Sublimation defrost system and sublimation defrost method for refrigeration apparatus
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F25B-041/00
F25B-047/02
F25D-017/02
F25B-001/10
F25B-007/00
F25D-021/10
F25B-009/00
F25B-041/04
F25B-049/02
F25D-021/12
F25D-021/14
F25B-025/00
F25B-023/00
출원번호
US-0904283
(2014-11-25)
등록번호
US-9863677
(2018-01-09)
우선권정보
JP-2013-259751 (2013-12-17)
국제출원번호
PCT/JP2014/081044
(2014-11-25)
국제공개번호
WO2015/093235
(2015-06-25)
발명자
/ 주소
Yoshikawa, Choiku
Kamimura, Takeshi
Furudate, Takahiro
Fukano, Shuji
출원인 / 주소
MAYEKAWA MFG. CO., LTD.
대리인 / 주소
Rossi, Kimms & McDowell LLP
인용정보
피인용 횟수 :
0인용 특허 :
3
초록▼
A sublimation defrost system for a refrigeration apparatus including: a cooling device in a freezer, and includes a casing containing a heat exchanger pipe; a refrigerating device for cooling and liquefying a CO2 refrigerant; and a refrigerant circuit connected to the heat exchanger pipe permitting
A sublimation defrost system for a refrigeration apparatus including: a cooling device in a freezer, and includes a casing containing a heat exchanger pipe; a refrigerating device for cooling and liquefying a CO2 refrigerant; and a refrigerant circuit connected to the heat exchanger pipe permitting the cooled and liquefied CO2 refrigerant to circulate. The defrost system includes: a dehumidifier device; a CO2 circulation path in the heat exchanger pipe, an on-off valve in the heat exchanger; a circulating unit for the CO2 refrigerant; a first heat exchanger part exchanging heat between a brine as a first heating medium and the circulating CO2 refrigerant; and a pressure adjusting unit for the circulating CO2 refrigerant during defrosting so that a condensing temperature of the CO2 refrigerant becomes equal to or lower than a freezing point of a water vapor in the freezer inner air without a drain receiving unit.
대표청구항▼
1. A sublimation defrost system for a refrigeration apparatus including: a cooling device which is disposed in a freezer, and includes a casing and a heat exchanger pipe disposed in the casing; a refrigerating device for cooling and liquefying a CO2 refrigerant; and a refrigerant circuit which is co
1. A sublimation defrost system for a refrigeration apparatus including: a cooling device which is disposed in a freezer, and includes a casing and a heat exchanger pipe disposed in the casing; a refrigerating device for cooling and liquefying a CO2 refrigerant; and a refrigerant circuit which is connected to the heat exchanger pipe and which is configured to permits the CO2 refrigerant cooled and liquefied in the refrigerating device to circulate to the heat exchanger pipe, the defrost system comprising: a dehumidifier device for dehumidifying freezer inner air in the freezer;a CO2 circulation path which is formed of a circulation path forming path connected to an inlet path and an outlet path of the heat exchanger pipe, and includes the heat exchanger pipe;an on-off valve disposed in each of the inlet path and the outlet path of the heat exchanger pipe and configured to be closed at a time of defrosting so that the CO2 circulation path becomes a closed circuit;a circulating unit for CO2 refrigerant, the circulating unit being disposed in the CO2 circulation path;a first heat exchanger part configured to cause heat exchange between a brine as a first heating medium and the CO2 refrigerant circulating in the CO2 circulation path; anda pressure adjusting unit which adjusts a pressure of the CO2 refrigerant circulating in the closed circuit at the time of defrosting so that a condensing temperature of the CO2 refrigerant becomes equal to or lower than a freezing point of a water vapor in the freezer inner air in the freezer; whereinthe defrosting is able to be achieved without a drain receiving unit. 2. The sublimation defrost system for the refrigeration apparatus according to claim 1, wherein the circulation path forming path is a defrost circuit branched from the inlet path and the outlet path of the heat exchanger pipe, andthe first heat exchanger part is formed in the defrost circuit. 3. The sublimation defrost system for the refrigeration apparatus according to claim 1, wherein the circulation path forming path is a bypass path disposed between the inlet path and the outlet path of the heat exchanger pipe, andthe first heat exchanger part is formed in a partial area of the heat exchanger pipe. 4. The sublimation defrost system for the refrigeration apparatus according to claim 1, wherein the CO2 circulation path is formed with a difference in elevation, and the first heat exchanger part is formed in a lower area of the CO2 circulation path, andthe circulating unit is configured to permits the CO2 refrigerant to naturally circulate in the closed circuit at the time of defrosting by a thermosiphon effect. 5. The sublimation defrost system for the refrigeration apparatus according to claim 1, further comprising: a second heat exchanger part for heating the brine with a second heating medium; anda brine circuit for permitting the brine heated by the second heating unit to be circulated to the first heating unit, the brine circuit being connected to the first heating unit and the second heating unit. 6. The sublimation defrost system for the refrigeration apparatus according to claim 5, wherein the heat exchanger pipe is provided with a difference in elevation in the cooling device,the brine circuit is formed in the cooling device and in a lower area of the heat exchanger pipe, andthe first heat exchanger part is formed between the brine circuit and the lower area of the heat exchanger pipe. 7. The sublimation defrost system for the refrigeration apparatus according to claim 6, wherein each of the heat exchanging pipe and the brine circuit is provided with a difference in elevation in the cooling device and is configured in such a manner that the brine flows from a lower side to an upper side in the brine circuit, anda flowrate adjustment valve is disposed at an intermediate position in the brine circuit in an upper and lower direction, and the first heat exchanger part is formed at a portion of the brine circuit on an upstream side of the flowrate adjustment valve. 8. The sublimation defrost system for the refrigeration apparatus according to claim 5, further comprising a first temperature sensor and a second temperature sensor which are respectively disposed at an inlet and an outlet of the brine circuit to detect a temperature of the brine flowing through the inlet and the outlet. 9. The sublimation defrost system for the refrigeration apparatus according to claim 1, wherein the pressure adjusting unit includes:a pressure sensor for detecting the pressure of the CO2 refrigerant circulating in the closed circuit;a pressure adjusting valve disposed in the outlet path of the heat exchanger pipe; anda control device for receiving a detected value from the pressure sensor, and controlling an opening aperture of the pressure adjusting valve in such a manner that the condensing temperature of the CO2 refrigerant circulating in the closed circuit becomes equal to or lower than the freezing point of the water vapor in the freezer inner air in the freezer. 10. The sublimation defrost system for the refrigeration apparatus according to claim 1, wherein the refrigerating device includes:a primary refrigerant circuit in which NH3 refrigerant circulates and a refrigerating cycle component is disposed;a secondary refrigerant circuit in which the CO2 refrigerant circulates, the secondary refrigerant circuit led to the cooling device, the secondary refrigerant circuit being connected to the primary refrigerant circuit through a cascade condenser; anda liquid CO2 receiver for storing the CO2 refrigerant liquefied in the cascade condenser and a liquid CO2 pump for sending the CO2 refrigerant stored in the liquid CO2 receiver to the cooling device, which are disposed in the secondary refrigerant circuit. 11. The sublimation defrost system for the refrigeration apparatus according to claim 10, further comprising: a second heat exchanger part for heating the brine with a second heating medium;a brine circuit for permitting the brine heated by the second heating unit to be circulated to the first heating unit, the brine circuit being connected to the first heating unit and the second heating unit; anda cooling water circuit led to a condenser provided as a part of the refrigerating cycle component disposed in the primary refrigerant circuit, whereinthe second heat exchanger part is a heat exchanger to which the cooling water circuit and the brine circuit are led, the heat exchanger configured to heat the brine circulating in the brine circuit with cooling water heated by the condenser. 12. The sublimation defrost system for the refrigeration apparatus according to claim 10, further comprising: a second heat exchanger part for heating the brine with a second heating medium;a brine circuit for permitting the brine heated by the second heating unit to be circulated to the first heating unit, the brine circuit being connected to the first heating unit and the second heating unit;a cooling water circuit led to a condenser provided as a part of the refrigerating cycle component disposed in the primary refrigerant circuit; anda cooling tower for cooling the cooling water circulating in the cooling water circuit by exchanging heat between the cooling water and spray water, whereinthe second heat exchanger part includes a heating tower for receiving the spray water and exchanging heat between the brine circulating in the brine circuit and the spray water, the heating tower being integrally formed with the cooling tower. 13. The sublimation defrost system for the refrigeration apparatus according to claim 1, wherein the refrigerating device is a NH3/CO2 cascade refrigerating device including:a primary refrigerant circuit in which NH3 refrigerant circulates and a refrigerating cycle component is disposed; anda secondary refrigerant circuit in which the CO2 refrigerant circulates and a refrigerating cycle component is disposed, the secondary refrigerant circuit led to the cooling device, the secondary refrigerant circuit being connected to the primary refrigerant circuit through a cascade condenser. 14. A sublimation defrost method using the sublimation defrost system for the refrigeration apparatus according to claim 1, the method comprising: a first step of dehumidifying the freezer inner air in the freezer with the dehumidifier device so that a partial pressure of the water vapor in the freezer inner air does not become a saturated vapor partial pressure;a second step of closing the on-off valve at the time of defrosting to form the closed circuit;a third step of adjusting the pressure of the CO2 refrigerant circulating in the closed circuit so that the condensing temperature of the CO2 refrigerant becomes equal to or lower than the freezing point of the water vapor in the freezer inner air in the freezer; anda fourth step of vaporizing the CO2 refrigerant by exchanging heat between the brine as a heating medium and the CO2 refrigerant circulating in the closed circuit; anda fifth step of permitting the CO2 refrigerant vaporized in the fourth step to circulate in the closed circuit, and removing frost attached on an outer surface of the heat exchanger pipe by sublimation with heat of the CO2 refrigerant. 15. A sublimation defrost method for the refrigeration apparatus according to claim 14, wherein in the fourth step, the brine and the CO2 refrigerant circulating in the closed circuit exchange heat in the lower area of the closed circuit provided with a difference in elevation, andin the fifth step, the CO2 refrigerant is permitted to naturally circulate in the closed circuit by a thermosiphon effect.
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