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What is the best way to harvest the energy of sound waves?
Can an mechanical resonance circuit be built to do this?
Perhaps a resonant cavity tube with a piezoelectric device at the end of the tube will work? Or something similar?
Or something I can't imagine?
Thought exercise
Let's say for instance I gave you the job of setting up a sound source in a room. It creates a sum total of 120db audio output with many strong harmonics that range from 1KHz to over 15KHz at 1kHz intervals. There's one twist though. I say to you I want you to recover all of the sound energy this device puts out and convert it to useable electrical energy to be used to power the room's light. You say to me- Convert all? All is a tall task and it's probably impossible. I agree and allow you to recover only what you can.
How much can you recover and what is your method?
At the moment this is only a thought exercise. BUT I do happen to have a sound source that meets the above criteria. It's my pulsed dc motor. I already have a thread talking about that. In this thread I would like input on the sound energy harvesting and conversion aspect of my project.
The sound created by my device is a byproduct of the bearings and coil. Let's assume that both byproducts are unavoidable. Given that... The resultant sound represents energy coming from the system that is currently considered a loss. Naturally I want to harvest the loss, convert it to useable electrical energy and reinvest it.
This is quite new to me but I have made a few mediocre attempts to do this using piezoelectric devices simply taped to the inside of the motor's enclosure. Videos of this can be seen here: First motor piezo test 12-4-11 - YouTube
and here: Second piezo test 12-4-11 and new record 68,000 rpm - YouTube
Video of Db measurement (cheap meter rated only up to 8kz frequency range): P-Motor update and decibel test 120db 12-14-11 - YouTube
Video of spectrum analysis (at the mercy of the camera's microphone's frequency response): Spectrum analysis of audio output at max speed and max piezo output - YouTube
If your solution is a cavity then what are the dimensions and material?
Can you demonstrate the formulas required to properly calculate the cavities dimensions?
Bear in mind that the optimum rpm of the motor has not been established. It has run up to 76,400 rpm which is a frequency of 76,400/60 = 1266.66...Hz. To keep it simple let's work with 1KHz (60,000 rpm).
What are your thoughts?
Jim
Can an mechanical resonance circuit be built to do this?
Perhaps a resonant cavity tube with a piezoelectric device at the end of the tube will work? Or something similar?
Or something I can't imagine?
Thought exercise
Let's say for instance I gave you the job of setting up a sound source in a room. It creates a sum total of 120db audio output with many strong harmonics that range from 1KHz to over 15KHz at 1kHz intervals. There's one twist though. I say to you I want you to recover all of the sound energy this device puts out and convert it to useable electrical energy to be used to power the room's light. You say to me- Convert all? All is a tall task and it's probably impossible. I agree and allow you to recover only what you can.
How much can you recover and what is your method?
At the moment this is only a thought exercise. BUT I do happen to have a sound source that meets the above criteria. It's my pulsed dc motor. I already have a thread talking about that. In this thread I would like input on the sound energy harvesting and conversion aspect of my project.
The sound created by my device is a byproduct of the bearings and coil. Let's assume that both byproducts are unavoidable. Given that... The resultant sound represents energy coming from the system that is currently considered a loss. Naturally I want to harvest the loss, convert it to useable electrical energy and reinvest it.
This is quite new to me but I have made a few mediocre attempts to do this using piezoelectric devices simply taped to the inside of the motor's enclosure. Videos of this can be seen here: First motor piezo test 12-4-11 - YouTube
and here: Second piezo test 12-4-11 and new record 68,000 rpm - YouTube
Video of Db measurement (cheap meter rated only up to 8kz frequency range): P-Motor update and decibel test 120db 12-14-11 - YouTube
Video of spectrum analysis (at the mercy of the camera's microphone's frequency response): Spectrum analysis of audio output at max speed and max piezo output - YouTube
If your solution is a cavity then what are the dimensions and material?
Can you demonstrate the formulas required to properly calculate the cavities dimensions?
Bear in mind that the optimum rpm of the motor has not been established. It has run up to 76,400 rpm which is a frequency of 76,400/60 = 1266.66...Hz. To keep it simple let's work with 1KHz (60,000 rpm).
What are your thoughts?
Jim
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