Apparatus and method for hybrid water heating and air cooling and control thereof
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F25B-013/00
F25B-005/02
F25B-006/02
F25B-006/04
F25B-029/00
F25B-041/04
F25B-049/02
F25B-006/00
F24H-004/02
F24H-004/06
F24H-006/00
F24H-009/20
F24D-003/18
F24D-005/12
F24D-012/02
F24D-015/04
F24D-017/02
F24D-019/10
F24F-001/00
F25B-049/00
출원번호
US-0476647
(2014-09-03)
등록번호
US-10041702
(2018-08-07)
발명자
/ 주소
Lowrimore, Walker R.
Long, Robert L.
Winters, Scott D.
Foster, Randy W.
출원인 / 주소
RHEEM MANUFACTURING COMPANY
대리인 / 주소
King & Spalding LLP
인용정보
피인용 횟수 :
0인용 특허 :
28
초록▼
A system for conditioning air circulated from an interior of a building includes a refrigerant path, an air-cooled condenser in the refrigerant path, a water-cooled condenser in the refrigerant path that transfers heat from refrigerant in the refrigerant path to the building water, an evaporator in
A system for conditioning air circulated from an interior of a building includes a refrigerant path, an air-cooled condenser in the refrigerant path, a water-cooled condenser in the refrigerant path that transfers heat from refrigerant in the refrigerant path to the building water, an evaporator in the refrigerant path, and a control system. The control system moves the system between operation of the air-cooled condenser and the water-cooled condenser based upon predetermined system conditions.
대표청구항▼
1. A system for conditioning air and for heating water, comprising: a refrigerant path;a first condenser in the refrigerant path and disposed in an air flow path so that the first condenser transfers heat to air in the air flow path from refrigerant moving through the first condenser in the refriger
1. A system for conditioning air and for heating water, comprising: a refrigerant path;a first condenser in the refrigerant path and disposed in an air flow path so that the first condenser transfers heat to air in the air flow path from refrigerant moving through the first condenser in the refrigerant path;a second condenser in the refrigerant path and that defines a water flow path so that the second condenser transfers heat to water in the water flow path from refrigerant moving through the second condenser in the refrigerant path;an evaporator in the refrigerant path and disposed in a second air flow path so that air in the second air flow path transfers heat to refrigerant moving through the evaporator;a compressor in the refrigerant path and configured to move refrigerant in the refrigerant path;a three-way valve comprising a first connection to a first output line in the refrigerant path from the compressor, a second connection to an input line in the refrigerant path to the first condenser, and a third connection to an input line in the refrigerant path to the second condenser;a port in the three-way valve, comprising a fourth connection distinct from each of the first connection, the second connection, and the third connection, the fourth connection connected to a bypass refrigerant path connected to an input to the compressor in the refrigerant path where such input is downstream from the evaporator with respect to the refrigerant path;a second output line in the refrigerant path from the first condenser to the evaporator; anda control system in operative communication with the refrigerant path and the three-way valve configured to selectively direct refrigerant flow from the first connection, through the second connection to the first condenser or through the third connection to the second condenser,upon directing refrigerant flow through the third connection to the second condenser without directing refrigerant flow through the second connection to the first condenser, draining refrigerant from the first condenser, in response to pressure in the first condenser or the second output line, andselectively open the port in the three-way valve in response to pressure in the first output line. 2. The system as in claim 1, including a temperature sensor in the water flow path and wherein the control system is configured to selectively direct refrigerant flow from the first connection, through the second connection to the first condenser or through the third connection to the second condenser responsively to an output signal of the temperature sensor. 3. The system as in claim 2, including a pump in the water flow path so that the pump moves water through the water flow path. 4. The system as in claim 1, wherein the control system is configured to drain the refrigerant from the first condenser to the evaporator. 5. The system as in claim 4, wherein the control system is configured to drain refrigerant from the first condenser to the evaporator in response to a difference between a pressure in the evaporator and the pressure in the first condenser or the second output line. 6. The system as in claim 5, comprising a temperature sensor disposed with respect to the second output line to detect an air temperature ambient to the second output line,wherein the temperature sensor outputs a signal to the control system corresponding to the ambient temperature, andwherein the control system is configured to compare the ambient temperature represented by the signal output from the temperature sensor to a predetermined temperature at which the difference is sufficient to permit the refrigerant to drain from the first condenser or the second output line to the evaporator and, if the ambient temperature represented by the signal is greater than the predetermined temperature, to drain the refrigerant from the first condenser to the evaporator. 7. The system as in claim 6, comprising a refrigerant drain line between the first condenser and the evaporator, and a valve in the refrigerant drain line, wherein the control system is in operative communication with the drain line valve to selectively open and close the drain line valve in response to comparison between the ambient temperature represented by the signal output from the temperature sensor and the predetermined temperature. 8. The system as in claim 6, comprising a pressure sensor in the refrigerant path at the evaporator that outputs a signal to the control system corresponding to pressure of refrigerant in the evaporator,wherein the control system is configured, if the ambient temperature represented by the signal from the temperature sensor is greater than the predetermined temperature, to compare a threshold pressure based on the ambient temperature represented by the signal from the temperature sensor to the pressure of refrigerant in the evaporator, and drain the refrigerant from the first condenser to the evaporator if comparison of the threshold pressure to the pressure of refrigerant in the evaporator meets a predetermined criteria. 9. A system for conditioning air and for heating water, comprising: a refrigerant path;a first condenser in the refrigerant path and disposed in a first air flow path so that the first condenser transfers heat to air in the first air flow path from refrigerant moving through the first condenser in the refrigerant path;a second condenser in the refrigerant path and that defines a water flow path so that the second condenser transfers heat to water in the water flow path from refrigerant moving through the second condenser in the refrigerant path;an evaporator in the refrigerant path and disposed in a second air flow path so that air in the second air flow path transfers heat to refrigerant moving through the evaporator;a compressor in the refrigerant path and configured to move refrigerant in the refrigerant path;a three-way valve comprising a first connection to a first output line in the refrigerant path from the compressor, a second connection to an input line in the refrigerant path to the first condenser, and a third connection to an input line in the refrigerant path to the second condenser;a port in the three-way valve, comprising a fourth connection distinct from each of the first connection, the second connection, and the third connection, the fourth connection connected to a bypass refrigerant path connected to an input to the compressor in the refrigerant path where such input is downstream from the evaporator with respect to the refrigerant path;a second output line in the refrigerant path from the first condenser to the evaporator, the second output line having an expansion valve; anda control system in operative communication with the refrigerant path and the three-way valve configured to selectively direct refrigerant flow from the first connection, to the second connection to the first condenser or to the third connection to the second condenser,upon directing refrigerant flow to the third connection to the second condenser without directing refrigerant flow to the second connection to the first condenser, draining refrigerant from the first condenser into a flow between the second condenser and the evaporator, in response to pressure in the first condenser or the second output line, andselectively open the port in the three-way valve in response to pressure in the first output line. 10. The system as in claim 9, including a temperature sensor in the water flow path and wherein the control system is configured to selectively direct refrigerant flow through the second connection to the first condenser or the third connection to the second condenser responsively to an output signal of the temperature sensor. 11. The system as in claim 9, wherein the control system is configured to drain the refrigerant from the first condenser to the evaporator. 12. The system as in claim 11, wherein the control system is configured to drain refrigerant from the first condenser to the evaporator in response to a difference between a pressure in the evaporator and the pressure in the first condenser or the second output line. 13. The system as in claim 12, comprising a temperature sensor disposed with respect to the second output line to detect a temperature ambient to the second output line,wherein the temperature sensor outputs a signal to the control system corresponding to the ambient temperature, andwherein the control system is configured to compare the ambient temperature represented by the signal output from the temperature sensor to a predetermined temperature at which the difference is sufficient to permit the refrigerant to drain from the first condenser or the second output line to the evaporator and, if the ambient temperature represented by the signal is greater than the predetermined temperature, to drain the refrigerant from the first condenser to the evaporator. 14. The system as in claim 13, comprising a refrigerant drain line between the first condenser and the evaporator, and a valve in the refrigerant drain line, wherein the control system is in operative communication with the drain line valve to selectively open and close the drain line valve in response to comparison between the ambient temperature represented by the signal output from the temperature sensor and the predetermined temperature. 15. The system as in claim 13, comprising a pressure sensor in the refrigerant path at the evaporator that outputs a signal to the control system corresponding to pressure of refrigerant in the evaporator,wherein the control system is configured, if the ambient temperature represented by the signal from the temperature sensor is greater than the predetermined temperature, to compare a threshold pressure based on the ambient temperature represented by the signal from the temperature sensor to the pressure of refrigerant in the evaporator, and drain the refrigerant from the first condenser to the evaporator if comparison of the threshold pressure to the pressure of refrigerant in the evaporator meets a predetermined criteria. 16. A system for conditioning air, and for heating water, comprising: a refrigerant path; a first condenser in the refrigerant path and disposed in a first air flow path so that the first condenser transfers heat to air in the first air flow path from refrigerant moving through the first condenser in the refrigerant path;a second condenser in the refrigerant path and that defines a water flow path so that the second condenser transfers heat to water in the water flow path from refrigerant moving through the second condenser in the refrigerant path;an evaporator in the refrigerant path and disposed in a second air flow path so that air in the second air flow path transfers heat to refrigerant moving through the evaporator;a compressor in the refrigerant path and configured to move refrigerant in the refrigerant path;a three-way valve comprising a first connection to a first output line in the refrigerant path from the compressor, a second connection to an input line in the refrigerant path to the first condenser, and a third connection to an input line in the refrigerant path to the second condenser;a port in the three-way valve, comprising a fourth connection distinct from each of the first connection, the second connection, and the third connection, the fourth connection connected to a bypass refrigerant path connected to an input to the compressor in the refrigerant path where such input is downstream from the evaporator with respect to the refrigerant path;a second output line in the refrigerant path from the first condenser to the evaporator, the second output line having an expansion valve;a refrigerant drain line from the second output line to the evaporator, downstream from the expansion valve with respect to the refrigerant path;a sensor disposed with respect to the second output line so that the sensor outputs a signal corresponding to pressure in the second output line; anda control system in operative communication with the sensor,the refrigerant drain line to selectively open and close the refrigerant drain line, andthe three-way valve,wherein the control system is configured to control opening of the refrigerant drain line responsively to the signal, andwherein the control system is configured to selectively open the port in the three-way valve in response to pressure in the first output line. 17. The system as in claim 16, wherein the control system comprises the three-way valve configured so that the three-way valve selectively directs the refrigerant from the first connection to the second connection to the first condenser or to the third connection to the second condenser, anda valve in the refrigerant drain line, andwherein the control system is in operative communication with the drain line valve to selectively open and close the drain line valve,wherein the control system is configured to actuate the three-way valve to at least a first state and a second state, wherein the three-way valve, in the first state, directs the refrigerant from the first connection to the second connection to the first condenser and, in the second state, directs the refrigerant from the first connection to the third connection to the second condenser and not to the second connection to the first condenser, and wherein the control system is configured, upon actuating the three-way valve to the second state, to control the drain line valve to open the drain line, responsive to pressure in the second output line as represented by the signal. 18. The system as in claim 17, wherein a temperature sensor is configured to detect a temperature ambient to the output line, and wherein the control system is configured to convert the ambient temperature into a pressure of refrigerant in the output line. 19. The system as in claim 17, further comprising a fan disposed with respect to the first condenser to move air in the first air flow path across the first condenser, wherein the control system is configured to move the three-way valve from the first state to the second state, and wherein, prior to moving the three-way valve from the first state to the second state, the control system determines, based on an output from the sensor, whether pressure of refrigerant in the second output line is above a predetermined threshold,if the pressure of the refrigerant in the second output line is above the predetermined threshold, controls the three-way valve to transition from the first state to the second state, and controls the drain line valve to open the drain line, andif the pressure of the refrigerant in the second output line is below the predetermined threshold, deactivates the fan while actuating the compressor with the three-way valve in the first state for a period of time prior to controlling the three-way valve to transition from the first state to the second state and controlling the drain line valve to open the drain line. 20. The system as in claim 16, wherein the expansion valve is a single valve. 21. A system for conditioning air and for heating water, comprising: a refrigerant path;a first condenser in the refrigerant path and disposed in a first air flow path so that the first condenser transfers heat to air in the first air flow path from refrigerant moving through the first condenser in the refrigerant path;a second condenser in the refrigerant path and that defines a water flow path so that the second condenser transfers heat to water in the water flow path from refrigerant moving through the second condenser in the refrigerant path;an evaporator in the refrigerant path and disposed in a second air flow path so that air in the second air flow path transfers heat to refrigerant moving through the evaporator;a compressor in the refrigerant path and configured to move refrigerant in the refrigerant path;a three-way valve comprising a first connection to an output line in the refrigerant path from the compressor, a second connection to an input line in the refrigerant path to the first condenser, and a third connection to an input line in the refrigerant path to the second condenser;a port in the three-way valve, comprising a fourth connection distinct from each of the first connection, the second connection, and the third connection, the fourth connection connected to a bypass refrigerant path connected to an input to the compressor in the refrigerant path where such input is downstream from the evaporator with respect to the refrigerant path;a temperature sensor disposed with respect to the refrigerant path to detect an air temperature ambient to the refrigerant path; anda control system in operative communication with the refrigerant path, the three-way valve, and the temperature sensor and configured to selectively direct refrigerant flow from the first connection, through the second connection to the first condenser or through the third connection to the second condenser and, upon transitioning refrigerant flow from one of the first condenser and the second condenser to the other of the first condenser and the second condenser, controlling refrigerant flow in the refrigerant path in response to ambient temperature detected by the temperature sensor, andselectively open the port in the three-way valve in response to pressure in the output line in the refrigerant path from the compressor.
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이 특허에 인용된 특허 (28)
Flammang,Kevin E., Ambient thermal energy recovery system.
Dudley Kevin F. (Cazenovia NY) Dunshee Kevin B. (Syracuse NY) Paige Lowell (Penneville NY), Control of space heating and water heating using variable speed heat pump.
Dudley Kevin F. (Cazenovia NY) Paige Lowell E. (Pennellville NY) Dunshee Kevin B. (Syracuse NY), Controllable variable speed heat pump for combined water heating and space cooling.
Murphy Jimmy (Rte. 6 ; Sunnybelle Acres Thomasville GA 31792) Fleetwood Ansley R. (4206 Lone Oak Rd. Nashville TN 37215), Energy conserving water heating system.
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