (Figure 11.99). A tiny meteorite with mass $0.06 kg$ travelling at a high speed of strikes the rod a distance $0.2 m$ from the center and bounces off with speed 60 m/s as shown in the diagram. The magnitudes of initial and final angles to the $x - a x i s$ of the small mass’s velocity are $θ_{i} = 26 °$ and $θ_{f} = 82 °$ .(a). Afterward, what is the velocity of the center of the rod? (b) Afterward, what is the angular velocity $\vec{ω}$ of the rod? (c) What is the increase in internal energy of the objects?

Model the motion of a meter stick suspended from one end on a low-friction. Do not make the small-angle approximation but allow the meter stick to swing with large angels. Plot on the game graph both $θ$ and the z component of $\vec{ω}$ vs. time, Try starting from rest at various initial angles, including nearly straight up (Which would be $θ_{i} = π$ radians. Is this a harmonic oscillator? Is it a harmonic oscillator for small angles?

An amusing trick is to press a finger down on a marble on a horizontal table top, in such a way that the marble is projected along the table with an initial linear speed $v$ and an initial backward rotational speed $ω$ about a horizontal axis perpendicular to $v$ . The coefficient of sliding friction between marble and top is constant. The marble has radius $R$ . (a) if the marble slides to a complete stop, What was $ω$ in terms of $v$ and $R$ ? (b) if the marble, skids to a stop, and then starts returning toward its initial position, with a final constant speed of $(3 / 7) v,$ What was $ω$ in terms of $v$ and $R$ ? Hint for part (b): when the marble rolls without slipping, the relationship between speed and angular speed is $v = ω R$ .

Show thath and angular momentum have the same units.

See all solutions

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