CN212895003U - High efficiency low pressure ozone generating device that hydrolysises - Google Patents

Abstract

The embodiment of the application discloses a high-efficiency low-pressure hydrolysis ozone generating device for improving the production rate of ozone. The embodiment of the application comprises the following steps: the system comprises a pure water barrel, a 304 heat dissipation pipeline, a liquid cooling heat dissipation device, a generator, a refrigeration device and a direct current power supply; 304 heat dissipation pipelines are arranged in the pure water barrel; the liquid cooling heat radiator is externally arranged on the pure water barrel and is communicated with the 304 heat radiating pipeline by using a pipeline; the pure water barrel is communicated with the generator by using a pipeline; the generator is electrically connected with the direct current power supply; a refrigerating device is fixed on the outer wall of the generator; 304 heat dissipation pipeline and liquid cooling heat abstractor combine to use the water cooling to the pure water bucket, and the pure water bucket is used for the generator to provide water, and when DC power supply was for the generator circular telegram, the generator was used for taking place to hydrolyze and prepare ozone, and refrigerating plant is used for cooling to the generator. The environment of the ozone in the discharging process is effectively cooled, the probability of reducing the ozone is greatly reduced, and the ozone production rate is improved to a certain extent.

Description

High efficiency low pressure ozone generating device that hydrolysises

Technical Field

The embodiment of the application relates to the field of electronic ozone preparation, in particular to a low-pressure hydrolysis ozone generating device.

Background

With the increase of the per capita income, the consumption level is also increased; the increasing consumption level leads to an increasing amount of waste being produced. The accumulation of the garbage inevitably produces odor pollution, and the odor can seriously affect the health of human beings and also cause secondary pollution.

In the prior art, the device for treating malodorous gas treats malodorous gas by using a uv photolysis technology, an ozone oxidation treatment technology and a photooxidation technology combined process, so that the malodorous gas can be quickly and effectively generated with a large amount of ozone and the ozone has strong oxidizing property, the treatment effect of the device on the malodorous gas is greatly improved, but the ozone gas can be quickly reduced into oxygen under the condition of high temperature, the device for treating malodorous gas can ensure that the temperature in the device is overhigh when continuously preparing ozone, so that more ozone gas in the generated ozone gas is reduced into oxygen, and the ozone preparation rate of the device for treating malodorous gas to a certain degree is not high.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a high efficiency low pressure ozone generating device that hydrolysises for make ozone effectively cool down at the environment of the in-process that discharges, the probability that the ozone was reduced that has significantly reduced has improved the speed of production ozone to a certain extent.

The application provides in a first aspect a high efficiency low pressure ozone generator that hydrolyses, includes: the system comprises a pure water barrel, a 304 heat dissipation pipeline, a liquid cooling heat dissipation device, a generator, a refrigeration device and a direct current power supply; the 304 heat dissipation pipeline is arranged in the pure water barrel; the liquid cooling heat dissipation device is externally arranged on the pure water barrel and is communicated with the 304 heat dissipation pipeline through a pipeline; the pure water barrel is communicated with the generator by using a pipeline; the generator is electrically connected with the direct current power supply; the outer wall of the generator is fixed with the refrigerating device; the 304 heat dissipation pipeline is used for being combined with the liquid cooling heat dissipation device to cool water in the pure water barrel, the pure water barrel is used for supplying water to the generator, when the direct current power supply supplies power to the generator, the generator is used for preparing ozone through hydrolysis, and the refrigerating device is used for cooling the generator.

Optionally, the high-efficiency low-pressure ozone generator for hydrolysis further comprises an ozone-resistant pump, wherein the ozone-resistant pump is connected with the pure water barrel through a pipeline and used for accelerating the ozone discharging speed when ozone is discharged from the pure water barrel.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises an electric discharge valve, and the electric discharge valve penetrates through an outer wall of one side of a pipeline communicating the pure water barrel and the generator.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises an ozone-resistant regulating valve, and the ozone-resistant regulating valve penetrates through the outer wall of one side of the pipeline communicated with the pure water barrel and the ozone-resistant air pump.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises a water replenishing pump, the water replenishing pump is communicated with the pure water barrel through a pipeline, and the water replenishing pump is used for replenishing water to the pure water barrel.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises a three-way joint, wherein the three-way joint is arranged at the junction of the water replenishing pump, the pure water barrel and the two pipelines communicated with the generator.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises a first ozone-resistant one-way valve and a second ozone-resistant one-way valve, wherein the first ozone-resistant one-way valve is mounted at the end of the ozone-resistant regulating valve, which is communicated with the ozone-resistant air pump; the second ozone-resistant one-way valve is arranged in the front of the junction of the water replenishing pump and the pipeline communicated with the generator and the pure water barrel and close to the pipeline of the water replenishing pump.

Optionally, the high-efficiency low-voltage hydrolysis ozone generating device further comprises an intelligent power supply device, and the intelligent power supply device is used for electrically connecting the generator with the direct-current power supply device.

Optionally, the 304 heat dissipation pipe is a folded-back bent pipe.

Optionally, the high-efficiency low-pressure ozone generator that hydrolysises still includes external pure water bucket, external pure water bucket with the moisturizing pump passes through the pipeline intercommunication.

According to the technical scheme, the embodiment of the application has the following beneficial effects:

the high-efficiency low-pressure hydrolysis ozone generating device is provided with a pure water barrel, a 304 heat dissipation pipeline, a liquid cooling heat dissipation device, a generator, a refrigerating device and a direct-current power supply; the 304 heat dissipation pipeline and the liquid cooling heat dissipation device are combined for cooling water in the pure water barrel, the pure water barrel is used for supplying water to the generator, when the generator is electrified by the direct-current power supply, the generator is used for generating hydrolysis to prepare ozone, and the refrigerating device is used for cooling the generator; when the generating liquid enters the generator, the temperature is relatively low, the generator is effectively cooled under the lasting work, so that the environment of ozone in the discharging process is effectively cooled, the ozone is reduced greatly, and the ozone production rate is improved to a certain extent.

Drawings

Figure 1 is a schematic structural diagram of a high-efficiency low-pressure hydrolysis ozone generating device.

Detailed Description

In the present application, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used only for explaining relative positional relationships between the respective members or components, and do not particularly limit specific mounting orientations of the respective members or components.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meaning of these terms in this application will be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In addition, the structures, the proportions, the sizes, and the like, which are illustrated in the accompanying drawings and described in the present application, are intended to be considered illustrative and not restrictive, and therefore, not limiting, since those skilled in the art will understand and read the present application, it is understood that any modifications of the structures, changes in the proportions, or adjustments in the sizes, which are not necessarily essential to the practice of the present application, are intended to be within the scope of the present disclosure without affecting the efficacy and attainment of the same.

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Referring to fig. 1, a first aspect of the present application provides a high efficiency low pressure hydrolysis ozone generator, comprising:

pure water barrels 101, 304 heat dissipation pipelines 102, liquid cooling heat dissipation devices 103, generators 104, refrigeration devices 105 and direct current power supplies 106; the pure water barrel 101 is internally provided with 304 heat dissipation pipelines 102; the liquid cooling heat radiator 103 is externally arranged on the pure water barrel 101 and communicated with the 304 heat radiation pipeline 102 by using a pipeline; the pure water barrel 101 is communicated with the generator 104 by a pipeline; the generator 104 is electrically connected to a dc power source 106; a refrigerating device 105 is fixed on the outer wall of the generator 104; 304 the heat dissipation pipe 102 and the liquid cooling heat dissipation device 103 are combined to cool the water in the pure water tank 101, the pure water tank 101 is used to provide water to the generator 104, when the generator 104 is powered by the dc power supply 106, the generator 104 is used to generate hydrolysis to prepare ozone, and the refrigeration device 105 is used to cool the generator 104.

In practical application, the pure water tank 101 stores the generation liquid, because the pure water tank 101 is communicated with the generator 104 by using a pipeline, the generation liquid in the pure water tank 101 is drained to the generator 104 by the pipeline, and when the direct current power supply 106 is electrically connected with the generator 104 and is powered on, the direct current power supply 106 supplies electric energy to the generator 104; at this time, the generating solution in the generator is electrolyzed to form ozone and hydrogen, heat is continuously emitted in the process of electrolyzing the generating solution, and the temperature of the generator 104 is increased; as the generator 104 continuously operates under the power supplied by the dc power supply 106, the temperature of the generator 104 continuously increases, and the ozone gas is rapidly reduced to oxygen at a certain high temperature, in order to reduce the probability of reducing the ozone gas to oxygen, in this embodiment, the cooling device 105 is used to cool the generator 104, so that the heat generated during the continuous operation of the generator 104 is greatly absorbed, and the probability of reducing the produced ozone gas to oxygen is reduced.

A 304 heat dissipation pipeline 102 is arranged in the pure water barrel 101, and a liquid cooling heat dissipation device 103 is externally arranged on the pure water barrel 101 and is communicated with the 304 heat dissipation pipeline 102 through a pipeline; the temperature of the generation liquid in the pure water tank 101 is kept within a certain temperature range, and the generation liquid guided to the generator 104 is prevented from being heated before the generator 104 is operated. 304 heat dissipation pipeline 102 absorbs the heat of the generated liquid in pure water bucket 101 through cooling medium, then brings the cooling medium absorbed heat into liquid cooling heat dissipation device 103 through pipeline, liquid cooling heat dissipation device 103 releases heat to the cooling medium and guides the cooling medium after releasing heat to 304 heat dissipation pipeline 102 through pipeline, so as to achieve sequential refrigeration of the generated liquid in pure water bucket 101, make the temperature of the generated liquid entering generator 104 relatively lower, and reduce the probability that the ozone generated by generator 104 is reduced in high temperature environment.

In the present application, the refrigeration device 105 may be a semiconductor refrigeration device, a liquid nitrogen refrigeration device, or the like, and is not particularly limited herein.

In the present application, the cooling medium in the 304 heat dissipation pipe 102 may be water, air, or the like, and is not limited herein.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises an ozone-resistant gas pump 107 and an ozone-resistant regulating valve 109, wherein the ozone-resistant gas pump 107 is connected with the pure water barrel 101 by using a pipeline and is used for accelerating the ozone discharging speed when ozone is discharged from the pure water barrel 101; the ozone-resistant regulating valve 109 penetrates through the outer wall of one side of the pipeline communicating the pure water tank 101 and the ozone-resistant gas pump 107.

In practical application, when the generated liquid in the pure water tank 101 is guided to the generator 104, the generator 104 is connected with the direct current power supply 106, then the generated liquid in the generator 104 is electrolyzed to prepare ozone, the ozone electrolyzed by the generator enters the pure water tank 101 through the ozone outlet 1041 of the generator, then the ozone is guided to the pipeline through the ozone port 1011 of the pure water tank above the top of the pure water tank 101 by using the pipeline, the ozone is pumped from the pure water tank 101 to the outside by using the pressure factor for use, the ozone resistant pump 107 adjusts the internal and external pressure of the ozone resistant pump 107 by using the ozone resistant adjusting valve 109, and a very small amount of air is guided to the pipeline through which the ozone pump 107 is communicated with the pure water tank 101 by using the pressure factor, so that the flowability of the air is utilized, the ozone for preparing ozone leaves the pure water tank 101 to the outside is accelerated.

Optionally, the high-efficiency low-pressure hydrolysis ozone generator further comprises an electric discharge valve 108, and the electric discharge valve 108 penetrates through an outer wall of one side of a pipeline communicating the pure water tank 101 with the generator 104.

In practical application, the generation liquid (water) in the pure water tank 101 enters the generator 105, the generator 104 is connected with the direct current power supply 106 and then carries out corresponding electrolytic reaction for preparing ozone, the electrolytic reaction is generated in the generator 104 to generate ozone, hydrogen and other small amount of gas, the ozone electrolyzed by the generator 104 is discharged through a pipeline communicated with the pure water tank 101 to the ozone-resistant air pump 107, and then the ozone-resistant air pump 107 is used for discharging the produced ozone to the outside by utilizing the pressure factor. The electric discharge valve 108 penetrates one side outer wall of the pipe communicating the deionized water tank 101 with the generator 104 for discharge of the generated liquid in the deionized water tank 101 and replenishment of the generated liquid in the generator 104. Because ozone has certain water solubility, a small amount of ozone gas is also blended into the generation liquid in the pure water barrel 101 in the ozone discharging process, and the larger the pure water barrel 101 is, the stronger the water storage capacity is, when the water storage capacity of the pure water barrel 101 can provide the generation liquid for the generator 104 for a long time, the generator 104 continuously works to prepare ozone. In the continuous discharge process of ozone, the generation liquid of the pure water tank 101 can continuously dissolve ozone, so that the concentration of the dissolved ozone in the generation liquid is higher and higher, and the generation liquid goes bad, and therefore, the generation liquid in the pure water tank 101 is discharged by using the automatic discharge valve 108 within a certain period of time. Since the deionized water tank 101 is connected to the generator 104, the generated liquid in the deionized water tank 101 will be continuously drained to the generator 104, and when the generated liquid in the generator 104 reaches the maximum capacity of the generator 104, the deionized water tank 101 will continue to supply the generated liquid to the generator 104, which will cause the generated liquid in the generator 104 to overflow, so in this embodiment, the automatic drain valve 108 is also used to limit the supply of the generated liquid from the deionized water tank 101 to the generator 104 when the generated liquid in the generator 104 reaches a certain liquid level height, so as to control the amount of the generated liquid (water amount) in the generator 104.

In the present embodiment, the electric discharge valve 108 may be discharged once every five days, or may be discharged once every three days, which is not limited herein.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises a water replenishing pump 110 and an external pure water barrel 115, the water replenishing pump 110 is communicated with the pure water barrel 101 by using a pipeline, and the water replenishing pump 110 is used for replenishing water to the pure water barrel 101; the external pure water barrel 115 is communicated with the water replenishing pump 110 through a pipeline.

In practical applications, the generation liquid needs to be filled into the deionized water tank 101 before the deionized water tank 101 supplies the generation liquid to the generator 104, and in this embodiment, the generation liquid is automatically pumped and drained into the deionized water tank 101 by the water replenishing pump 110, so that the generation liquid in the deionized water tank 101 is sufficient.

In this embodiment, the external pure water bucket 115 and the water replenishing pump are communicated through a pipeline, and the external pure water bucket 115 is used for containing the liquid that takes place that provides to the pure water bucket 101, and when the prevention was when water supply pipe stopped supplying water, can directly receive the influence that water supply pipe stopped supplying water in the pure water bucket 101 for the shortage takes place in the pure water bucket 101.

When the water replenishing pump 110 is used, the teeth of the gears in the water replenishing pump 110 are separated from each other to form low pressure, the generated liquid in the external pure water barrel 115 is sucked into the water replenishing pump from the water inlet 1101 and is pushed to the gear end close to the water outlet 1102 on the other side from the gear end close to the water inlet 1101 of the shell wall, the gears close to the water outlet 1102 are folded to form high pressure, and the generated liquid is pushed into the pure water barrel 101 from the water outlet 1102 to be replenished to the pure water barrel 101.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises a three-way joint 111, and the three-way joint 111 is arranged at a junction of two pipelines through which the water replenishing pump 110, the pure water barrel 101 and the generator 104 are connected.

In practical application, the pure water tank 101 supplies the generator 104 with the generation liquid, the generator 104 electrolyzes the generation liquid to prepare ozone, ozone and hydrogen gas are generated in the process of preparing ozone, the ozone gas has strong reducibility, the generator 104 penetrates through the pure water tank 101 in the process of discharging ozone, and the discharge of ozone through the pure water tank 101 can not only be discharged to the outside from the ozone port 1011 of the pure water tank, but also enter the water/hydrogen port 1012 of the pure water tank; the three-way joint 111 leads the hydrogen generated in the process of preparing ozone in the generator 104 to the pure water barrel 101, when the ozone in the discharge process enters the pure water barrel water/hydrogen port 1012, the hydrogen led from the generator hydrogen port 1042 of the generator 104 by the three-way joint 111 returns the ozone which enters the pipeline of the pure water barrel water/hydrogen port 1012 to the pure water barrel 101, and the pipeline of the pure water barrel water/hydrogen port 1012 communicated with the generator 104 is corroded by the ozone by using the stability of the hydrogen gas.

Optionally, the high-efficiency low-pressure hydrolysis ozone generating device further comprises at least two ozone-resistant one-way valves, and the first ozone-resistant one-way valve 112 is installed at the end of the opposite end where the ozone-resistant regulating valve 109 is communicated with the ozone-resistant air pump 107; the second ozone-resistant check valve 113 is installed in a pipe near the water replenishing pump 110 before the intersection of the water replenishing pump 110 with the generator 104 and the pure water tank 101.

In practical application, when the generator 104 is operated to produce ozone gas, the ozone-resistant gas pump 107 is used in combination with the ozone-resistant regulating valve 109 to rapidly discharge ozone from the pure water tank 101 to the outside, and the first ozone-resistant one-way valve 112 is used to prevent ozone which has been discharged to the outside from entering the pipeline of the pure water tank 101 communicated with the ozone-resistant gas pump 107 from the pipeline of the ozone-resistant regulating valve 109, so as to reduce the ineffective work of the ozone-resistant gas pump 107. The second ozone-resistant check valve 113 is installed in a pipeline close to the water replenishing pump 110 before the intersection of the water replenishing pump 110, the generator 104 and the pure water barrel 110, when a small amount of ozone enters the water replenishing pipeline for replenishing water to the pure water barrel 101 from the pipeline where the generator 104 prepares ozone and the generator hydrogen port 1042 are communicated with the water replenishing pump 110, the second ozone-resistant check valve 113 is used for preventing the ozone from entering the water replenishing pump 110 from the pipeline where the generator hydrogen port 1042 is communicated with the water replenishing pump 110, so that a small amount of ozone in the water replenishing pipeline for replenishing water to the pure water barrel 101 enters the water replenishing pipeline to corrode the water replenishing pipeline.

Optionally, the high-efficiency low-voltage hydrolysis ozone generating device further includes an intelligent power supply device 114, the intelligent power supply device 114 is electrically connected to the generator 104 and the dc power supply 106, and the dc power supply 114 is configured to control a magnitude of current input from the dc power supply to the generator.

In practical application, after the pure water tank 101 supplies the generator 104 with the generating liquid, the generator 104 is connected to the dc power supply 106, the generator 104 continuously works to electrolyze the generating liquid to prepare ozone, and the intelligent power supply device 114 changes the power supply mode of the dc power supply 106 to supply electric energy to the generator 104. The intelligent power supply device 114 can control the time of the direct current power box supplying power to the generator 104, and can also use a small-sized voltage transformation device to change the current directly supplied by the direct current power supply 106 to the generator 104, control the current of the generator 104 during operation, and reduce the damage of the generator 104 during operation. Generator 104 belongs to more accurate component in high efficiency low pressure ozone generating device that hydrolysises, is supplied power when the during operation, is cut off the power supply when not working, at frequent outage and the in-process of supplying power, causes generator 104's life to shorten easily, uses intelligent power supply unit 114 to set up the time of pre-starting current, and the current size of normal work prolongs generator 104's life.

Optionally, 304 the heat dissipating tubing 102 is a folded back bent tubing.

In practical applications, the heat radiation pipe 304 102 is a folded-back curved pipe, and when the heat radiation pipe 304 102 is a folded-back curved pipe, the contact area of the heat radiation pipe 304 102 with the pure water tank 101 is larger than that when the heat radiation pipe 304 is a straight pipe, so that the heat of the generated liquid in the pure water tank 101 can be absorbed, and the generated liquid in the pure water tank 101 can be cooled more effectively.

It is intended that the foregoing description of the disclosed embodiments enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A high efficiency low pressure ozone generator that hydrolyses, its characterized in that includes: the system comprises a pure water barrel, a 304 heat dissipation pipeline, a liquid cooling heat dissipation device, a generator, a refrigeration device and a direct current power supply; the 304 heat dissipation pipeline is arranged in the pure water barrel; the liquid cooling heat dissipation device is externally arranged on the pure water barrel and is communicated with the 304 heat dissipation pipeline through a pipeline; the pure water barrel is communicated with the generator by using a pipeline; the generator is electrically connected with the direct current power supply; the refrigerating device is fixed on the outer wall of the generator; the 304 heat dissipation pipeline is used for cooling the water in the pure water barrel in combination with the liquid cooling heat dissipation device, the pure water barrel is used for supplying water to the generator, when the direct current power supply supplies power to the generator, the generator is used for preparing ozone through hydrolysis, and the refrigerating device is used for cooling the generator.

2. The apparatus as claimed in claim 1, further comprising an ozone-resistant pump connected to the purified water tank by a pipe for increasing ozone discharging speed when ozone is discharged from the purified water tank.

3. The high efficiency low pressure hydrolysis ozone generator as claimed in claim 1, further comprising an electrically operated discharge valve penetrating an outer wall of one side of the pure water tank pipe communicating with the generator, the electrically operated discharge valve being adapted to discharge the water in the pure water tank.

4. The high efficiency low pressure hydrolysis ozone generator as claimed in claim 2, further comprising an ozone-resistant adjusting valve penetrating through an outer wall of one side of the pipeline communicating the pure water tank and the ozone-resistant pump, wherein the ozone-resistant adjusting valve is used for adjusting the flow rate of ozone in the pipeline.

5. The ozone generator for hydrolysis according to claim 2, further comprising a water replenishing pump connected to the purified water tank via a pipeline, wherein the water replenishing pump is used to replenish water to the purified water tank.

6. The high efficiency low pressure hydrolysis ozone generator as claimed in claim 5, further comprising a tee joint, wherein the tee joint is disposed at the junction of two pipes through which the water replenishing pump, the pure water tank and the generator communicate.

7. The high efficiency low pressure hydrolysis ozone generator as claimed in claim 5, further comprising a first ozone-resistant check valve and a second ozone-resistant check valve, wherein the first ozone-resistant check valve is installed at the end of the ozone-resistant regulating valve opposite to the ozone-resistant pump; the second ozone-resistant one-way valve is arranged at the intersection of the pipelines respectively connected with the water replenishing pump, the generator and the pure water barrel.

8. The high efficiency low pressure hydrolysis ozone generator as claimed in any one of claims 1 to 4, further comprising an intelligent power supply device, wherein the intelligent power supply device is electrically connected to the generator and the DC power supply respectively; the intelligent power supply device is used for controlling the current input to the generator by the direct current power supply.

9. The high efficiency low pressure hydrolysis ozone generator as claimed in any one of claims 1 to 4, wherein the 304 heat dissipation conduits are folded back and bent conduits.

10. The high efficiency low pressure hydrolysis ozone generator as claimed in claim 5, further comprising an external pure water tank, wherein the external pure water tank is communicated with the water replenishing pump through a pipeline; the external pure water barrel is used for storing water and supplying water to the pure water barrel through the water replenishing pump.

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