Power spent to keep a spring compressed

AI Thread Summary
To calculate the power needed to keep a spring compressed, it's essential to understand that while no distance means no work, a constant force is still required, which consumes energy. When using a solenoid, the electrical power needed to maintain the spring's compression can typically be found in the solenoid's data sheet, as calculating it directly can be complex. The power consumption is influenced by the spring's rate constant and the amount of compression required. Additionally, using inefficient methods like keeping a motor engaged can lead to wasted energy as heat. For optimal performance, consider using ideal components, such as superconducting windings, to minimize power loss.
MatheusMazur
Messages
3
Reaction score
2
I was wondering, I have an engine that should keep a spring compressed. How can I calculate the power necessary for this?
The work is Force x Distance, as there is no distance, there is no work, so no power... But obviously to keep the spring compressed the engine will have to produce a constant force and spend energy... So what am I missing?
 
Physics news on Phys.org
You are not missing anything.
If you turn the motor off and lock it into place, it will hold the spring and not consume any power.
 
  • Like
Likes MatheusMazur and Wrichik Basu
But, for example, if the spring is kept compressed by a coil, electricity must be flowing through the coil to keep the pressure, won't it require electrical power to keep producing this constant force?
 
MatheusMazur said:
But, for example, if the spring is kept compressed by a coil, electricity must be flowing through the coil to keep the pressure, won't it require electrical power to keep producing this constant force?
That's just an inefficient was of holding the motor in place. The motor will not move, and the power will go into heating up the motor. If the motor was using superconducting windings and other ideal components, it would hold so long as the power input was kept open (disconnected).
 
  • Like
Likes russ_watters and MatheusMazur
MatheusMazur said:
Got it. This question came to me after observing a spring return solenoid valve. It works with 24V and I wondered how could I calculate the necessary current to keep the spring compressed... Is there a way to calculate it?
It is extremely difficult to calculate. Much simpler to look up the data sheet for the solenoid. The data sheet should say how much power is needed to keep it energized.
 
  • Like
Likes russ_watters and MatheusMazur
anorlunda said:
It is extremely difficult to calculate. Much simpler to look up the data sheet for the solenoid. The data sheet should say how much power is needed to keep it energized.

Thanks!
 
Electrical power going into solenoid is dependent upon force that it is required to push.
This is then dependent upon the spring's rate constant multiplied by compression amount (displacement) needed.

This is similar to how peak-n-hold fuel-injectors work. A larger burst of power is needed to initiate the opening of the injector and open the solenoid fully against spring. Then power is backed down to just enough to keep it in that position for duration of injector pulse.
 

Similar threads

I Work-Energy Theorem for Moving Block and Spring System?
Replies
4
Views
2K
What speed v(t) enables constant power by release compressed spring?
Replies
17
Views
2K
I Is there a list of root-power quantities? Or a rule of thumb?
Replies
14
Views
2K
B The physics of flywheel launchers (like tennis ball shooters)
2
Replies
60
Views
4K
Power Loss in Transmission Lines: AC vs DC Comparison Explained with a Model
2
Replies
50
Views
12K
Calculating Final Positions & Velocities for M1, M2 & Spring After DeltaT
Replies
6
Views
2K
B Why is my experimental spring constant an order of magnitude off?
Replies
4
Views
1K
Distribution of Energy when work is done on a system of 2 masses connected by a spring
Replies
17
Views
1K
I Questions about a spring and its principle
Replies
9
Views
2K
Simulating an elastic bouncy ball
Replies
10
Views
3K

Hot Threads

Recent Insights

Back
Top