How to Calculate Potential Energy and Power Output of a Falling Mass

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To calculate the potential energy given up by a 5.5 kg mass dropped 2.0 m, use the formula mgh, resulting in 107.8 J. The power output can be determined by dividing the energy change by the time interval, yielding approximately 26.95 W. If this power output is maintained for 24 hours, the energy produced is calculated by multiplying the power by time, resulting in 646.8 kWh, although this figure needs to be adjusted to kilowatts for accuracy. The final energy output should be corrected to reflect the conversion from watts to kilowatts. Understanding these calculations is essential for solving similar physics problems effectively.
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If anyone could help me with my homework I would GREATLY appreciate it. I am totally lost. There are 2 questions. If you could tell me what/how to do it, I'd be happy to do it. I just need to know how. Thanks so much

Here is question 2:

A 5.5 kg mass is dropped at a constant velocity thru a vertical displacement of 2.0 m over a time interval of 4.0 seconds.

How much potential energy (joule) has it given up?
What is the power (watt) output?

If that power output was kept up for 24 hours how many kWhr of energy would be produced?
 
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"How much potential energy (joule) has it given up?"

Gravitational potential energy is equal to mgh, so the change is \ mg \Delta\ h.

"What is the power (watt) output?"

The power is the time rate of change in energy. Since the forces are constant throughout the process, this can be found by dividing the total energy change by the length of time.

"If that power output was kept up for 24 hours how many kWhr of energy would be produced?"

This is just multiplying the power output by the time, but paying attention to units.
 
LeonhardEuler said:
"How much potential energy (joule) has it given up?"

Gravitational potential energy is equal to mgh, so the change is \ mg \Delta\ h.

"What is the power (watt) output?"

The power is the time rate of change in energy. Since the forces are constant throughout the process, this can be found by dividing the total energy change by the length of time.

"If that power output was kept up for 24 hours how many kWhr of energy would be produced?"

This is just multiplying the power output by the time, but paying attention to units.


Ok, based on what you are telling me I came up with:
How much potential energy (joule) has it given up? = 107.8 J
What is the power (watt) output? = 26.95 W
If that power output was kept up for 24 hours how many kWhr of energy would be produced? = 646.8 kWh

Am I doing it correctly?
 
Pretty much correct, but you didn't switch to kilowatts, so your last answer is off by a factor of 1000.
 
LeonhardEuler said:
Pretty much correct, but you didn't switch to kilowatts, so your last answer is off by a factor of 1000.


Thank you, I did forget to do that.
 

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