JPH0454867B2 - - Google Patents

Description

[Detailed description of the invention]

[Industrial Application Field] The present invention relates to an air-conditioning, heating, and water supply system, and particularly to an air-conditioning, heating, and water supply system that is used in facilities that require a large amount of heat for hot water supply. [Prior Art] Conventionally, there has been known an air-conditioning/heating water supply device that uses a heat pump device to preheat hot water using the heating power of the heat pump device itself or exhaust heat during cooling (cooling exhaust heat). In general, the higher the outside temperature, the higher the capacity and efficiency of a heat pump device, while the heating load is reduced, leaving more capacity for the heat pump device and lowering energy costs for hot water supply compared to hot water boilers. There are advantages. However, when heating hot water to a high temperature using a heat pump device, not only the energy cost for hot water supply increases, but also the energy cost for heating. Therefore, in conventional air-conditioning/heating water supply systems, hot water is supplied by preheating the water to a predetermined temperature using a heat pump device, and then heating the water to the hot water supply temperature using a hot water boiler. [Problems to be solved by the invention] By the way, there is generally a peak in the hot water supply load;
During this peak period, a large amount of hot water is required, so
In other words, since a large amount of hot water flows at once, the capacity of the heat pump device is greatly exceeded, and the hot water preheating effect becomes extremely small, while the heating capacity is significantly reduced. There is a point. In addition, the efficiency of a heat pump device improves as the difference in heat pumping temperature is smaller, so the brine temperature is higher during cooling, while the lower the brine temperature during heating, the better the efficiency, and heat absorption in piping, etc. Alternatively, heat radiation loss is reduced. However, in the above case, during periods of extreme heat and extreme cold, the required heating and cooling capacity cannot be obtained unless the capacities of the air handling unit and fan coil unit are increased. Furthermore, the lower the hot water supply temperature, the greater the amount of preheated hot water by the heat pump device, and the less heat radiation loss occurs. However, when the hot water temperature is lowered, a hot water supply method using a hot water boiler without a reheating device requires a large amount of hot water to heat the hot water in the bathtub. Furthermore, if a hot water storage tank (preheating tank) is installed to store hot water heated by a heat pump device as a countermeasure against peak loads for hot water supply, since the hot water storage temperature is low, heat dissipation loss will be reduced, but the required amount of heat storage will be secured. Therefore, the tank capacity must be increased. An object of the present invention is to provide an air-conditioning/heating-water supply device that has good cooling/heating efficiency and hot water supply efficiency even during peak hot water supply times. Another object of the present invention is to provide an air-conditioning, heating, and hot-water supply system that requires a small hot water storage tank capacity. [Means for solving the problem] According to the present invention, a compressor, a first heat exchanger connected to the discharge side of the compressor via a first switching valve, and a first heat exchanger connected to the discharge side of the compressor via a first switching valve; a bypass pipe line arranged in parallel with the first heat exchanger via a switching valve;
a second heat exchanger having one end connected to the heat exchanger via a second switching valve and the other end connected to an expansion device; and one end connected to the second heat exchanger via the expansion device. a third heat exchanger, the other end of which is connected to the second switching valve, and the second switching valve is connected to the suction side of the compressor; a hot water preheating tank connected to the first heat exchanger by a circulation pipe, a circulation pump provided in the circulation pipe, a hot water boiler connected to the hot water preheating tank, and the second heat exchanger. There is obtained an air-conditioning/heating/water supply device characterized by having a brine tank connected to the container by a brine circulation pipe. The brine temperature in the brine tank and the hot water temperature in the hot water boiler may be adjusted in accordance with the outside temperature. Further, according to the present invention, a compressor, a first heat exchanger connected to the discharge side of the compressor via a first switching valve, and a first heat exchanger connected to the discharge side of the compressor via a first switching valve; a bypass pipe line arranged in parallel with the heat exchanger; and a second heat exchanger, one end of which is connected to the first heat exchanger via a second switching valve, and the other end of which is connected to an expansion device. a third heat exchanger having one end connected to the second heat exchanger and the other end connected to the second switching valve via the expansion device, a heat pump device having a valve connected to the suction side of the compressor; a hot water preheating tank connected to the first heat exchanger by a circulation line; a circulation pump provided in the circulation line; A hot water boiler connected to the hot water preheating tank, a brine tank connected to the second heat exchanger by a brine circulation pipe, and circulating hot water in the hot water boiler to exchange heat with brine in the brine tank. and a third switching valve for bypassing the fourth heat exchanger and circulating hot water from the hot water boiler to the hot water preheating tank. An air-conditioning, heating, and water-heating device is obtained. [Example] The present invention will be described below with reference to Examples. Referring to the drawings, first, the configuration of the air-conditioning, heating, and water supply system according to the present invention will be described. The discharge side (outlet side) of the compressor 1 is connected to the first port 2a of the three-way valve 2. The second port 2b of the three-way valve 2 is connected to one end of the heat exchanger 3 for preheating hot water supply, and the third port 2c of the three-way valve 2 and the other end of the heat exchanger 3 for preheating hot water supply are connected. That is, a bypass pipe line 31 is provided in parallel to the hot water supply preheating heat exchanger 3. The other end of the hot water preheating heat exchanger 3 is connected to the first end of the four-way valve 4.
It is connected to port 4a of. 2nd of four-way valve 4
The first port 5a of the three-way valve 5 is connected to the port 4b, and the second port 5b is connected to one end of the refrigerant-brine heat exchanger 6. The other end of the refrigerant-brine heat exchanger 6 is connected to the third port 5c of the three-way valve 5 and connected to one end of the refrigerant-air heat exchanger 7 equipped with a blower 8 via an expansion device (mechatronic expansion valve) 9. connected. The other end of the refrigerant-air heat exchanger 7 is connected to the third port 4c of the four-way valve 4.
The fourth port 4d of the four-way valve 4 is connected to the suction side (inlet side) of the compressor 1. A hot water preheating tank 13 is connected to the hot water preheating heat exchanger 3 through a hot water pipe 32 equipped with a check valve 32a, and city water is supplied to the hot water preheating tank 13 through the hot water pipe 32. Ru. Further, by driving the circulation pump 14, water in the hot water supply preheating tank 13 is circulated via the hot water supply preheating heat exchanger 3. The hot water preheating tank 13 is connected to the hot water boiler 15 by a hot water pipe 13 equipped with a three-way valve 17, and the water (hot water) in the hot water preheating tank 13 is circulated through the hot water boiler 15 by driving the circulation pump 16. do. On the other hand, the hot water boiler 15 has a hot water pipe 15.
Faucets 15a and 15b are attached via 1. Furthermore, one end of a backup heat exchanger 11 disposed in the brine tank 10 is connected to the three-way valve 17 as shown in the figure, and the other end of the backup heat exchanger 11 is connected to a hot water boiler 15. . The refrigerant-brine heat exchanger 6 is connected to an indoor unit (not shown) provided in a plurality of rooms by a brine pipe line 101 via a brine tank 10, and the brine in the brine tank 10 is used for brine circulation. It is circulated by a pump 12. In the case of cooling operation, the compressor 1 and the hot water preheating heat exchanger 3 are connected by the three-way valve 2, and the refrigerant from the compressor 1 is transferred to the hot water preheating heat exchanger 3 and the first four-way valve 4.
port 4a, third port 4c, refrigerant-air heat exchanger 7, expansion device 9, refrigerant-brine heat exchanger 6, three-way valve 5, second port 4b, fourth port 4d of four-way valve 4. so that it passes through and returns to compressor 1.
A coolant flow path is formed. City water is supplied to the hot water preheating tank 13 via the hot water preheating heat exchanger 3. That is, city water is preheated by the hot water preheating heat exchanger 3 and then supplied to the hot water preheating tank 13 . When the water supplied to the hot water preheating tank 13 is lower than a predetermined temperature, the circulation pump 14 is driven, and the water in the hot water preheating tank 13 is recirculated through the hot water preheating heat exchanger 3 and further heated. . Further, the brine circulation pump 12 is driven to circulate low-temperature brine (or cold water) to the indoor unit via the brine tank 10 and the refrigerant-brine heat exchanger 6. That is, the brine circulating in the indoor unit is cooled by the refrigerant-brine heat exchanger 6, resulting in cooling. Note that when the amount of heating by the hot water preheating heat exchanger 3 is large, the blower 8 is stopped. When hot water starts being supplied, the hot water in the hot water preheating tank 13 is heated by the hot water boiler 15 and hot water is supplied from the faucets 15a and 15b. The circulation pump 14 is always driven during hot water supply. During the off-season for cooling and heating, the refrigerant from the compressor 1 is transferred to the hot water preheating heat exchanger 3, the first port 4a and second port 4b of the four-way valve 4, the three-way valve 5, the expansion device 9, and the refrigerant. A refrigerant flow path returning to the compressor 1 is formed through the air heat exchanger 7, the third port 4c, and the fourth port 4d of the four-way valve 4. On the other hand, city water is preheated by the hot water supply preheating heat exchanger 3 and supplied to the water supply preheating tank 13 in the same manner as described above. When the water supplied to the hot water preheating tank is lower than a predetermined temperature, the circulation pump 14 is driven, and the water in the hot water preheating tank 13 is recirculated through the hot water preheating heat exchanger 3 and further heated. When hot water supply starts, the hot water in the hot water preheating tank 13 is transferred to the hot water boiler 1.
5, and hot water is supplied from faucets 15a and 15b. The circulation pump 14 is always driven during hot water supply. Note that if the hot water in the hot water preheating tank 13 exceeds a predetermined temperature and hot water is not being supplied, the drive of the heat pump device (that is, the compressor 1) is stopped. During heating, if the heat pump device has sufficient heating capacity and the brine temperature maintains the temperature required for heating, the compressor 1 and the hot water preheating heat exchanger 3 are connected by the three-way valve 2. The refrigerant from the compressor 1 is transferred to a hot water preheating heat exchanger 3 and a four-way valve 4.
The first port 4a, the second port 4b, the three-way valve 5, the refrigerant-brine heat exchanger 6, the expansion device 9, the refrigerant-air heat exchanger 7, the third port 4 of the four-way valve 4
c, a fluid flow path is formed so as to return to the compressor 1 through the fourth port 4d. By driving the brine circulation pump 12, high temperature brine (or hot water) is circulated to the indoor unit via the brine tank 10 and the refrigerant-brine heat exchanger 6. That is, the brine circulating through the indoor unit is heated by the refrigerant-brine heat exchanger 6, resulting in heating. On the other hand, city water is preheated by the hot water supply preheating heat exchanger 3 and supplied to the water supply preheating tank 13. Further, the circulation pump 14 is driven, and the hot water in the hot water supply preheating tank 13 is circulated and heated through the hot water supply preheating heat exchanger 3. When hot water supply starts, the hot water in the hot water preheating tank 13 is heated by the hot water boiler 15,
Hot water is supplied from faucets 15a and 15b. By the way, during heating, if there is not enough room in the heating capacity of the heat pump device (i.e. during a severe cold season or when heating starts), first, the refrigerant discharged from the compressor 1 by the three-way valve 2 is used to preheat hot water. Bypassing the heat exchanger 3, the first port 4a, second port 4b of the four-way valve 4, the first port 5a, second port 5b of the three-way valve 5, the refrigerant-brine heat exchanger 6, A fluid flow path is formed so as to return to the compressor 1 through the expansion device 9, the refrigerant-air heat exchanger 7, the third port 4c, and the fourth port 4d of the four-way valve 4. On the other hand, by driving the circulation pump 16, the hot water in the hot water boiler 15 is circulated to the backup heat exchanger 11 via the three-way valve 17. Therefore, brine tank 1
The brine in 0 is warmed. By driving the brine circulation pump 12, hot water (brine) heated by the backup heat exchanger 11 is circulated to the indoor unit to perform heating. By the way, 20 is a controller controlled by a microcomputer, and controls the three-way valves 2 and 5, the four-way valve 4, the brine circulation pump 12, and the blower 8 by operating mode switches (not shown) for cooling, heating, and hot water preheating. conduct. Further, the controller 20 controls the operation of the compressor 1 according to a signal from the brine temperature sensor 21 to control the brine temperature. During cooling, the refrigerant-brine heat exchanger 6
During heating, refrigerant temperature sensors (not shown) installed at the inlet and outlet of the refrigerant-air heat exchanger 7 Then, the refrigerant temperature is detected and the opening degree of the mechatronic expansion valve 9 is controlled by the controller 20. Further, the temperature difference between the outlet side temperature of the hot water preheating exchanger 3 and the hot water in the hot water preheating tank 13 is detected by the hot water preheating heat exchanger temperature sensor 22 and the hot water preheating temperature sensor 23. When the temperature of the preheating tank 13 decreases, the controller 20 operates the circulation pump 14 to perform reheating. Further, based on the outside air temperature detected by the outside air temperature sensor 25, the controller 20 controls the operation of the compressor 1 and the hot water boiler 15, and controls the hot water preheating temperature, the hot water heating temperature, and the brine temperature. The table below shows an example of the relationship (control) between the outside air temperature, brine temperature, and hot water temperature.

〔Effect of the invention〕

As explained above, the air-conditioning, heating and hot-water supply system according to the present invention can substantially increase the air-conditioning, heating and hot-water supply capacity compared to the conventional air-conditioning and hot-water supply system, and also prevents the cooling, heating and hot-water supply capacity from decreasing even during peak hot-water supply times. do not have. In addition, since the hot water in the hot water preheating tank is recirculated to the first heat exchanger and heated, the hot water in the hot water preheating tank can be maintained at an appropriate temperature.
Therefore, the hot water preheating tank can be downsized. Furthermore, in the present invention, since the hot water preheating tank, the brine tank, and the backup boiler are arranged in parallel, there is an effect that the backup boiler can be used for multiple purposes. In other words, the back-up boiler can be used for hot water supply during normal times, and the back-up boiler can be used for heating during extremely cold weather.

[Brief explanation of the drawing]

The drawings are diagrams showing one embodiment of the air-conditioning, heating, and hot-water supply apparatus according to the present invention. 1... Compressor, 2... Three-way valve, 3... Hot water preheating heat exchanger, 4... Four-way valve, 5... Three-way valve, 6... Refrigerant-brine heat exchanger, 7... Refrigerant-air heat exchanger, 8... Blower , 9... Expansion device, 10... Brine tank, 1
1...Backup heat exchanger, 12...Brine circulation pump, 13...Hot water preheating tank, 14...Circulation pump, 15...Hot water boiler, 16...Circulation pump, 1
7...Three-way valve.

Claims (1)

[Claims] 1 a compressor, a first heat exchanger connected to the discharge side of the compressor via a first switching valve, and a first heat exchanger connected in parallel to the first heat exchanger via the first switching valve; a second heat exchanger having one end connected to the first heat exchanger via a second switching valve and the other end connected to the expansion device; and the expansion device. one end is connected to the second heat exchanger via
a third heat exchanger whose other end is connected to the second switching valve, and the second switching valve is connected to the suction side of the compressor; a hot water preheating tank connected to the vessel by a circulation pipe, a circulation pump provided in the circulation pipe, a hot water boiler connected to the hot water preheating tank, the second heat exchanger, and brine circulation. a brine tank connected by a pipe, and a fourth heat exchanger that circulates hot water from the hot water boiler and exchanges heat with the brine in the brine tank;
and a third switching valve for bypassing the fourth heat exchanger and circulating hot water from the hot water boiler to the hot water preheating tank.