Organic rankine cycle with flooded expansion and internal regeneration
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01K-025/06
F01K-025/08
F01K-025/00
F03G-007/00
출원번호
US-0180426
(2011-07-11)
등록번호
US-8667797
(2014-03-11)
발명자
/ 주소
Woodland, Brandon Jay
Braun, James E.
Groll, Eckhard A.
Horton, W. Travis
출원인 / 주소
Purdue Research Foundation
대리인 / 주소
Hartman Global IP Law
인용정보
피인용 횟수 :
0인용 특허 :
4
초록▼
A heat engine system configured to extract thermal energy from a heat source, convert a first portion of the thermal energy to work using an expansion device, and reject a second portion of the thermal energy to a heat sink. The system utilizes a second fluid to inhibit a temperature drop of the fir
A heat engine system configured to extract thermal energy from a heat source, convert a first portion of the thermal energy to work using an expansion device, and reject a second portion of the thermal energy to a heat sink. The system utilizes a second fluid to inhibit a temperature drop of the first fluid within the expansion device.
대표청구항▼
1. A heat engine system comprising: a first pump operable to pump a first fluid from an inlet to an outlet thereof;a regenerator having first and second inlets and first and second outlets, the first inlet being fluidically coupled to the outlet of the first pump and to the first outlet of the regen
1. A heat engine system comprising: a first pump operable to pump a first fluid from an inlet to an outlet thereof;a regenerator having first and second inlets and first and second outlets, the first inlet being fluidically coupled to the outlet of the first pump and to the first outlet of the regenerator, the second inlet being fluidically coupled to the second outlet of the regenerator;a heat source fluidically coupled to the first outlet of the regenerator and in thermal communication with the first fluid after exiting the regenerator through the first outlet thereof;a mixer having an outlet and first and second inlets, the first inlet receiving the first fluid from the heat source;a second pump operable to pump a second fluid from an inlet to an outlet thereof, the outlet of the second pump being fluidically coupled to the heat source to deliver the second fluid into thermal communication with the heat source, the outlet of the second pump being further fluidically coupled to the second inlet of the mixer so that the first and second fluids are mixed and brought into thermal communication by the mixer as a fluid mixture after the first and second fluids are in thermal communication with the heat source;an expansion device having an inlet fluidically coupled to the outlet of the mixer, the expansion device further having an outlet through which the fluid mixture exits the expansion device;a separator having an inlet and first and second outlets, the inlet of the separator receiving the fluid mixture from the outlet of the expansion device, the separator being operable to separate the first fluid from the second fluid and cause the first and second fluids to exit the separator through the first and second outlets, respectively, thereof, the first outlet of the separator being fluidically coupled with the second inlet of the regenerator and the second outlet of the separator being fluidically coupled with the inlet of the second pump; anda heat sink fluidically coupled to the second outlet of the regenerator and in thermal communication with the first fluid after exiting the regenerator through the second outlet thereof, the inlet of the first pump being fluidically coupled to the heat sink to receive the first fluid from the heat sink. 2. The heat engine system of claim 1, further comprising means for recovering work from the expansion device. 3. The heat engine system of claim 2, wherein the work-recovering means is connected for delivering power to at least one of the first and second pumps. 4. The heat engine system of claim 1, wherein the first fluid follows a Rankine thermodynamic cycle within the heat engine system. 5. The heat engine system of claim 1, wherein the second fluid has a higher heat capacity than the first fluid. 6. The heat engine system of claim 1, wherein the first fluid is a liquid refrigerant. 7. The heat engine system of claim 1, wherein the second fluid is chosen from the group consisting of water and oils. 8. The heat engine system of claim 1, wherein the heat source is a waste heat stream or a geothermal temperature source. 9. A method of using the heat engine system of claim 1 to extract thermal energy from the heat source, convert a first portion of the thermal energy to work using the expansion device, and reject a second portion of the thermal energy to the heat sink, the method comprising using the second fluid to inhibit a temperature drop of the first fluid within the expansion device. 10. A heat engine system comprising: a first fluid comprising a liquid refrigerant;a second fluid that remains in a subcooled liquid state within the heat engine system, the second fluid having a higher heat capacity than the first fluid;a first pump operable to pump the first fluid from an inlet to an outlet thereof, the first liquid entering the inlet in a liquid state;a regenerator having first and second inlets and first and second outlets, the first inlet being fluidically coupled to the outlet of the first pump and to the first outlet of the regenerator, the second inlet being fluidically coupled to the second outlet of the regenerator, wherein in sequence the first fluid enters the regenerator through the first inlet thereof and flows through the regenerator to exit the regenerator at the first outlet thereof and subsequently the first fluid enters the regenerator through the second inlet thereof and flows through the regenerator to exit the regenerator at the second first outlet thereof;a heat source fluidically coupled to the first outlet of the regenerator and in thermal communication with the first fluid after exiting the regenerator through the first outlet thereof, the heat source operating to at least partially evaporate the first fluid;a mixer having an outlet and first and second inlets, the first inlet receiving the first fluid from the heat source;a second pump operable to pump the second fluid from an inlet to an outlet thereof, the outlet of the second pump being fluidically coupled to the heat source to deliver the second fluid into thermal communication with the heat source, the outlet of the second pump being further fluidically coupled to the second inlet of the mixer so that the first and second fluids are mixed and brought into thermal communication by the mixer as a fluid mixture after the first and second fluids are in thermal communication with the heat source;an expansion device having an inlet fluidically coupled to the outlet of the mixer, the second fluid and the subcooled liquid state thereof inhibiting a temperature drop of the first fluid during expansion of the first fluid within the expansion device and prior to the first fluid entering the regenerator through the second inlet thereof, the expansion device further having an outlet through which the fluid mixture exits the expansion device;a separator having an inlet and first and second outlets, the inlet of the separator receiving the fluid mixture from the outlet of the expansion device, the separator being operable to separate the first fluid from the second fluid and cause the first and second fluids to exit the separator through the first and second outlets, respectively, thereof, the first outlet of the separator being fluidically coupled with the second inlet of the regenerator and the second outlet of the separator being fluidically coupled with the inlet of the second pump; anda heat sink fluidically coupled to the second outlet of the regenerator and in thermal communication with the first fluid after exiting the regenerator through the second outlet thereof, the heat sink operating to return the first fluid to a liquid state, the inlet of the first pump being fluidically coupled to the heat sink to receive the first fluid from the heat sink. 11. The heat engine system of claim 10, further comprising means for recovering work from the expansion device. 12. The heat engine system of claim 11, wherein the work-recovering means is connected for delivering power to at least one of the first and second pumps. 13. The heat engine system of claim 10, wherein the first fluid follows a Rankine thermodynamic cycle within the heat engine system. 14. The heat engine system of claim 10, wherein the first fluid comprises at least one of R245fa, R717, R600a, n-Pentane and R245fa. 15. The heat engine system of claim 10, wherein the second fluid is chosen from the group consisting of water and oils. 16. The heat engine system of claim 10, wherein the heat source is a waste heat stream or a geothermal temperature source. 17. A method of using the heat engine system of claim 10 to extract thermal energy from the heat source, convert a first portion of the thermal energy to work using the expansion device, and reject a second portion of the thermal energy to the heat sink, the method comprising using the second fluid to inhibit the temperature drop of the first fluid during expansion of the first fluid within the expansion device and prior to the first fluid entering the regenerator through the second inlet thereof.
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이 특허에 인용된 특허 (4)
Ignatiev, Kirill; Caillat, Jean-Luc M, Injection system and method for refrigeration system compressor.
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