A microelectromechanical systems (MEMS) based heat engine capable of converting thermal energy gradients into mechanical or electrical energy, as well as its fabrication process is disclosed. This heat engine design consists of a stressed oscillating beam formed from a shape memory alloy (SMA) thin
A microelectromechanical systems (MEMS) based heat engine capable of converting thermal energy gradients into mechanical or electrical energy, as well as its fabrication process is disclosed. This heat engine design consists of a stressed oscillating beam formed from a shape memory alloy (SMA) thin film. As the temperature of the beam changes, its shape changes due to the phase transformation of the shape memory alloy, causing it to oscillate between a hot source and a cold source. Due to the hysteretic behavior of the phase transformation, the oscillating SMA cantilever beam produces a net mechanical work output that may be either converted to electrical energy or mechanically linked to other MEMS devices.
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What is claimed is: 1. An oscillating shape memory alloy heat engine comprising; an oscillating member wherein said member has a dimension less than 100 microns wherein a first portion of said member comprises a shape memory alloy a heat source a cold source wherein said heat engine has a temperatu
What is claimed is: 1. An oscillating shape memory alloy heat engine comprising; an oscillating member wherein said member has a dimension less than 100 microns wherein a first portion of said member comprises a shape memory alloy a heat source a cold source wherein said heat engine has a temperature gradient between said heat source and said cold source, wherein said temperature gradient is the difference between said heat source and said cold source, wherein said temperature gradient has a heat flow, wherein a portion of said heat flow is converted into mechanical power, wherein said mechanical power portion is a fraction of said heat flow, wherein said mechanical power fraction is proportional to said difference between said heat source and said cold source, wherein said heat engine contains an isolation region, wherein said isolation region reduces said heat flow into said cold source wherein said oscillating member contains at least one thin film wherein said heat source has a distance from said oscillating member, wherein said distance from said oscillating member oscillates when said oscillating member oscillates, wherein said oscillating member has at least a first and a second position, wherein said heat source has a heat source temperature above an austenite transformation temperature for said shape memory alloy, wherein said cold source has a cold source temperature below a martensite transformation temperature for said shape memory alloy, wherein said heat source temperature is capable of transforming the phase of a portion of the shape memory alloy of the oscillating member when in said first position from martensite to austenite thus changing the oscillating member position from said first position to said second position, wherein said cold source temperature is capable of transforming the phase of a portion of the shape memory alloy of the oscillating member when in said second position from austenite to martensite thus changing the oscillating member position from said second position to said first position, wherein said cold source transforming the phase occurs when said heat source is at said heat source temperature, wherein said oscillating member contains a means for converting mechanical energy into electrical energy. 2. The oscillating heat engine of claim 1 wherein; said oscillating member contains a cantilever beam and said oscillating member transfers thermal energy between said heat source and said cold source. 3. The oscillating heat engine of claim 1; wherein said shape memory alloy is Nitinol. 4. The oscillating heat engine of claim 1; wherein said oscillating member has a bi-layer structure, wherein said shape memory alloy has a temperature hysteresis between austenite and martensite phases, wherein said oscillating member oscillates with a heat source temperature variation of less than the shape memory alloy hysteresis. 5. The oscillating heat engine of claim 1 wherein said oscillating member has an externally applied mechanical load. 6. The oscillating heat engine of claim 4 wherein said bi-layer structure has a first layer and a second layer, wherein said first layer has a different thermal expansion coefficient than said second layer. 7. The oscillating heat engine of claim 6 wherein said first portion of said oscillating member is the first layer. 8. The oscillating heat engine of claim 1 wherein said oscillating member is a variable capacitor. 9. The oscillating heat engine of claim 1 wherein said oscillating member has a second portion; wherein said second portion has a magnetic permeability greater than air. 10. The oscillating heat engine of claim 1 wherein said second portion contains iron. 11. The oscillating heat engine of claim 8 wherein said variable capacitor is part of a variable capacitive electrostatic generator. 12. The oscillating heat engine of claim 9 wherein said second member is part of an inductive electrical generator. 13. A method of producing self assembled devices comprising; depositing a first layer on a substrate; depositing a second layer thus forming a shape; wherein said first and second layers have different thermal expansion coefficients; changing temperature of the layers by at least 10 degrees centigrade; wherein said changing of the temperature changes the shape, wherein said shape has a dimension less than 100 microns, wherein said self assembled device is a heat engine by adding, a heat source and a cold source, wherein said heat engine has a temperature gradient between said heat source and said cold source, wherein said temperature gradient is the difference between said heat source and said cold source, wherein said temperature gradient has a heat flow, wherein a portion of said heat flow is converted into mechanical power, wherein said mechanical power portion is a fraction of said heat flow, wherein said mechanical power fraction is proportional to said difference between said heat source and said cold source, wherein said heat engine contains an isolation region, wherein said isolation region reduces said heat flow into said cold source, wherein an oscillating member has at least a first and a second position, wherein said heat source has a distance from said oscillating member, wherein said distance from said oscillating member oscillates when said oscillating member oscillates wherein said heat source has a heat source temperature above the austenite transformation temperature, wherein said cold source has a cold source temperature below the martensite transformation temperature, wherein said heat source temperature is capable of transforming the phase of a portion of the shape memory alloy of the oscillating member when in said first position from martensite to austenite thus changing the oscillating member position from said first position to said second position, wherein said cold source temperature is capable of transforming the phase of a portion of the shape memory alloy of the oscillating member when in said second position from austenite to martensite thus changing the oscillating member position from said second position to said first position, wherein said cold source transforming the phase occurs when said heat source is at said heat source temperature, said heat engine having means for converting mechanical energy into electrical energy. 14. The method as claimed in claim l3; wherein said shape change causes contact with and moves a second device, wherein said second device is a micromirror. 15. The oscillating heat engine of claim 1 wherein said oscillating member has at least a first and a second position, wherein said oscillating member has a first temperature, wherein when said oscillating member at said first position has said first temperature, wherein when said oscillating member at said second position has said first temperature, wherein said heat source has a heat source temperature large enough to change the position of the oscillating member from the first position to the second position, wherein said cold source has a cold source temperature low enough to change the position of the oscillating member from the second position to the first position. 16. The oscillating heat engine of claim 1 wherein said oscillating member has at least a first and a second temperature, wherein said oscillating member has at least a first position, wherein said oscillating member has said first temperature at said first position, wherein said oscillating member has said second temperature at said first position, wherein said heat source has a heat source temperature at or above said first temperature, wherein said cold source has a cold source temperature at or below said second temperature, wherein said oscillating member transfers heat between said heat source and said cold source.
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