IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0763705
(2010-04-20)
|
등록번호 |
US-8371129
(2013-02-12)
|
발명자
/ 주소 |
|
출원인 / 주소 |
- King Abdul Aziz City for Science and Technology (KACST)
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
4 |
초록
▼
A standing wave thermoacoustic piezoelectric apparatus capable of generating electrical energy from heat energy is provided. The standing wave thermoacoustic piezoelectric apparatus includes a housing, a porous stack and a piezoelectric bimorph. The housing comprises a compressible fluid and has a f
A standing wave thermoacoustic piezoelectric apparatus capable of generating electrical energy from heat energy is provided. The standing wave thermoacoustic piezoelectric apparatus includes a housing, a porous stack and a piezoelectric bimorph. The housing comprises a compressible fluid and has a first portion and a second portion. The second portion receives the heat energy from a heat source for creating a temperature gradient between the first portion and the second portion. A cold heat exchanger within the first portion is positioned at one end of the porous stack. The compressible fluid traverses between the first portion and the second portion through the porous stack to generate standing acoustic waves for generating acoustic energy. The piezoelectric bimorph positioned at an end of the first portion opposite to an end of the first portion having the cold heat exchanger, oscillates based on the acoustic energy for generating the electrical energy.
대표청구항
▼
1. A standing wave thermoacoustic piezoelectric apparatus for generating electrical energy from heat energy, the standing wave thermoacoustic piezoelectric apparatus comprising: a housing comprising a compressible fluid, the housing having a first portion and a second portion, wherein the second por
1. A standing wave thermoacoustic piezoelectric apparatus for generating electrical energy from heat energy, the standing wave thermoacoustic piezoelectric apparatus comprising: a housing comprising a compressible fluid, the housing having a first portion and a second portion, wherein the second portion receives the heat energy from a heat source for creating a temperature gradient between the second portion and the first portion of the housing, the first portion comprising a cold heat exchanger;a porous stack configured within the housing, the porous stack having the cold heat exchanger positioned at one end, whereby the compressible fluid traverses between the first portion and the second portion through the porous stack to generate standing acoustic waves for generating acoustic energy in the first portion; anda piezoelectric bimorph configured at an end of the first portion opposite to an end of the first portion having the cold heat exchanger, wherein the piezoelectric bimorph is capable of oscillating based on the acoustic energy, the oscillation of the piezoelectric bimorph is utilized for generating the electrical energy. 2. The standing wave thermoacoustic piezoelectric apparatus of claim 1, wherein the heat energy supplied by the heat source to the second portion is varied based on a heat threshold to generate the standing acoustic waves in the first portion of the housing, the heat threshold is associated with an amount of heat required for generating the standing acoustic waves. 3. The standing wave thermoacoustic piezoelectric apparatus of claim 2, wherein temperature of the second portion is varied by changing the area of the second portion exposed to the heat source. 4. The standing wave thermoacoustic piezoelectric apparatus of claim 1 further comprising: a hot heat exchanger configured within the housing, the hot heat exchanger positioned at an end of the porous stack opposite to an end of the porous stack having the cold heat exchanger, wherein the hot heat exchanger receives the heat energy from the heat source for creating the temperature gradient. 5. The standing wave thermoacoustic piezoelectric apparatus of claim 4, wherein temperature of the second portion is varied by changing the area of the hot heat exchanger exposed to the heat source. 6. The standing wave thermoacoustic piezoelectric apparatus of claim 4, wherein temperature associated with the hot heat exchanger is varied to generate the standing acoustic waves in the first portion of the housing. 7. The standing wave thermoacoustic piezoelectric apparatus of claim 1, wherein temperature associated with the cold heat exchanger is varied to generate the standing acoustic waves in the first portion of the housing. 8. The standing wave thermoacoustic piezoelectric apparatus of claim 1, wherein temperature of the compressible fluid is varied to generate the standing acoustic waves in the first portion of the housing. 9. The standing wave thermoacoustic piezoelectric apparatus of claim 1, wherein the porous stack comprises at least one of metal foils, a metal mesh, a sheet of a foamed metal, and sheets of filter paper. 10. The standing wave thermoacoustic piezoelectric apparatus of claim 1, wherein the compressible fluid is one of air and helium. 11. The standing wave thermoacoustic piezoelectric apparatus of claim 1, wherein a configuration of the first portion of the housing is one of a straight configuration and an optimally shaped configuration. 12. The standing wave thermoacoustic piezoelectric apparatus of claim 1, wherein a configuration of the second portion of the housing is one of a straight configuration and an optimally shaped configuration. 13. A standing wave thermoacoustic piezoelectric system for generating electrical energy from heat energy, wherein the standing wave thermoacoustic piezoelectric system comprises: a solar concentrator configured to supply the heat energy for generating the electrical energy; anda standing wave thermoacoustic piezoelectric apparatus comprising,a housing having a first portion and a second portion, wherein the housing comprises a compressible fluid, wherein the second portion receives the heat energy from the solar concentrator for creating a temperature gradient between the second portion and the first portion of the housing, the first portion comprising a cold heat exchanger;a porous stack configured within the housing, the porous stack having the cold heat exchanger positioned at one end, whereby the compressible fluid traverses between the first portion and the second portion through the porous stack to generate standing acoustic waves for generating acoustic energy in the first portion, anda piezoelectric bimorph configured at an end of the first portion opposite to an end of the first portion having the cold heat exchanger, wherein the piezoelectric bimorph is capable of oscillating based on the acoustic energy, the oscillation of the piezoelectric bimorph is utilized for generating the electrical energy. 14. The standing wave thermoacoustic piezoelectric system of claim 13, wherein the heat energy supplied by the solar concentrator to the second portion is varied based on a heat threshold to generate the standing acoustic waves in the first portion of the housing, the heat threshold is associated with an amount of heat energy required for generating the standing acoustic waves. 15. The standing wave thermoacoustic piezoelectric system of claim 14, wherein temperature of the second portion is varied by changing the area of the second portion exposed to the solar concentrator. 16. The standing wave thermoacoustic piezoelectric system of claim 13 further comprising: a hot heat exchanger configured within the housing, the hot heat exchanger positioned at an end of the porous stack opposite to an end of the porous stack having the cold heat exchanger, wherein the hot heat exchanger receives the heat energy from the heat source for creating the temperature gradient. 17. The standing wave thermoacoustic piezoelectric system of claim 16, wherein temperature of the second portion is varied by changing the area of the hot heat exchanger exposed to the heat source. 18. The standing wave thermoacoustic piezoelectric system of claim 16, wherein temperature associated with the hot heat exchanger is varied to generate the standing acoustic waves in the first portion of the housing. 19. The standing wave thermoacoustic piezoelectric system of claim 13, wherein temperature associated with the cold heat exchanger is varied to generate the standing acoustic waves in the first portion of the housing. 20. The standing wave thermoacoustic piezoelectric system of claim 13, wherein temperature of the compressible fluid is varied to generate the standing acoustic waves in the first portion of the housing. 21. The standing wave thermoacoustic piezoelectric system of claim 13, wherein the porous stack comprises at least one of metal foils, a metal mesh, a sheet of a foamed metal, and sheets of filter paper. 22. The standing wave thermoacoustic piezoelectric system of claim 13, wherein the compressible fluid is one of air and helium. 23. The standing wave thermoacoustic piezoelectric system of claim 13, wherein a configuration of the first portion of the housing is one of a straight configuration and an optimally shaped configuration. 24. The standing wave thermoacoustic piezoelectric system of claim 13, wherein a configuration of the second portion of the housing is one of a straight configuration and an optimally shaped configuration.
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