CN209197011U - air conditioning system - Google Patents

Abstract

The application relates to an air conditioning system, including compressor, outdoor heat exchanger and the indoor heat exchanger that loops through the pipe connection, air conditioning system still includes solar heat collection device, set up in outdoor heat exchanger with between the indoor heat exchanger, outdoor heat exchanger solar heat collection device with the indoor heat exchanger loops through the pipe connection, solar heat collection device is used for doing the heat is provided to the heat-retaining device. The air conditioning system is provided with the solar heat collecting device, and solar energy is converted into heat energy to heat hot water in the solar heat collecting device, so that heating is performed at a heating end, the heating efficiency is not reduced while defrosting is achieved, and the comfort of a user is improved.

Description

Air-conditioning system

Technical field

This application involves air conditioner technical fields, more particularly to a kind of air-conditioning system.

Background technique

For traditional air source heat pump heating system when working in winter, machine discharges heat to refrigerant indoors, inhales in outdoor unit Receive heat.For outdoor unit due to being arranged in outdoor, winter makes outdoor temperature is lower, and the vapor in air is easily attached to outdoor unit heat exchange Droplet is formed on device, and then forms frost layer.With the formation of frost layer, the heating capacity of air conditioner declines, and leads to heating end temperature It reduces, influences user experience.Therefore, traditional air source heat pump heating system can periodically turn on defrosting mode, enable refrigerant reverse Circulation, refrigerant discharge heat in outdoor unit heat exchanger and defrost, and machine absorbs heat indoors, finally returns that compressor.

However, traditional air source heat pump heating system has a problem that: when opening defrosting mode, traditional air Source heat pump heating system is due to refrigerant reverse circulation, and leading to refrigerant, machine absorbs amount of heat indoors, and indoor unit is for room Interior heating, this will lead to heating system heating end temperature in defrosting and reduces, and influence user experience.

Utility model content

Based on this, it is necessary to it is directed to conventional heat pump air conditioning function system refrigerant reverse circulation in defrosting in traditional scheme, The problem of causing heating end temperature to reduce, provide a kind of air-conditioning system.

The application provides a kind of air-conditioning system, comprising:

Compressor；

Outdoor heat exchanger is connect with the compressor by refrigerant pipe；

Indoor heat exchanger, one end of the indoor heat exchanger is connect with the outdoor heat exchanger by refrigerant pipe, described The other end of indoor heat exchanger is connect with the compressor by refrigerant pipe；

Also with heating end by water route piping connection, the indoor heat exchanger is used in the air-conditioning indoor heat exchanger When system is in heating mode, by the heat release at the indoor heat exchanger of the refrigerant in refrigerant pipe, mentioned for the heating end Heating load is to realize heating；

Solar energy heat collector, one end of the solar energy heat collector and the indoor heat exchanger pass through refrigerant pipe Road connection, the other end of the solar energy heat collector are connect with the compressor by refrigerant pipe, the solar energy heating Device is used for when the air-conditioning system is in energy-saving mode, and the refrigerant to enter in the solar energy heat collector provides heat Amount, so that the refrigerant into the solar energy heat collector completes heating circulation；

The solar energy heat collector is also connect with the heating end by waterway pipe, and the solar energy heat collector is used In when the air-conditioning system is in defrost pattern, the refrigerant to enter in the solar energy heat collector provides heat, so that While the refrigerant into the solar energy heat collector completes heating circulation, heat is provided with reality for the heating end Now heat.

This application provides a kind of air-conditioning system, the air-conditioning system utilizes the sun by setting solar energy heat collector It is the hot water heating in heat-storing device that thermal energy, which can be converted into, and then is heated for heating end, is not dropped while defrosting to realize Low heat supply efficiency improves user's comfort.

Detailed description of the invention

Fig. 1 is the structural schematic diagram for the air-conditioning system that one embodiment of the application provides；

The structural schematic diagram of heat-storing device in the air-conditioning system that Fig. 2 provides for one embodiment of the application；

The structural schematic diagram of solar energy heat collector in the air-conditioning system that Fig. 3 provides for one embodiment of the application；

Fig. 4 is the structural schematic diagram for the air-conditioning system that one embodiment of the application provides；

Fig. 5 is the flow chart of the control method for the air-conditioning system that one embodiment of the application provides；

Fig. 6 is the flow chart of the control method sub-step for the air-conditioning system that one embodiment of the application provides；

Fig. 7 is the use state diagram for the air-conditioning system that one embodiment of the application provides；

Fig. 8 is the flow chart of the control method sub-step for the air-conditioning system that one embodiment of the application provides；

Fig. 9 is the use state diagram for the air-conditioning system that one embodiment of the application provides；

Figure 10 is the flow chart of the control method sub-step for the air-conditioning system that one embodiment of the application provides；

Figure 11 is the use state diagram for the air-conditioning system that one embodiment of the application provides.

Appended drawing reference:

10 compressors

100 air-conditioning systems

110 first interfaces

120 second interfaces

20 outdoor heat exchangers

200 heating ends

210 third interfaces

220 the 4th interfaces

30 indoor heat exchangers

310 the 5th interfaces

320 the 6th interfaces

330 the 7th interfaces

340 the 8th interfaces

40 solar energy heat collectors

400 heat-storing devices

410 heat storage water tanks

411 inner water tanks

412 outer coil pipes

413 first outlets

414 second outlets

415 temperature-detecting devices

420 solar heat-collection plates

430 inner coil pipes

440 first water pumps

450 first solar water-channel pipelines

460 second solar water-channel pipelines

50 four-way valves

510 first valve ports

520 second valve ports

530 third valve ports

540 the 4th valve ports

610 first triple valves

611 the 5th valve ports

612 the 6th valve ports

613 the 7th valve ports

620 second triple valves

621 the 8th valve ports

622 the 9th valve ports

623 the tenth valve ports

710 first expansion valves

711 first ports

712 second ports

720 second expansion valves

721 third ports

722 the 4th ports

800 waterway circulating units

810 water inlets

820 water outlets

830 second water pumps

840 third water pumps

Specific embodiment

In order to make the purpose of the application, technical solution and advantage are more clearly understood, right with reference to the accompanying drawings and embodiments Air-conditioning system 100 provided by the present application.It should be understood that specific embodiment described herein is only to explain this Shen Please, it is not used to limit the application.

The application provides a kind of air-conditioning system 100.Optionally, the application scenarios of air-conditioning system 100 provided by the present application are Winter.The air-conditioning system 100 is connect with the heating end 200, for heating for the heating end 200.It should be noted that Air-conditioning system 100 provided by the present application not only limits the air-conditioning system 100 applied to domestic type air-conditioning.Any kind of air-conditioning system 100 can be used all embodiments provided by the present application.

As shown in Figure 1, air-conditioning system 100 provided by the present application includes compressor 10, outdoor heat exchanger 20, indoor heat exchanger 30 and solar energy heat collector 40.

The compressor 10 is connect with the outdoor heat exchanger 20 by refrigerant pipe, one end of the indoor heat exchanger 30 It is connect with the outdoor heat exchanger 20 by refrigerant pipe, the other end of the indoor heat exchanger 30 passes through with the compressor 10 Refrigerant pipe connection.One end of the solar energy heat collector 40 is connect with the outdoor heat exchanger 20 by refrigerant pipe, institute The other end for stating solar energy heat collector 40 is connect with the compressor 10 by refrigerant pipe.The indoor heat exchanger 30 also with The heating end 200 passes through water route piping connection.

Optionally, the outdoor heat exchanger 20 is fin-tube heat exchanger.Optionally, the indoor heat exchanger 30 is board-like Heat exchanger.

Specifically, there are three modes: heating mode, energy-saving mode and defrosting mode for the tool of air-conditioning system 100.

When ambient temperature is moderate, when sunlight deficiency, the air-conditioning system 100 opens the heating mode.The system Heat pattern is conventional air-conditioning heating operating mode.When the air-conditioning system 100 is in the heating mode, from the compression The refrigerant for the high-temperature gas that machine 10 discharges generates the refrigerant of low temperature liquid and discharges big in 30 liquidation exothermic reaction of indoor heat exchanger The heat of amount heats for the heating end 200.Further, the refrigerant of the low temperature liquid enters outdoor heat exchanger 20, absorbs Heat in outdoor air, vaporization generate the refrigerant of high-temperature gas, return to the compressor 10 and continue cycling through.

When ambient temperature is lower, but it is sunny when, the air-conditioning system 100 opens the energy-saving mode.Work as institute When stating air-conditioning system 100 and being in the energy-saving mode, the high-temperature gas refrigerant discharged from the compressor 10 is changed in the interior Hot 30 liquidation exothermic reaction of device generates low temperature liquid refrigerant and discharges a large amount of heat, heats for the heating end 200.Further, The low temperature liquid refrigerant enters the solar energy heat collector 40, absorbs the heat in the solar energy heat collector 40, vapour Metaplasia returns to the compressor 10 and continues cycling through at the refrigerant of high-temperature gas.

When 20 frosting of the outdoor heat exchanger of the air-conditioning system 100 is serious, need defrost, and it is sunny when, institute It states air-conditioning system 100 and opens the defrost pattern.When the air-conditioning system 100 is in defrost pattern, discharged from compressor 10 High temperature gaseous coolant in 20 liquidation exothermic reaction of outdoor heat exchanger, generate the refrigerant of low temperature liquid and discharge a large amount of heat Amount.The heat discharged in exothermic process is used to melt the frost layer on 20 surface of outdoor heat exchanger.Further, the Low Temperature Liquid The refrigerant of state enters the solar energy heat collector 40 and absorbs the heat in the solar energy heat collector 40, and vaporization generates high temperature Gaseous refrigerant returns to the compressor 10 and continues cycling through.The solar energy heat collector 40 is contained with heat-storage medium.It is described too Positive energy heat collector 40 acquires solar energy, converts solar energy into thermal energy, and then heat the heat-storage medium.

Air-conditioning system 100 provided by the present application is converted into thermal energy using solar energy by setting solar energy heat collector 40 It for the hot water heating in solar energy heat collector 40, and then heats for heating end 200, so that realizing does not reduce while defrosting Heat supply efficiency improves user's comfort.

As shown in Fig. 2, the solar energy heat collector 40 includes heat-storing device 400, institute in the embodiment of the application Stating heat-storing device 400 can be a heat storage water tank 410.The heat storage water tank 410 includes inner water tank 411 and outer coil pipe 412. The outer coil pipe 412 is sheathed on the inner water tank 411.

The inner water tank 411 is for holding recirculated water.The outer coil pipe 412 is used for transmission in the air-conditioning system 100 Refrigerant.Above-mentioned heat-storing device 400 can provide stable heat source with efficient storage heat for the air-conditioning system 100, it is at low cost and It is convenient to carry out.

As shown in figure 3, the solar energy heat collector 40 further includes solar heat-collection plate in the embodiment of the application 420 and inner coil pipe 430.The solar heat-collection plate 420 is connect with the heat storage water tank 410 by waterway pipe.The inner disc Pipe 430 is connect with the solar heat-collection plate 420.The solar heat-collection plate 420 turns for collecting solar energy, and by solar energy Turn to thermal energy.The solar heat-collection plate 420 is also used to transfer thermal energy to heat-conducting medium.The inner coil pipe 430 is set to institute It states in inner water tank 411, for holding the heat-conducting medium.The inner coil pipe 430 is also used to through the heat-conducting medium to institute State the recirculated water transmission heat in inner water tank 411.

Specifically, the bending of inner coil pipe 430, which is spiraled, is set in the inner water tank 411.In the inner coil pipe 430 It is empty.The heat-conducting medium that the inner coil pipe 430 is held can be water.As shown in figure 4, the solar energy heat collector 40 also wraps Include the first water pump 440.First water pump 440 is used to the heat-conducting medium being transmitted to the solar heat-collection plate 420.Please after Continue refering to Fig. 4, the solar energy heat collector 40 further includes the first solar water-channel pipeline 450 and the second solar water-channel pipeline 460.The solar heat-collection plate 420 and the inner coil pipe 430 pass through the first solar water-channel pipeline 450 and described second Solar water-channel pipeline 460 connects, and realizes circulating heat transfer for the heat-conducting medium.The heat-conducting medium is in the solar energy collection It is heated in hot plate 420, the inner coil pipe 430 is transmitted to by the first solar water-channel pipeline 450, so that the inner coil pipe 430 transmit heat by the recirculated water of the heat-conducting medium into the inner water tank 411.It is logical in the inner coil pipe 430 After crossing recirculated water transmission heat of the heat-conducting medium into the inner water tank 411, the heat-conducting medium passes through described First water pump 440 is back to the solar heat-collection plate 420 through the second solar water-channel pipeline 460, continues to heat, hold Continuous circulation.

Above-mentioned solar heat-collection plate 420 can convert solar energy into thermal energy in the case where sunny, be the storage Boiler 410 provides heat, further provides heating source for the air-conditioning system 100, environmentally protective, saves electric power money Source.

Please continue to refer to Fig. 4, in the embodiment of the application, the air-conditioning system 100 further includes four-way valve 50, first Triple valve 610 and the second triple valve 620.The four-way valve 50 is connected to the compressor 10 and the room by refrigerant pipe Between external heat exchanger 20.First triple valve 610 is connected to the outdoor heat exchanger 20 and the heat accumulation by refrigerant pipe Between water tank 410.Second triple valve 620 is connected to the compressor 10 and the indoor heat exchanger by refrigerant pipe Between 30.

With continued reference to Fig. 4, in the embodiment of the application, the air-conditioning system 100 further includes 710 He of the first expansion valve Second expansion valve 720.First expansion valve 710 is connected to first triple valve 610 and the interior by refrigerant pipe Between heat exchanger 30.Second expansion valve 720 is connected to first triple valve 610 and the heat accumulation by refrigerant pipe Between water tank 410.

With continued reference to Fig. 4, in the embodiment of the application, the four-way valve 50 includes the first valve port 510, the second valve port 520, third valve port 530 and the 4th valve port 540.First triple valve 610 includes the 5th valve port 611, the 6th valve port 612 and the Seven valve ports 613.Second triple valve 620 includes the 8th valve port 621, the 9th valve port 622 and the tenth valve port 623.

Above-mentioned four-way valve 50, the first triple valve 610 and the second triple valve 620 are respectively arranged with multiple valve ports, convenient for described Air-conditioning system 100 switches multiple operating modes, and operation difficulty is low, and work can be realized in the switch that user need to only control different valve ports The adjustment of mode, securely and reliably.

First expansion valve 710 includes first port 711 and second port 712.Second expansion valve 720 includes the Three ports 721 and the 4th port 722.

First expansion valve 710 and the second expansion valve 720 are used for the reducing pressure by regulating flow of refrigerant, while adjustable described cold The flow of matchmaker prevents the air-conditioning system 100 from overheating, it is stable to maintain the air-conditioning system 100.

The compressor 10 includes first interface 110 and second interface 120.The outdoor heat exchanger 20 includes third interface 210 and the 4th interface 220.The indoor heat exchanger 30 includes the 5th interface 310, the 6th interface 320, the 7th interface 330 and the Eight interfaces 340.

First valve port 510 is connect with the first interface 110 by refrigerant pipe.Second valve port 520 and institute The 5th interface 310 is stated to connect by refrigerant pipe.The third valve port 530 is connected with the 9th valve port 622 by refrigerant pipe It connects.4th valve port 540 is connect with the third interface 210 by refrigerant pipe.5th valve port 611 and the described 4th Interface 220 is connected by refrigerant pipe.6th valve port 612 is connect with the third port 721 by refrigerant pipe.It is described 7th valve port 613 is connect with the first port 711 by refrigerant pipe.8th valve port 621 and the second interface 120 It is connected by refrigerant pipe.Tenth valve port 623 is connect with the outer coil pipe 412 by refrigerant pipe.The second port 712 are connect with the 6th interface 320 by refrigerant pipe.4th port 722 passes through refrigerant pipe with the outer coil pipe 412 Road connection.

With continued reference to Fig. 4, in the embodiment of the application, the air-conditioning system 100 further includes waterway circulating unit 800.The waterway circulating unit 800 includes water inlet 810 and water outlet 820.The water inlet 810 and the 7th interface 330 are connected by waterway pipe.The water outlet 820 is connect with the 8th interface 340 by waterway pipe.The water outlet 820 also connect with the heating end 200.

Specifically, when the air-conditioning system 100 is in the heating mode and the energy-saving mode, the water inlet 810 flow into cold water or normal-temperature water, flow into the 7th interface 330 by waterway pipe, pass through the indoor heat exchanger 30 and stream The high temperature refrigerant heat exchange for entering the indoor heat exchanger 30, becomes hot water.Hot water is flowed out from the 8th interface 340, passes through water route Pipeline heats to the water outlet 820 for the heating end 200.The heating end 200 can be the common heating of family Piece.The waterway circulating unit 800 further includes the second water pump 830, and second water pump 830 is set to 810 He of water inlet On waterway pipe between 7th interface 330.Second water pump 830 is for by the cold water of the water inlet 810 or often Warm water is transmitted to the indoor heat exchanger 30.

With continued reference to Fig. 4, in the embodiment of the application, the heat storage water tank 410 further includes being provided with the water tank The first outlet 413 and second outlet 414 of 411 side wall of liner.The water inlet 810 passes through water route with the first outlet 413 Pipeline connection.The water outlet 820 is connect with the second outlet 414 by waterway pipe.

Specifically, when the air-conditioning system 100 is in the energy-saving mode and the defrosting mode, through the water inlet The cold water or normal-temperature water of 810 inflows flow into the heat storage water tank 410 by the first outlet 413, by the solar energy heating Device 40 heats, as the recirculated water.When the air-conditioning system 100 is in the defrosting mode, since refrigerant circulation is released The heat put is used for the defrosting of the outdoor heat exchanger 20, and refrigerant cannot pass through the indoor heat exchanger 30, the heating end 200 Lack heat source.At this point, the recirculated water in the heat storage water tank 410 passes through after the solar energy heat collector 40 heating The second outlet 414 flows into the water outlet 820, for the persistently heating of heating end 200.The waterway circulating unit 800 It further include third water pump 840, the third water pump 840 is set to the water between the water inlet 810 and the first outlet 413 On the pipeline of road.The third water pump 840 is used to the cold water of the water inlet 810 or normal-temperature water being transmitted to the heat storage water tank 410。

Above-mentioned waterway circulating unit 800 is realized by cooperating with the heat storage water tank 410 in the air-conditioning system 100 be in the energy-saving mode when, be 200 circulation heating of heating end, save the energy, reduce heating cost.In the sky When adjusting system 100 is in the defrosting mode, described adopt is continuously during not influencing the defrosting of the outdoor heat exchanger 20 Warm 200 heating of end, improves user's comfort.

With continued reference to Fig. 4, in the embodiment of the application, the heat storage water tank 410 further includes temperature-detecting device 415.The temperature-detecting device 415 is fixedly installed in the inner water tank 411, for detecting in the heat storage water tank 410 The temperature of the recirculated water.By the temperature-detecting device 415, user can follow according to described in the heat storage water tank 410 The temperature of ring water, switches the operating mode of the air-conditioning system 100, and can monitor the working condition of the air-conditioning system 100, It is intuitive easy.

In the embodiment of the application, the solar energy heat collector 40 can also replace with to gas furnace, realize with The seamless interfacing of gas heating system provides convenience to the upgrading in the area Lao Fang for using conventional gas heating system.

As shown in figure 5, additionally providing a kind of control method of air-conditioning system 100 in the embodiment of the application.It needs Illustrate, the control method of air-conditioning system 100 provided by the present application is not intended to limit executing subject.In the embodiment of the application In, the executing subject of the control method of the air-conditioning system 100 can be the controller connecting with the air-conditioning system 100.Institute The control method for stating air-conditioning system 100 includes the following steps S100 to step S600:

S100 controls the temperature value that the temperature-detecting device 415 detects the recirculated water in the heat storage water tank 410.

Specifically, the temperature-detecting device 415 detects the temperature of the recirculated water in the heat storage water tank 410 Value, and the temperature value of the recirculated water is sent to the controller.

S200, judges whether the temperature value of the recirculated water in the heat storage water tank 410 is greater than the first preset temperature value.

Specifically, first preset temperature value can voluntarily be preset by user.

S300 is controlled if the temperature value of the recirculated water is greater than first preset temperature value in the heat storage water tank 410 The air-conditioning system 100 is made into defrost pattern, and is heated to described for heating end 200.

It specifically, can if the temperature value of the recirculated water is greater than first preset temperature value in the heat storage water tank 410 To determine that outdoor solar light is more sufficient, the solar energy heat collector 40 acquires more solar energy, the heat storage water tank 410 The temperature value of the interior recirculated water is higher.Further, the heat stored in the heat storage water tank 410 is enough to change for outdoor It heats while hot 20 defrost of device for the heating end 200.At this point, the controller controls 100 entranceization of air-conditioning system White mode.

S400, if the temperature value of the recirculated water is not more than first preset temperature value in the heat storage water tank 410, Judge whether the temperature value of the recirculated water in the heat storage water tank 410 is less than second preset temperature value.Described first is pre- If temperature value is greater than second preset temperature value.

Specifically, if the temperature value of the recirculated water is not more than first preset temperature value in the heat storage water tank 410, It can determine that outdoor solar light is bad, the shortage of heat stored in the heat storage water tank 410 is to be used for 20 defrost of outdoor heat exchanger While for the heating end 200 heat.The controller continues to judge whether the temperature value of the recirculated water is less than described Two preset temperature values.Second preset temperature value can voluntarily be preset by user.

S500 is controlled if the temperature value of the recirculated water is less than second preset temperature value in the heat storage water tank 410 The air-conditioning system 100 is made into heating mode, and heat to the heating end 200.

It specifically, can if the temperature value of the recirculated water is less than second preset temperature value in the heat storage water tank 410 To determine that outdoor solar light is very poor, and outdoor temperature is lower.Further, the heat of storage can not be in the heat storage water tank 410 It heats at the heating end 200.At this point, the controller, which controls the air-conditioning system 100, enters heating mode, the air-conditioning system 100 by refrigerant circulation be that the heating end 200 is heated, and the heat storage water tank 410 is not involved in heating.

S600, if the temperature value of the recirculated water is not less than second preset temperature value in the heat storage water tank 410, Determine that the temperature value of the recirculated water in the heat storage water tank 410 is in second preset temperature value to first preset value Within the temperature range of, the air-conditioning system 100 is controlled into energy-saving mode, and is heated to the heating end 200.

Specifically, if the temperature value of the recirculated water is not less than second preset temperature value in the heat storage water tank 410, It can determine that the temperature value of the recirculated water in the heat storage water tank 410 is in second preset temperature value to described first pre- If within the temperature range of value, and then can determine that outdoor solar light is general.Further, the heat stored in the heat storage water tank 410 Amount can only heat for the heating end 200, but deficiency thinks 20 defrost of outdoor heat exchanger.At this point, the controller control The air-conditioning system 100 is made into heating mode, the air-conditioning system 100 is the heating end by the heat storage water tank 410 200 heating.

The control method of above-mentioned air-conditioning system 100 passes through the temperature value of recirculated water in detection heat storage water tank 410, according to described in The size of the temperature value of recirculated water controls the air-conditioning system 100 and enters different operating modes, to improve the air-conditioning system The heating efficiency of system 100, and save the energy.

As shown in Figure 6 and Figure 7, in the embodiment of the application, the step S300 includes the following steps 310 to step 340:

S310 is controlled and is connected between first valve port 510 and the 4th valve port 540, controls second valve port It is connected between 520 and the third valve port 530.

S320, controls the 5th valve port 611 and the 7th valve port 613 is opened, and controls the 6th valve port 612 and closes It closes.

S330, controls the 8th valve port 621 and the tenth valve port 623 is opened, and controls the 9th valve port 622 and closes It closes.

S340 controls the compressor 10 and refrigerant is discharged, so that the refrigerant is through 20 heat release of outdoor heat exchanger and melts The frost layer for changing 20 surface of outdoor heat exchanger is absorbed heat through the heat storage water tank 410, finally returns that the compressor 10 completes system Thermal cycle.

Specifically, the air-conditioning system 100 is in the defrosting mode at this time, and the gaseous coolant of high temperature is through the compressor The gaseous coolant of 10 boil down to high temperature and pressure flows into the outdoor heat exchanger 20 through the four-way valve 50, is changed by the outdoor Hot device 20 exchanges heat with outdoor air, and liquefaction release amount of heat melts the frost layer on 20 surface of outdoor heat exchanger, generates low temperature The liquid refrigerants of high pressure.The liquid refrigerants of the cryogenic high pressure flows into second expansion valve through first triple valve 610 720, it is the liquid refrigerants of low temperature through second expansion valve 720 decompression.The liquid refrigerants of the low temperature flows into the water storage High temperature circulation water heat exchange in case 410, with the heat storage water tank 410, vaporization absorption amount of heat, the gaseous state for generating high temperature are cold Matchmaker.The gaseous coolant of the high temperature flows out the outer coil pipe 412, returns to the compressor 10 through second triple valve 620.Institute The high temperature circulation water stated in heat storage water tank 410 flows into the water outlet 820 through the second outlet 414, is the heating end 200 Heating.

As shown in Figure 8 and Figure 9, in the embodiment of the application, the step S500 includes the following steps 510 to step 540:

S510 controls and is connected between first valve port 510 and second valve port 520, controls the third valve port 530 It is connected between the 4th valve port 540.

S520, controls the 5th valve port 611 and the 6th valve port 612 is opened, and controls the 7th valve port 613 and closes It closes.

S530, controls the 8th valve port 621 and the 9th valve port 622 is opened, and controls the tenth valve port 623 and closes It closes.

S540 controls the compressor 10 and refrigerant is discharged, so that the refrigerant is through 30 heat release of indoor heat exchanger, through institute The heat absorption of outdoor heat exchanger 20 is stated, finally returns that the compressor 10 completes heating circulation.

Specifically, the air-conditioning system 100 is in the heating mode at this time, and the gaseous coolant of high temperature is through the compressor The gaseous coolant of 10 boil down to high temperature and pressure flows into the indoor heat exchanger 30 through the four-way valve 50, is changed by the interior Hot device 30 exchanges heat with the cold water or normal-temperature water flowed into through the water inlet 810, and liquefaction release amount of heat generates cryogenic high pressure Liquid refrigerants and for the heating end 200 heat.The liquid refrigerants of the cryogenic high pressure is depressurized through first expansion valve 710 For the liquid refrigerants of low temperature.The liquid refrigerants of the low temperature flows into the outdoor heat exchanger 20 through first triple valve 610, leads to It crosses the outdoor heat exchanger 20 to exchange heat with outdoor air, vaporization absorption amount of heat generates the gaseous coolant of high temperature.The high temperature Gaseous coolant flow into the four-way valve 50, return to the compressor 10 through second triple valve 620.

As shown in Figure 10 and Figure 11, in the embodiment of the application, the step S600 includes the following steps 610 to step Rapid 640:

S610 controls and is connected between first valve port 510 and second valve port 520, controls the third valve port 530 It is connected between the 4th valve port 540.

S620, controls the 6th valve port 612 and the 7th valve port 613 is opened, and controls the 5th valve port 611 and closes It closes.

S630, controls the 8th valve port 621 and the tenth valve port 623 is opened, and controls the 9th valve port 622 and closes It closes.

S640 controls the compressor 10 and refrigerant is discharged, so that the refrigerant is through 30 heat release of indoor heat exchanger, through institute The heat absorption of heat storage water tank 410 is stated, finally returns that the compressor 10 completes heating circulation.

Specifically, the air-conditioning system 100 is in the energy-saving mode at this time, and the gaseous coolant of high temperature is through the compressor The gaseous coolant of 10 boil down to high temperature and pressure flows into the indoor heat exchanger 30 through the four-way valve 50, is changed by the interior Hot device 30 exchanges heat with the cold water or normal-temperature water flowed into through the water inlet 810, and liquefaction release amount of heat generates cryogenic high pressure Liquid refrigerants.The liquid refrigerants of the cryogenic high pressure is the liquid refrigerants of low temperature through first expansion valve 710 decompression.It is described The liquid refrigerants of low temperature flows into the heat storage water tank 410 through first triple valve 610 and second expansion valve 720, with institute The high temperature circulation water heat exchange in heat storage water tank 410 is stated, vaporization absorption amount of heat generates the gaseous coolant of high temperature.The high temperature Gaseous coolant flow out the outer coil pipe 412, return to the compressor 10 through second triple valve 620.

In the embodiment of the application, user can be with the operating mode of air-conditioning system 100 described in manual switching.In this Shen In an embodiment please, user can preset the operating mode of the air-conditioning system 100 according to the time.For example, being controlled in the morning The air-conditioning system 100 executes energy-saving mode, controls the air-conditioning system 100 at noon and executes defrosting mode, controls at night The air-conditioning system 100 executes heating mode.

The control method of above-mentioned air-conditioning system 100 controls the four-way valve 50, the first triple valve by the controller 610 and second triple valve 620 different valve ports unlatching and/or closing, the air-conditioning system 100 is flexibly switched not Same operating mode provides user's convenience of heating, provides users'comfort.

Each technical characteristic of embodiment described above can be combined arbitrarily, for simplicity of description, not to above-mentioned reality It applies all possible combination of each technical characteristic in example to be all described, as long as however, the combination of these technical characteristics is not deposited In contradiction, all should be considered as described in this specification.

The several embodiments of the application above described embodiment only expresses, the description thereof is more specific and detailed, but simultaneously The limitation to the application the scope of the patents therefore cannot be interpreted as.It should be pointed out that for those of ordinary skill in the art For, without departing from the concept of this application, various modifications and improvements can be made, these belong to the guarantor of the application Protect range.Therefore, the scope of protection shall be subject to the appended claims for the application patent.

Claims (10)

1. a kind of air-conditioning system characterized by comprising

Compressor (10)；

Outdoor heat exchanger (20) is connect with the compressor (10) by refrigerant pipe；

Indoor heat exchanger (30), one end and the outdoor heat exchanger (20) of the indoor heat exchanger (30) are connected by refrigerant pipe It connects, the other end of the indoor heat exchanger (30) is connect with the compressor (10) by refrigerant pipe；

Also with heating end (200) by water route piping connection, the indoor heat exchanger (30) is used for the indoor heat exchanger (30) When the air-conditioning system (100) is in heating mode, through the refrigerant in refrigerant pipe at the indoor heat exchanger (30) Heat release provides heat for the heating end (200) to realize heating；

Solar energy heat collector (40), one end and the indoor heat exchanger (20) of the solar energy heat collector (40) pass through cold The connection of matchmaker's pipeline, the other end of the solar energy heat collector (40) are connect with the compressor (10) by refrigerant pipe, institute It states solar energy heat collector (40) to be used for when the air-conditioning system (100) is in energy-saving mode, to enter the solar energy collection Refrigerant in thermal (40) provides heat, so that the refrigerant entered in the solar energy heat collector (40) completes heating Circulation；

The solar energy heat collector (40) is also connect with the heating end (200) by waterway pipe, the solar energy heating Device (40) is used for when the air-conditioning system (100) is in defrost pattern, to enter in the solar energy heat collector (40) Refrigerant provide heat so that it is described enter the solar energy heat collector (40) in refrigerant complete heating circulation while, Heat is provided for the heating end (200) to realize heating.

2. air-conditioning system according to claim 1, which is characterized in that the solar energy heat collector (40) includes heat accumulation dress It sets (400), the heat-storing device (400) is a heat storage water tank (410), and the heat storage water tank (410) includes:

Inner water tank (411), for holding recirculated water；

Outer coil pipe (412), is sheathed on the inner water tank (411), the refrigerant being used for transmission in the air-conditioning system (100).

3. air-conditioning system according to claim 2, which is characterized in that the solar energy heat collector (40) further include:

Solar heat-collection plate (420) is connect with the heat storage water tank (410) by waterway pipe, for collecting solar energy and inciting somebody to action Solar energy is converted into thermal energy, and the solar heat-collection plate (420) is also used to transfer thermal energy to heat-conducting medium, for the heat accumulation Water tank (410) provides heat.

4. air-conditioning system according to claim 3, which is characterized in that the solar energy heat collector (40) further include:

Inner coil pipe (430) is connect with the solar heat-collection plate (420), and the inner coil pipe (430) is set to the inner water tank (411) in, for holding the heat-conducting medium, the inner coil pipe (430) is also used to through the heat-conducting medium to the water tank The recirculated water in liner (411) transmits heat.

5. air-conditioning system according to claim 4, which is characterized in that further include:

Four-way valve (50) is connected between the compressor (10) and the outdoor heat exchanger (20) by refrigerant pipe；

First triple valve (610), by refrigerant pipe be connected to the outdoor heat exchanger (20) and the heat storage water tank (410) it Between；And

Second triple valve (620) is connected between the compressor (10) and the indoor heat exchanger (30) by refrigerant pipe.

6. air-conditioning system according to claim 5, which is characterized in that further include:

First expansion valve (710) is connected to first triple valve (610) and the indoor heat exchanger (30) by refrigerant pipe Between；And

Second expansion valve (720) is connected to first triple valve (610) and the heat storage water tank (410) by refrigerant pipe Between.

7. air-conditioning system according to claim 6, which is characterized in that the four-way valve (50) include the first valve port (510), Second valve port (520), third valve port (530) and the 4th valve port (540)；

First triple valve includes the 5th valve port (611), the 6th valve port (612) and the 7th valve port (613)；

Second triple valve (620) includes the 8th valve port (621), the 9th valve port (622) and the tenth valve port (623)；

First expansion valve (710) includes first port (711) and second port (712)；

Second expansion valve (720) includes third port (721) and the 4th port (722)；

The compressor (10) includes first interface (110) and second interface (120)；

The outdoor heat exchanger (20) includes third interface (210) and the 4th interface (220)；

The indoor heat exchanger (30) includes the 5th interface (310), the 6th interface (320), the 7th interface (330) and the 8th interface (340)；

First valve port (510) is connect with the first interface (110) by refrigerant pipe；

Second valve port (520) is connect with the 5th interface (310) by refrigerant pipe；

The third valve port (530) is connect with the 9th valve port (622) by refrigerant pipe；

4th valve port (540) is connect with the third interface (210) by refrigerant pipe；

5th valve port (611) is connect with the 4th interface (220) by refrigerant pipe；

6th valve port (612) is connect with the third port (721) by refrigerant pipe；

7th valve port (613) is connect with the first port (711) by refrigerant pipe；

8th valve port (621) is connect with the second interface (120) by refrigerant pipe；

Tenth valve port (623) is connect with the outer coil pipe (412) by refrigerant pipe；

The second port (712) is connect with the 6th interface (320) by refrigerant pipe；

4th port (722) is connect with the outer coil pipe (412) by refrigerant pipe.

8. air-conditioning system according to claim 7, which is characterized in that further include:

Waterway circulating unit (800), including water inlet (810) and water outlet (820)；

The water inlet (810) is connect with the 7th interface (330) by waterway pipe, the water outlet (820) with it is described 8th interface (340) is connected by waterway pipe, and the water outlet (820) also connect with the heating end (200).

9. air-conditioning system according to claim 8, which is characterized in that the heat storage water tank (410) further includes being provided with institute The first outlet (413) and second outlet (414) of inner water tank (411) side wall are stated, the water inlet (810) goes out with described first Mouth (413) is connected by waterway pipe, and the water outlet (820) is connect with the second outlet (414) by waterway pipe.

10. air-conditioning system according to claim 9, which is characterized in that the heat storage water tank (410) further include:

Temperature-detecting device (415) is fixedly installed in the inner water tank (411), for detecting the heat storage water tank (410) The temperature of the interior recirculated water.