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Chapter 9: Problem 78

A thin, light wire is wrapped around the rim of a wheel as shown in Fig. E9.45. The wheel rotates about a stationary horizontal axle that passes through the center of the wheel. The wheel has radius 0.180 m and moment of inertia for rotation about the axle of \(I =\) 0.480 kg \(\cdot\) m\(^2\). A small block with mass 0.340 kg is suspended from the free end of the wire. When the system is released from rest, the block descends with constant acceleration. The bearings in the wheel at the axle are rusty, so friction there does \(-\)9.00 J of work as the block descends 3.00 m. What is the magnitude of the angular velocity of the wheel after the block has descended 3.00 m?

Short Answer

Expert verified
The angular velocity of the wheel is approximately 3.12 rad/s.

Step by step solution

01

Understand the Given Values and Problem

We have a wheel with radius \( r = 0.180 \) m and moment of inertia \( I = 0.480 \) kg \( \cdot \) m\(^2\). A block of mass \( m = 0.340 \) kg descends 3.00 m, and friction does \(-9.00 \) J of work. We need the angular velocity of the wheel after the block descends.
02

Calculate the Potential Energy Change

The change in potential energy \( \Delta U \) when the block descends is given by \( \Delta U = m g h \), where \( g = 9.81 \) m/s\(^2\) and \( h = 3.00 \) m. Hence, \( \Delta U = 0.340 \times 9.81 \times 3.00 \).
03

Apply the Work-Energy Principle

The initial potential energy is converted into kinetic energy of the block and wheel, minus work done by friction. The relation is \( \Delta U = \Delta K_{block} + \Delta K_{wheel} + \text{work by friction} \).
04

Write the Equations for Kinetic Energies

The kinetic energy of the block \( \Delta K_{block} = \frac{1}{2} m v^2 \) and for the wheel \( \Delta K_{wheel} = \frac{1}{2} I \omega^2 \). The velocities are related by \( v = r \omega \).
05

Solve for Block's Linear Velocity

Substitute \( v = r \omega \) into \( \Delta K_{block} \) and combine with previous equations to write \( m g h - 9.00 = \frac{1}{2} m (r \omega)^2 + \frac{1}{2} I \omega^2 \).
06

Isolate \( \omega \) and Solve

Rearrange to \( m g h - 9.00 = \frac{1}{2} m r^2 \omega^2 + \frac{1}{2} I \omega^2 \). Combine terms: \( \omega^2 = \frac{2(m g h - 9.00)}{m r^2 + I} \).
07

Calculate Angular Velocity

Substitute values: \( \omega = \sqrt{ \frac{2(0.340 \times 9.81 \times 3.00 - 9.00)}{0.340 \times 0.180^2 + 0.480} } \). Compute \( \omega \).
08

Conclude with \( \omega \) Value

After calculations, \( \omega \approx 3.12 \) rad/s. The magnitude of the angular velocity of the wheel is \( 3.12 \) rad/s.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Moment of Inertia
The moment of inertia is a crucial concept in rotational dynamics. It is analogous to mass in linear motion, indicating how much torque is needed for a desired angular acceleration. Moment of inertia ( I ) depends on the mass distribution relative to the axis of rotation. In this exercise, we have a wheel with a specified moment of inertia of 0.480 kg · m ² . This means that the resistance of the wheel to any change in its rotational motion is determined by this value. The greater the moment of inertia, the more difficult it is to change the object's rotational state. In practical terms, if two wheels have the same size but different mass distributions, the one with more mass spread farther from the axis will have a higher moment of inertia. This concept helps in calculating the angular velocity by integrating with other principles like energy transformation.
Work-Energy Principle
The work-energy principle is essential in understanding how energy changes forms but is conserved within a system. It states that the work done on a system is equal to the change in its kinetic energy. In this problem, the wheel's friction does -9.00 J of work, which affects the energy conservation during the block’s descent. Using the principle, we equate the change in potential energy to the work done by friction and the change in kinetic energy of both the wheel and block. This allows us to understand how the system's energy evolves and aids in solving for unknowns, like angular velocity, by balancing all energy changes. It assures us that the total mechanical energy, minus work done by friction, gets distributed between the kinetic energies of the wheel and the block.
Potential Energy
Potential energy is stored energy due to an object's position, generally in a gravitational field. In this case, when the block hangs from the wheel, it possesses gravitational potential energy determined by its height above the ground level. The potential energy ( U ) is quantified by the equation U = mgh , where m is mass, g is gravitational acceleration, and h is the height. As the block descends 3.00 meters, its potential energy decreases, converting this energy into other forms. This decrease in potential energy drives the motion of the wheel, culminating in mechanical work, specifically rotational kinetic energy, while considering the energy lost due to friction, which is how the work-energy principle is applied.
Kinetic Energy
Kinetic energy is the energy of motion, applicable to both linear and rotational movements. For linear motion, like that of the falling block, kinetic energy is defined as \( rac{1}{2} mv^2 \), where m is mass and v is velocity.For rotational motion, shown by the wheel, it's described by \( rac{1}{2} I \omega^2 \), indicating the influence of both the angular velocity \( \omega \)and the moment of inertia \( I \).In this exercise, when the block descends, the system’s potential energy shifts substantially to these kinetic energy forms. The relationship between linear and angular velocities is given by v = r\omega, ensuring interconnected transformations.Solving the exercise involves equating the potential energy change to combined kinetic energies, showing how various energies interplay under the influence of the work-energy principle.

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Most popular questions from this chapter

An electric fan is turned off, and its angular velocity decreases uniformly from 500 rev/min to 200 rev/min in 4.00 s. (a) Find the angular acceleration in rev/s\(^2\) and the number of revolutions made by the motor in the 4.00-s interval. (b) How many more seconds are required for the fan to come to rest if the angular acceleration remains constant at the value calculated in part (a)?

If a person of mass \(M\) simply moved forward with speed \(V\), his kinetic energy would be \\( \frac{1}{2} \\)\(MV^2\). However, in addition to possessing a forward motion, various parts of his body (such as the arms and legs) undergo rotation. Therefore, his total kinetic energy is the sum of the energy from his forward motion plus the rotational kinetic energy of his arms and legs. The purpose of this problem is to see how much this rotational motion contributes to the person's kinetic energy. Biomedical measurements show that the arms and hands together typically make up 13% of a person's mass, while the legs and feet together account for 37%. For a rough (but reasonable) calculation, we can model the arms and legs as thin uniform bars pivoting about the shoulder and hip, respectively. In a brisk walk, the arms and legs each move through an angle of about \(\pm30^\circ\) (a total of 60\(^\circ\)) from the vertical in approximately 1 second. Assume that they are held straight, rather than being bent, which is not quite true. Consider a 75-kg person walking at 5.0 km/h, having arms 70 cm long and legs 90 cm long. (a) What is the average angular velocity of his arms and legs? (b) Using the average angular velocity from part (a), calculate the amount of rotational kinetic energy in this person's arms and legs as he walks. (c) What is the total kinetic energy due to both his forward motion and his rotation? (d) What percentage of his kinetic energy is due to the rotation of his legs and arms?

You are a project manager for a manufacturing company. One of the machine parts on the assembly line is a thin, uniform rod that is 60.0 cm long and has mass 0.400 kg. (a) What is the moment of inertia of this rod for an axis at its center, perpendicular to the rod? (b) One of your engineers has proposed to reduce the moment of inertia by bending the rod at its center into a V-shape, with a 60.0\(^\circ\) angle at its vertex. What would be the moment of inertia of this bent rod about an axis perpendicular to the plane of the V at its vertex?

A light, flexible rope is wrapped several times around a \(hollow\) cylinder, with a weight of 40.0 N and a radius of 0.25 m, that rotates without friction about a fixed horizontal axis. The cylinder is attached to the axle by spokes of a negligible moment of inertia. The cylinder is initially at rest. The free end of the rope is pulled with a constant force \(P\) for a distance of 5.00 m, at which point the end of the rope is moving at 6.00 m/s. If the rope does not slip on the cylinder, what is \(P\)?

While riding a multispeed bicycle, the rider can select the radius of the rear sprocket that is fixed to the rear axle. The front sprocket of a bicycle has radius 12.0 cm. If the angular speed of the front sprocket is 0.600 rev/s, what is the radius of the rear sprocket for which the tangential speed of a point on the rim of the rear wheel will be 5.00 m/s? The rear wheel has radius 0.330 m.
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