CN104406247A - Multipurpose air conditioner heat-pump water heater system - Google Patents

Abstract

The invention discloses a multi-purpose air-conditioning heat pump water heater system, which belongs to the field of air-conditioning and water heaters. The heater, throttling device, indoor heat exchanger, gas-liquid separator, the first to the thirteenth channel, the first to the thirteenth control valve, and the one-way valve are connected through pipelines. The system mainly changes the flow direction of the refrigerant by automatically controlling the valve, so that it can realize indoor cooling while producing domestic hot water in summer, and indoor heating while producing domestic hot water in winter, and can realize indoor cooling, heating and cooling. Taking hot water works separately. The system meets the needs of air conditioning and domestic hot water in people's daily life, is economical, energy-saving and environmentally friendly, and has broad application prospects.

Description

A multi-purpose air-conditioning heat pump water heater system

technical field

The invention relates to the field of air-conditioning water heaters, in particular to a multi-purpose air-conditioning heat pump water heater system capable of cooling and heating hot water.

Background technique

Nowadays, with the improvement of family living standards, people pay more and more attention to the quality of life and an environmentally friendly, economical and comfortable lifestyle. Air conditioners and water heaters have entered thousands of households, and while they bring people a comfortable life, they also have some impacts. In summer, people use air conditioners to cool and consume electricity to transfer indoor heat, but at the same time, a large amount of condensation heat is released, which is directly discharged into the atmosphere, causing a certain amount of waste and further exacerbating global warming. In terms of hot water production, both electric water heaters and gas water heaters consume electric energy. High-grade energy such as natural gas and gas have low utilization efficiency and bring a certain burden to the daily expenses of the family. Then there are solar water heaters. Although Economical, but its use is limited by climate conditions, so air energy water heaters have become the main development direction at present.

However, if the air conditioner and the air source water heater are used at the same time, there will be two outdoor units, which is troublesome to install, and the outer wall is not beautiful. At present, the technologies of air conditioners and air energy water heaters are relatively mature, but they are self-contained, and there are few products that combine the two. There are two types of well-known ones. One is a multi-purpose central air conditioner, which is mainly composed of a compressor, four The through valve, condenser, throttle valve and evaporator are connected in series. The condenser of the outdoor unit is replaced with a water-cooled type. While cooling, the water is heated by condensation heat and transported to the room. The advantage is that the air conditioner is well recovered. Condensation heat, the disadvantage is that the heat pump system cannot operate independently, and it is more suitable for applications that require a large number of hot water, such as hotels, bathrooms, etc., and is not suitable for home use. The other type is the air conditioner water heater, which mainly connects the water heater tank in series between the compressor and the condenser of the original air conditioner. The disadvantage is that the heat pump water heater system cannot operate independently, and when the hot water temperature is too high, it is easy to cause the compressor to discharge. If the air pressure is too high, the compressor will be burned.

The current patent number is 200920053715.8, a utility model patent named "recovery air-conditioning heat pump water heater", which is mainly based on the above-mentioned second type of air-conditioning water heater on the low-pressure intake pipe of the four-way valve and the exhaust pipe for outdoor heat exchange. A circuit is connected in parallel, and the subcooler, expansion valve and check valve are connected to the circuit in sequence, and a bypass circuit is connected in parallel on the intake and exhaust pipeline of the water heater condenser, and the solenoid valve is connected to the circuit. Although the solution of this patent solves the above two main shortcomings, the first disadvantage is that the air-conditioning system cannot operate independently, and the air-conditioning system can only be operated independently after the water in the water tank reaches the temperature and the solenoid valve is opened; the second disadvantage is that the four-way valve uses refrigeration. The four-way valve is easy to be damaged; the third disadvantage is that the thermal expansion valve and the capillary tube are used to realize the throttling process twice, which makes the system complicated; the fourth disadvantage is that the capillary tube is easily blocked.

Contents of the invention

Based on the problems existing in the above-mentioned prior art, the present invention provides a multi-purpose air-conditioning heat pump water heater system that can realize domestic hot water production in summer and indoor cooling at the same time, and can realize indoor cooling and hot water production separately; Indoor heating can produce domestic hot water at the same time, and it can realize the heat pump water heater system that indoor heating and domestic hot water can work independently in winter, which solves the problem that the existing recycling air-conditioning heat pump water heater air-conditioning system is limited by the heat The problem of water temperature and the problem that the winter and summer heat pump systems cannot be run at the same time.

In order to solve the above technical problems, the present invention provides a multi-purpose air-conditioning heat pump water heater system, including:

Compressor (1), its discharge port is connected with the inlet of oil separator (2), the outlet of described oil separator (2) is connected with the a port of the first tee joint (13) through pipeline, and the compressor The suction port of the machine (1) is connected with the d port of the regenerator (7);

The spiral coil heat exchanger (5) is arranged in the pressurized heat preservation water tank (6), and the inlet of the spiral coil heat exchanger (5) is connected to the first three-way joint ( 13) connected to port c, the outlet of the spiral coil heat exchanger (5) is connected to port b of the third three-way joint (15) through a one-way valve (36);

An outdoor heat exchanger (3), the inlet thereof is connected to port b of the sixth three-way joint (18), and the outlet of the outdoor heat exchanger (3) is connected to port c of the fifth three-way joint (17);

The inlet of the indoor heat exchanger (10) is connected to port a of the thirteenth joint (22) through the twelfth control valve (34), and the outlet of the indoor heat exchanger (10) is connected through the tenth control valve (32 ) is connected with the b port of the ninth three-way joint (21);

Port a of the regenerator (7) is connected to port a of the third three-way joint (15), port b of the regenerator (7) is connected to the throttling device (9), the eighth The c port of the three-way joint (20) is connected, and the c port of the regenerator (7) is connected with the c port of the seventh three-way joint (19);

The b port of the first three-way joint (13) is connected to the b port of the second three-way joint (14) by a pipeline provided with a first control valve (23);

Port c of the second three-way joint (14) is connected to port b of the thirteenth joint (22) through a pipeline provided with a thirteenth control valve (35);

Port c of the thirteenth joint (22) is connected to port b of the seventh three-way joint (19) through a pipeline provided with an eleventh control valve (33);

The a port of the seventh three-way joint (19) is connected to the a port of the sixth three-way joint (18) through a pipeline provided with a seventh control valve (29);

Port c of the sixth three-way joint (18) is connected to port a of the second three-way joint (14) through a pipeline provided with a third control valve (25);

The c-port of the second three-way joint (15) is connected to the c-port of the fourth three-way joint (16) through a pipeline provided with a fifth control valve (27);

Port a of the fourth three-way joint (16) is connected to port b of the fifth three-way joint (17) through a pipeline provided with a fourth control valve (26);

Port b of the fourth three-way joint (16) is connected to port a of the ninth three-way joint (21) through a pipeline provided with a ninth control valve (31);

Port c of the ninth three-way joint (21) is connected to port b of the eighth three-way joint (20) through a pipeline provided with a tenth control valve (30);

Port a of the eighth three-way joint (20) is connected to port a of the fifth three-way joint (17) through a pipeline provided with a sixth control valve (28).

The beneficial effects of the present invention are: the compressor, the indoor heat exchanger, the outdoor heat exchanger, the spiral coil heat exchanger, the throttling device and the reflux are organically connected through pipelines, several control valves and several tees to form a set of It is convenient to control, not only can realize indoor cooling while making domestic hot water in summer, and indoor heating while making domestic hot water in winter, but also can realize indoor cooling. The air-conditioning heat pump water heater system for heating and hot water working separately can It is convenient to change the flow direction of the refrigerant through the cooperation of the control valve and the pipe connected by the three-way, which meets the needs of refrigeration and hot water in people's daily life.

Description of drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following will briefly introduce the accompanying drawings that need to be used in the description of the embodiments. Obviously, the accompanying drawings in the following description are only some embodiments of the present invention. For Those skilled in the art can also obtain other drawings based on these drawings without any creative work.

Figure 1 is a schematic diagram of a multi-purpose air-conditioning heat pump water heater system provided by an embodiment of the present invention;

Fig. 2 is a schematic diagram of the state of separately producing hot water by the multi-purpose air-conditioning heat pump water heater system provided by the embodiment of the present invention;

Fig. 3 is a schematic diagram of the state of indoor cooling and hot water production of the multi-purpose air-conditioning heat pump water heater system provided by the embodiment of the present invention;

Fig. 4 is a schematic diagram of the state of individual indoor cooling of the multi-purpose air-conditioning heat pump water heater system provided by the embodiment of the present invention;

Fig. 5 is a schematic diagram of the individual indoor heating state of the multi-purpose air-conditioning heat pump water heater system provided by the embodiment of the present invention;

Fig. 6 is a schematic diagram of the state of the multi-purpose air-conditioning heat pump water heater system provided by the embodiment of the present invention heating indoors and producing hot water at the same time.

Detailed ways

The following clearly and completely describes the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only some of the embodiments of the present invention, but not all of them. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the protection scope of the present invention.

The system of the present invention will be further described below in conjunction with the accompanying drawings and specific embodiments.

Figure 1 shows a multi-purpose air-conditioning heat pump water heater system provided by an embodiment of the present invention, which can independently refrigerate or produce hot water, or simultaneously refrigerate and produce hot water. The system includes: a compressor 1, an oil separator 2, Outdoor heat exchanger 3, spiral coil heat exchanger 5, pressurized heat preservation water tank 6, regenerator 7, throttling device 9, indoor heat exchanger 10, first to thirteenth joints 13-22, first To the thirteenth control valves 23-35 and the one-way valve 36, each equipment is connected through pipelines, and each control valve is set on the connected pipelines;

Wherein, the compressor (1), its exhaust port is connected with the a port 13a of the first three-way joint 13 through a pipeline, and the suction port of the compressor 1 is connected with the d port 7d of the regenerator 7 through the gas-liquid separator 10 ;

The spiral coil heat exchanger 5 is arranged in the pressure-bearing heat preservation water tank 6. The inlet of the spiral coil heat exchanger 5 is connected with the c port 13c of the first three-way joint 13 through the second control valve 24. The spiral coil heat exchanger The outlet of the heat exchanger 5 is connected to the b port 15b of the third three-way joint 15 through a one-way valve 36;

The outdoor heat exchanger 3, its inlet is connected to the b port 18b of the sixth three-way joint 18, and the outlet of the outdoor heat exchanger 3 is connected to the c port 17c of the fifth three-way joint 17;

The inlet of the indoor heat exchanger 10 is connected to the a port 22a of the thirteenth joint 22 through the twelfth control valve 34, and the outlet of the indoor heat exchanger 10 is connected to the ninth three-way joint 21 through the tenth control valve 32. B port 21b connection;

The a port 7a of the regenerator 7 is connected with the a port 15a of the third three-way joint 15, the b port 7b of the regenerator 7 is connected with the throttling device 9, the c port 20c of the eighth three-way joint 20 in sequence, and the return The c port 7c of the heater 7 is connected with the c port 19c of the seventh three-way joint 19;

The b-port 13b of the first three-way joint 13 is connected to the b-port 14b of the second three-way joint 14 through a pipeline provided with a first control valve 23;

The c-port 14c of the second three-way joint 14 is connected to the b-port 22b of the thirteenth-way joint 22 through a pipeline provided with a thirteenth control valve 35;

The c-port 22c of the thirteenth-way joint 22 is connected to the b-port 19b of the seventh three-way joint 19 through a pipeline provided with an eleventh control valve 33;

The a-port 19a of the seventh three-way joint 19 is connected to the a-port 18a of the sixth three-way joint 18 through a pipeline provided with a seventh control valve 29;

The c-port 18c of the sixth three-way joint 18 is connected to the a-port 14a of the second three-way joint 14 through a pipeline provided with a third control valve 25;

The c-port 15c of the second three-way joint 15 is connected to the c-port 16c of the fourth three-way joint 16 through a pipeline provided with a fifth control valve 27;

Port a 16a of the fourth three-way joint 16 is connected to port b 17b of the fifth three-way joint 17 through a pipeline provided with a fourth control valve 26;

The b-port 16b of the fourth three-way joint 16 is connected to the a-port 21a of the ninth three-way joint 21 through a pipeline provided with a ninth control valve 31;

The c-port 21c of the ninth three-way joint 21 is connected to the b-port 20b of the eighth three-way joint 20 through a pipeline provided with a tenth control valve 30;

The port a 20 a of the eighth three-way joint 20 is connected to the port a 17 a of the fifth three-way joint 17 through a pipeline provided with a sixth control valve 28 .

In the above system, the throttling device is a capillary tube, an electromagnetic expansion valve or an electronic expansion valve, etc. Generally, the throttling device is preferably a capillary tube. The system also includes: a dry filter 8, connected between the b port 7b of the regenerator 7 and the throttling device 9, and the dry filter 8 can prevent the throttling device 9 from being blocked when a capillary tube is used.

Further, the above system also includes: a gas-liquid separator 10 connected between the suction port of the compressor 1 and the d port 7d of the regenerator 7 to prevent liquid from entering the compressor 1 and affecting the operation and life of the compressor 1 .

In the above system, the outdoor heat exchanger 2, the indoor heat exchanger 9 and the spiral coil heat exchanger 4 are connected in parallel. Every two heat exchangers are connected in parallel with two tees. In each operation mode, when two heat exchangers form a loop, the other is connected in parallel to one of the heat exchangers.

In the above system, each control valve can be an automatic control valve, which is convenient for automatic control.

In the above system, the outdoor heat exchanger 3 is provided with an outdoor fan 4 ; the indoor heat exchanger 10 is provided with an indoor fan 11 .

The working process of the above-mentioned system is divided into the following situations (taking the system including the oil separator 2 and the dry filter 10 as an example for illustration):

(1) When the hot water is produced separately (as shown in Figure 2), the second, sixth and seventh control valves 24, 28, and 29 are opened, and the other control valves are closed. The system circulates from the compressor 1 through the oil The separator 2, the first three-way joint 13 and the second control valve 24 enter the spiral coil heat exchanger 5, and then pass through the check valve 36, the third three-way joint 15, the regenerator 7, the drying filter 8, The throttling device 9 (capillary tube can be used), the eighth three-way joint 20, the sixth control valve 28, and the fifth three-way joint 17 enter the outdoor heat exchanger 3, and then pass through the sixth three-way joint 18, the seventh control valve 29. The seventh three-way joint 19, the regenerator 7, and the gas-liquid separator 12 return to the compressor 1. At this time, the outdoor heat exchanger 2 is an evaporator, absorbing heat in the air, and the spiral coil heat exchanger 4 is used as Condenser emits heat to heat cold water, when the temperature of hot water in the pressure-insulated water tank 6 reaches the set value, the automatic control control valves 17, 19, 23, 24 are closed, and the system stops running. During this process, the domestic hot water circulation loop starts to work separately. The refrigerant condenses in the spiral coil heat exchanger in the pressure-insulated water tank, releases heat to the cold water in the water tank, evaporates in the outdoor heat exchanger, and absorbs Atmospheric heat, refrigerant path: compressor - oil separator - spiral coil heat exchanger - regenerator - dry filter - throttling device (capillary tube can be used) - outdoor heat exchanger - - Regenerator - Gas-liquid separator - Compressor.

(2) When refrigeration is simultaneously produced and hot water is circulated (as shown in Figure 3), the second, eighth, tenth, eleventh, and twelfth control valves 24, 30, 32, 33, and 34 are opened, The other control valves are closed, and the system circulation enters the spiral coil heat exchanger 5 from the compressor 1 through the oil separator 2, the first three-way joint 13 and the second control valve 24, and then through the one-way valve 36, the third three-way Joint 15, regenerator 7, dry filter 8, throttling device 9 (capillary tube can be used), eighth three-way joint 20, eighth control valve 30, ninth three-way joint 21, tenth control valve 32 enter into The indoor heat exchanger 10 returns to the compressor 1 through the twelfth control valve 34, the thirteenth joint 22, the eleventh control valve 33, the regenerator 7, and the gas-liquid separator 12. At this time, the indoor heat exchange The device 10 is an evaporator, which absorbs indoor heat to realize refrigeration, and the spiral coil heat exchanger 5 is used as a condenser to emit heat to heat cold water.

When the temperature of the hot water in the water tank reaches the set value, the second control valve 24 is closed, and the first, third, fourth and fifth control valves 23, 25, 26, and 27 are opened. At this time, the system becomes an air-conditioning independent refrigeration cycle. Running (as shown in Figure 4), the system circulates from the compressor 1 through the oil separator 2, the first three-way joint 13, the first control valve 23, the second three-way joint 14, the third control valve 25, the sixth and third through the joint 18, enter the outdoor heat exchanger 3, and then pass through the fifth three-way joint 17, the fourth control valve 26, the fourth three-way joint 16, the fifth control valve 27, the third three-way joint 15, and the regenerator 7. Dry filter 8, throttling device 9, eighth three-way joint 20, eighth control valve 30, ninth three-way joint 21, and tenth control valve 32 enter the indoor heat exchanger 10, and then pass through the twelfth The control valve 34, the 13th port joint 22, the 11th control valve 33, the regenerator 7, and the gas-liquid separator 12 return to the compressor 1. At this time, the outdoor heat exchanger 3 is a condenser, and the heat is supplied to the atmosphere, and the indoor The heat exchanger 10 is an evaporator, which absorbs indoor heat to achieve the purpose of cooling. During this process, the indoor refrigeration and hot water circulation loop starts to work at the same time, the refrigerant condenses in the spiral coil heat exchanger in the pressurized heat preservation water tank, releases heat to the cold water in the water tank, evaporates in the indoor heat exchanger, absorbs Indoor heat, to achieve the purpose of cooling and making hot water at the same time, the refrigerant path: compressor - oil separator - spiral coil heat exchanger - regenerator - dry filter - throttling device (optional Using capillary tube)—indoor heat exchanger—regenerator—gas-liquid separator—compressor.

(3) When the indoor heating cycle runs alone (as shown in Figure 5), the first, fifth, sixth, seventh, ninth, tenth, twelfth and thirteenth control valves 23, 27, 28, 29, 31, 32, 34, and 35 are opened, other control valves are closed, and the system circulates from the compressor 1 through the oil separator 2, the first three-way joint 13, the first control valve 23, the second three-way joint 14, The thirteenth control valve 35, the thirteenth joint 22, and the twelfth control valve 34 enter the indoor heat exchanger 10, and then pass through the tenth control valve 32, the ninth three-way joint 21, the ninth control valve 31, the Four three-way joint 16, fifth control valve 27, third three-way joint 15, regenerator 7, dry filter 8, throttling device 9, eighth three-way joint 20, sixth control valve 28, fifth and third The connection joint 17 enters the outdoor heat exchanger 3, and then returns to the compressor 1 through the sixth three-way joint 18, the seventh control valve 29, the seventh three-way joint 19, the regenerator 7, and the gas-liquid separator 12. When the outdoor heat exchanger 3 is an evaporator to absorb the heat of the outdoor air, the indoor heat exchanger 10 is used as a condenser to release heat to the indoor air to achieve the purpose of heating. During this process, the indoor heating cycle begins to work. The refrigerant condenses in the indoor heat exchanger, releases heat to the indoor air, evaporates in the outdoor heat exchanger, and absorbs atmospheric heat. The refrigerant path: compressor-oil separation Heater—indoor heat exchanger—regenerator—dry filter—throttling device (capillary tube can be used)—outdoor heat exchanger—regenerator—gas-liquid separator—compressor.

If you still need to use hot water at this time, you only need to open the control valve 24 (as shown in Figure 6), and the system circulation is divided into two circuits after the compressor 1 passes through the oil separator 2 and the first three-way joint 13 , one way enters the spiral coil heat exchanger 5 from the c port 13c of the first three-way joint 13 through the second control valve 24, and then passes through the check valve 36 and the third three-way joint 15; the other way is from the first three-way joint The b port 13b of the joint 13 enters the indoor heat exchanger 10 through the first control valve 23, the second three-way joint 14, the thirteenth control valve 35, the thirteenth joint 22, and the twelfth control valve 34, and then After the tenth control valve 32, the ninth three-way joint 21, the ninth control valve 31, the fourth three-way joint 16, the fifth control valve 27, and the third three-way joint 15, the two lines are at the third three-way joint 15 After collection, it enters the regenerator 7 from the a port 15a of the third three-way joint 15, and then passes through the dry filter 8, the throttling device 9, the eighth three-way joint 20, the sixth control valve 28, and the fifth three-way joint 17 enters the outdoor heat exchanger 3, and finally returns to the compressor 1 through the sixth three-way joint 18, the seventh control valve 29, the seventh three-way joint 19, the regenerator 7, and the gas-liquid separator 12. At this time, the outdoor The heat exchanger 3 is an evaporator, which absorbs the heat of the outdoor air, and the indoor heat exchanger 10 and the spiral coil heat exchanger 5 are condensers, which release heat to the indoor air and the cold water in the water tank respectively, so as to realize heating and simultaneously produce living Purpose of using hot water. During this process, the indoor heating and domestic hot water circulation loop starts to work, the refrigerant condenses in the indoor heat exchanger and the spiral coil heat exchanger respectively, and releases heat to the indoor air and the heat preservation water tank. Cold water evaporates in the outdoor heat exchanger and absorbs the heat of the atmosphere. The refrigerant path: compressor—oil separator—indoor heat exchanger and spiral coil heat exchanger—regenerator—dry filter—— Throttling device (capillary tube can be used) - outdoor heat exchanger - regenerator - compressor.

The system of the embodiment of the present invention mainly uses several automatic control valves, three-way joints and various equipment connected by pipelines to change the flow direction of the refrigerant, so that it can realize domestic hot water production in summer while indoor cooling, and domestic hot water production in winter At the same time, indoor heating can realize indoor cooling, heating and hot water making work independently. The system meets the needs of air conditioning and domestic hot water in people's daily life, is economical, energy-saving and environmentally friendly, and has broad application prospects.

The above is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any person familiar with the technical field can easily conceive of changes or changes within the technical scope disclosed in the present invention. Replacement should be covered within the protection scope of the present invention. Therefore, the protection scope of the present invention should be determined by the protection scope of the claims.

Claims (7)

1. A multipurpose air-conditioning heat pump water heater system, characterized in that it comprises: Compressor (1), its discharge port is connected with the a port of the first three-way joint (13) through pipeline, and the suction port of described compressor (1) passes gas-liquid separator (10) and regenerator ( 7) D port connection; The spiral coil heat exchanger (5) is arranged in the pressurized heat preservation water tank (6), and the inlet of the spiral coil heat exchanger (5) is connected to the first three-way joint ( 13) connected to port c, the outlet of the spiral coil heat exchanger (5) is connected to port b of the third three-way joint (15) through a one-way valve (36); An outdoor heat exchanger (3), the inlet thereof is connected to port b of the sixth three-way joint (18), and the outlet of the outdoor heat exchanger (3) is connected to port c of the fifth three-way joint (17); The inlet of the indoor heat exchanger (10) is connected to port a of the thirteenth joint (22) through the twelfth control valve (34), and the outlet of the indoor heat exchanger (10) is connected through the tenth control valve (32 ) is connected with the b port of the ninth three-way joint (21); Port a of the regenerator (7) is connected to port a of the third three-way joint (15), port b of the regenerator (7) is connected to the throttling device (9), the eighth The c port of the three-way joint (20) is connected, and the c port of the regenerator (7) is connected with the c port of the seventh three-way joint (19); The b port of the first three-way joint (13) is connected to the b port of the second three-way joint (14) by a pipeline provided with a first control valve (23); Port c of the second three-way joint (14) is connected to port b of the thirteenth joint (22) through a pipeline provided with a thirteenth control valve (35); Port c of the thirteenth joint (22) is connected to port b of the seventh three-way joint (19) through a pipeline provided with an eleventh control valve (33); The a port of the seventh three-way joint (19) is connected to the a port of the sixth three-way joint (18) through a pipeline provided with a seventh control valve (29); Port c of the sixth three-way joint (18) is connected to port a of the second three-way joint (14) through a pipeline provided with a third control valve (25); The c-port of the second three-way joint (15) is connected to the c-port of the fourth three-way joint (16) through a pipeline provided with a fifth control valve (27); Port a of the fourth three-way joint (16) is connected to port b of the fifth three-way joint (17) through a pipeline provided with a fourth control valve (26); Port b of the fourth three-way joint (16) is connected to port a of the ninth three-way joint (21) through a pipeline provided with a ninth control valve (31); Port c of the ninth three-way joint (21) is connected to port b of the eighth three-way joint (20) through a pipeline provided with a tenth control valve (30); Port a of the eighth three-way joint (20) is connected to port a of the fifth three-way joint (17) through a pipeline provided with a sixth control valve (28). 2. A multi-purpose air-conditioning heat pump water heater system according to claim 1, wherein the throttling device is a capillary tube, an electromagnetic expansion valve or an electronic expansion valve. 3. A multi-purpose air-conditioning heat pump water heater system according to claim 1 or 2, characterized in that it further comprises: an oil separator (2), connected between the exhaust port of the compressor (1) and the first Between the a ports of a tee joint (13). 4. A multi-purpose air-conditioning heat pump water heater system according to claim 1 or 2, characterized in that it also includes: a dry filter (8), connected between port b of the regenerator (7) and the node between flow devices (9). 5. A multipurpose air-conditioning heat pump water heater system according to claim 1 or 2, characterized in that the outdoor heat exchanger (2), the indoor heat exchanger (9) and the spiral coil heat exchanger (4) The three are connected in parallel. 6. A multi-purpose air-conditioning heat pump water heater system according to claim 1 or 2, characterized in that, the outdoor heat exchanger (3) is provided with an outdoor fan (4); the indoor heat exchanger (10) is provided with There are indoor fans (11). 7. A multipurpose air-conditioning heat pump water heater system according to claim 1 or 2, wherein the control valves are automatic control valves.