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Chapter 7: Problem 65

In a truck loading station at a post office, a small 0.200 \(\mathrm{kg}\) package is released from rest at point \(A\) on a track that is one-quarter of a circle with radius 1.60 \(\mathrm{m}(\mathrm{Fig} .7 .39) .\) The size of the package is much less than \(1.60 \mathrm{m},\) so the package can be treated as a particle. It slides down the track and reaches point \(B\) with a speed of 4.80 \(\mathrm{m} / \mathrm{s}\) . From point \(B,\) it slides on a level surface a distance of 3.00 \(\mathrm{m}\) to point \(C,\) where it comes to rest (a) What is the coefficient of kinetic friction on the horizontal surface? (b) How much work is done on the package by friction as it slides down the circular are from \(A\) to \(B ?\)

Short Answer

Expert verified
(a) The coefficient of kinetic friction \( \mu_k \) is 0.392. (b) The work done by friction from A to B is \(-1.57 \text{J}\).

Step by step solution

01

Define the Problem Variables

We have a package with mass \( m = 0.200 \, \text{kg} \), a radius of the circular arc \( r = 1.60 \, \text{m} \), initial speed \( v_A = 0 \, \text{m/s} \), final speed at point B \( v_B = 4.80 \, \text{m/s} \), and sliding distance on a horizontal surface \( d = 3.00 \, \text{m} \). We need to find the coefficient of kinetic friction \( \mu_k \) for the surface from B to C and the work done by friction from A to B.
02

Use Conservation of Energy on the Circular Track

The package starts with gravitational potential energy at point A and ends with kinetic energy at point B. Use the conservation of mechanical energy equation: \[ mgh_A = \frac{1}{2}mv_B^2 + W_{friction} \]Here, \( h_A = r \cdot (1 - \cos(\theta)) \) is the height drop, where \( \theta = 90^\circ \rightarrow \cos(\theta) = 0 \), and \( W_{friction} \) is the work done by friction, which will be calculated later.
03

Calculate Potential Energy and Kinetic Energy

The height at point A is \( h_A = 1.60 \, \text{m} \). The potential energy at A is:\[ PE_A = mgh_A = 0.200 \times 9.8 \times 1.60 \]The kinetic energy at B is:\[ KE_B = \frac{1}{2}mv_B^2 = \frac{1}{2} \times 0.200 \times (4.80)^2 \]
04

Determine Work Done by Friction from B to C

On the horizontal surface, the work done by kinetic friction brings the package to rest: \[ W_{friction, BC} = \mu_k mgd \]We know that the package comes to rest after sliding 3.00 m, so kinetic energy at point B is entirely dissipated.
05

Solve for \(\mu_k\) on the Horizontal Surface

Using the work-energy principle, equate the kinetic energy at B to the work done by friction from B to C:\[ \frac{1}{2}mv_B^2 = \mu_k \cdot mg \cdot 3.00 \]Solving for \( \mu_k \):\[ \mu_k = \frac{\frac{1}{2}mv_B^2}{mg \cdot 3.00} \]
06

Calculate Work Done by Friction on the Circular Arc

Return to the conservation of energy equation from Step 2 and solve for \( W_{friction} \) on the arc:\[ mgh_A - \frac{1}{2}mv_B^2 = W_{friction, AB} \]Calculate \( W_{friction, AB} \) substituting the values of \( m, g, h_A, \) and \( v_B \).

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Key Concepts

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

Kinetic Friction
Kinetic friction is an essential concept when studying objects moving across surfaces, including the scenario where our package moves from point B to C. This type of friction occurs when two surfaces slide against each other, creating a resistance to the motion. The magnitude of this force is typically calculated using the coefficient of kinetic friction (\( \mu_k \)) and the normal force (\( F_n \)) acting on the object.
To put it simply, the kinetic friction force \( F_{friction} \) can be expressed using:
  • \( F_{friction} = \mu_k \times F_n \)
For the package sliding on the horizontal surface, the normal force is simply the weight of the package, \( mg \), given that there are no other vertical forces acting. Hence, the kinetic friction force becomes \( F_{friction} = \mu_k \times mg \). As the package moves from point B to C, this frictional force does work on it, which can be calculated through the formula for work done by a force:
  • \( W_{friction, BC} = \mu_k \times mg \times d \)
where \( d \) is the distance traveled. Through understanding and calculating these values, we can see how kinetic friction affects the motion of objects.
Mechanical Energy
Mechanical energy is the sum of potential energy and kinetic energy of an object. In many physics problems, particularly those involving motion like our package's journey, conservation of mechanical energy is a critical principle. It states that in an isolated system (with no external work done), mechanical energy remains constant.
For our package, the initial mechanical energy at point A includes only gravitational potential energy because it starts at rest, which is given by:
  • \( PE_A = mgh_A \)
As the package slides down to point B, this potential energy transforms into kinetic energy, depicted by:
  • \( KE_B = \frac{1}{2}mv_B^2 \)
However, not all of the initial potential energy turns into kinetic energy due to the work done by friction as it slides. The conservation of mechanical energy can be represented by the equation:
  • \( mgh_A = \frac{1}{2}mv_B^2 + W_{friction} \)
This equation helps us understand how potential energy, kinetic energy, and work by friction interact and balance within this system.
Work-Energy Principle
The work-energy principle is a foundational concept in physics that relates the work done on an object to the change in its kinetic energy. This principle underpins many calculations involving energy transformations and is integral to both parts of our package problem, from the circular arc to the horizontal slide.
The work-energy principle states:
  • The work done by all forces acting on an object equals the change in the object's kinetic energy.
Initially, as the package moves from A to B, gravitational force does positive work, converting potential energy into kinetic energy while friction does negative work, absorbing some of this energy. This can be expressed as:
  • \( mgh_A - W_{friction, AB} = \frac{1}{2}mv_B^2 \)
On the horizontal path from B to C, the work-energy principle tells us that the work done by kinetic friction equals the loss of kinetic energy, bringing the package to rest:
  • \( \frac{1}{2}mv_B^2 = W_{friction, BC} \)
By applying the work-energy principle, we can determine how forces like friction affect the energy and motion of objects.

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Most popular questions from this chapter

A proton with mass \(m\) moves in one dimension. The potential-energy function is \(U(x)=\alpha / x^{2}-\beta / x,\) where \(\alpha\) and \(\beta\) are positive constants. The proton is released from rest at \(x_{0}=\alpha / \beta\) (a) Show that \(U(x)\) can be written as $$ U(x)=\frac{\alpha}{x_{0}^{2}}\left[\left(\frac{x_{0}}{x}\right)^{2}-\frac{x_{0}}{x}\right] $$ Graph \(U(x)\) . Calculate \(U\left(x_{0}\right)\) and thereby locate the point \(x_{0}\) on the graph. (b) Calculate \(v(x),\) the speed of the proton as a function of position. Graph \(v(x)\) and give a qualitative description of the motion. (c) For what value of \(x\) is the speed of the proton a maximum? What is the value of that maximum speed? (d) What is the force on the proton at the point in part (c)? (e) Let the proton be released instead at \(x_{1}=3 \alpha / \beta\) . Locate the point \(x_{1}\) on the graph of \(U(x)\) . Calculate \(v(x)\) and give a qualitative description of the motion. (f) For each release point \(\left(x=x_{0} \text { and } x=x_{1}\right),\) what are the maximum and minimum values of \(x\) reached during the motion?

An object has several forces acting on it. One force is \(\overrightarrow{\boldsymbol{F}}=\alpha x \hat{\imath},\) a force in the \(x\) -direction whose magnitude depends on the position of the object. (See Problem \(6.96 . )\) The constant is \(\alpha=2.00 \mathrm{N} / \mathrm{m}^{2} .\) The object moves along the following path: (1) It starts at the origin and moves along the \(y\) -axis to the point \(x=0\) , \(y=1.50 \mathrm{m} ;(2)\) it moves parallel to the \(x\) -axis to the point \(x=1.50 \mathrm{m}, y=1.50 \mathrm{m} ;(3)\) it moves parallel to the \(y\) -axis to the point \(x=1.50 \mathrm{m}, y=0 ;(4)\) it moves parallel to the \(x\) -axis back to the origin. (a) Sketch this path in the \(x y\) -plane. (b) Calculate the work done on the object by \(\overrightarrow{\boldsymbol{F}}\) for each leg of the path and for the complete round trip. (c) Is \(\overrightarrow{\boldsymbol{F}}\) conservative or nonconservative? Explain.

Up and Down the Hill. A \(28-\mathrm{kg}\) rock approaches the foot of a hill with a speed of 15 \(\mathrm{m} / \mathrm{s}\) . This hill slopes upward at a constant angle of \(40.0^{\circ}\) above the horizontal. The coefficients of static and kinetic friction between the hill and the rock are 0.75 and 0.20 , respectively. (a) Use energy conservation to find the maximum height above the foot of the hill reached by the rock. (b) Will the rock remain at rest at its highest point, or will it slide back down the hill? (c) If the rock does slide back down, find its speed when it returns to the bottom of the hill.

You and three friends stand at the corners of a square whose sides are 8.0 \(\mathrm{m}\) long in the middle of the gym floor, as shown in Fig. \(7.26 .\) You take your physics book and push it from one person to the other. The book has a mass of 1.5 \(\mathrm{kg}\) , and the coefficient of kinetic friction between the book and the floor is \(\mu_{\mathrm{x}}=0.25 .\) (a) The book slides from you to Beth and then from Beth to Carlos, along the lines connecting these people. What is the work done by friction during this displacement? (b) You slide the book from you to Carlos along the diagonal of the square. What is the work done by friction during this displacement? (c) You slide the book to Kim who then slides it back to you. What is the total work done by friction during this motion of the book? (d) Is the friction force on the book conservative or nonconservative? Explain.

A machine part of mass \(m\) is attached to a horizontal ideal spring of force constant \(k\) that is attached to the edge of a friction-free horizontal surface. The part is pushed against the spring compressing it a distance \(x_{0},\) and then released from rest. Find the maximum (a) speed and (b) acceleration of the machine part. (c) Where in the motion do the maxima in parts (a) and (b) occur? (d) What will be the maximum extension of the spring? (e) Describe the subsequent motion of this machine part. Will it ever stop permanently?
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