Power - AP Physics 1

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Question

A crane is being used to lift a crate to a height of above the ground. If the crane's engine can provide a power output of , how long does it take for the crane to complete the task?

Answer

First we find the total work required to lift the crate:

$W=\Delta PE=mg\Delta h$

We are given the mass, change in height, and the acceleration of gravity. Using these values, we can solve for the total work done.

$W=(100kg)(9.8\frac{m}{s^2})(10m)=9800J$

Next, we can use the equation for power to find the time to complete this task if the engine is working at its maximum power.

$P=\frac{\Delta W}{\Delta t}$

$2000W=\frac{9800J}{\Delta t}$

$\Delta t=\frac{9800J}{2000W}=4.9s$

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Question

A man with mass 50kg is wearing a backpack of mass 5kg and running up a hill with a slope of 30 degrees at a constant velocity of $2\frac{m}{s}$ . What is the man's power output?

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

Answer

Since the man's kinetic energy remains constant, we are really solving for the rate at which he gains potential energy.

However, when we find the change of this with respect to time (aka power), the expression becomes:

$P = \frac{\Delta U}{t}=\frac{mg\Delta h}{t}$

We can calculate the change in height by using the velocity of the man and the slope of the hill:

$\frac{\Delta h}{t} = v_y = v\cdot sin(30^{\circ})$

Substituting this into the equation for power, we get:

$P = m\cdot g \cdot v\cdot sin(30^{\circ})$

We know all of these values, so we can plug in and solve:

$P = (55)(10)(2)sin(30^{\circ}) = 550 W$

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Question

An elevator of mass 1000kg has five passengers, each with an average mass of 80kg. The elevator accelerates from rest to a velocity of $3\frac{m}{s}$ over 6 seconds. How much work was done over this time?

Answer

We can use the work-energy theorem to solve this problem, which says the the net work done is equal to the change in kinetic energy:

$W_{net} = \Delta K$

We can expand this to write:

$W_{net} = \frac{1}{2}m(v_f^2-v_i^2)$

We know that the elevator was initially at a standstill, so the equation becomes:

$W_{net} = \frac{1}{2}mv_f^2$

We are given the mass of the elevator plus passengers, as well as the final velocity, so we can simply solve:

$W_{net} = \frac{1}{2}(1400kg)(3\frac{m}{s})^2 = 6300J$

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Question

A skydiver of mass 50kg is falling at a terminal velocity of $75\frac{m}{s}$ . How much power is the air exerting on the diver?

Answer

Since the diver is at terminal velocity, we know that the force exerted by the air is equal to the gravitational force. Let's calculate that first:

$F = mg = 50kg\cdot 10\frac{m}{s^2} = 500 N$

Now that we know the force exerted by the wind, we have to connect the dots to turn this into units of power. We can do this by using the velocity of the man. Power is simply work done over time. We aren't given a time frame in the problem statement, so let's just choose a time frame of 1 second to keep things simple. Over 1 second, we know that the diver falls 75 meters. From this, we can calculate how much gravitational potential energy is lost over this distance:

$\Delta U = mg\Delta h = 500N \cdot 75 m = 37500 J$

This means that 37500J were exerted by the wind over a period of 1 second. Now we can simply use the formula for power:

$P = \frac{W}{t} = \frac{37500 J}{1s} = 37500 W = 37.5 kW$

This problem emphasizes a great tactic in solving most physics problems. If you ever get stuck, simply follow your units. See what units you have, what units you can work with, and try to figure out a logical path that combines them to get to the units that your answer should be. Although this is NOT how you should go about physics, it is a good tactic to use when you can't simply work through the problem with the concepts you have been taught.

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Question

A man is pushing a crate through a flat warehouse at a rate of $1.5\frac{m}{s}$ . If the crate has a mass of 20kg and the coefficient of kinetic friction between the crate and the floor is 0.2, how much power is the man exerting?

Answer

We first need to know the frictional force between the crate and floor:

$F_f = \mu_k N = (0.2)(10\frac{m}{s^2})(20kg) = 40N$

Now that we have the frictional force, we can simply multiply it by the velocity of the crate to find power:

$P = F_fv = (40N)(1.5\frac{m}{s}) = 60W$

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Question

A professional diver of mass is competing in the tournament. If the diver jumps from a platform above the surface of the water and comes to a stop after hitting the water at a depth of , what is the average power that the water exerts on the diver?

Answer

We can use the equation for conservation of energy to solve for the work done by the water on the diver:

We can eliminate both kinetic energies since the diver is stationary at the initial and final states. If we assume a final height of , we can also eliminate final potential energy. Keep in mind that this assumption requires that we add the distances above and below the water, making our total height 21m. Substituting in our expresssion for initial potential energy, we get:

$W = mgh_i = (70kg)(10\frac{m}{s^2})(21m)$

That is the work done on the diver. Since we know the time period during which this work is done, we can calculate the average power of the water on the diver:

$P = \frac{W}{t}=\frac{14.7kJ}{0.4s}=36.8kW$

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Question

Suppose that a 1000kg car accelerates from rest to $50: \frac{m}{s}$ in 7.5s. What is the power of the engine needed for this process?

Answer

We are given the mass of the car, its initial velocity, its final velocity, and the amount of time needed to reach its final velocity. We are then asked to calculate the power involved in the overall process. We can first start by noting that power is equal to work divided by time:

$P=\frac{W}{t}$

Since we are given the amount of time in the question stem, we'll need to find a way to calculate . To do so, we can relate the work done by the change in the kinetic energy of the car.

$W=\Delta KE=KE_{f}-KE_{i}$

Since we're given mass, final velocity, and initial velocity, we can use these values to calculate the change in kinetic energy.

$W=\frac{1}{2}mv_{f}^{2}-\frac{1}{2}mv_{i}^{2}$

Furthermore, since the car is starting from rest, its initial velocity is equal to zero. Thus, the initial kinetic energy is equal to zero, meaning that the work done is equal to the final kinetic energy.

$W=\frac{1}{2}mv_{f}^{2}$

Substitute into the the equation for power and solve.

$W=\frac{\frac{1}{2}mv_{f}^{2}}{t}$

$W=\frac{mv_{f}^{2}}{2t}=\frac{(1000 kg)(50\frac{m}{s})^{2}}{2(7.5 s)}=166666.667W=167kW$

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Question

A car of mass goes from $0 \frac{m}{s}$ to $50\frac{m}{s}$ in .

Assuming perfect traction and ignoring air resistance, estimate the power of the car.

Answer

First, we need to find the change in energy.

Our initial energy was zero.

Our final energy consists solely of the final kinetic energy

$.5m{v_f}^2=W$

We plug in our values

$.5\cdot2018\cdot50^2=W$

$2.5\times10^6=W$

Our definition of power is

$P=\frac{W}{\Delta t}$

Plugging in our values again, we get

$P=\frac{2.5\times10^6}{11.2}$

$2.2\times10^5 watts=P$

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Question

You are on the ground floor of a parking garage building. You then run up the stairs to the roof, taking to reach a height of . You have a mass of . Determine your power in watts.

Answer

First, we will need to calculate the total amount of energy gained, also known as the work done.

$W=E_{final}-E_{intial}$

Since we are on the ground floor, we will assume our initial energy to be zero.

Using our formula for gravitational potential energy

$PE_{gravitational}=mgh$

$PE_{gravitational}=55\cdot 9.8\cdot20$

$1.0\times10^6 J=PE_{gravitational}$

These $1.0\times10^6 J$ were obatined in .

Using our definition of power

$P=\frac{W}{\Delta t}$

$P=\frac{1.0\times10^6}{60}$

$1.7\times10^4 Watts=P$

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Question

A 5 kg box is being pulled up a ramp by a wench. This ramp has an inclination of 30 degrees and is 1 meter long. Assuming the wench pulls the box across this 1 meter in 4 seconds, what is the average power out put of the wench? Also assume the box does not change speed.

Answer

Power is most basically put as the change in energy over time.

$P=\frac{\Delta E}{t}$

For this problem, the only energy change we are able to consider is the change in gravititational potential energy. We are told the speed does not change so the kinetic energy is constant. The power output of the wench is going only into bringing the box higher in the gravitiational field. We ignore friction for this problem. So, rewriting the first equation:

$P=\frac{\Delta GPE}{t}$

$P=\frac{(mgh)_{f}-(mgh)_{i}}{t}$

We have the liberty to set the initial height to zero and then guage the final height starting from zero. This eliminates the initial term.

$P=\frac{(mgh)_{f}}{t}$

We are given the mass and time, but we need to use trig to solve for the height. We can solve for the height of the ramp using sin.

is for the opposite side of the triangle and H is the hypotenuse, not to get confused with h. The opposite side of the triangle is our height h.

$\sin(\Theta )=O/H$

So, $H\sin (\Theta )=O$

Rewriting h in our power equation:

$P=\frac{(mgH\sin (\Theta ))_}{t}$

Plugging into this equation we get

$6.1: \textup{Watts}$ .

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Question

Determine the work needed to push a block up an incline that's $30^\circ$ to the horizontal, up to a height of .

Assume there is no friction or air resistance.

Assume the value of the gravitational constant to be

$g=9.8\frac{m}{s^2}$

Answer

Firstly, remember that the only force in play here is gravity. Since gravity is a conservative force, to move up , it's going to require work equal to:

$W=mg\Delta h$ , where is the mass of the object, is the gravitational constant, and $\Delta h$ is the change in distance from the ground. Since we are moving the object up by , $\Delta h=7m$

In our problem, and $g=9.8\frac{m}{s^2}$

Work required to move up an object is going to be:

$W=12kg\cdot9.8\frac{m}{s^2}\cdot7m= 820J$

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Question

How much power does a person with a mass of exert when they climb up 10 meters in 100 seconds?

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

Answer

The equation for power is given by:

$P=\frac{W}{t}$

Where is power, is work and is time.

However, this equation can be simplified even further:

$P = \frac{Fd}{t}$

Since we know that Force is equal to the mass times the acceleration (due to gravity in this scenario):

$P = \frac{ma*d}{t}$

Here we can substitute our known values and solve for power.

$P = \frac{(50kg)(10\frac{m}{s^2})(10m)}{100sec}= 50W$

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Question

Which of the following units best represents power?

Answer

The formula for power is given by:

$P= \frac{W}{t}$

Breaking this formula down to its constituents we can determine the units:

$P = \frac{mad}{t}= \frac{(kg)(\frac{m}{s^2})(m)}{s}= \frac{N\cdot m}{s}$

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Question

A car of mass is accelerated from $10 \frac{m}{s}$ to $35 \frac{m}{s}$ in 2s.

Determine the power output of the car during this time frame.

Answer

Use the definition of work:

Use the definition of power:

$P=\frac{W}{\Delta t}$

$P=\frac{6.2*10^5}{2}$

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Question

A person of mass is riding a ferris wheel of radius . The wheel is spinning at a constant angular velocity of . Determine the average power experienced by the rider during their ascent.

Answer

If the radius is , then the height gained during the ascent is .

Thus, the gravitational potential energy gained is:

$mgh=PE_{grav}$

$959.820=PE_{grav}$

$18.6kJ=PE_{grav}$

The ascent took $\frac{1}{2}$ of a rotation, thus:

$t=\frac{1 minute}{rotation}\frac{60 seconds}{1 minute}.5rotations$

$t=\30 seconds$

Use the definition of power:

$P=\frac{\Delta E}{\Delta t}$

$P=\frac{18.6kJ}{30 seconds}$

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Question

A cyclist maintains an average velocity of $13.4\ \frac{\text m}{\text s}$ on flat surfaces. In order to overcome air resistance and maintain that velocity, the cyclist must be constantly accelerating at $0.291\ \frac{\text m}{\text s^{2}}$ . If the cyclist has a mass of $81.5\textup{ kg}$ , how much power is being generated by the cyclist?

Answer

To have power, an object needs to have a force and a velocity:

$P = F \cdot v$

$P = \left ( m \cdot a\right ) \cdot v$

The acceleration comes from the air resistance that's trying to constantly decelerate the cyclist, and the velocity is the speed the cyclist is maintaining:

$P = \left ( 81.5kg \cdot .291\frac{m}{s^{2}}\right ) \cdot 13.4\frac{m}{s}$

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Question

A spaceship of mass accelerates from $0\frac{m}{s}$ to $\15\frac{m}{s}$ in . Determine the average power of the engine during this timeframe.

Answer

Calculate work:

Only kinetic energy involved:

Plug in values:

Definition of power:

$Power=\frac{Work}{time}$

Plug in values:

$Power=\frac{8.4*10^5}{2.5s}$

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Question

A car of mass goes from to $100\frac{km}{hr}$ in . Estimate the power of the engine.

Answer

Power is defined as:

$Power=\frac{Work}{time}$

Calculate work, with only kinetic energy involved:

Convert $\frac{km}{hr}$ to $\frac{m}{s}$ :

$\frac{100km}{hr}\frac{1000m}{1km}\frac{1 hr}{3600 s}=27.8\frac{km}{hr}$

$\frac{0km}{hr}\frac{1000m}{1km}\frac{1 hr}{3600 s}=0\frac{km}{hr}$

Plug in values:

Plugging in values:

$Power=\frac{5.4*10^5}{7s}$

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Question

A car goes from $0\frac{m}{s}$ to $45\frac{m}{s}$ in . Estimate how long it would take the car to accelerate to $60\frac{m}{s}$ , assuming the same engine power.

Answer

Definition of power:

$J=\frac{W}{\Delta t}$

Definition of work:

Since all energy in this case is kinetic:

Initial velocity is zero:

Combine equations:

$J=\frac{.5mv_f^2}{\Delta t}$

Plugg in values for both final velocities and solve for the change in time:

$J=\frac{.5150045^2}{4.5}=\frac{.5150060^2}{\Delta t}$

$\Delta t = 8s$

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Question

A car goes from $0\frac{m}{s}$ to $45\frac{m}{s}$ in . Estimate how long it would take the same engine to accelerate a truck to the same velocity, assuming the same engine power.

Answer

Definition of power:

$J=\frac{W}{\Delta t}$

Definition of work:

Since all energy in this case is kinetic:

Initial velocity is zero:

Combine equations:

$J=\frac{.5mv_f^2}{\Delta t}$

Plug in values for both vehicles and solve for the change in time:

$J=\frac{.5150045^2}{4.5}=\frac{.5250045^2}{\Delta t}$

$\Delta t = 7.5s$

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