IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
UP-0391378
(2009-02-24)
|
등록번호 |
US-7752857
(2010-08-02)
|
우선권정보 |
JP-2003-398271(2003-11-28) |
발명자
/ 주소 |
- Wakamoto, Shinichi
- Kouda, Toshihide
- Sugihara, Masahiro
- Unezaki, Fumitake
- Kakuta, Masayuki
|
출원인 / 주소 |
- Mitsubishi Denki Kabushiki Kaisha
|
대리인 / 주소 |
Leydig, Voit & Mayer, Ltd.
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
9 |
초록
▼
A refrigerator has a coolant cooler for cooling a coolant at the entrance of a flow control valve, when the cooling amount in the coolant cooler is deficient as well as excessive. The refrigerator includes a compressor for compressing the coolant, a radiator for radiating heat from the coolant, a co
A refrigerator has a coolant cooler for cooling a coolant at the entrance of a flow control valve, when the cooling amount in the coolant cooler is deficient as well as excessive. The refrigerator includes a compressor for compressing the coolant, a radiator for radiating heat from the coolant, a coolant cooler for cooling the coolant, a flow control valve for regulating the flow volume of the coolant, an evaporator for evaporating the coolant, and a heat-exchange-amount control for controlling the amount of heat exchanged in the coolant cooler. The coolant is circulated through the compressor, the radiator, the coolant cooler, the flow control valve, and the evaporator, in that sequence.
대표청구항
▼
What is claimed is: 1. A refrigerator comprising: a first compressor for compressing carbon dioxide as a first coolant; a first radiator for radiating heat from the first coolant; a first flow control valve for regulating flow volume of the first coolant; a first evaporator for evaporating the firs
What is claimed is: 1. A refrigerator comprising: a first compressor for compressing carbon dioxide as a first coolant; a first radiator for radiating heat from the first coolant; a first flow control valve for regulating flow volume of the first coolant; a first evaporator for evaporating the first coolant; coolant cooling means for cooling the first coolant and including a second compressor for compressing a second coolant, the second coolant having an energy consumption efficiency higher than that of the first coolant, a condenser for radiating heat from the second coolant, a second flow control valve for regulating flow volume of the second coolant, and a second evaporator for evaporating, with heat from the first coolant, the second coolant; heat-exchange-amount control means for controlling quantity of heat exchanged in the coolant cooling means so that a coefficient of performance (COP) value is obtained, in which the difference between the COP value and the maximum COP value obtained when the quantity of heat exchanged in the coolant cooling means is varied under predetermined operational conditions, is within a first predetermined range, wherein the first coolant is circulated through the first compressor, the first radiator, the coolant cooling means, the first flow control valve, and the first evaporator, in that sequence, the second coolant is circulated through the second compressor, the condenser, the second flow control valve, and the second evaporator, in that sequence, and the second coolant, in a second refrigeration cycle, has a cooling capacity in a range of from about one-tenth to about one-fifth of cooling capacity of the first coolant in a first refrigeration cycle. 2. The refrigerator as claimed in claim 1, further comprising: first temperature-measuring means for measuring first flow-control-valve entrance temperature as temperature of the first coolant entering the first flow control valve, wherein the heat-exchange-amount control means includes: flow-control-valve-entrance-temperature control-range determination means for determining control range of the first flow-control-valve entrance temperature, so that the COP value is obtained, in which the difference between the COP value and the maximum COP value obtained when the first flow-control-valve entrance temperature is varied under predetermined operational conditions is within a second predetermined range; and control means for controlling flow volume of the second coolant flowing in the coolant cooling means, so that the temperature of the first coolant measured by the second temperature-measuring means is within the control range. 3. The refrigerator as claimed in claim 1, further comprising: first temperature-measuring means for measuring coolant temperature of the first coolant exiting the first radiator, wherein the heat-exchange-amount control means includes: flow-control-valve-entrance-temperature estimation means for estimating, from the coolant temperature measured by the first temperature-measuring means and the quantity of heat exchanged in the coolant cooling means, temperature of the first coolant entering the first flow control valve as first flow-control-valve entrance temperature; flow-control-valve-entrance-temperature control-range determination means for determining control range of the first flow-control-valve entrance temperature, so that the COP value is obtained, in which the difference between the COP value and the maximum COP value, obtained when the first flow-control-valve entrance temperature is varied under predetermined operational conditions, is within a predetermined range; and control means for controlling flow volume of the second coolant flowing in the coolant cooling means, so that the first flow-control-valve entrance temperature estimated by the flow-control-valve-entrance-temperature estimation means is within the control range. 4. The refrigerator as claimed in claim 2, further comprising at least one of pressure-measuring means for measuring pressure of the first coolant between exiting the first flow control valve and entering the first evaporator, and second temperature-measuring means for measuring temperature of the first coolant exiting the first flow control valve, wherein the flow-control-valve-entrance-temperature control-range determination means determines control range of the temperature of the first coolant entering the first flow control valve, using the pressure of the first coolant measured by the pressure-measuring means or the temperature of the first coolant measured by the second temperature-measuring means. 5. The refrigerator as claimed in claim 2, further comprising pressure-measuring means for measuring pressure of the first coolant between exiting the first radiator and entering the first flow control valve, wherein the flow-control-valve-entrance-temperature control-range determination means determines control range of the temperature of the first coolant entering the first flow control valve, using the pressure of the first coolant measured by the pressure-measuring means. 6. The refrigerator as claimed in claim 3, further comprising at least one of pressure-measuring means for measuring pressure of the first coolant between exiting the first flow control valve and entering the first evaporator, and second temperature-measuring means for measuring temperature of the first coolant exiting the first flow control valve, wherein the flow-control-valve-entrance-temperature control-range determination means determines a control range of the temperature of the first coolant entering the first flow control valve, using the pressure of the first coolant measured by the pressure-measuring means or the temperature of the first coolant measured by the second temperature-measuring means. 7. The refrigerator as claimed in claim 3, further comprising pressure-measuring means for measuring pressure of the first coolant between exiting the first radiator and entering the first flow control valve, wherein the flow-control-valve-entrance-temperature control-range determination means determines a control range of the temperature of the first coolant entering the first flow control valve, using the pressure of the first coolant measured by the pressure-measuring means. 8. An air conditioner comprising: a first compressor for compressing carbon dioxide as a first coolant; a first four-way valve for switching direction in which the first coolant output from the first compressor flows; an outdoor heat exchanger for exchanging heat between the first coolant and outdoor air; a first flow control valve for regulating flow volume of the first coolant; and an indoor heat exchanger for exchanging heat between the first coolant and indoor air; coolant cooling/heating means for cooling and heating the first coolant, wherein the coolant cooling/heating means includes a second compressor for compressing a second coolant, the second coolant having an energy consumption efficiency higher than that of the first coolant, a second four-way valve for switching direction in which the second coolant output from the second compressor flows, a first heat exchanger for exchanging heat between the second coolant and outdoor air, a second flow control valve for regulating flow volume of the second coolant, and a second heat exchanger for exchanging heat between the first coolant and the second coolant; heat-exchange-amount control means for controlling quantity of heat exchanged in the coolant cooling/heating means so that a coefficient of performance (COP) value is obtained, in which the difference between the COP value and the maximum COP value obtained when the quantity of heat exchanged in the coolant cooling/heating means is varied under predetermined operational conditions, is within a first predetermined range, wherein when the air conditioner is being operated for cooling, the first coolant is circulated through the first compressor, the outdoor heat exchanger, the coolant cooling/heating means, the first flow control valve, and the indoor heat exchanger, in that sequence, and the second coolant is circulated through the second compressor, the second heat exchanger, the second flow control valve, and the first heat exchanger, in that sequence, when the air conditioner is being operated for warming, the first coolant is circulated through the first compressor, the indoor heat exchanger, the first flow control valve, the coolant cooling/heating means, and the outdoor heat exchanger, in that sequence, and the second coolant is circulated through the second compressor, the second heat exchanger, the second flow control valve, and the first heat exchanger, in that sequence, and the second coolant, in a second refrigeration cycle, has a cooling capacity in a range of from about one-tenth to about one-fifth of cooling capacity of the first coolant in a first refrigeration cycle. 9. A refrigerator comprising: a first compressor for compressing carbon dioxide as a first coolant; a first radiator for radiating heat from the first coolant; a first flow control valve for regulating flow volume of the first coolant; a first evaporator for evaporating the first coolant; coolant cooling means for cooling the first coolant and including a second compressor for compressing a second coolant, the second coolant having an energy consumption efficiency higher than that of the first coolant, a condenser for radiating heat from the second coolant, a second flow control valve for regulating flow volume of the second coolant, and a second evaporator for evaporating, with heat from the first coolant, the second coolant; heat-exchange-amount control means for controlling quantity of heat exchanged in the coolant cooling means, wherein the first coolant is circulated through the first compressor, the first radiator, the coolant cooling means, the first flow control valve, and the first evaporator, in that sequence, the second coolant is circulated through the second compressor, the condenser, the second flow control valve, and the second evaporator, in that sequence, and the second coolant, in a second refrigeration cycle, has a cooling capacity in a range of from about one-tenth to about one-fifth of cooling capacity of the first coolant in a first refrigeration cycle; and first temperature-measuring means for measuring coolant temperature of the first coolant exiting the first radiator, the heat-exchange-amount control means further including: flow-control-valve-entrance-temperature estimation means for estimating, from the coolant temperature measured by the first temperature-measuring means and the quantity of heat exchanged in the coolant cooling means, temperature of the first coolant entering the first flow control valve as first flow-control-valve entrance temperature, flow-control-valve-entrance-temperature control-range determination means for determining control range of the first flow-control-valve entrance temperature, so that a coefficient of performance (COP) value is obtained, in which the difference between the COP value and the maximum COP value, obtained when the first flow-control-valve entrance temperature is varied under predetermined operational conditions, is within a predetermined range, and control means for controlling flow volume of the second coolant flowing in the coolant cooling means, so that the first flow-control-valve entrance temperature estimated by the flow-control-valve-entrance-temperature estimation means is within the control range. 10. The refrigerator as claimed in claim 9, further comprising at least one of pressure-measuring means for measuring pressure of the first coolant between exiting the first flow control valve and entering the first evaporator, and second temperature-measuring means for measuring temperature of the first coolant exiting the first flow control valve, wherein the flow-control-valve-entrance-temperature control-range determination means determines a control range of the temperature of the first coolant entering the first flow control valve, using the pressure of the first coolant measured by the pressure-measuring means or the temperature of the first coolant measured by the second temperature-measuring means. 11. The refrigerator as claimed in claim 9, further comprising pressure-measuring means for measuring pressure of the first coolant between exiting the first radiator and entering the first flow control valve, wherein the flow-control-valve-entrance-temperature control-range determination means determines a control range of the temperature of the first coolant entering the first flow control valve, using the pressure of the first coolant measured by the pressure-measuring means.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.