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Chapter 5: Problem 120

A small remote-controlled car with mass 1.60 \(\mathrm{kg}\) moves at a constant speed of \(v=12.0 \mathrm{m} / \mathrm{s}\) in a vertical circle inside a hollow metal cylinder that has a radius of 5.00 \(\mathrm{m}(\) Fig. \(\mathrm{P} 5.120) .\) What is the magnitude of the normal force exerted on the car by the walls of the cylinder at (a) point \(A\) (at the bottom of the vertical circle) and (b) point \(B(\) at the top of the vertical circle)?

Short Answer

Expert verified
At point A, the normal force is 61.76 N; at point B, it's 30.40 N.

Step by step solution

01

Determine forces at point A (bottom of the circle)

The car experiences gravitational force and a normal force from the walls at the bottom of the circle. The normal force acts upwards and must counteract the gravitational force and provide the centripetal force for circular motion. - Gravitational force, \( F_g = mg = 1.60 \, \text{kg} \times 9.8 \, \text{m/s}^2 = 15.68 \, \text{N} \).- Centripetal force needed, \( F_c = \frac{mv^2}{r} = \frac{1.60 \, \text{kg} \times (12.0 \, \text{m/s})^2}{5.00 \, \text{m}} = 46.08 \, \text{N} \).The normal force \( N_A \) equals the gravitational force plus the centripetal force:\[ N_A = F_g + F_c = 15.68 \, \text{N} + 46.08 \, \text{N} = 61.76 \, \text{N}. \]
02

Determine forces at point B (top of the circle)

At the top of the circle, the gravitational force and the normal force both act downwards and contribute to providing the required centripetal force.- Gravitational force, \( F_g = 15.68 \, \text{N} \). - Centripetal force needed, \( F_c = 46.08 \, \text{N} \).The normal force \( N_B \) equals the centripetal force needed minus the gravitational force because both forces can combine to meet the required centripetal force:\[ N_B = F_c - F_g = 46.08 \, \text{N} - 15.68 \, \text{N} = 30.40 \, \text{N}. \]

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Key Concepts

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

Normal Force
The normal force is an essential concept when considering circular motion. It refers to the force exerted by a surface (in this case, the walls of the cylinder) to support the car and keep it moving in a circle. At point A, which is the bottom of the circle, the normal force acts upwards against gravity. This is because gravity pulls down on the car, and the surface pushes up.
The normal force is not just counteracting gravity; it also provides the additional centripetal force necessary for circular motion. This means at the bottom of the circle, the normal force is stronger as it has to balance both gravity and the centripetal force required to keep the car on its circular path.
  • At point A, the normal force is the sum of the gravitational force and centripetal force: 61.76 N.
  • At point B, however, the scenario flips. Here, the normal force and gravitational pull both act downwards, contributing together to provide the required centripetal force.
  • The normal force at the top, therefore, just fills in the gap to reach the needed centripetal force: 30.40 N.
Understanding how normal force works differently at various points in a circular path is key to mastering circular motion dynamics.
Centripetal Force
Centripetal force is the force that keeps an object moving in a circular path. Without this force, an object would move off in a straight line due to inertia. When the remote-controlled car travels around the inside of the cylinder, this inward force is what keeps the car in its circular trajectory.
To calculate the centripetal force required, we use the formula: \[ F_c = \frac{mv^2}{r} \] where: \( m \) is the mass of the car, \( v \) is the speed, and \( r \) is the radius of the circle.
For the car:
  • Mass \( m = 1.60 \; \text{kg} \)
  • Speed \( v = 12.0 \; \text{m/s} \)
  • Radius \( r = 5.00 \; \text{m} \)
With these values, the centripetal force is calculated to be 46.08 N. This force is constant for both points A and B but interacts differently with the other forces acting on the car, such as gravity and normal force.
Gravitational Force
Gravitational force always acts downward, that is, toward the center of the Earth. This force is constant and is calculated by the formula: \[ F_g = mg \] where \( g \) is the acceleration due to gravity, approximately 9.8 \( \text{m/s}^2 \). For our car with mass \( m = 1.60 \; \text{kg} \), the gravitational force \( F_g = 15.68 \; \text{N} \).
At any given point in the circle, gravity's pull remains the same in magnitude but interacts differently with other forces.
  • At point A, gravity acts downward while normal force acts upward, both playing a role in ensuring the car's circular motion by meeting the centripetal force requirement together.
  • At point B, both gravity and normal force point downwards, effectively adding up to provide the necessary centripetal force.
Understanding gravitational force in circular motion contexts is crucial because it consistently influences how other forces, such as the normal and centripetal forces, are applied or calculated in the system.

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Most popular questions from this chapter

On the ride "Spindletop" at the amusement park Six Flags Over Texas, people stood against the inner wall of a hollow vertical cylinder with radius 2.5 \(\mathrm{m} .\) The cylinder started to rotate, and when it reached a constant rotation rate of 0.60 rev/s, the floor on which people were standing dropped about 0.5 \(\mathrm{m}\) . The people remained pinned against the wall. (a) Draw a force diagram for a person on this ride, after the floor has dropped. (b) What minimum coefficient of static friction is required if the person on the ride is not to slide downward to the new position of the floor? (c) Does your answer in part (b) depend on the mass of the passenger? (Note: When the ride is over, the cylinder is slowly brought to rest. As it slows down, people slide down the walls to the floor.)

A 550 -N physics student stands on a bathroom scale in an 850 -kg (including the student) elevator that is supported by a cable. As the elevator starts moving, the scale reads 450 \(\mathrm{N}\) . (a) Find the acceleration of the elevator (magnitude and direction). (b) What is the acceleration if the scale reads 670 \(\mathrm{N}\) ? (c) If the scale reads zero, should the student worry? Explain. (d) What is the tension in the cable in parts (a) and (c)?

You are working for a shipping company. Your job is to stand at the bottom of a \(8.0-\mathrm{m}\) -long ramp ramp that is inclined at \(37^{\circ}\) above the horizontal. You grab packages off a conveyor belt and propel them up the ramp. The coefficient of kinetic friction between the packages and the ramp is \(\mu_{\mathrm{k}}=0.30\) . (a) What speed do you need to give a package at the bottom of the ramp so that it has zero speed at the top of the ramp? (b) Your coworker is supposed to grab the packages as they arrive at the top of the ramp, but she misses one and it slides back down. What is its speed when it returns to you?

A small button placed on a horizontal rotating platform with diameter 0.320 \(\mathrm{m}\) will revolve with the platform when it is brought up to a speed of 40.0 rev/min, provided the button is no more than 0.150 \(\mathrm{m}\) from the axis. (a) What is the coefficient of static friction between the button and the platform? (b) How far from the axis can the button be placed, without slipping, if the platform rotates at 60.0 \(\mathrm{rev} / \mathrm{min}\) ?

Two blocks with masses 4.00 \(\mathrm{kg}\) and 8.00 \(\mathrm{kg}\) are connected by a string and slide down a \(30.0^{\circ}\) inclined plane (Fig. \(\mathrm{P5.98).~The~}\) coefficient of kinetic friction between the \(4.00-\) kg block and the plane is \(0.25 ;\) that between the 8.00 -kg block and the plane is 0.35 (a) Calculate the acceleration of each block. (b) Calculate the tension in the string. (c) What happens if the positions of the blocks are reversed, so the \(4.00-\mathrm{kg}\) block is above the 8.00 -kg block?
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