CN215483277U - Single-unit-room air water-making and water-supplying system - Google Patents

Abstract

The utility model discloses a single-room air water making and supplying system, which comprises an outdoor unit and an indoor unit, wherein the outdoor unit comprises a water tank, a water pump and a water tank; the outdoor unit comprises an air water generator, a lower water tank and a flow pump; the pipeline of the air water generator is connected with the lower water tank; the lower water tank pipeline is connected with the water inlet end of the flow pump; the indoor unit comprises a booster pump, a reverse osmosis membrane, a wastewater ratio, a cold water tank and a water outlet device; a water inlet end pipeline of the booster pump is connected with a flow pump; the water inlet end pipeline of the reverse osmosis membrane is connected with the water outlet end of the booster pump; the wastewater ratio is respectively connected with a wastewater outlet end of the reverse osmosis membrane and a lower water tank through pipelines; the cold water tank pipeline is connected with a drinking water outlet end of the reverse osmosis membrane; the water outlet device pipeline is connected with the cold water tank. The reverse osmosis membrane water filter can improve the pressure of water entering the reverse osmosis membrane, and further improve the working efficiency of reverse osmosis membrane filtering water.

Description

Single-unit-room air water-making and water-supplying system

Technical Field

The utility model relates to the technical field of air water production, in particular to a single-room air water production and supply system.

Background

Air water production is a technology for directly extracting water molecules from air without a water source and processing the water molecules into high-quality drinking water, and meanwhile, when drinking water is to be obtained, a reverse osmosis membrane is adopted to filter the water so as to divide the water into two types, namely the drinking water and the waste water containing impurities such as dissolved salts, colloids, microorganisms and organic matters. However, the long distance outdoor water making system has the problem that the pressure of water is insufficient due to the long distance, so that the efficiency of filtering water into drinking water at the reverse osmosis membrane is low, and thus, the waste of resources is caused.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: the single-room air water-making and water-supplying system can improve the working efficiency of reverse osmosis membrane filtering water.

In order to solve the technical problems, the utility model adopts the technical scheme that: a single-room air water making and supplying system comprises an outdoor unit and an indoor unit;

the outdoor unit comprises an air water generator, a lower water tank and a flow pump; the pipeline of the air water generator is connected with the lower water tank; the lower water tank pipeline is connected with the water inlet end of the flow pump;

the indoor unit comprises a booster pump, a reverse osmosis membrane, a wastewater ratio, a cold water tank and a water outlet device; a water inlet end pipeline of the booster pump is connected with a flow pump; the water inlet end pipeline of the reverse osmosis membrane is connected with the water outlet end of the booster pump;

the wastewater ratio is respectively connected with a wastewater outlet end of the reverse osmosis membrane and a lower water tank through pipelines; the cold water tank pipeline is connected with a drinking water outlet end of the reverse osmosis membrane; the water outlet device pipeline is connected with the cold water tank.

Further, the air water generator comprises an air filter screen, a water generating system and a water receiving tray;

the air filter screen pipeline is connected with a water production system;

a water receiving disc is arranged at the water outlet end of the water production system;

the water receiving tray pipeline is connected with the lower water tank.

Further, be provided with first water level probe, first active carbon filter and first UV sterilizer in the lower water tank, first water level probe line connection air water maker.

Furthermore, a second activated carbon filter is arranged at the water inlet end of the reverse osmosis membrane, a water inlet end pipeline of the second activated carbon filter is connected with the water outlet end of the booster pump, and a third activated carbon filter is arranged at the drinking water outlet end of the reverse osmosis membrane.

Furthermore, a first water outlet valve, a first pressure switch, a water inlet valve and a second pressure switch are arranged between the flow pump and the reverse osmosis membrane pipeline;

the water inlet end pipeline of the first water outlet valve is connected with the water outlet end of the flow pump;

the first pressure switch is positioned at the water outlet end of the first water outlet valve, and a first pressure switch circuit is respectively connected with the first water outlet valve and the flow pump;

the water outlet end pipeline of the water inlet valve is connected with the water inlet end of the booster pump;

the second pressure switch is positioned at the water inlet end of the water inlet valve, and a second pressure switch circuit is respectively connected with the water inlet valve and the booster pump.

Furthermore, a first water outlet valve and a water inlet valve are arranged between the flow pump and the reverse osmosis membrane pipeline;

the water inlet end pipeline of the first water outlet valve is connected with the water outlet end of the flow pump;

the water outlet end pipeline of the water inlet valve is connected with the water inlet end of the booster pump;

and a second water level probe is arranged in the cold water tank, and the lines of the second water level probe are respectively connected with the first water outlet valve, the water inlet valve, the flow pump and the booster pump.

Further, a fourth activated carbon filter and a second UV sterilizer are arranged in the cold water tank.

Furthermore, a hot tank is arranged in the indoor unit, and the hot tank is respectively connected with a cold water tank and a water outlet device through pipelines.

Furthermore, the water outlet device comprises a three-way water outlet pump, a second water outlet valve, a water outlet pump and a third water outlet valve;

a water inlet end pipeline of the three-way water outlet pump is connected with the cold water tank, a water outlet end pipeline of the three-way water outlet pump is connected with a third UV sterilizer, a pipeline of the third UV sterilizer is connected with the cold water tank, and the other water outlet end pipeline of the three-way water outlet pump is connected with a second water outlet valve;

and a water inlet end pipeline of the water outlet pump is connected with the hot tank, and a water outlet end pipeline of the water outlet pump is connected with a third water outlet valve.

The utility model has the beneficial effects that: the water in the air is condensed into water by the air water generator and is collected in the lower water tank, then the water in the lower water tank is pumped to the indoor unit by the flow pump, and then the booster pump boosts the water in the pipeline to ensure that the water has enough pressure to enter the reverse osmosis membrane for filtration treatment. Thereby realizing the improvement of the working efficiency of reverse osmosis membrane filtering water.

Drawings

Fig. 1 is a schematic structural diagram of a single-room air to water supply system according to a first embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a single-room air to water supply system according to a first embodiment of the present invention;

description of reference numerals:

1. an outdoor unit; 11. an air water generator; 111. an air filter screen; 112. a water production system; 113. a water pan;

12. a lower water tank; 121. a first water level probe; 122. a first activated carbon filter; 123. a first UV sterilizer;

13. a flow pump;

2. an indoor unit; 21. a booster pump; 22. a reverse osmosis membrane; 23. the ratio of waste water to waste water;

24. a cold water tank; 241. a second water level probe; 242. a fourth activated carbon filter; 243. a second UV sterilizer;

25. a water outlet device; 251. a water outlet pump is arranged; 252. a second water outlet valve; 253. discharging the water pump; 254. a third water outlet valve;

26. heating the tank;

3. a second activated carbon filter; 4. a third activated carbon filter; 5. a first water outlet valve; 6. a first pressure switch; 7. a water inlet valve; 8. a second pressure switch; 9. and a third UV sterilizer.

Detailed Description

In order to explain technical contents, achieved objects, and effects of the present invention in detail, the following description is made with reference to the accompanying drawings in combination with the embodiments.

Referring to fig. 1 and 2, a single-room air to water supply system includes an outdoor unit 1 and an indoor unit 2;

the outdoor unit 1 comprises an air water maker 11, a lower water tank 12 and a flow pump 13; the air water generator 11 is connected with the lower water tank 12 through a pipeline; the pipeline of the lower water tank 12 is connected with the water inlet end of the flow pump 13;

the indoor unit 2 comprises a booster pump 21, a reverse osmosis membrane 22, a wastewater ratio 23, a cold water tank 24 and a water outlet device 25; a water inlet end pipeline of the booster pump 21 is connected with the flow pump 13; a water inlet end pipeline of the reverse osmosis membrane 22 is connected with a water outlet end of the booster pump 21;

the wastewater ratio 23 is respectively connected with a wastewater outlet end of the reverse osmosis membrane 22 and the lower water tank 12 through pipelines; the pipeline of the cold water tank 24 is connected with the drinking water outlet end of the reverse osmosis membrane 22; the water outlet device 25 is connected with the cold water tank 24 through a pipeline.

The working principle is as follows: in the process of water production, the air water producer 11 of the outdoor unit 1 condenses the water in the air into water, and collects the water into the lower water tank 12. Then the water in the lower water tank 12 is pumped to the indoor unit 2 by the flow pump 13, and then the booster pump 21 boosts the pressure of the water in the pipeline to ensure that the water has enough pressure to enter the reverse osmosis membrane 22 for filtration treatment, and because the membrane aperture of the reverse osmosis membrane 22 is very small, impurities such as dissolved salts, colloid, microorganisms, organic matters and the like in the water can be effectively removed. Thus separating the water at the reverse osmosis membrane 22 into drinking water that passes through the reverse osmosis membrane 22 and waste water that does not pass through the reverse osmosis membrane 22. The drinking water enters the cold water tank 24 through the pipeline, and the drinking water in the cold water tank 24 can be taken out for drinking by opening the water outlet device 25. The waste water is returned to the lower tank 12 through a pipe. Meanwhile, the amount of pure water and the amount of waste water generated at the reverse osmosis membrane 22 can be adjusted by adjusting the waste water ratio 23.

From the above description, the beneficial effects of the present invention are: the water in the air is condensed into water by the air water generator 11 and collected in the lower water tank 12, then the water in the lower water tank 12 is pumped to the indoor unit 2 by the flow pump 13, and the booster pump 21 boosts the pressure of the water in the pipeline to ensure that the water has enough pressure to enter the reverse osmosis membrane 22 for filtration treatment. Thereby realizing the improvement of the working efficiency of the reverse osmosis membrane 22 for filtering water.

Further, the air water generator 11 comprises an air filter screen 111, a water generation system 112 and a water receiving tray 113;

the air filter 111 is connected with a water production system 112 through a pipeline;

a water receiving tray 113 is arranged at the water outlet end of the water production system 112;

the water receiving tray 113 is connected with the lower water tank 12 through a pipeline.

As can be seen from the above description, before the water in the extracted air is condensed into water, the water production system 112 filters out larger particle impurities in the air through the air filter 111, and then the water pan 113 receives and collects the water produced by the water production system 112, and finally the water collected by the water pan 113 flows into the lower water tank 12 through a pipeline for storage.

Further, a first water level probe 121, a first activated carbon filter 122 and a first UV sterilizer 123 are arranged in the lower water tank 12, and the first water level probe 121 is connected with the air water generator 11 through a line.

As can be seen from the above description, the first water level probe 121 is disposed in the lower water tank 12, the water storage capacity in the lower water tank 12 is monitored in real time through the first water level probe 121, and when the first water level probe 121 monitors that the water storage capacity in the lower water tank 12 is lower than a set value, the air water generator 11 is controlled to start water generation operation. When the first water level probe 121 monitors that the water storage capacity in the lower water tank 12 reaches a set value, the air water generator 11 is controlled to stop the water generation operation. Meanwhile, the first activated carbon filter 122 and the first UV sterilizer 123 are disposed in the lower water tank 12, and water can be pretreated once before entering the reverse osmosis membrane 22 for filtration, so as to reduce the operation pressure of the reverse osmosis membrane 22.

Furthermore, a second activated carbon filter 3 is arranged at the water inlet end of the reverse osmosis membrane 22, the water inlet end of the second activated carbon filter 3 is connected with the water outlet end of the booster pump 21, and a third activated carbon filter 4 is arranged at the drinking water outlet end of the reverse osmosis membrane 22.

As can be seen from the above description, the water is pretreated by the second activated carbon filter 3 before entering the reverse osmosis membrane 22 for filtration, so as to reduce impurities deposited on the surface after the reverse osmosis membrane 22 is filtered. Then the drinking water flowing out from the drinking water outlet end of the reverse osmosis membrane 22 is subjected to primary purification treatment through the third activated carbon filter 4 so as to ensure the cleanness of the drinking water.

Further, a first water outlet valve 5, a first pressure switch 6, a water inlet valve 7 and a second pressure switch 8 are arranged between the flow pump 13 and the reverse osmosis membrane 22 pipeline;

the water inlet end pipeline of the first water outlet valve 5 is connected with the water outlet end of the flow pump 13;

the first pressure switch 6 is positioned at the water outlet end of the first water outlet valve 5, and the lines of the first pressure switch 6 are respectively connected with the first water outlet valve 5 and the flow pump 13;

the water outlet end pipeline of the water inlet valve 7 is connected with the water inlet end of the booster pump 21;

the second pressure switch 8 is positioned at the water inlet end of the water inlet valve 7, and the lines of the second pressure switch 8 are respectively connected with the water inlet valve 7 and the booster pump 21.

As can be seen from the above description, when the first pressure switch 6 and the second pressure switch 8 detect that the pressure in the pipeline is less than the set value (i.e. the storage amount of the drinking water in the cold water tank 24 is insufficient), the first pressure switch 6 will control the first water outlet valve 5 to open and control the flow pump 13 to pump the water in the lower water tank 12, and at the same time, the second pressure switch 8 will control the water inlet valve 7 to open and the booster pump 21 to boost the pressure of the water in the pipeline to ensure that the water has sufficient pressure to pass through the reverse osmosis membrane 22 to prepare the drinking water. When the first pressure switch 6 and the second pressure switch 8 detect that the pressure in the pipeline reaches the set value (i.e. the amount of the drinking water stored in the cold water tank 24 is sufficient), the first pressure switch 6 controls the first water outlet valve 5 to be closed and controls the flow pump 13 to stop operating, and the second pressure switch 8 controls the water inlet valve 7 to be closed and the booster pump 21 to stop operating.

Further, a first water outlet valve 5 and a water inlet valve 7 are arranged between the flow pump 13 and the reverse osmosis membrane 22 pipeline;

the water inlet end pipeline of the first water outlet valve 5 is connected with the water outlet end of the flow pump 13;

the water outlet end pipeline of the water inlet valve 7 is connected with the water inlet end of the booster pump 21;

a second water level probe 241 is arranged in the cold water tank 24, and the lines of the second water level probe 241 are respectively connected with the first water outlet valve 5, the water inlet valve 7, the flow pump 13 and the booster pump 21.

As can be seen from the above description, when the second water level probe 241 in the cold water tank 24 detects that the drinking water storage in the cold water tank 24 is lower than the set value, the first outlet valve 5 and the inlet valve 7 are controlled to open, and the flow pump 13 and the booster pump 21 start to operate. When the second water level probe 241 in the cold water tank 24 detects that the drinking water storage in the cold water tank 24 reaches the set value, the first water outlet valve 5 and the water inlet valve 7 are controlled to be closed, and the flow pump 13 and the booster pump 21 stop operating.

Further, a fourth activated carbon filter 242 and a second UV sterilizer 243 are provided in the cold water tank 24.

As can be seen from the above description, the drinking water in the cold water tank 24 can be further filtered by the fourth carbon filter 242 and the second UV sterilizer 243.

Furthermore, a hot tank 26 is arranged in the indoor unit 2, and the hot tank 26 is respectively connected with the cold water tank 24 and the water outlet device 25 through pipelines.

As is apparent from the above description, the hot tank 26 is provided in the indoor unit 2, and the hot tank 26 is connected to the cold water tank 24 and the outlet 25 by pipes, respectively, so that hot water can be drunk when pure water is drunk.

Further, the water outlet device 25 comprises a three-way water outlet pump 251, a second water outlet valve 252, a water outlet pump 253 and a third water outlet valve 254;

a water inlet end pipeline of the three-way water outlet pump 251 is connected with the cold water tank 24, a water outlet end pipeline of the three-way water outlet pump 251 is connected with a third UV sterilizer 9, a pipeline of the third UV sterilizer 9 is connected with the cold water tank 24, and the other water outlet end pipeline of the three-way water outlet pump 251 is connected with a second water outlet valve 252;

the water inlet end pipeline of the water outlet pump 253 is connected with the hot tank 26, and the water outlet end pipeline of the water outlet pump 253 is connected with the third water outlet valve 254.

As can be seen from the above description, when the water is not used, the three-way water outlet pump 251 can periodically pump the drinking water in the cold water tank 24 into the third UV sterilizer 9 for sterilization, and finally the drinking water flows back into the cold water tank 24. The hot tank 26 heats the drinking water inside at regular intervals, thus not only ensuring that hot water is supplied when hot water is needed, but also sterilizing the water.

Example one

Referring to fig. 1, a single-room air to water supply system includes an outdoor unit 1 and an indoor unit 2; the outdoor unit 1 comprises an air water maker 11, a lower water tank 12 and a flow pump 13; the air water generator 11 is connected with the lower water tank 12 through a pipeline; the pipeline of the lower water tank 12 is connected with the water inlet end of the flow pump 13; the indoor unit 2 comprises a booster pump 21, a reverse osmosis membrane 22, a wastewater ratio 23, a cold water tank 24 and a water outlet device 25; a water inlet end pipeline of the booster pump 21 is connected with the flow pump 13; a water inlet end pipeline of the reverse osmosis membrane 22 is connected with a water outlet end of the booster pump 21; the wastewater ratio 23 is respectively connected with a wastewater outlet end of the reverse osmosis membrane 22 and the lower water tank 12 through pipelines; the pipeline of the cold water tank 24 is connected with the drinking water outlet end of the reverse osmosis membrane 22; the water outlet device 25 is connected with the cold water tank 24 through a pipeline.

The air water generator 11 comprises an air filter screen 111, a water generating system 112 and a water receiving tray 113; the air filter 111 is connected with a water production system 112 through a pipeline; a water receiving tray 113 is arranged at the water outlet end of the water production system 112; the water receiving tray 113 is connected with the lower water tank 12 through a pipeline. A first water level probe 121, a first activated carbon filter 122 and a first UV sterilizer 123 are arranged in the lower water tank 12, and the first water level probe 121 is connected with the air water generator 11 through a line. Reverse osmosis membrane 22's water inlet end department is provided with second active carbon filter 3, the play water end of booster pump 21 is connected to second active carbon filter 3's the end of intaking pipeline, reverse osmosis membrane 22's drinking water outlet end is provided with third active carbon filter 4.

A first water outlet valve 5, a first pressure switch 6, a water inlet valve 7 and a second pressure switch 8 are arranged between the flow pump 13 and the reverse osmosis membrane 22 pipeline; the water inlet end pipeline of the first water outlet valve 5 is connected with the water outlet end of the flow pump 13; the first pressure switch 6 is positioned at the water outlet end of the first water outlet valve 5, and the lines of the first pressure switch 6 are respectively connected with the first water outlet valve 5 and the flow pump 13; the water outlet end pipeline of the water inlet valve 7 is connected with the water inlet end of the booster pump 21; the second pressure switch 8 is positioned at the water inlet end of the water inlet valve 7, and the lines of the second pressure switch 8 are respectively connected with the water inlet valve 7 and the booster pump 21.

A fourth activated carbon filter 242 and a second UV sterilizer 243 are disposed in the cold water tank 24. A hot tank 26 is arranged in the indoor unit 2, and the hot tank 26 is respectively connected with a cold water tank 24 and a water outlet device 25 through pipelines. The water outlet device 25 comprises a three-way water outlet pump 251, a second water outlet valve 252, a water outlet pump 253 and a third water outlet valve 254; a water inlet end pipeline of the three-way water outlet pump 251 is connected with the cold water tank 24, a water outlet end pipeline of the three-way water outlet pump 251 is connected with a third UV sterilizer 9, a pipeline of the third UV sterilizer 9 is connected with the cold water tank 24, and the other water outlet end pipeline of the three-way water outlet pump 251 is connected with a second water outlet valve 252; the water inlet end pipeline of the water outlet pump 253 is connected with the hot tank 26, and the water outlet end pipeline of the water outlet pump 253 is connected with the third water outlet valve 254.

Example two

Referring to fig. 2, a single-room air to water supply system includes an outdoor unit 1 and an indoor unit 2; the outdoor unit 1 comprises an air water maker 11, a lower water tank 12 and a flow pump 13; the air water generator 11 is connected with the lower water tank 12 through a pipeline; the pipeline of the lower water tank 12 is connected with the water inlet end of the flow pump 13; the indoor unit 2 comprises a booster pump 21, a reverse osmosis membrane 22, a wastewater ratio 23, a cold water tank 24 and a water outlet device 25; a water inlet end pipeline of the booster pump 21 is connected with the flow pump 13; a water inlet end pipeline of the reverse osmosis membrane 22 is connected with a water outlet end of the booster pump 21; the wastewater ratio 23 is respectively connected with a wastewater outlet end of the reverse osmosis membrane 22 and the lower water tank 12 through pipelines; the pipeline of the cold water tank 24 is connected with the drinking water outlet end of the reverse osmosis membrane 22; the water outlet device 25 is connected with the cold water tank 24 through a pipeline.

The air water generator 11 comprises an air filter screen 111, a water generating system 112 and a water receiving tray 113; the air filter 111 is connected with a water production system 112 through a pipeline; a water receiving tray 113 is arranged at the water outlet end of the water production system 112; the water receiving tray 113 is connected with the lower water tank 12 through a pipeline. A first water level probe 121, a first activated carbon filter 122 and a first UV sterilizer 123 are arranged in the lower water tank 12, and the first water level probe 121 is connected with the air water generator 11 through a line. Reverse osmosis membrane 22's water inlet end department is provided with second active carbon filter 3, the play water end of booster pump 21 is connected to second active carbon filter 3's the end of intaking pipeline, reverse osmosis membrane 22's drinking water outlet end is provided with third active carbon filter 4.

A first water outlet valve 5 and a water inlet valve 7 are arranged between the flow pump 13 and the reverse osmosis membrane 22 pipeline; the water inlet end pipeline of the first water outlet valve 5 is connected with the water outlet end of the flow pump 13; the water outlet end pipeline of the water inlet valve 7 is connected with the water inlet end of the booster pump 21; a second water level probe 241 is arranged in the cold water tank 24, and the lines of the second water level probe 241 are respectively connected with the first water outlet valve 5, the water inlet valve 7, the flow pump 13 and the booster pump 21.

A fourth activated carbon filter 242 and a second UV sterilizer 243 are disposed in the cold water tank 24. A hot tank 26 is arranged in the indoor unit 2, and the hot tank 26 is respectively connected with a cold water tank 24 and a water outlet device 25 through pipelines. The water outlet device 25 comprises a three-way water outlet pump 251, a second water outlet valve 252, a water outlet pump 253 and a third water outlet valve 254; a water inlet end pipeline of the three-way water outlet pump 251 is connected with the cold water tank 24, a water outlet end pipeline of the three-way water outlet pump 251 is connected with a third UV sterilizer 9, a pipeline of the third UV sterilizer 9 is connected with the cold water tank 24, and the other water outlet end pipeline of the three-way water outlet pump 251 is connected with a second water outlet valve 252; the water inlet end pipeline of the water outlet pump 253 is connected with the hot tank 26, and the water outlet end pipeline of the water outlet pump 253 is connected with the third water outlet valve 254.

In summary, the utility model provides a single-unit-chamber air water-making and water-supplying system, which condenses water in air into water by an air water-making device, collects the water in a lower water tank, pumps water in the lower water tank to an indoor unit by a flow pump, and pressurizes the water in a pipeline by a booster pump so as to ensure that the water has enough pressure to enter a reverse osmosis membrane for filtration treatment. Thereby realizing the improvement of the working efficiency of reverse osmosis membrane filtering water.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes made by using the contents of the present specification and the drawings, or applied directly or indirectly to the related technical fields, are included in the scope of the present invention.

Claims (9)

1. The utility model provides a unit room air system water supply system which characterized in that: comprises an outdoor unit and an indoor unit;

the outdoor unit comprises an air water generator, a lower water tank and a flow pump; the pipeline of the air water generator is connected with the lower water tank; the lower water tank pipeline is connected with the water inlet end of the flow pump;

the indoor unit comprises a booster pump, a reverse osmosis membrane, a wastewater ratio, a cold water tank and a water outlet device; a water inlet end pipeline of the booster pump is connected with a flow pump; the water inlet end pipeline of the reverse osmosis membrane is connected with the water outlet end of the booster pump; the wastewater ratio is respectively connected with a wastewater outlet end of the reverse osmosis membrane and a lower water tank through pipelines; the cold water tank pipeline is connected with a drinking water outlet end of the reverse osmosis membrane; the water outlet device pipeline is connected with the cold water tank.

2. The single-room air to water supply system according to claim 1, wherein: the air water generator comprises an air filter screen, a water generating system and a water receiving tray;

the air filter screen pipeline is connected with a water production system;

a water receiving disc is arranged at the water outlet end of the water production system;

the water receiving tray pipeline is connected with the lower water tank.

3. The single-room air to water supply system according to claim 1, wherein: a first water level probe, a first activated carbon filter and a first UV sterilizer are arranged in the lower water tank, and the first water level probe is connected with an air water generator through a line.

4. The single-room air to water supply system according to claim 1, wherein: the water inlet end of the reverse osmosis membrane is provided with a second activated carbon filter, the water inlet end of the second activated carbon filter is connected with the water outlet end of the booster pump through a pipeline, and the drinking water outlet end of the reverse osmosis membrane is provided with a third activated carbon filter.

5. The single-room air to water supply system according to claim 1, wherein: a first water outlet valve, a first pressure switch, a water inlet valve and a second pressure switch are arranged between the flow pump and the reverse osmosis membrane pipeline;

the water inlet end pipeline of the first water outlet valve is connected with the water outlet end of the flow pump;

the first pressure switch is positioned at the water outlet end of the first water outlet valve, and a first pressure switch circuit is respectively connected with the first water outlet valve and the flow pump;

the water outlet end pipeline of the water inlet valve is connected with the water inlet end of the booster pump;

the second pressure switch is positioned at the water inlet end of the water inlet valve, and a second pressure switch circuit is respectively connected with the water inlet valve and the booster pump.

6. The single-room air to water supply system according to claim 1, wherein: a first water outlet valve and a water inlet valve are arranged between the flow pump and the reverse osmosis membrane pipeline;

the water inlet end pipeline of the first water outlet valve is connected with the water outlet end of the flow pump;

the water outlet end pipeline of the water inlet valve is connected with the water inlet end of the booster pump;

and a second water level probe is arranged in the cold water tank, and the lines of the second water level probe are respectively connected with the first water outlet valve, the water inlet valve, the flow pump and the booster pump.

7. The single-room air to water supply system according to claim 1, wherein: and a fourth activated carbon filter and a second UV sterilizer are arranged in the cold water tank.

8. The single-room air to water supply system according to claim 1, wherein: and a hot tank is arranged in the indoor unit and is respectively connected with a cold water tank and a water outlet device through pipelines.

9. The single-room air to water supply system according to claim 1, wherein: the water outlet device comprises a three-way water outlet pump, a second water outlet valve, a water outlet pump and a third water outlet valve;

a water inlet end pipeline of the three-way water outlet pump is connected with the cold water tank, a water outlet end pipeline of the three-way water outlet pump is connected with a third UV sterilizer, a pipeline of the third UV sterilizer is connected with the cold water tank, and the other water outlet end pipeline of the three-way water outlet pump is connected with a second water outlet valve;

and a water inlet end pipeline of the water outlet pump is connected with the hot tank, and a water outlet end pipeline of the water outlet pump is connected with a third water outlet valve.

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