Gas supply device and refrigeration device for container provided with said gas supply device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A23B-007/152
F25D-011/00
A23B-007/148
B01D-053/04
F25D-023/12
출원번호
US-0550391
(2016-02-04)
등록번호
US-9872508
(2018-01-23)
우선권정보
JP-2015-039254 (2015-02-27)
국제출원번호
PCT/JP2016/000580
(2016-02-04)
국제공개번호
WO2016/136153
(2016-09-01)
발명자
/ 주소
Yokohara, Kazuma
Nakano, Masataka
Kamei, Noritaka
Tanaka, Naohiro
Ozato, Atsushi
Fujimoto, Yuusuke
출원인 / 주소
DAIKIN INDUSTRIES, LTD.
대리인 / 주소
Birch, Stewart, Kolasch & Birch, LLP
인용정보
피인용 횟수 :
0인용 특허 :
8
초록▼
Disclosed is a gas supply device provided for a container in which a breathing plant is housed. The device supplies nitrogen-enriched air into the container. The device is provided with a malfunction diagnosis section which checks whether each of components of the device works properly or not and sp
Disclosed is a gas supply device provided for a container in which a breathing plant is housed. The device supplies nitrogen-enriched air into the container. The device is provided with a malfunction diagnosis section which checks whether each of components of the device works properly or not and specifies a malfunctioning portion if an oxygen concentration of the nitrogen-enriched air does not fall to or below a predetermined concentration. The malfunction diagnosis section checks whether each of an air pump, a motor, and a switching mechanism works properly or not, and determines that an adsorbent is not working properly when it is determined that all of the air pump, the motor, and the switching mechanism are working properly.
대표청구항▼
1. A gas supply device provided for a container in which a breathing plant is housed, the device comprising: a first adsorption portion and a second adsorption portion in each of which an adsorbent for adsorbing nitrogen in air is provided;an air pump having a first pump mechanism connected to one o
1. A gas supply device provided for a container in which a breathing plant is housed, the device comprising: a first adsorption portion and a second adsorption portion in each of which an adsorbent for adsorbing nitrogen in air is provided;an air pump having a first pump mechanism connected to one of the first adsorption portion and the second adsorption portion, and a second pump mechanism connected to the other one of the first adsorption portion and the second adsorption portion, the first pump mechanism supplying outside air to the first or second adsorption portion to allow the adsorbent to adsorb nitrogen in the outside air and thereby producing oxygen-enriched air having a higher oxygen concentration than the outside air, the second pump mechanism sucking air from the first or second adsorption portion and thereby producing nitrogen-enriched air containing the nitrogen desorbed from the adsorbent;a motor which drives the air pump;a switching mechanism which alternately switches between a first connection state in which the first adsorption portion is connected to the first pump mechanism and the second adsorption portion is connected to the second pump mechanism, and a second connection state in which the second adsorption portion is connected to the first pump mechanism and the first adsorption portion is connected to the second pump mechanism;a supply passage which allows the second pump mechanism to communicate with an interior of the container and guides the nitrogen-enriched air to the interior of the container; andan oxygen discharge passage which allows the first and second adsorption portions to communicate with an outside and guides the oxygen-enriched air to the outside, whereinthe gas supply device has a malfunction diagnosis section which checks whether each of components of the gas supply device works properly or not and specifies a malfunctioning portion if an oxygen concentration of the nitrogen-enriched air does not fall to or below a predetermined concentration, andthe malfunction diagnosis section checks whether each of the air pump, the motor, and the switching mechanism works properly or not, and determines that the adsorbent is not working properly when it is determined that all of the air pump, the motor, and the switching mechanism work properly. 2. The gas supply device of claim 1, comprising: a unit case which houses at least the air pump and the motor, whereinthe malfunction diagnosis section determines that the air pump and the motor work properly if a temperature in the unit case increases after start of operation of the air pump from a temperature in the unit case before the start of the operation of the air pump, anddetermines that the air pump or the motor malfunctions if the temperature in the unit case does not increase after the start of the operation of the air pump from the temperature in the unit case before the start of the operation of the air pump. 3. The gas supply device of claim 1, wherein the malfunction diagnosis section determines that the air pump and the motor work properly if a pressure in the oxygen discharge passage increases after start of operation of the air pump from a pressure in the oxygen discharge passage before the start of the operation of the air pump, anddetermines that the air pump or the motor malfunctions if the pressure in the oxygen discharge passage does not increase after the start of the operation of the air pump from the pressure in the oxygen discharge passage before the start of the operation of the air pump. 4. The gas supply device of claim 2, wherein the malfunction diagnosis section determines that the air pump malfunctions if it is determined that the air pump or the motor is malfunctioning and a value of a current of the motor is in a predetermined normal range, anddetermines that the motor malfunctions if it is determined that the air pump or the motor is malfunctioning and the value of the current of the motor does not fall within the predetermined normal range. 5. The gas supply device of claim 1, wherein the switching mechanism includesa first solenoid valve which switches between a first state where the first adsorption portion is connected to the first pump mechanism, and a second state where the first adsorption portion is connected to the second pump mechanism, anda second solenoid valve which switches between a first state where the second adsorption portion is connected to the second pump mechanism, and a second state where the second adsorption portion is connected to the first pump mechanism, whereinthe switching mechanism is capable of switching between a dual pressurization state in which the first solenoid valve is in the first state and the second solenoid valve is in the second state, and a dual depressurization state in which the first solenoid valve is in the second state and the second solenoid valve is in the first state,the first and second solenoid valves are switched to one of the dual pressurization state and the dual depressurization state when both of the first and second solenoid valves are not energized, and switched to the other one of the dual pressurization state and the dual depressurization state when the both of the first and second solenoid valves are energized, andthe malfunction diagnosis section determines that the switching mechanism works properly if a difference in pressure in the oxygen discharge passage before and after a switching operation, in which the first and second solenoid valves are simultaneously switched from a nonenergized state to an energized state, is more than or equal to a predetermined pressure, anddetermines that the switching mechanism malfunctions if the difference in the pressure in the oxygen discharge passage before and after the switching operation is less than the predetermined pressure. 6. The gas supply device of claim 1, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 7. A container refrigeration apparatus attached to a container in which a breathing plant is housed, the apparatus comprising: a refrigerant circuit which performs a refrigeration cycle to cool inside air of the container; andan inside air control system which includes a gas supply device which supplies gas into the container, and an exhaust portion through which the inside air of the container is exhausted outside, the inside air control system controlling a composition of the inside air in the container, whereinthe gas supply device is comprised of the gas supply device of claim 1. 8. The gas supply device of claim 3, wherein the malfunction diagnosis section determines that the air pump malfunctions if it is determined that the air pump or the motor is malfunctioning and a value of a current of the motor is in a predetermined normal range, anddetermines that the motor malfunctions if it is determined that the air pump or the motor is malfunctioning and the value of the current of the motor does not fall within the predetermined normal range. 9. The gas supply device of claim 2, wherein the switching mechanism includesa first solenoid valve which switches between a first state where the first adsorption portion is connected to the first pump mechanism, and a second state where the first adsorption portion is connected to the second pump mechanism, anda second solenoid valve which switches between a first state where the second adsorption portion is connected to the second pump mechanism, and a second state where the second adsorption portion is connected to the first pump mechanism, whereinthe switching mechanism is capable of switching between a dual pressurization state in which the first solenoid valve is in the first state and the second solenoid valve is in the second state, and a dual depressurization state in which the first solenoid valve is in the second state and the second solenoid valve is in the first state,the first and second solenoid valves are switched to one of the dual pressurization state and the dual depressurization state when both of the first and second solenoid valves are not energized, and switched to the other one of the dual pressurization state and the dual depressurization state when the both of the first and second solenoid valves are energized, andthe malfunction diagnosis section determines that the switching mechanism works properly if a difference in pressure in the oxygen discharge passage before and after a switching operation, in which the first and second solenoid valves are simultaneously switched from a nonenergized state to an energized state, is more than or equal to a predetermined pressure, anddetermines that the switching mechanism malfunctions if the difference in the pressure in the oxygen discharge passage before and after the switching operation is less than the predetermined pressure. 10. The gas supply device of claim 3, wherein the switching mechanism includesa first solenoid valve which switches between a first state where the first adsorption portion is connected to the first pump mechanism, and a second state where the first adsorption portion is connected to the second pump mechanism, anda second solenoid valve which switches between a first state where the second adsorption portion is connected to the second pump mechanism, and a second state where the second adsorption portion is connected to the first pump mechanism, whereinthe switching mechanism is capable of switching between a dual pressurization state in which the first solenoid valve is in the first state and the second solenoid valve is in the second state, and a dual depressurization state in which the first solenoid valve is in the second state and the second solenoid valve is in the first state,the first and second solenoid valves are switched to one of the dual pressurization state and the dual depressurization state when both of the first and second solenoid valves are not energized, and switched to the other one of the dual pressurization state and the dual depressurization state when the both of the first and second solenoid valves are energized, andthe malfunction diagnosis section determines that the switching mechanism works properly if a difference in pressure in the oxygen discharge passage before and after a switching operation, in which the first and second solenoid valves are simultaneously switched from a nonenergized state to an energized state, is more than or equal to a predetermined pressure, anddetermines that the switching mechanism malfunctions if the difference in the pressure in the oxygen discharge passage before and after the switching operation is less than the predetermined pressure. 11. The gas supply device of claim 4, wherein the switching mechanism includesa first solenoid valve which switches between a first state where the first adsorption portion is connected to the first pump mechanism, and a second state where the first adsorption portion is connected to the second pump mechanism, anda second solenoid valve which switches between a first state where the second adsorption portion is connected to the second pump mechanism, and a second state where the second adsorption portion is connected to the first pump mechanism, whereinthe switching mechanism is capable of switching between a dual pressurization state in which the first solenoid valve is in the first state and the second solenoid valve is in the second state, and a dual depressurization state in which the first solenoid valve is in the second state and the second solenoid valve is in the first state,the first and second solenoid valves are switched to one of the dual pressurization state and the dual depressurization state when both of the first and second solenoid valves are not energized, and switched to the other one of the dual pressurization state and the dual depressurization state when the both of the first and second solenoid valves are energized, andthe malfunction diagnosis section determines that the switching mechanism works properly if a difference in pressure in the oxygen discharge passage before and after a switching operation, in which the first and second solenoid valves are simultaneously switched from a nonenergized state to an energized state, is more than or equal to a predetermined pressure, anddetermines that the switching mechanism malfunctions if the difference in the pressure in the oxygen discharge passage before and after the switching operation is less than the predetermined pressure. 12. The gas supply device of claim 8, wherein the switching mechanism includesa first solenoid valve which switches between a first state where the first adsorption portion is connected to the first pump mechanism, and a second state where the first adsorption portion is connected to the second pump mechanism, anda second solenoid valve which switches between a first state where the second adsorption portion is connected to the second pump mechanism, and a second state where the second adsorption portion is connected to the first pump mechanism, whereinthe switching mechanism is capable of switching between a dual pressurization state in which the first solenoid valve is in the first state and the second solenoid valve is in the second state, and a dual depressurization state in which the first solenoid valve is in the second state and the second solenoid valve is in the first state,the first and second solenoid valves are switched to one of the dual pressurization state and the dual depressurization state when both of the first and second solenoid valves are not energized, and switched to the other one of the dual pressurization state and the dual depressurization state when the both of the first and second solenoid valves are energized, andthe malfunction diagnosis section determines that the switching mechanism works properly if a difference in pressure in the oxygen discharge passage before and after a switching operation, in which the first and second solenoid valves are simultaneously switched from a nonenergized state to an energized state, is more than or equal to a predetermined pressure, anddetermines that the switching mechanism malfunctions if the difference in the pressure in the oxygen discharge passage before and after the switching operation is less than the predetermined pressure. 13. The gas supply device of claim 2, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 14. The gas supply device of claim 3, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 15. The gas supply device of claim 4, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 16. The gas supply device of claim 8, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 17. The gas supply device of claim 5, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 18. The gas supply device of claim 9, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 19. The gas supply device of claim 10, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion. 20. The gas supply device of claim 11, comprising a malfunction notifier which, if the malfunction diagnosis section specifies a malfunctioning portion in the gas supply device, notifies a user of the malfunctioning portion.
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