A heat pump system includes a heat source unit, a usage-side unit, and a usage-side controller. The heat source unit has a heat source-side compressor for compressing a heat source-side refrigerant, and a heat source-side heat exchanger capable of functioning as an evaporator of the heat source-side
A heat pump system includes a heat source unit, a usage-side unit, and a usage-side controller. The heat source unit has a heat source-side compressor for compressing a heat source-side refrigerant, and a heat source-side heat exchanger capable of functioning as an evaporator of the heat source-side refrigerant. The usage-side unit is connected to the heat source unit and has a capacity-variable-type usage-side compressor for compressing a usage-side refrigerant, a usage-side heat exchanger capable of functioning as a radiator of the heat source-side refrigerant and functioning as an evaporator of the usage-side refrigerant, and a refrigerant-water heat exchanger capable of functioning as a radiator of the usage-side refrigerant and heating an aqueous medium. The usage-side controller performs usage-side capacity variation control for incrementally varying the operating capacity of the usage-side compressor during a usual operation.
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1. A heat pump system comprising: a heat source unit having a heat source-side compressor configured to compress a heat source-side refrigerant and a heat source-side heat exchanger configured to function as an evaporator of the heat source-side refrigerant;a usage side unit connected to the heat so
1. A heat pump system comprising: a heat source unit having a heat source-side compressor configured to compress a heat source-side refrigerant and a heat source-side heat exchanger configured to function as an evaporator of the heat source-side refrigerant;a usage side unit connected to the heat source unit, the usage side unit having a capacity-variable-type usage-side compressor configured to compress a usage-side refrigerant,a usage-side heat exchanger configured to function as a radiator of the heat source-side refrigerant and functioning as an evaporator of the usage-side refrigerant; anda refrigerant-water heat exchanger configured to function as a radiator of the usage-side refrigerant and configured to heat an aqueous medium,the heat source-side compressor, the heat source-side heat exchanger, and the usage-side heat exchanger forming parts of a heat source-side refrigerant circuit, the heat source-side compressor being a capacity-variable-type compressor, andthe usage-side compressor, the usage-side heat exchanger, and the refrigerant-water heat exchanger forming parts of a usage-side refrigerant circuit;a usage-side controller configured to perform a usage-side capacity variation control in which an operating capacity of the usage-side compressor is incrementally variable during a normal operation; anda heat source-side controller configured to monitor a condensation temperature of the heat source-side refrigerant in the usage-side heat exchanger and to control the heat source-side compressor such that the condensation temperature of the heat source-side refrigerant in the usage-side heat exchanger reaches a heat source-side condensation target temperature, the heat source-side controller being further configured to perform a heat source-side capacity variation control in which an operating capacity of the heat source-side compressor is incrementally varied by incrementally varying the heat source-side condensation target temperature when the usage-side controller is performing the usage-side capacity variation control,when the usage-side controller reduces operating capacity of the usage-side compressor during the usage-side capacity variation control, the heat source-side controller performing the heat source-side capacity variation control by raising the heat source-side condensation target temperature in order to increase operating capacity of the heat source-side compressor. 2. The heat pump system according to claim 1, wherein the usage-side controller is further configured to perform a capacity control on the usage-side compressor in which condensation temperature of the usage-side refrigerant in the refrigerant-water heat exchanger reaches a usage-side condensation target temperature, andthe usage-side capacity variation control by incrementally varying the usage-side condensation target temperature. 3. The heat pump system according to claim 1, wherein the usage-side controller is further configured to perform the usage-side capacity variation control during a predetermined time duration following a start of operation of the usage-side compressor. 4. The heat pump system according to claim 1, wherein the usage-side controller is further configured to limit operating capacity of the usage-side compressor to a predetermined capacity or lower during the usage-side capacity variation control, andperform capacity non-limiting control in which operating capacity of the usage-side compressor is controlled without limiting operating capacity to the predetermined capacity or lower after the usage-side capacity variation control; andthe heat source-side controller is further configured to perform a control in which operating capacity of the heat source-side compressor is reduced during the capacity non-limiting control by lowering the heat source-side condensation target temperature to a value lower than during the usage-side capacity variation control. 5. A heat pump system comprising: a heat source unit having a heat source-side compressor configured to compress a heat source-side refrigerant and a heat source-side heat exchanger configured to function as an evaporator of the heat source-side refrigerant;a usage-side unit connected to the heat source unit, the usage side unit having a capacity-variable-type usage-side compressor configured to compress a usage-side refrigerant,a usage-side heat exchanger configured to function as a radiator of the heat source-side refrigerant and functioning as an evaporator of the usage-side refrigerant, anda refrigerant-water heat exchanger configured to function as a radiator of the usage-side refrigerant and configured to heat an aqueous medium,the heat source-side compressor, the heat source-side heat exchanger, and the usage-side heat exchanger funning parts of a heat source-side refrigerant circuit, the heat source-side compressor being a capacity-variable-type compressor, andthe usage-side compressor, the usage-side heat exchanger, and the refrigerant-water heat exchanger forming parts of a usage-side refrigerant circuit;a usage-side controller configured to perform a usage-side capacity variation control in which an operating capacity of the usage-side compressor is incrementally variable during a normal operation; anda heat source-side controller configured to monitor an evaporation temperature of the usage-side refrigerant in the usage-side heat exchanger and control the heat source-side compressor such that evaporation temperature of the usage-side refrigerant in the usage-side heat exchanger reaches a usage-side evaporation target, temperature, the heat source-side controller being further configured perform a heat source-side capacity variation control in which an operating capacity of the heat source-side compressor is incrementally varied by incrementally varying the usage-side evaporation target temperature when the usage-side controller is performing the usage-side capacity variation control,when the usage-side controller reduces the operating capacity of the usage-side compressor during the usage-side capacity variation control, the heat source-side controller performing the heat source-side capacity variation control by raising the usage-side evaporation target temperature in order to increase the operating capacity of the heat source-side compressor. 6. The heat pump system according to claim 5, wherein the usage-side controller is further configured to limit operating capacity of the usage-side compressor to a predetermined capacity or lower during the usage-side capacity variation control, andperform capacity non-limiting control in which operating capacity of the usage-side compressor is controlled without limiting operating capacity to the predetermined capacity or lower after the usage-side capacity variation control; andthe heat source-side controller is further configured to perform a control in which operating capacity of the heat source-side compressor is reduced during the capacity non-limiting control by lowering the usage-side evaporation target temperature to a value lower than during the usage-side capacity variation control. 7. The heat pump system according to claim 1, wherein the usage-side controller is further configured to perform the usage-side capacity variation control dining a predetermined time duration following a start of operation of the usage-side compressor; andthe heat source-side controller is further configured to set the heat source-side condensation target temperature to a predetermined temperature or higher at the start of operation of the usage-side compressor, andthereafter incrementally lower the heat source-side condensation target temperature until the predetermined temperature is reached. 8. The heat pump system according to claim 1, further comprising: a receiver configured to receive a command to initiate the usage-side capacity variation control,the usage-side controller being further configured to perform the usage-side capacity variation control when the receiver has received the command to initiate the usage-side capacity variation control. 9. The heat pump system according to claim 2, wherein the usage-side controller is further configured to perform the usage-side capacity variation control during a predetermined time duration following a start of operation of the usage-side compressor. 10. The heat pump system according to claim 5, wherein the usage-side controller is further configured to perform a capacity control on the usage-side compressor in which condensation temperature of the usage-side refrigerant in the refrigerant-water heat exchanger reaches a usage-side condensation target temperature, andthe usage-side capacity variation control by incrementally varying the usage-side condensation target temperature. 11. The heat pump system according to claim 5, wherein the usage-side controller is further configured to perform the usage-side capacity variation control during a predetermined time duration following a start of operation of the usage-side compressor. 12. The heat pump system according to claim 5, wherein the usage-side controller is further configured to perform the usage-side capacity variation control during a predetermined time duration following a start of operation of the usage-side compressor; andthe heat source-side controller is further configured to set the usage-side evaporation target temperature to a predetermined temperature or higher at the start of operation of the usage-side compressor, andthereafter incrementally lower the usage-side evaporation target temperature until the predetermined temperature is reached. 13. The heat pump system according to claim 5, further comprising: a receiver configured to receive a command to initiate the usage-side capacity variation control,the usage-side controller being further configured to perform the usage-side capacity variation control when the receiver has received the command to initiate the usage-side capacity variation control. 14. The heat pump system according to claim 10, wherein the usage-side controller is further configured to perform the usage-side capacity on control during a predetermined time duration following a start of operation of the usage-side compressor.
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이 특허에 인용된 특허 (5)
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