Reverse Piezoelectric Effect - how much?

AI Thread Summary
The reverse piezoelectric effect allows for deformation of materials when a direct current (DC) voltage is applied, while alternating current (AC) causes vibration. The degree of deformation is controllable and repeatable, but the effect may diminish over time due to material fatigue. Induction and moving magnetic fields do not activate the reverse piezoelectric effect. Coating a thin piece of metal with a piezoelectric material can indeed result in bending the metal when electricity is applied, as metals themselves do not exhibit piezoelectric properties. For further information, research on piezoelectric cantilevers is recommended.
tarnishd
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Hello Everyone,

Thank you for the help! I'm trying to better understand the reverse piezoelectric effect. More specifically what the reaction of the material would be with an applied energy.

Is there deformation or just vibration?
Is it controllable?
Is it repeatable?
Does it diminish over time?
Can it be activated by induction?
Moving magnetic field?

Let's say for example I coat one side of a thin piece of metal with a piezoelectric material. Apply some electricity, would it be possible to bend the metal? (Assume the metal is very thin/flexible).

Also any sources that are on this specific topic would be greatly appreciated. Even papers in journals and the sort would be great. Thanks again,

Thanks,

-T
 
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tarnishd said:
Hello Everyone,

Thank you for the help! I'm trying to better understand the reverse piezoelectric effect. More specifically what the reaction of the material would be with an applied energy.

Is there deformation or just vibration?
Is it controllable?
Is it repeatable?
Does it diminish over time?
Can it be activated by induction?
Moving magnetic field?

Let's say for example I coat one side of a thin piece of metal with a piezoelectric material. Apply some electricity, would it be possible to bend the metal? (Assume the metal is very thin/flexible).

Also any sources that are on this specific topic would be greatly appreciated. Even papers in journals and the sort would be great. Thanks again,

Thanks,

-T

You can check out the datasheets for various piezo film products, to get an idea for their capabilities. I googled piezo film, and got lots of good hits. Here's the first hit, for a manufacturer of piezo film sensors:

http://www.meas-spec.com/piezo-film-sensors.aspx

.
 
tarnishd said:
Hello Everyone,

Thank you for the help! I'm trying to better understand the reverse piezoelectric effect. More specifically what the reaction of the material would be with an applied energy.

Is there deformation or just vibration?
Is it controllable?
Is it repeatable?
Does it diminish over time?
Can it be activated by induction?
Moving magnetic field?

Let's say for example I coat one side of a thin piece of metal with a piezoelectric material. Apply some electricity, would it be possible to bend the metal? (Assume the metal is very thin/flexible).

Also any sources that are on this specific topic would be greatly appreciated. Even papers in journals and the sort would be great. Thanks again,

Thanks,

-T

Is there deformation or just vibration? ***Deformation under DC voltage. Vibration under AC.
Is it controllable? ***degree of deformation depends upon the value of input voltage.
Is it repeatable? ***Yes.
Does it diminish over time? ***The amount of deformation will hold as long as the voltage is on. There is fatigue over time.
Can it be activated by induction? ***No.
Moving magnetic field? ***No.

Also, for the example you gave, yes, you can bend the metal that way because metals are not piezoelectric (thus no reverse piezoelectric effect for them). Google "piezoelectric cantilevers" and you will find tons of info on that.
 

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