A refrigeration cycle apparatus simultaneously performs a cooling operation mode in which a refrigerant from a compressor is caused to flow to an indoor heat exchanger of an indoor unit having a cooling load, and a hot water supply operation mode in which a refrigerant from the compressor is caused
A refrigeration cycle apparatus simultaneously performs a cooling operation mode in which a refrigerant from a compressor is caused to flow to an indoor heat exchanger of an indoor unit having a cooling load, and a hot water supply operation mode in which a refrigerant from the compressor is caused to flow to a water heat exchanger of a hot water supply unit having a hot water supply demand. An operation control part switches the control mode of the simultaneous cooling and heating and hot water supply operation mode between a cooling-prioritized mode and a hot-water-supply-prioritized mode according to the relationship between the cooling load and the hot water supply load.
대표청구항▼
1. A refrigeration cycle apparatus comprising: a heat source unit including a compressor whose operation frequency is controllable;a hot water supply unit including a water-side circuit configured by connecting, by a pipe, a hot water storage tank, and a water heat exchanger that heats water within
1. A refrigeration cycle apparatus comprising: a heat source unit including a compressor whose operation frequency is controllable;a hot water supply unit including a water-side circuit configured by connecting, by a pipe, a hot water storage tank, and a water heat exchanger that heats water within the hot water storage tank;an indoor unit connecting by a pipe to the heat source unit in parallel with the hot water supply unit; anda controller including an operation control part that controls operations of individual units, whereinthe operation control part includes a simultaneous cooling and hot water supply operation mode, in which a cooling operation mode in which a refrigerant from the compressor is caused to flow to the indoor unit having a cooling load, and a hot water supply operation mode in which the refrigerant from the compressor is caused to flow to the hot water supply unit having a hot water supply demand, are performed simultaneously,includes, as control modes of the simultaneous cooling and hot water supply operation mode, a cooling-prioritized mode in which the operation frequency of the compressor is controlled according to the cooling load and a hot-water-supply-prioritized mode in which the operation frequency of the compressor is controlled according to the hot water supply demand, andswitches the control mode of the simultaneous cooling and hot water supply operation mode between the cooling-prioritized mode and the hot-water-supply-prioritized mode, according to a relationship between the cooling load and the hot water supply demand. 2. The refrigeration cycle apparatus of claim 1, wherein the controller further includes a hot water storage amount calculation part configured to calculate an amount of hot water storage in the hot water storage tank, andthe operation control part further selects between the cooling-prioritized mode and the hot-water-supply-prioritized mode, which are control modes of the simultaneous cooling and hot water supply operation mode, according to the amount of hot water storage, and selects a fixed amount of the operation frequency of the compressor when the hot-water-supply-prioritized mode is selected. 3. The refrigeration cycle apparatus of claim 1, further comprising a heat source pressure reducing mechanism configured to control the flow rate of the refrigerant flowing through the heat source unit, whereinin a case where the control mode of the simultaneous cooling and hot water supply operation mode is the cooling-prioritized mode, when the operation frequency of the compressor is higher than a target frequency in the hot-water-supply-prioritized mode, the operation control part enters the cooling-prioritized mode, andin a case where the control mode is the hot-water-supply-prioritized mode, when the opening degree of the heat source pressure reducing mechanism is a lower limit and an evaporating temperature is equal to or higher than a target evaporating temperature, the operation control part controls the operation frequency of the compressor so that the evaporating temperature is the target evaporating temperature. 4. The refrigeration cycle apparatus of claim 3, further comprising: indoor temperature measuring means for measuring an air temperature at an installation place of the indoor unit;an indoor pressure reducing mechanism configured to control the flow rate of the refrigerant flowing through the indoor unit; andevaporating temperature detection means for detecting an evaporating temperature between the indoor pressure reducing mechanism and the compressor, whereinthe operation control part further controls, in the hot-water-supply-prioritized mode of the simultaneous cooling and hot water supply operation mode, the opening degree of the heat source pressure reducing mechanism so that the evaporating temperature is the target evaporating temperature, andsets the target evaporating temperature in accordance with a maximum temperature difference between the indoor temperature and a set temperature of the indoor unit. 5. The refrigeration cycle apparatus of claim 4, further comprising: a heat radiation plate that rejects heat generated from an electronic substrate provided within the heat source unit; heat radiation plate temperature detection means for detecting a temperature of the heat radiation plate; and heat-source-side degree-of-superheat detection means for detecting a degree of superheat of a heat-source-side heat exchanger disposed in the heat source unit or indoor degree-of-superheat detection means for detecting a degree of superheat of an indoor heat exchanger disposed in the indoor unit, whereinthe operation control part further controls, in the cooling-prioritized mode of the simultaneous cooling and hot water supply operation mode, a rotation speed of a heat source air-sending device which supplies outside air to the heat-source-side heat exchanger so that the heat radiation plate temperature is lower than or equal to a heat radiation plate target temperature, which is a temperature at which the electronic substrate is not damaged, andcontrols, in the hot-water-supply-prioritized mode of the simultaneous cooling and hot water supply operation mode, the rotation speed of the heat source air-sending device so that the heat radiation plate temperature is lower than or equal to the heat radiation plate target temperature and any one of a state in which the heat-source-side degree of superheat is equal to or greater than a predetermined value and a state in which the indoor degree of superheat is smaller than or equal to a predetermined value is attained. 6. The refrigeration cycle apparatus of claim 5, wherein in a case where a rotation speed of the heat source air-sending device is maximum in the hot-water-supply-prioritized mode of the simultaneous cooling and hot water supply operation mode,the operation control part further controls, when a degree of superheat of the heat-source-side heat exchanger is smaller than or equal to a predetermined value, the opening degree of the heat source pressure reducing mechanism so that the degree of superheat of the heat-source-side heat exchanger is the predetermined value, orwhen the degree of superheat of the indoor heat exchanger is equal to or greater than the predetermined value, the opening degree of the heat source pressure reducing mechanism so that the degree of superheat of the indoor heat exchanger is smaller than or equal to the predetermined value. 7. The refrigeration cycle apparatus of claim 4, further comprising degree-of-subcooling detection means for detecting a degree of subcooling of the water heat exchanger, whereinin the hot-water-supply-prioritized mode of the simultaneous cooling and hot water supply operation mode,the operation control part further controls, when opening degrees of all the indoor pressure reducing mechanisms reach a lower limit, the opening degree of the heat source pressure reducing mechanism so that the degree of subcooling of the water heat exchanger is a predetermined value. 8. The refrigeration cycle apparatus of claim 4, wherein the controller further includes a communication part that is capable of inputting, to the controller via communication, a capacity of the indoor unit having a cooling load and a capacity of the hot water supply unit having the hot water supply demand, andthe operation control part determines, when selection of the control mode of the simultaneous cooling and hot water supply operation mode is switched from the cooling-prioritized mode to the hot-water-supply-prioritized mode, an initial opening degree of the heat source pressure reducing mechanism in accordance with the capacity of the indoor unit, the capacity of the hot water supply unit, and an opening degree of the indoor pressure reducing mechanism. 9. The refrigeration cycle apparatus of claim 1, wherein in the simultaneous cooling and hot water supply operation mode, the operation control part sets a temperature, by which the indoor unit is caused to enter a cooling-thermo-OFF state, lower than the cooling operation mode by 1 degree Celsius or more, and sets a temperature, by which the indoor unit is caused to enter a cooling-thermo-ON state, higher than the cooling operation mode by 1 degree Celsius or more. 10. The refrigeration cycle apparatus of claim 1, further comprising: a hot water supply remote controller including a display part that displays a priority threshold switching relation amount related to switching between the cooling-prioritized mode and the hot-water-supply-prioritized mode as the control modes, and a hot-water-supply-prioritized operation switching relation amount related to the operation frequency of the compressor in the hot-water-supply-prioritized mode, and an input part through which the priority threshold switching relation amount and the hot-water-supply-prioritized operation switching relation amount are input. 11. The refrigeration cycle apparatus of claim 1, wherein the operation control part further includes a second simultaneous cooling and hot water supply operation mode, in which the cooling operation mode and a second hot water supply operation mode in which the refrigerant from the compressor is caused to flow to the water heat exchanger of the hot water supply unit not having a hot water supply demand, are performed simultaneously, andthe second simultaneous cooling and hot water supply operation mode has the cooling-prioritized mode as a control mode, andthe operation control part further executes, when there is the cooling load but no hot water supply demand, the second simultaneous cooling and hot water supply operation mode in which the control mode is the cooling-prioritized mode, and executes, when there is the cooling load and the hot water supply demand, the simultaneous cooling and hot water supply operation mode in which hot water supply is prioritized. 12. The refrigeration cycle apparatus of claim 11, further comprising: high pressure detection means for detecting high pressure in the cooling operation mode and the second simultaneous cooling and hot water supply operation mode; cooling high pressure estimation means for estimating the high pressure in the cooling operation mode; and second cooling and hot water supply high pressure estimation means for estimating the high pressure in the second simultaneous cooling and hot water supply operation mode, whereinthe controller further includes an additional exhaust heat recovery determination part that determines whether or not to execute the second simultaneous cooling and hot water supply operation mode when there is the cooling load but no hot water supply demand, andthe additional exhaust heat recovery determination partperforms switching from the cooling operation mode to the second simultaneous cooling and hot water supply operation mode when a ratio of the estimated high pressure in the simultaneous cooling and hot water supply operation mode to the high pressure in the cooling operation mode is smaller than or equal to a high pressure determination threshold in the cooling operation mode, and performs switching from the second simultaneous cooling and hot water supply operation mode to the cooling operation mode when the ratio of the estimated high pressure in the second simultaneous cooling and hot water supply operation mode to the estimated high pressure in the cooling operation mode is equal to or greater than the high pressure determination threshold in the second simultaneous cooling and hot water supply operation mode. 13. The refrigeration cycle apparatus of claim 1, wherein the indoor unit comprises a plurality of indoor units that are connected, by a pipe, in parallel with the heat source unit. 14. The refrigeration cycle apparatus of claim 13, wherein the plurality of indoor units are connected to the heat source unit via a branch unit.
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