Refrigeration circuit, gas-liquid separator and heating and cooling system
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F25B-043/00
F25B-029/00
F25B-006/02
F25B-041/04
F25B-007/00
F25B-040/04
출원번호
US-0130759
(2011-07-05)
등록번호
US-9500395
(2016-11-22)
국제출원번호
PCT/EP2011/061310
(2011-07-05)
§371/§102 date
20140103
(20140103)
국제공개번호
WO2013/004298
(2013-01-10)
발명자
/ 주소
Scheumann, Christian
Hellmann, Sascha
출원인 / 주소
CARRIER CORPORATION
대리인 / 주소
Cantor Colburn LLP
인용정보
피인용 횟수 :
0인용 특허 :
5
초록▼
A refrigeration circuit is disclosed circulating a refrigerant and comprising in the direction of flow of the refrigerant a compressor (2); at least one condenser (14, 16) for rejecting heat to ambient air; an expansion device (8); and an evaporator (10). The refrigeration circuit further comprises
A refrigeration circuit is disclosed circulating a refrigerant and comprising in the direction of flow of the refrigerant a compressor (2); at least one condenser (14, 16) for rejecting heat to ambient air; an expansion device (8); and an evaporator (10). The refrigeration circuit further comprises a collecting container (12), the output of which being connected to the expansion device (8); a heat rejecting heat exchanger (4) for heat exchange of the refrigerant to a heat pump system, the output of the heat rejecting heat exchanger (4) being connected to the collecting container (12); and means (V1, V2) for connecting the heat rejecting heat exchanger (4) or at least one of the condenser(s) (14, 16) to the output of the compressor (2) depending on the availability of cooling power at the heat rejecting heat exchanger (4).
대표청구항▼
1. A refrigeration circuit for circulating a refrigerant and comprising in the direction of flow of the refrigerant: a compressor;at least one condenser for rejecting heat to ambient air;an expansion device; andan evaporator;the refrigeration circuit further comprisinga collecting container, the out
1. A refrigeration circuit for circulating a refrigerant and comprising in the direction of flow of the refrigerant: a compressor;at least one condenser for rejecting heat to ambient air;an expansion device; andan evaporator;the refrigeration circuit further comprisinga collecting container, the output of which being connected to the expansion device;a heat rejecting heat exchanger for heat exchange of the refrigerant to a heat pump system, the output of the heat rejecting heat exchanger being connected to the collecting container andat least one valve connecting the heat rejecting heat exchanger or the at least one condenser to the output of the compressor depending on the availability of cooling power at the heat rejecting heat exchanger; anda gas-liquid-separator arranged in a line connecting an output of the heat rejecting heat exchanger to the collecting container, the gas-liquid-separator separating the refrigerant coming from the heat rejecting heat exchanger into a gaseous phase refrigerant portion and liquid phase refrigerant portion and having a gaseous phase output and a liquid phase output. 2. The refrigeration circuit of claim 1, the pressure line of the compressor branching into a first pressure line portion leading to the at least one condenser and into a second pressure line portion leading to the heat rejecting heat exchanger, further comprising a valve arranged in the first pressure line portion being configured to open and close the first pressure line portion and a valve arranged in the second pressure line portion being configured to open and close the second pressure line portion. 3. The refrigeration circuit of claim 2, wherein the valve in the first pressure line portion is configured to be closed when cooling power is available at the heat rejecting heat exchanger and to be opened when no cooling power is available at the heat rejecting heat exchanger. 4. The refrigeration circuit of claim 2, wherein the valve in the second pressure line portion is configured to be opened when cooling power is available at the heat rejecting heat exchanger and to be closed when no cooling power is available at the heat rejecting heat exchanger. 5. The refrigeration circuit of claim 2, wherein at least two condensers are provided being connected in parallel, wherein the first pressure line portion branches into separate line portions for each of the condenser. 6. The refrigeration circuit of claim 5, wherein the at least two condensers being connected in parallel differ in their maximum achievable condensing power. 7. The refrigeration circuit of claim 1, wherein the gas-liquid-separator is provided in the line connecting the output of the heat rejecting heat exchanger to the collecting container, the gas-liquid-separator separating the refrigerant coming from the heat rejecting heat exchanger into a gaseous phase refrigerant portion and liquid phase refrigerant portion and having a gaseous phase output and a liquid phase output. 8. The refrigeration circuit of claim 7, wherein the gaseous phase output of the gas-liquid-separator is selectively connected to the at least one condenser, and/or wherein the liquid phase output of the gas-liquid-separator is connected to the collecting container. 9. The refrigeration circuit of claim 1, further comprising valves for selectively connecting the first pressure line portion or the liquid phase output of the gas-liquid-separator to the at least one condenser. 10. The refrigeration circuit of claim 1, wherein the refrigeration circuit is configured to determine the condensing power needed in order to provide the desired cooling at the evaporator. 11. The refrigeration circuit of claim 10, wherein the refrigeration circuit is configured to measure the condensing power delivered by the heat rejecting heat exchanger. 12. The refrigeration circuit of claim 10, wherein the refrigeration circuit is configured to compare the condensing power needed to the condensing power available through the heat rejecting heat exchanger and the at least one condenser. 13. The refrigeration circuit of claim 12, wherein the refrigeration circuit is configured, in the state when no cooling power is available at the heat rejecting heat exchanger, the valve in the first pressure line portion is opened and the valve in the second pressure line portion is closed, to connect the first pressure line portion to the at least one condenser needed to deliver the condensing power needed. 14. The refrigeration circuit of claim 13, wherein, in the state when no cooling power is available at the heat rejecting heat exchanger, when the valve in the first pressure line portion is opened and when the valve in the second pressure line portion is closed, the refrigeration circuit is configured to connect, by means of valves, the first pressure line portion to a first condenser providing a lower condensing power in case only little condensing power is needed, the first pressure line portion to a second condenser providing a higher condensing power in case more condensing power is needed, and the first pressure line portion to both condensers in case maximum condensing power is needed. 15. The refrigeration circuit of claim 10, wherein, in the state when cooling power is available at the heat rejecting heat exchanger, when the valve in the second pressure line portion is opened and when the valve in the first pressure line portion is closed, the refrigeration circuit is configured to compare the condensing power needed to the condensing power delivered by the heat rejecting heat exchanger in order to obtain the additional condensing power to be delivered by the at least one condenser. 16. The refrigeration circuit of claim 15, wherein, in the state when cooling power is available at the heat rejecting heat exchanger, when the valve in the second pressure line portion is opened and when the valve in the first pressure line portion is closed, the refrigeration circuit is configured to connect the gaseous phase output of the gas-liquid-separator to the at least one condenser needed to deliver the additional condensing power needed. 17. The refrigeration circuit of claim 16, wherein, in the state when cooling power is available at the heat rejecting heat exchanger, when the valve in the second pressure line portion is opened and when the valve in the first pressure line portion is closed, the refrigeration circuit is configured to connect, by means of valves, the gaseous phase output of the gas-liquid-separator to a first condenser providing a lower condensing power in case only little additional condensing power is needed, the gaseous phase output of the gas-liquid-separator to a second condenser providing a higher condensing power in case more additional condensing power is needed, and the gaseous phase output of the gas-liquid-separator to both condensers in case maximum additional condensing power is needed. 18. The refrigeration circuit of claim 17, wherein, in the state when cooling power is available at the heat rejecting heat exchanger, when the valve in the second pressure line portion is opened and when the valve in the first pressure line portion is closed, the refrigeration circuit is configured such that the gaseous phase output of the gas-liquid-separator is disconnected, by means of valves, from any of the condenser, in case no additional condensing power is needed. 19. A gas-liquid-separator, for use in a refrigeration circuit, the gas-liquid-separator connected to an inlet line in which refrigerant comprising a gaseous phase and a liquid phase flows, the gas-liquid-separator comprising: a broadened line portion having a larger diameter than the inlet line and being connected to the inlet line extending in the same direction as the inlet line in which refrigerant comprising a gaseous phase and a liquid phase flows, wherein the velocity of flow of the refrigerant is reduced in the broadened line portion, such that the liquid phase refrigerant flows at the bottom and the gaseous phase refrigerant flows above the liquid phase refrigerant; anda T-branch, with the first branch to be connected to a gaseous refrigerant output line and the second branch to be connected to a liquid refrigerant output line, wherein the branches of the T-branch are arranged basically rectangularly to the inlet line and to the broadened line portion. 20. The gas-liquid-separator of claim 19, wherein the first branch of the T-branch to be connected to a gaseous refrigerant output line extends in an upwards direction and the second branch of the T-branch to be connected to a liquid refrigerant output line extends in a downwards direction. 21. A heating and cooling system comprising a refrigeration circuit according to claim 1; anda heat-pump system;wherein the first heat rejecting heat exchanger of the refrigeration circuit is configured to serve as a heat source in the heat pump system. 22. The refrigeration circuit of claim 1, wherein the at least one valve comprises two valves.
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