The present invention relates to a combined air-conditioning and hot water supply system that can execute an air-conditioning operation (cooling operation/heating operation) and a hot water supply operation simultaneously. More specifically, the present invention relates to a combined air-conditioning and hot water supply system which, by controlling an operation of a compressor, maintains high efficiency and indoor comfort, prevents hot water supply completion time to become long, and prevents hot water to become short of supply.
Conventionally, there have existed combined air-conditioning and hot water supply systems that are equipped with a refrigerant circuit formed by connecting a use unit (indoor unit) and a hot water supply unit (hot water supply device) to a heat source unit (outdoor unit) by pipes, thereby enabling an air-conditioning operation and a hot water supply operation to be executed at the same time (see, for example, Patent Literatures 1 to 3).
In these combined air-conditioning and hot water supply systems, conventionally, a plurality of use units (indoor units) are connected to a heat source unit (outdoor unit) via connecting pipes (refrigerant pipes), thereby allowing individual use units to execute a cooling operation or a heating operation. In addition, by connecting the hot water supply unit to a heat source side unit by connecting pipes (refrigerant pipes) or a cascade system, the hot water supply unit can perform hot water supply operation. That is, the air-conditioning operation of a use-side unit and the hot water supply operation of the hot water supply unit can be executed simultaneously. Also, in combined air-conditioning and hot water supply systems, hot water supply operation is executed in the hot water supply unit when cooling operation is being executed in the use unit. Therefore, waste heat generated in the cooling operation can be recovered, thereby achieving highly efficient operation.
Relating to the combined air-conditioning and hot water supply system described in Patent Literature 1, the time required for hot water supply is computed on the basis of the average temperature of hot water in a hot water supply tank, a set hot water supply temperature, and heating capacity, and the starting time of hot water supply is computed by advancing the time set by a timer by the time required for hot water supply. In this method, the heating capacity is always constant. Consequently, if the heating capacity is set to a large value, hot water supply needs to be executed in a low-efficiency operational state.
In the combined air-conditioning and hot water supply system described in Patent Literature 2, the maximum set hot water supply temperature is calculated from the total cooling load of a plurality of indoor units, and hot water is supplied with the maximum set hot water supply temperature as a set hot water supply temperature. In this method, there is no need to determine the operating frequency of the compressor so that the cooling capacity equals the total cooling load and process excess waste heat through indoor-outdoor heat exchange. Therefore, although a simultaneous cooling and hot water supply operation can be executed with high efficiency, the simultaneous cooling and hot water supply operation is not executed during hot water supply at high temperature, leading to low efficiency. Also, when the total cooling load is small, the cooling capacity is small, and the hot water supply capacity also becomes small. Thus, it takes a long time for hot water supply to be completed, and there is a possibility that hot water may run out.
In the combined air-conditioning and hot water supply system described in Patent Literature 3, the operating frequency of the compressor is controlled to a fixed value when the cooling load in the indoor unit is small, and the operating frequency of the compressor is controlled in accordance with the cooling load when the cooling load is large. In this method, when the cooling load is small and the quantity of heat required for hot water supply is small, even though it does not take much time for the hot water supply to be completed, the operating frequency of the compressor is controlled to be relatively high with respect to the cooling load, resulting in a low-efficiency operation.
According to the present invention, during simultaneous cooling and hot water supply operation, when the temperature differential ΔTwm between the inlet water temperature and the set hot water supply temperature is small, a control section controls the operating frequency of the compressor so that the cooling capacity and the cooling load in the use unit become equal, and when the temperature differential ΔTwm is large, the control section controls the operating frequency of the compressor in accordance with a hot water supply request from the hot water supply unit. An object of the present invention is to provide a combined air-conditioning and hot water supply system that executes this control to recover waste heat generated in cooling for hot water supply with high efficiency and, without compromising the cooled indoor comfort, prevent the hot water supply completion time from becoming long, thereby preventing running out of hot water.
A cooling and hot water supply system according to the present invention includes:
a heat source unit that has a compressor whose operating frequency can be controlled and a first heat exchanger;
a use unit that is connected to the heat source unit, the use unit having a second heat exchanger;
a hot water supply unit that is connected to the heat source unit, the hot water supply unit having a water-heat exchanger that heats water in a hot water supply tank by heating water in a water circuit in which the water circulates;
a measuring section that detects an inlet water temperature Twi of water entering the water-heat exchanger in the water circuit, a suction air temperature of air sucked by the use unit, and a water temperature in the hot water supply tank; and
a control section that executes a simultaneous operation of a cooling operation using the second heat exchanger and a hot water supply operation using the water-heat exchanger, when the control section receives both a cooling request signal that requests the cooling operation of the use unit and a hot water supply request signal that requests the hot water supply operation of the hot water supply unit, by causing a discharge refrigerant discharged from the compressor to pass through the second heat exchanger from the water-heat exchanger.
While the control section simultaneously executes the cooling operation and the hot water supply operation, the control section executes:
a cooling priority mode when a temperature differential ΔTwm between a set hot water supply temperature Twset that is held in advance, and the inlet water temperature Twi detected by the measuring section is smaller than a priority operation determination threshold M that is set in advance, the cooling priority mode being a mode that controls an operating frequency of the compressor in accordance with a temperature differential between the suction air temperature detected by the measuring section and a cooling set temperature of the use unit that is held in advance; and
a hot water supply priority mode when the temperature differential ΔTwm is equal to or more than the priority operation determination threshold M, the hot water supply priority mode being a mode that controls the operating frequency of the compressor in accordance with a temperature differential between the set hot water supply temperature Twset and the water temperature in the hot water supply tank detected by the measuring section.
According to the cooling and hot water supply system of the present invention, waste heat generated in cooling is recovered for hot water supply with high efficiency and, while maintaining indoor comfort, it is possible to prevent the hot water supply completion time from becoming long, thereby preventing running out of hot water.
Hereinafter, Embodiment 1 will be described with reference to
The combined air-conditioning and hot water supply system 100 is a three-pipe multi-system combined air-conditioning and hot water supply system that can simultaneously handle a selected cooling operation or heating operation in a use unit and a hot water supply operation in a hot water supply unit, by carrying out a vapor compression refrigeration cycle operation. The combined air-conditioning and hot water supply system 100 executes a hot water supply operation in the hot water supply unit when a cooling operation is being performed, thereby enabling recovery of waste heat generated in the cooling operation. Thus, the combined air-conditioning and hot water supply system 100 is highly efficient, and can prevent running out of hot water by ensuring that it does not take a long time to complete hot water supply.
The combined air-conditioning and hot water supply system 100 has a heat source unit 301, a branch unit 302, a use unit 303, the hot water supply unit 304, and the hot water supply tank 305. The heat source unit 301 and the branch unit 302 are connected via a liquid extension pipe 6 that is a refrigerant pipe, and a gas extension pipe 12 that is a refrigerant pipe. One side of the hot water supply unit 304 is connected to the heat source unit 301 via a hot water supply gas extension pipe 15 that is a refrigerant pipe, and the other side is connected to the branch unit via a hot water supply liquid pipe 18 that is a refrigerant pipe. The use unit 303 and the branch unit 302 are connected via an indoor gas pipe 11 that is a refrigerant pipe, and an indoor liquid pipe 8 that is a refrigerant pipe. Also, the hot water supply tank 305 and the hot water supply unit 304 are connected by an upstream water pipe 20 that is a water pipe, and a downstream water pipe 21 that is a water pipe.
While Embodiment 1 is directed to a case where a single heat source unit 1 is connected with a single use unit, a single hot water supply unit, and a single hot water supply tank, the present invention is not limited to this case. The numbers of these components may be more than or equal to, or less than or equal to those illustrated in the drawings. Also, the refrigerant used in the combined air-conditioning and hot water supply system 100 is, for example, a HFC (hydrofluorocarbon) refrigerant such as R410A, R407C, or R404A, a HCFC (hydrochlorofluorocarbon) refrigerant such as R22 or R134a, or a natural refrigerant such as carbon hydride, helium, or carbon dioxide.
Also, the combined air-conditioning and hot water supply system 100 includes a system control device 110 as illustrated in
Operations modes that can be executed by the combined air-conditioning and hot water supply system 100 will be briefly described. In the combined air-conditioning and hot water supply system 100, the operation mode of the heat source unit 301 is determined in accordance with the ratio between the hot water supply load in the connected hot water supply unit 304 and the cooling load or heating load in the connected use unit 303. The combined air-conditioning and hot water supply system 100 is capable of executing three operation modes described below (a cooling operation mode, a simultaneous heating and hot water supply operation mode, and a simultaneous cooling and hot water supply operation mode).
The cooling operation mode is the operation mode of the heat source unit 301 when there is no hot water supply request signal (described later) and the use unit 303 executes a cooling operation. The simultaneous heating and hot water supply operation mode is the operation mode of the heat source unit 301 when executing a simultaneous operation of a heating operation by the use unit 303 and a hot water supply operation by the hot water supply unit 304. The simultaneous cooling and hot water supply operation mode is the operation mode of the heat source unit 301 when executing a simultaneous operation of a cooling operation by the use unit 303 and a hot water supply operation by the hot water supply unit 304.
The use unit 303 is connected to the heat source unit 301 via the branch unit 302. The use unit 303 is installed in a location that allows the use unit 303 to blow conditioned air to an air-conditioned area (e.g. concealed or suspended on the ceiling inside a building, or hung on the wall surface). The use unit 303 is connected to the heat source unit 301 via the branch unit 302, the liquid extension pipe 6, and the gas extension pipe 12, and constitutes a part of the refrigerant circuit.
The use unit 303 includes an indoor-side refrigerant circuit that constitutes a part of the refrigerant circuit. This indoor-side refrigerant circuit is configured by an indoor heat exchanger 9 (second heat exchanger) that serves as a use-side heat exchanger. Also, the use unit 303 is provided with an indoor air-sending device 10 for supplying conditioned air that has exchanged heat with the refrigerant passing through the indoor heat exchanger 9 to an air-conditioned area such as an indoor area.
The indoor heat exchanger 9 can be configured by, for example, a cross-fin type fin-and-tube heat exchanger including a heat-transfer tube and a number of fins. Also, the indoor heat exchanger 9 may be configured by a micro-channel heat exchanger, a shell-and-tube heat exchanger, a heat-pipe heat exchanger, or a double-pipe heat changer. When the use unit 303 executes the cooling operation mode and the simultaneous cooling and hot water supply operation mode, the indoor heat exchanger 9 functions as an evaporator of the refrigerant to cool the air in the air-conditioned area, and when the use unit 303 executes the simultaneous heating and hot water supply mode, the indoor heat exchanger 9 functions as a condenser (radiator) of the refrigerantmm to heat the air in the air-conditioned area.
The indoor air-sending device 10 has the function of causing indoor air to be sucked into the use unit 303, and after making the indoor air exchange heat with the refrigerant in the indoor heat changer 9, supplying the air to the air-conditioned area as conditioned air. That is, in the use unit 303, heat can be exchanged between the indoor air taken in by the indoor air-sending device 10, and the refrigerant flowing through the indoor heat exchanger 9. The indoor air-sending device 10 is configured to be able to vary the flow rate of conditioned air supplied to the indoor heat exchanger 9. For example, the indoor air-sending device 10 includes a fan such as a centrifugal fan or a multi-blade fan, and a motor that drives this fan, for example, a DC fan motor.
Further, the use unit 303 is provided with various sensors described below:
(1) an indoor liquid temperature sensor 206 that is provided on the liquid side of the indoor heat exchanger 9, and detects the temperature of a liquid refrigerant;
(2) an indoor gas temperature sensor 207 that is provided on the gas side of the indoor heat exchanger 9, and detects the temperature of a gas refrigerant; and
(3) an indoor suction temperature sensor 208 that is provided on the suction port side of the indoor air of the use unit 303, and detects the temperature of the indoor air entering the unit.
As illustrated in
The hot water supply unit 304 is connected to the heat source unit 301 via the branch unit 302. As illustrated in
The hot water supply unit 304 includes a hot water supply-side refrigerant circuit that constitutes a part of the refrigerant circuit. This hot water supply-side refrigerant circuit has a plate water-heat exchanger 16 (water-heat exchanger) as its functional constituent. Also, the hot water supply unit 304 is provided with a water supply pump 17 for supplying hot water that has exchanged heat with the refrigerant in the plate water-heat exchanger 16 to the hot water supply tank or the like.
In the hot water supply operation mode executed by the hot water supply unit 304, the plate water-heat exchanger 16 functions as a condenser (or radiator) of the refrigerant, and heats water that is supplied by the water supply pump 17. The water supply pump 17 has the function of supplying water into the hot water supply unit 304, causing the water to exchange heat in the plate water-heat exchanger 16 and turn into hot water, and thereafter supplying the hot water into the hot water supply tank 305 for heat exchange with the water in the hot water supply tank 305. That is, in the hot water supply unit 304, heat can be exchanged between the water supplied from the water supply pump 17 and the refrigerant flowing through the plate water-heat exchanger 16, and also heat can be exchanged between the water supplied from the water supply pump 17 and the water in the hot water supply tank 305. Also, the hot water supply unit 304 is configured to be able to vary the flow rate of water supplied to the plate water-heat exchanger 16.
Also, the hot water supply unit 304 is provided with various sensors described below:
(1) a hot water supply liquid temperature sensor 209 that is provided on the liquid side of the plate water-heat exchanger 16, and detects the temperature of a liquid refrigerant;
(2) an inlet water temperature sensor 210 that is provided on the water inlet side of the hot water supply unit 304, and detects the temperature of water entering the unit; and
(3) an outlet water temperature sensor 211 that is provided on the water outlet side of the hot water supply unit 304, and detects the temperature of water exiting the unit.
As illustrated in
The hot water supply tank is installed outside a building, for example, and has the function of storing hot water boiled up by the hot water supply unit 304. One side of the hot water supply tank 305 is connected to the hot water supply unit 304 via the upstream water pipe 20, and the other side is connected to the hot water supply unit 304 via the downstream water pipe 21. The hot water supply tank 305 constitutes a part of a water circuit 304-1 in the combined air-conditioning and hot water supply system 100. That is, as illustrated in
The water fed by the water supply pump 17 in the hot water supply unit 304 is heated by the refrigerant in the plate water-heat exchanger 16 and turns into hot water, and enters the hot water supply tank 305 via the upstream water pipe 20. The hot water that has entered the hot water supply tank 305 exchanges heat with the water in the tank and turns into cold water. After exiting the hot water supply tank 305, the cold water enters the hot water supply unit 304 again via the downstream water pipe 21. After being fed again by the water supply pump 17, the cold water turns into hot water in the plate water-heat exchanger 16. Through this process, hot water is boiled up in the hot water supply tank 305. While hot water is boiled up indirectly according to the specifications in
Also, the hot water supply tank 305 is provided with various sensors described below:
(1) a first hot water supply tank water temperature sensor 212 that is provided on an upper side surface of the hot water supply tank 305, and detects hot water supply temperature in an upper portion of the tank;
(2) a second hot water supply tank water temperature sensor 213 that is provided below the first hot water supply tank water temperature sensor 212, and detects hot water supply temperature in a portion of the tank located below the installation position of the first hot water supply tank water temperature sensor 212; (3) a third hot water supply tank water temperature sensor 214 that is provided below the second hot water supply tank water temperature sensor 213, and detects hot water supply temperature in a portion of the tank located below the installation position of the second hot water supply tank water temperature sensor 213; (4) a fourth hot water supply tank water temperature sensor 215 that is provided on an lower side surface of the hot water supply tank 305, and detects hot water supply temperature in a lower portion of the tank; and
(5) a water supply temperature sensor 216 that detects the temperature of water supplied from the bottom of the hot water supply tank 305.
The heat source unit 301 is installed outside a building, for example. The heat source unit 301 is connected to the use unit 303 via the liquid extension pipe 6, the gas extension pipe 12, and the branch unit 302. Also, the heat source unit 301 is connected to the hot water supply unit 304 via the hot water supply gas extension pipe 15, the liquid extension pipe 6, and the branch unit 302. The heat source unit 301 constitutes a part of the refrigerant circuit in the combined air-conditioning and hot water supply system 100.
The heat source unit 301 includes an outdoor-side refrigerant circuit that constitutes a part of the refrigerant circuit. This outdoor-side refrigerant circuit has, as its constituent devices, a compressor 1 that compresses the refrigerant, two four-way valves (a first four-way valve 2 and a second four-way valve 13) for switching the direction of flow of the refrigerant in accordance with the outdoor operation mode, an outdoor heat exchanger 3 (a first heat exchanger) serving as a heat source side heat exchanger, and an accumulator 14 for storing excess refrigerant. Also, the heat source unit 301 includes an outdoor air-sending device 4 for supplying air to the outdoor heat exchanger 3, and an outdoor pressure-reducing mechanism (heat source-side pressure-reducing mechanism) 5 for controlling the flow rate of the refrigerant to be distributed.
The compressor 1 sucks a refrigerant, and compresses the refrigerant into a high-temperature high-pressure state. The compressor 1 that is equipped in Embodiment 1 is capable of varying its operation capacity, and is configured by, for example, a positive displacement compressor that is driven by a motor (not illustrated) controlled by an inverter. While Embodiment 1 is directed to a case where there is only one compressor 1, the present invention is not limited to this. Depending on the connected number of use units 303 and hot water supply units 304, or the like, two or more compressors 1 may be connected in parallel. Also, the discharge-side pipe connected to the compressor 1 is branched midway such that one side is connected to the gas extension pipe 12 via the second four-way valve 13, and the other side is connected to the hot water supply gas extension pipe 15 via the first four-way valve 2.
The first four-way valve 2 and the second four-way valve 13 each function as a flow switching device that switches the direction of flow of the refrigerant in accordance with the operation mode of the heat source unit 301.
The first four-way valve 2 is switched to the “solid line” in a cooling only operation mode. That is, in the cooling only operation mode, in order to make the outdoor heat exchanger 3 function as a condenser for the refrigerant that is compressed in the compressor 1, the first four-way valve 2 is switched so as to connect the discharge side of the compressor 1 to the gas side of the outdoor heat exchanger 3. Also, the first four-way valve 2 is switched to the “broken line” in the simultaneous heating and hot water supply operation mode or simultaneous cooling and hot water supply operation mode. That is, in the simultaneous heating and hot water supply operation mode or simultaneous cooling and hot water supply operation mode, in order to make the outdoor heat exchanger 3 function as an evaporator for the refrigerant, the first four-way valve 2 is switched so as to connect the discharge side of the compressor 1 to the gas side of the plate water-heat exchanger 16, and connect the suction side of the compressor 1 to the gas side of the outdoor heat exchanger 3.
The second four-way valve 13 is switched to the “solid line” in the cooling only operation mode or simultaneous cooling and hot water supply operation mode. That is, in the cooling only operation mode or simultaneous cooling and hot water supply operation mode, in order to make the indoor heat exchanger 9 function as an evaporator for the refrigerant that is compressed in the compressor 1, the second four-way valve 13 is switched so as to connect the suction side of the compressor 1 to the gas side of the indoor heat exchanger 9. Also, the second four-way valve 13 is switched to the “broken line” in the simultaneous heating and hot water supply operation mode. That is, in the simultaneous heating and hot water supply operation mode, in order to make the indoor heat exchanger 9 function as a condenser for the refrigerant, the second four-way valve 13 is switched so as to connect the discharge side of the compressor 1 to the gas side of the indoor heat exchanger 9.
The gas side of the outdoor heat exchanger 3 is connected to the first four-way valve 2, and the liquid side is connected to an outdoor pressure-reducing mechanism 5. The outdoor heat exchanger 3 can be configured by, for example, a cross-fin type fin-and-tube heat exchanger including a heat-transfer tube and a number of fins. Also, the outdoor heat exchanger 3 may be configured as a micro-channel heat exchanger, a shell-and-tube heat exchanger, a heat-pipe heat exchanger, or a double-pipe heat changer. The outdoor heat exchanger 3 functions as a condenser for the refrigerant to heat the refrigerant in the cooling only operation mode or simultaneous cooling and hot water supply operation mode, and functions as an evaporator for the refrigerant to cool the refrigerant in the simultaneous heating and hot water supply operation mode.
The outdoor air-sending device 4 has the function of sucking the outdoor air into the heat source unit 301, causing the outdoor air to exchange heat in the outdoor heat exchanger 3, and thereafter emitting the air outdoors. That is, in the heat source unit 301, heat can be exchanged between the outside air taken in by the outdoor air-sending device 4, and the refrigerant flowing through the outdoor heat exchanger 3. The outdoor air-sending device 4 is configured to be able to vary the flow rate of air supplied to the outdoor heat exchanger 3. The outdoor air-sending device 4 includes a fan such as a propeller fan, and a motor that drives this fan, for example, a DC fan motor.
The accumulator 14 is provided on the suction side of the compressor 1. The accumulator 14 has the function of storing a liquid refrigerant to prevent liquid backflow to the compressor 1 when an abnormality occurs in the combined air-conditioning and hot water supply system 100 or during the transient response of the operational state caused by a change in operation control.
Also, the heat source unit 301 is provided with various sensors described below:
(1) a high-pressure pressure sensor 201 (high-pressure detecting device) that is provided on the discharge side of the compressor 1, and detects a high-pressure side pressure;
(2) a discharge temperature sensor 202 that is provided on the discharge side of the compressor 1, and detects a discharge temperature;
(3) an outdoor gas temperature sensor 203 that is provided on the gas side of the outdoor heat exchanger 3, and detects a gas refrigerant temperature;
(4) an outdoor liquid temperature sensor 204 that is provided on the liquid side of the outdoor heat exchanger 3, and detects the temperature of a liquid refrigerant; and
(5) an outside air temperature sensor 205 that is provided on the suction port side of the outside air of the heat source unit 301, and detects the temperature of the outside air entering the unit.
The operations of the compressor 1, first four-way valve 2, outdoor air-sending device 4, outdoor pressure-reducing mechanism 5, and second four-way valve 13 are controlled by the control section 103 that functions as normal operation control means for performing normal operation including the cooling operation mode, the simultaneous heating and hot water supply operation mode, and the simultaneous cooling and hot water supply operation mode.
The branch unit 302 is installed inside a building, for example. The branch unit 302 is connected to the heat source unit 301 via the liquid extension pipe 6 and the gas extension pipe 12, is connected to the use unit 303 via the indoor liquid pipe 8 and the indoor gas pipe 11, and is connected to the hot water supply unit 304 via the hot water supply liquid pipe 18. The branch unit 302 constitutes a part of the refrigerant circuit in the combined air-conditioning and hot water supply system 100. The branch unit 302 has the function of controlling the flow of the refrigerant in accordance with the operation that is being required in each of the use unit 303 and the hot water supply unit 304.
The branch unit 302 includes a branch refrigerant circuit that constitutes a part of the refrigerant circuit. This branch refrigerant circuit has, as its constituent devices, an indoor pressure-reducing mechanism (use-side pressure-reducing mechanism) 7 for controlling the flow rate of the refrigerant to be distributed, and a hot water supply pressure-reducing mechanism 19 for controlling the flow rate of the refrigerant to be distributed.
The indoor pressure-reducing mechanism 7 is provided in the indoor liquid pipe 8. Also, the hot water supply pressure-reducing mechanism 19 is provided in the hot water supply liquid pipe 18 within the branch unit 302. The indoor pressure-reducing mechanism 7 functions as a pressure reducing valve or an expansion valve. In the cooling operation mode or the simultaneous cooling and hot water supply operation mode, the indoor pressure-reducing mechanism 7 reduces the pressure of the refrigerant flowing through the liquid extension pipe 6 to thereby cause the refrigerant to expand, and in the simultaneous heating and hot water supply operation mode, the indoor pressure-reducing mechanism 7 reduces the pressure of the refrigerant flowing through the indoor liquid pipe 8 to thereby cause the refrigerant to expand. The hot water supply pressure-reducing mechanism 19 functions as a pressure reducing valve or an expansion valve. In the simultaneous cooling and hot water supply operation mode or the simultaneous heating and hot water supply operation mode, the hot water supply pressure-reducing mechanism 19 reduces the pressure of the refrigerant flowing through the hot water supply liquid pipe 18 to thereby cause the refrigerant to expand. The indoor pressure-reducing mechanism 7 and the hot water supply pressure-reducing mechanism 19 are each preferably configured so that its opening degree can be variably controlled, for example, precision flow control means formed by an electronic expansion valve, or inexpensive refrigerant flow control means such as a capillary tube.
As illustrated in
Also, as illustrated in
Specifically, the control section 103 executes various operation modes by controlling the driving frequency of the compressor 1, switching of the first four-way valve 2, the rotation speed (including ON/OFF) of the outdoor air-sending device 4, the opening degree of the outdoor pressure-reducing mechanism 5, the opening degree of the indoor pressure-reducing mechanism 7, the rotation speed (including ON/OFF) of the indoor air-sending device 10, switching of the second four-way valve 13, the rotation speed (including ON/OFF) of the water supply pump 17, and the opening degree of the hot water supply pressure-reducing mechanism 19, on the basis of the operation mode inputted via a remote control (e.g. a cooling request signal that requests the cooling operation of the use unit 303), a hot water supply request signal described later, command regarding a temperature setting or the like, and information detected by various sensors. The measuring section 101, the computing section 102, and the control section 103 may be provided integrally, or may be provided separately. Also, the measuring section 101, the computing section 102, and the control section 103 may be provided in one of the units. Further, the measuring section 101, the computing section 102, and the control section 103 may be provided in each unit.
The combined air-conditioning and hot water supply system 100 executes the cooling operation mode, the simultaneous heating and hot water supply operation mode, and the simultaneous cooling and hot water supply operation mode by controlling various devices equipped to the heat source unit 301, the branch unit 302, the use unit 303, and the hot water supply unit 304 in accordance with each individual operating load required in the use unit 303, and a hot water supply request signal requested to the hot water supply unit 304. The simultaneous cooling and hot water supply operation mode allows waste heat generated in cooling to be used for hot water supply, thereby achieving high efficiency.
As will be described later with reference to
Specifically, the control section 103 operates in the cooling priority mode in a case where
ΔTwm<M.
The cooling priority mode is a mode in which the control section 103 controls the operating frequency of the compressor 1 in accordance with the indoor suction temperature detected by the measuring section 101 (detected by the measuring section 101 via the indoor suction temperature sensor 208), and the indoor set temperature of the use unit 303 that is held in advance (received by the control section 103 from a remote control or the use unit 303, for example).
Also, the control section 103 operates in the hot water supply priority mode in a case where
ΔTwm≧M.
The hot water supply priority mode is a mode in which the control section 103 controls the operating frequency of the compressor 1 in accordance with the temperature differential between the set hot water supply temperature Twset, and the water temperature in the hot water supply tank 305 detected by the measuring section 101 (detected by the measuring section 101 via the first hot water supply tank water temperature sensors 212 to 215, and the like).
A hot water supply request signal is outputted by the hot water supply unit 304 when the temperature of water stored in the hot water supply tank 305 is below a set hot water supply temperature. When the hot water supply request signal is outputted, in order to raise the temperature of water in the hot water supply tank to the set hot water supply temperature in as a short time as possible, the control section 103 makes the operating frequency of the compressor 1 higher to increase the hot water supply capacity. Also, in a case where the operating frequency of the compressor 1 is to be controlled in accordance with the cooling load, the cooling load is estimated from the temperature differential (indoor temperature differential) between the indoor suction temperature (suction air temperature) and the indoor set temperature (cooling set temperature), and the operating frequency is controlled by regarding that the larger the indoor temperature differential, the larger the cooling load.
In a case where the simultaneous cooling and hot water supply operation mode is executed in the hot water supply priority mode, the control section 103 determines the operating frequency of the compressor 1 in accordance with a hot water supply request signal from the hot water supply unit 304. For this reason, heat needs to be rejected in the outdoor heat exchanger 3 in order to make the cooling capacity and the cooling load equal. When the hot water supply unit 304 (or the computing section 102) ceases to output a hot water supply request signal and hot water supply is complete, the control section 103 executes a cooling operation. In this operation, the operating frequency of the compressor 1 is raised to increase the hot water supply capacity, thereby completing hot water supply in a short time.
In a case where the simultaneous cooling and hot water supply operation mode is executed in the cooling priority mode, the operating frequency of the compressor 1 is determined in accordance with the cooling load in the use unit 303. Therefore, the cooling capacity and the cooling load become equal, and there is no need to remove heat in the outdoor heat exchanger 3. When there is no longer a hot water supply request signal from the hot water supply unit 304 and hot water supply is complete, the control section 103 executes a cooling operation. In this operation, the operating frequency of the compressor 1 is set lower than that in the hot water supply priority operation, and thus hot water supply can be performed with high efficiency. However, because the hot water supply capacity becomes smaller, it takes time to complete hot water supply.
The specific operations of the cooling operation mode, simultaneous heating and hot water supply operation mode, and simultaneous cooling and hot water supply operation mode executed by the combined air-conditioning and hot water supply system 100 will be described. The operations of the four-way valves in individual operation modes are as illustrated in
In the cooling operation mode, the use unit 303 is in the cooling operation mode. In the cooling operation mode, the first four-way valve 2 is in the state indicated by the solid line, that is, a state in which the discharge side of the compressor 1 is connected to the gas side of the outdoor heat exchanger 3. Also, the second four-way valve 13 is in the state indicated by the solid line, that is, a state in which the suction side of the compressor 1 is connected to the indoor heat exchanger 9 via the gas extension pipe 12.
In this state of the refrigerant circuit, the compressor 1, the outdoor air-sending device 4, and the indoor air-sending device 10 are activated. Then, a low-pressure gas refrigerant is sucked into the compressor 1, where the refrigerant is compressed into a high-temperature high-pressure gas refrigerant. Thereafter, the high-temperature high-pressure gas refrigerant enters the outdoor heat exchanger 3 via the first four-way valve 2, where the gas refrigerant is condensed by exchanging heat with the outdoor air supplied by the outdoor air-sending device 4, and turns into a high-pressure gas refrigerant. After exiting the outdoor heat exchanger 3, the refrigerant flows to the outdoor pressure-reducing mechanism 5, where its pressure is reduced. Thereafter, the refrigerant enters the branch unit 302 via the liquid extension pipe 6. At this time, the outdoor pressure-reducing mechanism 5 is being controlled to the maximum opening degree. The refrigerant that has entered the branch unit 302 is reduced in pressure in the indoor pressure-reducing mechanism 7, and turns into a two-phase gas-liquid refrigerant at low pressure, Thereafter, the refrigerant exits the branch unit 302, and enters the use unit 303 via the indoor liquid pipe 8.
The refrigerant that has entered the use unit 303 enters the indoor heat exchanger 9, and is evaporated into a low-pressure gas refrigerant by exchanging heat with the indoor air supplied by the indoor air-sending device 10. The degree of subcooling of the refrigerant on the liquid side of the outdoor heat exchanger 3 is calculated by subtracting the temperature detected by the outdoor liquid temperature sensor 204, from the saturation temperature (condensing temperature) computed from the pressure detected by the high-pressure pressure sensor 201.
The indoor pressure-reducing mechanism 7 controls the flow rate of the refrigerant flowing through the indoor heat exchanger 9 so that the degree of subcooling of the refrigerant on the liquid side of the outdoor heat exchanger 3 becomes a predetermined value. Consequently, the low-pressure gas refrigerant that has been evaporated in the outdoor heat exchanger 3 has a predetermined degree of subcooling. In this way, in the indoor heat exchanger 9, refrigerant flows at a flow rate corresponding to the cooling load required in the conditioned space where the use unit 303 is installed.
The refrigerant that has exited the indoor heat exchanger 9 exits the use unit 303, and flows to the gas extension pipe 12 after passing through the indoor gas pipe 11 and the branch unit 302. The refrigerant then passes through the accumulator 14 via the second four-way valve 13, and is sucked into the compressor 1 again.
The operating frequency of the compressor 1 is controlled by the control section 103 so that in the use unit 303, there is no temperature difference between the indoor set temperature and the indoor suction temperature detected by the indoor suction temperature sensor 208. Also, the air flow of the outdoor air-sending device 4 is controlled by the control section 103 so that the condensing temperature becomes a predetermined value in accordance with the outside air temperature detected by the outside air temperature sensor 205. Here, the condensing temperature is the saturation temperature computed from the pressure detected by the high-pressure pressure sensor 201.
In the simultaneous heating and hot water supply operation mode, the use unit 303 is in the heating operation mode, and the hot water supply unit 304 is in the hot water supply operation mode. In the simultaneous heating and hot water supply operation mode, the first four-way valve 2 is in the state indicated by the broken line, that is, the discharge side of the compressor 1 is connected to the gas side of the plate water-heat exchanger 16, and the suction side of the compressor 1 is connected to the gas side of the outdoor heat exchanger 3. Also, the second four-way valve 13 is in the state indicated by the broken line, that is, the discharge side of the compressor 1 is connected to the gas side of the indoor heat exchanger 9.
In this state of the refrigerant circuit, the compressor 1, the outdoor air-sending device 4, the indoor air-sending device 10, and the water supply pump 17 are activated. Then, a low-pressure gas refrigerant is sucked into the compressor 1, where the gas refrigerant is compressed into a high-temperature high-pressure gas refrigerant. Thereafter, the high-temperature high-pressure gas refrigerant is distributed so as to flow through the first four-way valve 2 or the second four-way valve 13.
The refrigerant that has entered the first four-way valve 2 exits the heat source unit 301, and enters the hot water supply unit 304 via the hot water supply gas extension pipe 15. The refrigerant that has entered the hot water supply unit 304 enters the plate water-heat exchanger 16, where the refrigerant is condensed by exchanging heat with the water supplied by the water supply pump 17 and turns into a high-pressure liquid refrigerant, and exits the plate water-heat exchanger 16. After the refrigerant that has heated the water in the plate water-heat exchanger 16 exits the hot water supply unit 304, the refrigerant enters the branch unit 302 via the hot water supply liquid pipe 18, and is reduced in pressure by the hot water supply pressure-reducing mechanism 19 and turns into a two-phase gas-liquid refrigerant at low pressure. Thereafter, the refrigerant joins the refrigerant that has flown through the indoor pressure-reducing mechanism 7, and exits the branch unit 302.
The hot water supply pressure-reducing mechanism 19 is controlled by the control section 103 to such an opening degree that the degree of subcooling on the liquid side of the plate water-heat exchanger 16 becomes a predetermined value. The degree of subcooling on the liquid side of the plate water-heat exchanger 16 is calculated by computing the saturation temperature (condensing temperature) from the pressure detected by the high-pressure pressure sensor 201, and subtracting the temperature detected by the hot water supply liquid temperature sensor 209 from the saturation temperature. Since the hot water supply pressure-reducing mechanism 19 controls the flow rate of refrigerant flowing through the plate water-heat exchanger 16 so that the degree of subcooling of the refrigerant on the liquid side of the plate water-heat exchanger 16 becomes a predetermined value, the high-pressure liquid refrigerant that has been condensed in the plate water-heat exchanger 16 has a predetermined degree of subcooling. In this way, in the plate water-heat exchanger 16, refrigerant flows at a flow rate corresponding to the hot water supply request requested in accordance with the use condition of hot water in the facility where the hot water supply unit 304 is installed.
Meanwhile, the refrigerant that has entered the second four-way valve 13 exits the heat source unit 301, and flows to the branch unit 302 via the gas extension pipe 12. Thereafter, the refrigerant enters the use unit 303 via the indoor gas pipe 11. The refrigerant that has entered the use unit 303 enters the indoor heat exchanger 9, where the refrigerant is condensed by exchanging heat with the indoor air supplied by the indoor air-sending device 10 and turns into a high-pressure liquid refrigerant, and exits the indoor heat exchanger 9. The refrigerant that has heated the indoor air in the indoor heat exchanger 9 exits the use unit 303, and enters the branch unit 302 via the indoor liquid pipe 8. The refrigerant is then reduced in pressure by the indoor pressure-reducing mechanism 7, and turns into a two-phase gas-liquid or liquid-phase refrigerant at low pressure. Thereafter, the refrigerant joins the refrigerant that has flown through the hot water supply pressure-reducing mechanism 19, and exits the branch unit 302.
The indoor pressure-reducing mechanism 7 is controlled by the control section 103 to such an opening degree that the degree of subcooling on the liquid side of the indoor heat exchanger 9 becomes a predetermined value. The degree of subcooling on the liquid side of the indoor heat exchanger 9 is calculated by computing the saturation temperature (condensing temperature) from the pressure detected by the high-pressure pressure sensor 201, and subtracting the temperature detected by the indoor liquid temperature sensor 206 from the saturation temperature. That is, the indoor pressure-reducing mechanism 7 is controlled by the control section 103 to such an opening degree that the degree of subcooling of the refrigerant on the liquid side of the indoor heat exchanger 9 becomes a predetermined value. Since the indoor pressure-reducing mechanism 7 controls the flow rate of refrigerant flowing through the indoor heat exchanger 9 so that the degree of subcooling of the refrigerant on the liquid side of the indoor heat exchanger 9 becomes a predetermined value, the high-pressure liquid refrigerant that has been condensed in the indoor heat exchanger 9 has a predetermined degree of subcooling. Consequently, in the indoor heat exchanger 9, refrigerant flows at a flow rate corresponding to the heating load required in the conditioned space where the use unit 303 is installed.
The refrigerant that has exited the branch unit 302 enters the heat source unit 301 via the liquid extension pipe 6, and after passing through the outdoor pressure-reducing mechanism 5, the refrigerant enters the outdoor heat exchanger 3. The opening degree of the outdoor pressure-reducing mechanism 5 is being controlled to the full opening. The refrigerant that has entered the outdoor pressure-reducing mechanism 5 is evaporated by exchanging heat with the outside air supplied by the outdoor air-sending device 4, and turns into a low-pressure gas refrigerant. After exiting the outdoor heat exchanger 3, this refrigerant passes through the accumulator 14 via the first four-way valve 2, and is thereafter sucked into the compressor 1 again.
The operating frequency of the compressor 1 is controlled by the control section 103 from a hot water supply request signal detected by the hot water supply tank. Also, the air flow of the outdoor air-sending device 4 is controlled by the control section 103 so that the evaporating temperature becomes a predetermined value in accordance with the outside air temperature detected by the outside air temperature sensor 205. Here, the evaporating temperature is calculated from the temperature detected by the outdoor liquid temperature sensor 204.
In the simultaneous cooling and hot water supply operation mode, the use unit 303 is in the cooling operation mode, and the hot water supply unit 304 is in the hot water supply operation mode. In the simultaneous cooling and hot water supply operation mode, the first four-way valve 2 is in the state indicated by the broken line, that is, the discharge side of the compressor 1 is connected to the plate water-heat exchanger 16 via the hot water supply gas extension pipe 15, and the suction side of the compressor 1 is connected to the gas side of the outdoor heat exchanger 3. Also, the second four-way valve 13 is in the state indicated by the broken line, that is, the suction side of the compressor 1 is connected to the indoor heat exchanger 9 via the gas extension pipe 12.
In this state of the refrigerant circuit, the compressor 1, when the outdoor air-sending device 4, the indoor air-sending device 10, and the water supply pump 17 are activated, a low-pressure gas refrigerant is sucked into the compressor 1, where the gas refrigerant is compressed into a high-temperature high-pressure gas refrigerant. Thereafter, the high-temperature high-pressure gas refrigerant enters the first four-way valve 2.
The refrigerant that has entered the first four-way valve 2 exits the heat source unit 301, and enters the hot water supply unit 304 via the hot water supply gas extension pipe 15. The refrigerant that has entered the hot water supply unit 304 enters the plate water-heat exchanger 16, where the refrigerant is condensed by exchanging heat with the water supplied by the water supply pump 17 and turns into a high-pressure liquid refrigerant, and exits the plate water-heat exchanger 16. The refrigerant that has heated the water in the plate water-heat exchanger 16 exits the hot water supply unit 304, and enters the branch unit 302 via the hot water supply liquid pipe 18.
The refrigerant that has entered the branch unit 302 is reduced in pressure by the hot water supply pressure-reducing mechanism 19, and turns into a two-phase gas-liquid or liquid-phase refrigerant at intermediate pressure. At this time, the hot water supply pressure-reducing mechanism 19 is controlled to the maximum opening. Thereafter, the refrigerant is divided into a refrigerant that enters the liquid extension pipe 6, and a refrigerant that enters the indoor pressure-reducing mechanism 7.
The refrigerant that has entered the indoor pressure-reducing mechanism 7 is reduced in pressure into a two-phase gas-liquid state at low pressure, and enters the use unit 303 via the indoor liquid pipe 8. The refrigerant that has entered the use unit 303 enters the indoor heat exchanger 9, where the refrigerant is evaporated by exchanging heat with the indoor air supplied by the indoor air-sending device 10 and turns into a low-pressure gas refrigerant.
The indoor pressure-reducing mechanism 7 is controlled by the control section 103 to such an opening degree that the degree of subcooling of the refrigerant on the liquid side of the plate water-heat exchanger 16 becomes a predetermined value. The method of calculating this degree of subcooling is as previously described with reference to the cooling operation mode.
The refrigerant that has flown through the indoor heat exchanger 9 thereafter exits the use unit 303, and enters the heat source unit 301 via the indoor gas pipe 11, the branch unit 302, and the gas extension pipe 12. The refrigerant that has entered the heat source unit 301 passes through the second four-way valve 13, and thereafter joins the refrigerant that has passed through the indoor heat exchanger 3.
Meanwhile, the refrigerant that has entered the liquid extension pipe 6 thereafter enters the heat source unit 301, and after being reduced in pressure into a two-phase gas-liquid refrigerant at low pressure by the heat source-side pressure-reducing mechanism 5, the refrigerant enters the outdoor heat exchanger 3, where the refrigerant is evaporated by exchanging heat with the outdoor air supplied by the outdoor air-sending device 4. Thereafter, the refrigerant passes through the first four-way valve 2, and joins the refrigerant that has passed through the indoor heat exchanger 9. Thereafter, the refrigerant passes through the accumulator 14 and is sucked into the compressor 1 again.
(1) In a case where the simultaneous cooling and hot water supply operation mode is the hot water supply priority mode, the operating frequency of the compressor 1 is controlled by the control section 103 in accordance with a hot water supply request from the hot water supply unit 304. Therefore, in order to make the cooling capacity equal to the cooling load in the use unit 303, heat needs to be removed in the outdoor heat exchanger 3. The opening degree of the outdoor pressure-reducing mechanism 5 is controlled by the control section 103 so that the degree of superheat on the gas side of the outdoor heat exchanger 3 becomes a predetermined value. The degree of superheat on the gas side of the outdoor heat exchanger 3 is calculated by subtracting the temperature detected by the outdoor liquid temperature sensor 204 from the temperature detected by the outdoor gas temperature sensor 203. The air flow of the outdoor air-sending device 4 is controlled by the control section 103 so that in the use unit 303, there is no temperature difference between the indoor set temperature and the temperature detected by the indoor suction temperature sensor 208.
(2) Also, in a case where the simultaneous cooling and hot water supply operation mode is the cooling priority mode, the operating frequency of the compressor 1 is determined by the temperature differential between the indoor suction temperature and the indoor set temperature in accordance with the cooling load in the use unit 303. Thus, there is no need to remove heat in the outdoor heat exchanger 3.
Therefore, the opening degree of the outdoor pressure-reducing mechanism 5 is controlled to a small opening by the control section 103, and the outdoor air-sending device 4 is controlled so as to be stopped by the control section 103.
While hot water can be supplied with higher efficiency by performing the simultaneous cooling and hot water supply operation mode in cooling priority than in hot water supply priority, it takes time for hot water supply to be completed. For this reason, in a case where a large quantity of heat is required until completion of hot water supply, it is necessary to perform the simultaneous cooling and hot water supply operation mode in hot water supply priority in order to prevent running out of hot water. Also, it is considered that in a case where the inlet water temperature is low relative to the set hot water supply temperature, the water temperature in the hot water supply tank 305 is also low, and thus a large quantity of heat is required for hot water supply. Accordingly, it is regarded that the larger the temperature differential between the set hot water supply temperature Twset [° C.] and the inlet water temperature Twi [° C.]. the larger the quantity of heat required for hot water supply, and the cooling priority and the hot water supply priority are switched in accordance with the temperature differential ΔTwm [° C.] (hot water supply temperature differential) between the set hot water supply temperature Twset [° C.] and the inlet water temperature Twi [° C.].
T
wm
=T
wset
−T
wi (1)
The set hot water supply temperature Twset refers to the temperature of hot water that is set by the user with a remote control (not illustrated), the temperature of hot water in the hot water supply tank, or the like.
The time schedule of daily hot water usage is prepared by recording the amount of hot water usage into a memory within the microcomputer at intervals of every hour or more (e.g. every two hours) over a day or more days (e.g. one week), Also, the time schedule may be inputted by the user.
The computing section 102 computes the heat quantity QTANK [KJ] in the hot water supply tank from Equation (2) below, by using the temperature sensors provided to the hot water supply tank 305 according to Embodiment 1:
where
ρw [g/m3] denotes the density of water,
Cp,w [kJ/kgK] denotes the specific heat of water,
VTANK, 1 [L] denotes the internal volume of the hot water supply tank from the top of the hot water supply tank 305 to the installation height of the first hot water supply tank water temperature sensor 212,
VTANK, 2 [L] denotes the internal volume of the hot water supply tank from the top of the hot water supply tank 305 to the installation height of the second hot water supply tank water temperature sensor 213,
VTANK, 3 [L] denotes the internal volume of the hot water supply tank from the top of the hot water supply tank 305 to the installation height of the third hot water supply tank water temperature sensor 214, and
VTANK, 4 [L] denotes the internal volume of the hot water supply tank from the top of the hot water supply tank 305 to the installation height of the fourth hot water supply tank water temperature sensor 215.
Since the cross-sectional area of the hot water supply tank is already known from the device specifications, the internal volumes can be computed by determining the installation heights of the respective sensors in advance at the time of design.
TTANK, 1 [° C.] denotes the detection temperature of the first hot water supply tank water temperature sensor 212,
TTANK, 2 [° C.] denotes the detection temperature of the second hot water supply tank water temperature sensor 213,
TTANK, 3 [° C.] denotes the detection temperature of the third hot water supply tank water temperature sensor 214, and
TTANK, 4 [° C.] denotes the detection temperature of the fourth hot water supply tank water temperature sensor 215.
Also, TTANKwi [° C.] denotes the detection temperature of the water supply temperature sensor 216.
In this way, it is possible to compute the stored heat quantity stored in the hot water supply tank 305.
For example, the computing section 102 computes the heat quantity QTANK in the hot water supply tank 305 by setting TTANK, 1, TTANK, 2, TTANK, 3, TTANK, 4 to Tw, set, by regarding that the temperature of hot water in the hot water supply tank 305 has reached the hot water supply temperature Tw, set. Then, in a case where the value of QTANK computed from sensor information on the current temperature of the hot water supply tank 305 is equal to or less than half (predetermined heat quantity) of this computed value, the control section 103 sets the operation to the hot water supply priority operation mode irrespective of the hot water supply temperature differential ΔTwm. Specifically, while executing a simultaneous operation of the cooling operation and the hot water supply operation, the control section 103 receives input of a stored heat quantity stored in the hot water supply tank 305 from the computing section 102 (stored heat quantity computing section) that computes the stored heat quantity. The control section 103 executes the hot water supply priority mode when the stored heat quantity inputted from the computing section 102 is smaller than a predetermined heat quantity. This control prevents running out of hot water. While four temperature sensors are installed on the side surface of the tank in the hot water supply tank according to Embodiment 1, the number of temperature sensors is not limited to this. It is possible to compute the heat quantity in the hot water supply tank 305 with higher precision by installing more temperature sensors in the height direction of the tank.
By using the heat quantity QTANK in the hot water supply tank 305, the computing section 102 can compute the remaining amount of hot water Lw [L] as follows.
where Twu denotes the temperature [° C.] hot water used by the user. Also, for example, when the remaining amount of hot water Lw [L] becomes equal to or less than half of the capacity (predetermined capacity) of the hot water supply tank 305, the operation is set to the hot water supply priority operation mode irrespective of the hot water supply temperature differential ΔTwm. That is, while executing a simultaneous operation of the cooling operation and the hot water supply operation, the control section 103 receives input of the remaining amount of hot water Lw remaining in the hot water supply tank 305 from the computing section (remaining hot water amount computing section) that computes the remaining amount of hot water, and executes the hot water supply priority mode when the inputted remaining amount of hot water Lw is less than a predetermined amount. This control prevents running out of hot water.
Also, in a case where the simultaneous cooling and hot water supply operation mode is executed in the cooling priority mode, and the cooling load in the use unit 303 is small, the operating frequency of the compressor 1 is controlled lower, and thus it takes time for hot water supply to be completed even if the priority operation determination threshold M is small. Therefore, the control section 103 measures the operating time of the cooling priority mode by the clock section 104, and makes the operating frequency of the compressor 1 higher to thereby increase the hot water supply capacity when the operating time of the cooling priority mode becomes equal to or more than a predetermined time. At this time, the larger the hot water supply temperature differential ΔTwm, the higher the operating frequency of the compressor 1 is controlled. That is, while executing a simultaneous operation of the cooling operation and the hot water supply operation, when the execution time of the cooling priority mode becomes equal to or more than a predetermined time, the larger the temperature differential Twm, the higher the control section 103 controls the operating frequency of the compressor 1. Through this control, hot water can be supplied with higher efficiency than when the operation is executed in hot water supply priority, and the hot water supply time can be shortened, thereby preventing running out of hot water. Also, the operation may be forcibly set to the hot water supply priority mode.
When the cooling load is high, the operating frequency of the compressor 1 is controlled higher. Therefore, the superiority of the cooling priority mode to the hot water supply priority mode in terms of the coefficient of performance becomes smaller. In this case, the operation may be executed in the hot water supply priority mode to give priority to shortening of the hot water supply time. Specifically, since the quantity of heat removed in the outdoor heat exchanger 3 is 0, the coefficient of performance (COP) [-] of the cooling priority mode in cooling waste-heat recovery operation can be computed by the equation below from the sum of the cooling capacity of the use unit 303 and the hot water supply capacity of the hot water supply unit 304 with respect to the amount of input to the compressor 1.
where Qw denotes the hot water supply capacity [kW], and WCOMP denotes the compressor input “kW”. The second term of the numerator is the cooling capacity, which is the difference between the hot water supply capacity Qw and the compressor input WCOMP. WCOMP is computed by the equation below from the operational state of the refrigeration cycle:
W
COMP
=G
r×(hd−hs) (5)
where
Gr [kg/s] denotes the circulation amount of refrigerant at the discharge of the compressor, and is determined from the saturation temperature (condensing temperature) of the pressure detected by the high-pressure pressure sensor 201, the temperature (evaporating temperature) detected by the indoor liquid temperature sensor 206, and the compressor frequency.
hd [kJ/kg] denotes the specific enthalpy at the discharge of the compressor, and is computed from the pressure detected by the high-pressure pressure sensor 201, and the temperature detected by the discharge temperature sensor 202.
hS [kJ/kg] denotes the specific enthalpy at the suction of the compressor, and since the circuit is an accumulator circuit, the degree of suction superheating is 0, and the specific enthalpy is computed from the indoor liquid temperature sensor 206.
Also, Qw is computed by the equation below from the difference between the outlet and inlet temperatures of water supplied to the hot water supply unit 304:
Q
w=ρw×Cp,w×Vw×(Two−Twi) (6)
where
ρw [kg/m3] denotes the density of water,
Cp,w [kJ/(kg° C.)] denotes the specific heat of water,
Vw [m3/s] denotes the flow rate of water,
Two [° C.] denotes the water temperature at the outlet of the plate water-heat exchanger 16, and
Twi denotes the water temperature at the inlet of the plate water-heat exchanger 16.
Through the above process, the control section 103 can compute the coefficient of performance (COP) from the operational state. The control section 103 forcibly sets the operation to the hot water supply priority mode when COP becomes equal to or less than a predetermined value.
In this way, while executing the cooling priority mode, the control section 103 receives input of the coefficient of performance (COP) of the cooling priority mode from the computing section (coefficient-of-performance computing section) that computes the coefficient of performance (COP) of the cooling priority mode, and when the inputted coefficient of performance (COP) is equal to or less than a predetermined value, the control section 103 switches the cooling priority mode that is being executed to the hot water supply priority mode.
Also, the use unit 303 or a remote control for operating the use unit 303 may be provided with a display section that allows the operation of the combined air-conditioning and hot water supply system 100 or the heat source unit 301 to be recognized, so that the user can change the operation of the heat source unit 301.
For example, during the simultaneous cooling and hot water supply operation mode, an indication of the cooling priority mode or hot water supply priority mode is displayed on the display section. Then, when the user recognizes an abrupt increase in the consumption of hot water, the hot water supply priority mode is forcibly designated with the remote control (operating section), thereby preventing running out of hot water.
Alternatively, it is also preferable to display an indication of the cooling operation mode, the simultaneous heating and hot water supply operation mode, the simultaneous cooling and hot water supply operation mode, or the like so that the user can easily recognize the operational state.
That is, as illustrated in
When the flow rate of water in the plate heat-water exchanger 16 is constant, the condensing temperature CT [° C.] of the outdoor heat exchanger 3 varies with the detection temperature of the inlet water temperature sensor 210. Therefore, ΔT in Equation 7 below calculated by the temperature differential between the condensing temperature CT [° C.] of the outdoor heat exchanger 3 and the set hot water supply temperature Twset [° C.] may be used instead of the temperature differential ΔTwm [° C.]. In this way, even if there is no inlet water temperature sensor 210, ΔT in Equation 7 can be used to determine whether the operation is to be the cooling priority operation or the hot water supply priority operation on the basis of the priority operation determination threshold M.
In this way, while executing a simultaneous operation of the cooling operation and the hot water supply operation, the control section 103 receives input of the condensing temperature CT of the outdoor heat exchanger 3 from the computing section 102 (condensing temperature computing section) that computes the condensing temperature CT. Then, instead of the hot water supply temperature differential ΔTwm, the control section 103 uses the temperature differential ΔT (Equation 7 below) between the set hot water supply temperature Twset and the condensing temperature CT.
ΔT=Twset−CT (7)
According to Embodiment 1 described above, it is possible to provide the combined air-conditioning and hot water supply system 100 capable of recovering waste heat generated in cooling to the hot water supply operation, which is highly efficient and does not compromise indoor comfort, and does not require a long time for hot water supply to be completed, thereby preventing running out of hot water.
Hereinafter, Embodiment 2 will be described with reference to
The combined air-conditioning and hot water supply system 200 is a three-pipe multisystem combined air-conditioning and hot water supply system that can simultaneously handle a selected cooling operation or heating operation in the use unit 303 and a hot water supply operation in the hot water supply unit, by carrying out a vapor compression refrigeration cycle operation. The combined air-conditioning and hot water supply system 200 executes the hot water supply operation in the hot water supply unit when the cooling operation is being performed, thereby enabling recovery of waste heat generated in the cooling operation. Thus, the combined air-conditioning and hot water supply system 200 is highly efficient and does not compromise indoor comfort, and can prevent running out of hot water by ensuring that it does not take a long time to complete hot water supply.
The combined air-conditioning and hot water supply system 200 includes the heat source unit 301, the use unit 303, the hot water supply unit 304, and the hot water supply tank 305. Since the combined air-conditioning and hot water supply system 200 according to Embodiment 2 is provided with a single use unit, with regard to the representation of the components related to the use unit 303, alphabets following the corresponding numerals are not indicated. The heat source unit 301 and the use unit 303 are connected via the liquid extension pipe 6 that is a refrigerant pipe, and the gas extension pipe 12 that is a refrigerant pipe. The heat source unit 301 and the hot water supply unit 304 are connected by the hot water supply gas extension pipe 15 that is a refrigerant pipe, and a hot water supply liquid extension pipe 26 that is a refrigerant pipe. The hot water supply unit 304 and the hot water supply tank 305 are connected by the upstream water pipe 20 that is a water pipe, and the downstream water pipe 21 that is a water pipe.
The configuration of the refrigerant circuit of each of the use unit 303 and the hot water supply unit 304 is the same as that of the combined air-conditioning and hot water supply system 100 according to Embodiment 1. Also, the configuration of the water circuit of the hot water supply tank 305 is the same as that of the combined air-conditioning and hot water supply system 100 according to Embodiment 1. The circuit configuration of the heat source unit 301 is such that the first four-way valve 2, the second four-way valve 13, and the accumulator 14 are removed from the combined air-conditioning and hot water supply system 100 according to Embodiment 1, and an air-conditioning discharge solenoid valve 22 that controls the direction of flow of refrigerant, a hot water supply discharge solenoid valve 25, a low-pressure equalizing solenoid valve 27, a third three-way valve 23 that switches the direction of flow of refrigerant, and a receiver 24 for storing excess refrigerant are installed. That is, as its constituent devices, the outdoor-side refrigerant circuit provided in the heat source unit 301 has the compressor 1, the third four-way valve 23, the outdoor heat exchanger 3, the outdoor air-sending device 4, the outdoor pressure-reducing mechanism 5, the receiver 24, the air-conditioning discharge solenoid valve 22, the hot water supply discharge solenoid valve 25, and the low-pressure equalizing solenoid valve 27.
Like the combined air-conditioning and hot water supply system 100 according to Embodiment 1, the combined air-conditioning and hot water supply system 200 can execute three operation modes (a cooling operation mode, a simultaneous heating and hot water supply operation mode, and a simultaneous cooling and hot water supply operation mode).
In the cooling operation mode, the third four-way valve 23 is in the state indicated by the solid line, that is, a state in which the discharge side of the compressor 1 is connected to the gas side of the outdoor heat exchanger 3, and the suction side of the compressor 1 is connected to the gas side of the indoor heat exchanger 9. Also, the air-conditioning discharge solenoid valve 22 is open, the hot water supply discharge solenoid valve 25 is closed, and the low-pressure equalizing solenoid valve 27 is closed. In this state of the refrigerant circuit, the control section 103 activates the compressor 1, the outdoor air-sending device 4, and the indoor air-sending device 10. Then, a low-pressure gas refrigerant is sucked into the compressor 1, where the gas refrigerant is compressed into a high-temperature high-pressure gas refrigerant. Thereafter, the high-temperature high-pressure gas refrigerant enters the outdoor heat exchanger 3 via the third four-way valve 23, where the gas refrigerant is condensed by exchanging heat with the outdoor air supplied by the outdoor air-sending device 4, and turns into a low-pressure gas refrigerant.
After exiting the outdoor heat exchanger 3, the refrigerant flows to the outdoor pressure-reducing mechanism 5, where the refrigerant is reduced in pressure. The outdoor pressure-reducing mechanism 5 is controlled so that the degree of subcooling on the liquid side of the outdoor heat exchanger 3 becomes a predetermined value. The degree of subcooling on the liquid side of the outdoor heat exchanger 3 is calculated by subtracting the temperature detected by the outdoor liquid temperature sensor 204, from the saturation temperature computed from the pressure detected by the high-pressure pressure sensor 201.
After exiting the outdoor pressure-reducing mechanism 5, the refrigerant passes through the receiver 24, is reduced in pressure in the indoor pressure-reducing mechanism 7, and exits the heat source unit 301. Then, the refrigerant enters the use unit 303 via the liquid extension pipe 6, and enters the indoor heat exchanger 9, where the refrigerant is evaporated by exchanging heat with the indoor air supplied from the indoor air-sending device 10, and turns into a low-pressure gas refrigerant. The indoor pressure-reducing mechanism 7 is controlled so that the degree of superheat on the gas side of the indoor heat exchanger 9 becomes a predetermined value. The degree of superheat on the gas side of the indoor heat exchanger 9 is calculated by subtracting the temperature detected by the indoor liquid temperature sensor 206, from the temperature detected by the indoor gas temperature sensor 207. After exiting the indoor heat exchanger 9, the refrigerant exits the use unit 303, and enters the heat source unit 301 via the gas extension pipe 12. Thereafter, the refrigerant passes through the third three-way valve 23, and enters the compressor 1 again.
The operating frequency of the compressor 1 is controlled by the control section 103 so that in the use unit 303, the temperature difference between the indoor set temperature and the temperature detected by the indoor suction temperature sensor 208 becomes small. Also, the air flow of the outdoor air-sending device 4 is controlled by the control section 103 so that the condensing temperature becomes a predetermined value in accordance with the outside air temperature detected by the outside air temperature sensor 205. Here, the condensing temperature is the saturation temperature computed from the pressure detected by the high-pressure pressure sensor 201.
In the simultaneous heating and hot water supply operation mode, the third four-way valve 23 is in the state indicated by the broken line, that is, the discharge side of the compressor 1 is connected to the gas side of the indoor heat exchanger 9, and the suction side of the compressor 1 is connected to the gas side of the outdoor heat exchanger 3. Also, the air-conditioning discharge solenoid valve 22 is open, the hot water supply discharge solenoid valve 25 is open, and the low-pressure equalizing solenoid valve 27 is closed. In this state of the refrigerant circuit, the compressor 1, the outdoor air-sending device 4, the indoor air-sending device 10, and the water supply pump 17 are activated. Then, a low-pressure gas refrigerant is sucked into the compressor 1, where the refrigerant is compressed into a high-temperature high-pressure gas refrigerant. Thereafter, the high-temperature high-pressure gas refrigerant is distributed so as to flow through the hot water supply discharge solenoid valve 25 or the air-conditioning discharge solenoid valve 22.
The refrigerant that has entered the hot water supply discharge solenoid valve 25 exits the heat source unit 301, and enters the hot water supply unit 304 via the hot water supply gas extension pipe 15. The refrigerant that has entered the hot water supply unit 304 enters the plate water-heat exchanger 16, where the refrigerant is condensed by exchanging heat with the water supplied by the water supply pump 17 and turns into a high-pressure liquid refrigerant, and exits the plate water-heat exchanger 16. After the refrigerant that has heated the water in the plate water-heat exchanger 16 exits the hot water supply unit 304, the refrigerant enters the heat source unit 301 via the hot water supply liquid extension pipe 26, and is reduced in pressure by the hot water supply pressure-reducing mechanism 19. Thereafter, the refrigerant joins the refrigerant that has flown through the indoor pressure-reducing mechanism 7. The hot water supply pressure-reducing mechanism 19 is controlled by the control section 103 to such an opening degree that the degree of subcooling on the liquid side of the plate water-heat exchanger 16 becomes a predetermined value. The degree of subcooling on the liquid side of the plate water-heat exchanger 16 is calculated by computing the saturation temperature (condensing temperature) from the pressure detected by the high-pressure pressure sensor 201, and subtracting the temperature detected by the hot water supply liquid temperature sensor 209 from the saturation temperature.
Meanwhile, after the refrigerant that has entered the air-conditioning discharge solenoid valve 22 passes through the third four-way valve 23, the refrigerant exists the heat source unit 301, and enters the use unit 303 via the gas extension pipe 12. The refrigerant that has entered the use unit 303 enters the indoor heat exchanger 9, where the refrigerant is condensed by exchanging heat with the indoor air supplied by the indoor air-sending device 10 and turns into a high-pressure liquid refrigerant, and exits the indoor heat exchanger 9. The refrigerant that has heated the indoor air in the indoor heat exchanger 9 exits the use unit 303, enters the heat source unit 301 via the liquid extension pipe 6, and is reduced in pressure by the indoor pressure-reducing mechanism 7. Thereafter, the refrigerant joins the refrigerant that has flown through the hot water supply pressure-reducing mechanism 19. Here, the indoor pressure-reducing mechanism 7 is controlled by the control section 103 to such an opening degree that the degree of subcooling of the refrigerant on the liquid side of the indoor heat exchanger 9 becomes a predetermined value. The degree of subcooling of the refrigerant on the liquid side of the indoor heat exchanger 9 is calculated by subtracting the temperature detected by the indoor liquid temperature sensor 206, from the saturation temperature (condensing temperature) computed from the pressure detected by the high-pressure pressure sensor 201.
Thereafter, the joined refrigerant passes through the receiver 24, is reduced in pressure by the outdoor pressure-reducing mechanism 5, and enters the outdoor heat exchanger 2. The opening degree of the outdoor pressure-reducing mechanism 5 is controlled so that the degree of superheat on the gas side of the outdoor heat exchanger 3 becomes a predetermined value. The degree of superheat on the gas side of the outdoor heat exchanger 3 is calculated by subtracting the temperature detected by the outdoor liquid temperature sensor 204 from the temperature detected by the outdoor gas temperature sensor 203. The refrigerant that has entered the outdoor heat exchanger 3 is evaporated by exchanging heat with the indoor air supplied by the outdoor air-sending device 4 and turns into a low-pressure gas refrigerant. After exiting the outdoor heat exchanger 3, this refrigerant is sucked into the compressor 1 again via the third four-way valve 23.
The operating frequency of the compressor 1 is controlled by the control section 103 from a hot water supply request signal detected by the hot water supply tank. Also, the air flow of the outdoor air-sending device 4 is controlled by the control section 103 so that the evaporating temperature becomes a predetermined value in accordance with the outside air temperature detected by the outside air temperature sensor 205. Here, the evaporating temperature is calculated from the temperature detected by the outdoor liquid temperature sensor 204.
In the simultaneous cooling and hot water supply operation mode, the third four-way valve 23 is in the state indicated by the solid line, that is, the discharge side of the compressor 1 is connected to the gas side of the outdoor heat exchanger 3, and the suction side of the compressor 1 is connected to the gas side of the indoor heat exchanger 9. Also, the air-conditioning discharge solenoid valve 22 is closed, the hot water supply discharge solenoid valve 25 is open, and the low-pressure equalizing solenoid valve 27 is open. In this state of the refrigerant circuit, when the compressor 1, the outdoor air-sending device 4, the indoor air-sending device 10, and the water supply pump 17 are activated, a low-pressure gas refrigerant is sucked into the compressor 1, where the refrigerant is compressed into a high-temperature high-pressure gas refrigerant. Thereafter, the high-temperature high-pressure gas refrigerant passes through the hot water supply discharge solenoid valve 25 and exits the heat source unit 301, and enters the hot water supply unit 304 via the hot water supply gas extension pipe 15. The refrigerant that has entered the hot water supply unit 304 enters the plate water-heat exchanger 16, where the refrigerant is condensed by exchanging heat with the water supplied by the water supply pump 17 and turns into a high-pressure liquid refrigerant, and exits the plate water-heat exchanger 16. The refrigerant that has heated the water in the plate water-heat exchanger 16 exits the hot water supply unit 304, and enters the heat source unit 301 via the hot water supply liquid extension pipe 26.
The refrigerant that has entered the heat source unit 301 passes through the hot water supply pressure-reducing mechanism 19 that is fixed to the maximum opening, and thereafter, the refrigerant is divided into a refrigerant that enters the indoor pressure-reducing mechanism 7, and a refrigerant that enters the receiver 24. The refrigerant that has entered the indoor pressure-reducing mechanism 7 is reduced in pressure. Thereafter, the refrigerant exits the heat source unit 301, and enters the use unit 303 via the liquid extension pipe 6. The refrigerant then enters the indoor heat exchanger 9, where the refrigerant is evaporated by exchanging heat with the indoor air supplied by the indoor air-sending device 10 and turns into a low-pressure gas refrigerant. Here, the indoor pressure-reducing mechanism 7 is controlled so that the degree of superheat on the gas side of the indoor heat exchanger 9 becomes a predetermined value, The method of calculating this degree of superheat is the same as in the case of the cooling operation mode.
The refrigerant that has flown through the indoor heat exchanger 9 thereafter exits the use unit 303, and enters the heat source unit 301 via the gas extension pipe 12. The refrigerant that has entered the heat source unit 301 passes through the third four-way valve 23, and thereafter joins the refrigerant that has passed through the indoor heat exchanger 3.
Meanwhile, the refrigerant that has entered the receiver 24 passes through the outdoor pressure-reducing mechanism 5 that is fixed to a small opening, where the pressure of the refrigerant is reduced to a low pressure. Thereafter, the refrigerant is heated by the outside air in the outdoor heat exchanger 3, and turns into a low-pressure gas refrigerant. Thereafter, the refrigerant passes through the low-pressure equalizing solenoid valve 27, and joins the refrigerant that has passed through the indoor heat exchanger 9. After joining, the resulting refrigerant is sucked into the compressor 1 again.
Since the low-pressure equalizing solenoid valve 27 is installed in order to make the pressure in the outdoor heat exchanger 3 low, its bore diameter is small. Therefore, the low-pressure equalizing solenoid valve 27 is unable to remove excess heat of cooling. Therefore, the air flow of the outdoor air-sending device 4 is controlled to the minimum value required to cool the radiator plate, and the opening degree of the outdoor pressure-reducing mechanism 5 is controlled to a small opening.
In a case where the simultaneous cooling and hot water supply operation mode is the hot water supply priority mode, the operating frequency of the compressor 1 is controlled by the control section 103 on the basis of a hot water supply request from the hot water supply unit 304. Also, in a case where the simultaneous cooling and hot water supply operation mode is the cooling priority mode, the operating frequency of the compressor 1 is determined from the temperature differential between the indoor suction temperature and the indoor set temperature in accordance with the cooling load in the use unit 303.
In the case of the combined air-conditioning and hot water supply system 200 according to Embodiment 2, in the simultaneous cooling and hot water supply operation mode, the small bore diameter of the low-pressure equalizing valve 27 makes it impossible to make a large amount of refrigerant flow to the outdoor heat exchanger 3. Consequently, heat cannot be removed in the outdoor heat exchanger 3, which means that waste heat generated in cooling is completely recovered for the hot water supply. Therefore, the operation according to the hot water supply priority mode differs from that in the case of the combined air-conditioning and hot water supply system 100 according to Embodiment 1.
In this way, while executing a simultaneous operation of the cooling operation and the hot water supply operation, when the suction air temperature of the use unit 303 becomes higher than the indoor set temperature, the control section 103 stops the cooling operation of the use unit 303 until the suction air temperature of the use unit 303 becomes higher than the indoor set temperature.
While the current indoor suction temperature is used in this case to determine cooling thermo OFF, a value computed after a predetermined time may be used.
In this way, the storing section 105 stores indoor suction temperature data indicative of variation of the suction air temperature of the use unit 303 with elapse of time while a simultaneous operation of the cooling operation and the hot water supply operation is executed.
The computing section 102 simulates the variation of suction air temperature with elapse of time on the basis of the indoor suction temperature data stored in the storing section 105. Then, when executing a simultaneous operation of the cooling operation and the hot water supply operation, the control section 103 stops the cooling operation of the use unit 303 during periods of time in which the suction air temperature simulated by the computing section 102 is lower than the indoor set temperate.
The operation in a case where the simultaneous cooling and hot water supply operation is executed in the cooling priority mode is the same as that in the combined air-conditioning and hot water supply system according to Embodiment 1. That is, the operating frequency of the compressor 1 is determined in accordance with the cooling load in the use unit 303, and thus the cooling capacity and the cooling load become equal. The cooling indoor temperature of the use unit 303 is controlled to the indoor set temperature. When there is no longer hot water supply request from the hot water supply unit 304 and hot water supply is complete, the cooling operation is performed. In this operation, the operating frequency of the compressor 1 is set lower than that during operation in hot water supply priority. Therefore, hot water can be supplied with high efficiency, but the cooling capacity becomes smaller, which means that it takes longer for hot water supply to be completed.
Even in a case where, as in the combined air-conditioning and hot water supply system 200 according to Embodiment 2, waste heat generated in cooling is completely recovered for hot water supply in the simultaneous cooling and hot water supply operation mode, by introducing the priority operation determination threshold 5M as in the combined air-conditioning and hot water supply system 200 according to Embodiment 1, it is possible to appropriately estimate the quantity of heat required for hot water supply. That is, the control section 103 supplies hot water with high efficiency in the cooling priority mode in a case where a small quantity of heat is required for hot water supply, and supplies hot water in the hot water supply priority mode to prevent running out of hot water in a case where a large quantity of heat is required for hot water supply. Also, in the hot water supply priority mode, when the cooling indoor temperature of the use unit 303 becomes lower than the indoor set temperature, the control section 103 turns the cooling thermo OFF and performs the hot water supply operation, and once the cooling indoor temperature becomes higher than the indoor set temperature, the control section 103 executes the hot water supply priority mode of the simultaneous cooling and hot water supply operation again. Therefore, it is possible to shorten the hot water supply time while executing cooling without compromising indoor comfort.
While the combined air-conditioning and hot water supply system 100 (cooling and hot water supply system) has been described in the above embodiments, the operation of the combined air-conditioning and hot water supply system 100 can be also grasped as a cooling and hot water supply method. That is, the operation of the combined air-conditioning and hot water supply system 100 can be grasped as a cooling and hot water supply method in which the controller 103 executes the control described in the above embodiments with respect to a hot water supply device including the heat source unit 301, the use unit 303a, 303b, the hot water supply unit 304, the measuring section 101, and the like.
1 compressor; 2 first four-way valve; 3 outdoor heat exchanger; 4 outdoor air-sending device; 5 outdoor pressure-reducing mechanism; 6 liquid extension pipe; 7 indoor pressure-reducing mechanism; 8 indoor liquid pipe; 9 indoor heat exchanger; 10 indoor air-sending device; 11 indoor gas pipe; 12 gas extension pipe; 13 second four-way valve; 14 accumulator; 15 hot water supply gas extension pipe; 16 plate water-heat exchanger; 17 water supply pump; 18 hot water supply liquid pipe; 19 hot water supply pressure-reducing mechanism; 20 upstream water pipe; 21 downstream water pipe; 22 air-conditioning discharge solenoid valve; 23 third four-way valve; 24 receiver; 25 hot water supply discharge solenoid valve; 26 hot water supply liquid extension pipe; 27 low-pressure equalizing solenoid valve; 100 combined air-conditioning and hot water supply system; 110 system control device; 101 measuring section; 102 computing section; 103 control section; 104 clock section; 105 storing section; 200 combined air-conditioning and hot water supply system; 201 high-pressure pressure sensor; 202 discharge temperature sensor; 203 outdoor gas temperature sensor; 204 outdoor liquid temperature sensor; 205 outside air temperature sensor; 206 indoor liquid temperature sensor; 207 indoor gas temperature sensor; 208 indoor suction temperature sensor; 209 hot water supply liquid temperature sensor; 210 inlet water temperature sensor; 211 outlet water temperature sensor; 212 first hot water supply tank water temperature sensor; 213 second hot water supply tank water temperature sensor; 214 third hot water supply tank water temperature sensor; 215 fourth hot water supply tank water temperature sensor; 216 water supply temperature sensor; 301 heat source unit; 302 branch unit; 303 use unit; 303-1 display section; 303-2 operating section; 304 hot water supply unit; 304-1 water circuit; 305 hot water supply tank.
Number | Date | Country | Kind |
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2010-210446 | Sep 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/055373 | 3/8/2011 | WO | 00 | 2/20/2013 |