Springs - AP Physics 1

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Question

A block with a mass of 1kg is hanging vertically from a spring that has a constant of $40\frac{N}{m}$ . If the block is pulled downward 1.5m past equilibrium and released, what is the velocity of the block as it passes back through the equilibrium position?

$g=10\frac{m}{s^2}$

Answer

This problem deals with the conservation of energy in the form of a spring. The formula for the conservation of energy is:

We can eliminate initial kinetic energy to get:

We have two forms of potential energy in this problem: gravitational and spring. Therefore, we can rewrite the expression to be:

$U_{is} = K_f + U_{fg}$

There is no initial gravitational potential energy and no final spring potential energy. Subsituting our expressions for potential and kinetic energy, we get:

$\frac{1}{2}kx^2 = \frac{1}{2}mv_f^2 + mgh$

Rearranging for final velocity, we get:

$v_f = \sqrt{\frac{kx^2}{m}-2gh}$

is the original displacement (the same as ).

We have all of the values, so we can solve:

$v_f = \sqrt{\frac{40\cdot(1.5)^2}{1} - (2\cdot 10\cdot 1.5)}$

$v_f = \sqrt{60} = 7.7 \frac{m}{s}$

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Question

A spring with a constant of $3\frac{N}{m}$ is hanging from the ceiling of an elevator. A block of mass 1kg is attached to the end of the spring. If the elevator begins to accelerate at a rate of $2\frac{m}{s^2}$ , how far will the equilibrium position of the spring shift?

Answer

Before the elevator begins to accelerate, the block has a weight of:

$F = mg = (1kg)(10\frac{m}{s^2}) = 10N$

While the elevator is accelerating, the block has a weight of:

$F = m(g+a) = (1kg)(10\frac{m}{s^2}+2\frac{m}{s^2}) = 12 N$

Now we can say that the weight of the block has effectively increased by 2N.

We can use this increase in force to find out how much the equilibrium position will shift:

Rearranging for x (displacement), we get:

$\Delta x = \frac{\Delta F}{k} = \frac{2N}{3\frac{N}{m}} = 0.67 m$

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Question

A horizontal spring with a constant of $25 \frac{N}{m}$ is on a frictionless surface. If a mass of attached to the spring has a maximum acceleration of $10 \frac{m}{s^2}$ , what is its maximum velocity?

Answer

We know that the maximum acceleration of a spring occurs when it is at its maximum displacement. At this point, we can write an expression for the force that the block is under:

Rearranging for the distance, we get:

$x = \frac{ma}{k}$

This is also the point at which the spring is storing its maximum potential energy:

$U = \frac{1}{2}kx^2$

We can substitute our rearranged distance equation into the equation for potential energy:

$U = \frac{1}{2}k(\frac{ma}{k})^2= \frac{m^2a^2}{2k}$

We also know that the maximum velocity of a spring occurs when it is at the point of equilibrium. Since the spring is on a frictionless surface, we can say that its kinetic energy at this point is equal to the maximum potential energy:

Plugging in the expressions for these variables:

$\frac{m^2a^2}{2k} = \frac{1}{2}mv^2$

Rearranging for velocity:

$v = \sqrt{\frac{2ma^2}{2k}}$

We know all of the values, so we can plug and chug:

$v = \sqrt{\frac{2(2kg)(10\frac{m}{s^2})^2}{2(25\frac{N}{m})}} = 2.8\frac{m}{s}$

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Question

A horizontal spring with a spring constant of $20 \frac{N}{m}$ sits on a table and has a mass of attached to one end. The coefficient of kinetic friction between the mass and table is . If the spring is stretched to a distance of past its point of equilibrium and released, how many times does the mass pass through the point of equilibrium before coming to rest?

$g = 10\frac{m}{s^2}$

Answer

From the problem statement, we can calculate how much potential energy is initially stored in the spring. Since we are neglecting air resistance, we can say that all of this energy is lost through friction as the system comes to a stop.

Calculating initial potential energy:

$U = \frac{1}{2}kx^2 = \frac{1}{2}(20\frac{N}{m})(2m)^2 = 40 J$

Then we can write an expression for the force of friction on the mass:

$F_f = \mu F_N = (0.20)(1kg)(10\frac{m}{s^2}) = 2N$

We can then write an expression of the work done by friction:

$W = F_f\cdot d = (2N)d$

Setting this equal to the initial potential energy:

Therefore, the mass travels a total distance of 20 meters before coming to rest. We know that the distance between maximum compression and maximum extension of the spring is 4 meters. Therefore, we can say that the mass travels from one maximum displacement to the other five times, passing through the equilibrium once each time. The mass passes through the equilibrium point 5 times.

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Question

A spring with a spring constant of $50 \frac{N}{m}$ is compressed past its point of equilibrium. If internal friction results in an average power loss of , how long does the spring oscillate after being released until it comes to rest?

$g = 10\frac{m}{s^2}$

Answer

We can calculate the initial potential energy of the spring from what we are given in the problem statement:

$U = \frac{1}{2}kx^2 = \frac{1}{2}(50\frac{N}{m})(3m)^2 = 225J$

Assuming the only energy loss of the spring is through internal friction, we can write:

$P=\frac{W}{t}=\frac{\Delta U}{t}\rightarrow \Delta U=P\cdot t$

$225J = P\cdot t = (5W)t$

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Question

A homogenous mass of 0.25kg is fixed to a 0.5kg Hookean spring. When the mass/spring system is stretched 1cm from the equilibrium, it takes 3N of force to hold the mass in place. If the displacement from equilibrium is doubled, the force necessary to keep the system in place will __________.

Answer

Since the spring is Hookean, the relationship between the force and displacement from equilibrium of the mass can be expressed by Hooke's Law:

Since this equation is linear, the force and displacement are directly proportional. Thus, when the displacement doubles, the force doubles.

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Question

A block falls off of a table and collides with a spring on the floor with velocity $10\frac{m}{s}$ . The spring has a spring constant of $100\frac{N}{m}$ . How much is the spring compressed when the velocity of the block is ?

Answer

This problem can be solved by the conservation of energy. The block initially has kinetic energy equal to:

$\frac{1}{2}mv^2 = \frac{1}{2}\cdot 5kg\cdot (10\frac{m}{s})^2 = 250 J$

When the velocity of the block is zero, all the kinetic energy has been transferred to potential spring energy.

$250 J = \frac{1}{2}kx^2$

$250 J = \frac{1}{2}\cdot 100 \frac{N}{m} \cdot x^2$

$x = \sqrt{5}=2.24m$

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Question

Suppose that a 10kg object is sliding along a frictionless, horizontal surface at a speed of $2: \frac{m}{s}$ when suddenly, it hits and compresses a spring. If this spring has a spring constant of $0.1: \frac{N}{m}$ , what is the maximum length by which the spring is compressed?

Answer

To find the answer to this problem, we'll need to consider the case before the object collides with the spring, and also after it collides. Before the collision, all of the object's energy is in the form of kinetic energy.

$E_{i}=\frac{1}{2}mv^{2}$

Upon collision, the spring will be compressed by the moving object. The maximum displacement, however, will occur the instant the object stops moving. At this point, the object will no longer have any kinetic energy because it has stopped moving. Furthermore, all of the energy has now been transferred into the spring, and is held as spring potential energy.

$E_{f}=\frac{1}{2}kx^{2}$

Also, since we are told in the question stem that no friction is involved, we have a situation in which mechanical energy is conserved. In other words, we can relate the initial and final energies as equal to one another.

$E_{i}=E_{f}$

Set these two equations equal to each other, and solve for the maximum displacement.

$\frac{1}{2}mv^{2}=\frac{1}{2}kx^{2}$

$mv^{2}=kx^{2}$

$x=\sqrt{\frac{mv^{2}}{k}}=v\sqrt{\frac{m}{k}}$

$x=2 \frac{m}{s}\sqrt{\frac{10 kg}{0.1 \frac{N}{m}}}$

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Question

A object is undergoing SHM with amplitude of . If the spring constant is $250 \frac{N}{m}$ , calculate the maximum speed of the object.

Answer

To solve this problem, we must use our knowledge of the relationship between angular frequency, the spring constant, and the mass.

$\omega = \sqrt{\frac{k}{m}}=\sqrt{\frac{250\frac{N}{m}}{4 kg}}=7.9 \frac{rad}{s^2}$

We can then use this, and the derived maximum speed of the object in terms of the amplitude and angular frequency, to find the answer.

$v_{max}=A\omega=0.2m\left( 7.9\frac{rad}{s}\right )=1.58 \frac{m}{s}$

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Question

What are the units of the spring constant in Hooke's Law?

Answer

Hooke's Law is:

here is in meters and is in newtons.

Solve for to see what the units are:

$k=-\frac{F}{x}$

This means that the units of the spring constant, is:

$\frac{N}{m}=\frac{kg\cdot m}{s^2 \cdot m}=\frac{kg}{s^2}$

We can ignore the negative sign when we determine units, as the negative sign only indicates the direction of the force.

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Question

A spring is compressed to its smallest point and then released. Assume that there is a frictional force that counters the motion of the spring. If we were to create a model plotting the position with time , which of the following could be appropriate for this system? Assume that at , is at its minimum point.

Answer

To determine which type of sinusoid is used, we have to look at its starting point and where it goes. It starts at its minimum and moves towards its maxima. The simplest model we can use is a negative cosine model, which will require no phase shifts.

$X=-\cos(t)$

At , will be at its minimal value.

However, there is also a counteracting frictional force that decreases the amplitude of the spring over time. One way to do so would be to add an $e^{-t}$ term in front of the cosine, so that we have an ever decreasing amplitude as time moves on.

The only appropriate model is

$X=-e^{-t}\cos(t)$

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Question

In the lab, a student has created an oscillator by hanging a weight from a spring. The student releases the oscillator from rest and uses a sensor and computer to find the equation of motion for the oscillator: $x(t)=0.13m;cos(6.3\frac{radians}{s}t+0.14:radians)$

The student then pulls the weight down twice as far and releases it from rest. What would the new equation of motion be for the oscillator?

Answer

Doubling the initial distance the weight is displaced from equilibrium doubles the amplitude, but does not change the period or the phase of the oscillator. So in the general equation of an oscillator:

$x(t)=Acos(\omega t+\phi)$ , only the term changes, and it doubles.

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Question

In the lab, a student has created an oscillator by hanging a weight from a spring. The student releases the oscillator from rest and uses a sensor and computer to find the equation of motion for the oscillator: $x(t)=0.13m;cos(6.3\frac{radians}{s}t+0.14:radians)$

The student then replaces the spring with a new spring whose spring constant, , is twice as large as that of the original spring.The student again releases the weight from rest from the same displacement from equilibrium. What would the new equation of motion be for the oscillator?

Answer

The amplitude does not change since the student pulls the weight the same displacement. Changing the spring constant changes the frequency of the oscillator. Since the period decreases, the frequency increases, but it does not double. The frequency and the period depend on the square root of the spring constant, so the frequency increases by $\sqrt{2}=1.41$ . In the equation of motion for an oscillator,

$x(t)=Acos(\omega t+\phi)$ , only the frequency $\omega$ , changes.

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Question

Given that a spring is held above the ground and an object of mass tied to the spring is displaced below the equilibrium position, determine the spring constant .

$g=10\frac{m}{s^2}$

Answer

Since there are two forces acting on the object, and it isn't moving, there is an equality of the two forces. This means that:

$F_{spring}=F_{gravity}$

Equivalently:

Where is the spring constant, is the displacement of the spring, is the equilibrium position, is mass of the object and is the gravitational constant given as $10\frac{m}{s^2}$

Since we know that the mass on the spring spring is displaced , the mass is , and we know the gravitational constant we plug in and solve for the spring constant.

$-k(-3m)=6kg10\frac{m}{s^2}$

$k=20 \frac{kg}{s^2}$

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Question

A horizontal spring with spring constant $100\frac{N}{m}$ is attached to a wall and a mass of . The mass can slide without friction on a frictionless surface.

Determine the frequency of motion of the system if the system is stretched by .

Answer

Use the equation:

$\omega=\sqrt{\frac{k}{m}}$ for a mass on a horizontal spring (so no gravity in the direction of motion)

The stretch length will have no effect.

Plug in values:

$\omega=\sqrt{\frac{100}{50}}$

$\omega=\frac{1.41}{s}$

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Question

A block is attached to a horizontal spring with a constant $10\ \frac{\textup{N}}{\textup{m}}$ and is on a frictionless surface. If the maximum displacement is $0.5\textup{ m}$ and the maximum velocity is $1.4\ \frac{\textup{m}}{\textup{s}}$ , what is the mass of the block? Neglect air resistance and any frictional forces.

Answer

We know that when the block is at its maximum displacement, it is not moving and therefore has no kinetic energy. Also, we know that the block has its maximum kinetic energy (thus velocity) when it is passing through the springs equilibrium and therefore has no potential energy. Therefore, we can say:

$PE_{max}=KE_{max}$

Where the potential energy of a spring is:

$PE_{max}=\frac{1}{2}kx_{max}^2$

And the expression for kinetic energy is:

$KE_{max}=\frac{1}{2}mv_{max}^2$

Substituting in these expressions, we get:

$\frac{1}{2}kx_{max}^2=\frac{1}{2}mv_{max}^2$

Canceling out the fractions:

$kx_{max}^2=mv_{max}^2$

No rearranging for mass, we get:

$m = k\frac{x_{max}^2}{v_{max}^2}$

We have all of these values, so we can solve the problem:

$m = \left ( 10\frac{N}{m}\right )\frac{\left ( 0.5m\right )^2}{\left ( 1.4\frac{m}{s}\right )^2}$

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Question

A horizontal spring with a constant $k = 8\ \frac{\textup{N}}{\textup{m}}$ is on a frictionless surface with a block attached to the end of it. If the block has a maximum potential energy of $15\textup{ J}$ , and a maximum velocity of $3\ \frac{\textup{m}}{\textup{s}}$ what is the period of the spring assuming simple harmonic motion?

Answer

The expression for the period of a spring in simple harmonic motion is:

$T= 2\pi \sqrt{\frac{m}{k}}$

We have the spring constant, so we just need to calculate the mass of the block. For a spring in simple harmonic motion, we know that the maxmium potential energy is equal to the maximum kinetic energy. Therefore we can say:

$PE_{max}=KE_{max}=15J$

$KE_{max}=\frac{1}{2}mv^2$

Rearranging for mass, we get:

$m = \frac{2KE_{max}}{v^2}$

Plugging in our values, we get:

$m = \frac{2(15J)}{\left ( 3\frac{m}{s}\right )^2}$

$m = \frac{10}{3}kg$

Now we can use the expression for period to solve the equation:

$T= 2\pi \sqrt{\frac{m}{k}}$

Plugging in our values:

$T = 2\pi \sqrt{\frac{\left ( \frac{10}{3}kg\right )}{\left ( 8\frac{N}{m}\right )}}$

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Question

A spring with constant $k = 50\ \frac{\textup{N}}{\textup{m}}$ is hanging from a ceiling. A block of mass $4\textup{ kg}$ is attached and the spring is compressed $0.4\textup{ m}$ from equilibrium. The block is then released from rest. What is the velocity of the block as it passes through equilibrium?

$g = 10\ \frac{\textup{m}}{\textup{s}^2}$

Answer

We can use the expression for conservation of energy to solve this problem:

We can eliminate initial kinetic energy (block initially at rest) and final potential energy (block at equilibrium of spring) to get:

Substituting in expressions for each of these, we get:

$mgh_i +\frac{1}{2}kx_i^2=\frac{1}{2}mv_f^2$

Where initial height is simply the displacement of the spring:

$mgx_i +\frac{1}{2}kx_i^2=\frac{1}{2}mv_f^2$

Multiplying both sides of the expression by 2 and rearranging for final velocity, we get:

$v_f = \sqrt{\frac{2mgx_i+kx_i^2}{m}}$

Plugging in values for each of these variables, we get:

$v_ f = \sqrt{\frac{2(4kg)\left ( 10\frac{m}{s^2}\right )(0.4m)+\left ( 50\frac{N}{m}\right )(0.4m)^2}{4kg}}$

$v_f = 3.2\frac{m}{s}$

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Question

A mass is hung on a vertical spring which extends the spring by 2 meters. What is the spring constant of the spring in $\frac{N}{m}$ ?

Answer

The spring constant is equal to $k=\frac{mg}{x}$ .

$k=\frac{3kg*10\frac{m}{s^2}}{2m}=\boldsymbol{15\frac{N}{m}}$

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Question

A horizontal spring is oscillating with a mass sliding on a perfectly frictionless surface. If the amplitude of the oscillation is and the mass has a value of and a velocity at the rest length of $4\frac{m}{s}$ , determine the frequency of oscillation.

Answer

Using conservation of energy:

While at the maximum value of stretch (the amplitude), the velocity will be zero. While at the maximum velocity, the stretch will be zero.

Plugging in values:

Solving for

$k=\frac{71N}{m}$

$\omega=\sqrt{\frac{k}{m}}$

Plugging in values:

$\omega=\frac{30.8 rad}{s}$

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