KR20140006423A - A water purifier - Google Patents

Abstract

The present invention relates to a water purifier which can generate hydrogen reduction water using the electrolysis of water. Disclosed is a structure of the water purifier which maximizes the dissolved hydrogen rate to obtain high quality hydrogen reduction water. The water purifier includes a water purification filter, a water tank, a water collection cock, an electrolysis device, and a hydrogen dissolving device. [Reference numerals] (140) Control unit

Description

A water purifier

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water purifier, and more particularly, to a water purifier provided to generate hydrogen-reduced water using electrolysis of water.

Recently, it has been reported that active oxygen in the body promotes aging as well as becoming a major factor in diseases such as hypertension, diabetes and heart disease. Therefore, efforts have been made to remove active oxygen in the body by drinking hydrogen- ought.

As a part of this movement, in the field of water purifier, there have been developed things that can be converted to hydrogen-reduced water through the filter device and supplied to consumers.

The registered patent application of Korean Patent Registration No. 0704955 filed and filed by the present applicant discloses the structure of a water purifier capable of generating hydrogen reduced water as described above.

The water purifier disclosed in the above publication comprises a filter device for filtering the raw water supplied from the outside, a water tank for storing a part of the purified water passed through the filter device, a water intake cock for taking out the water stored in the water tank to the outside, And a hydrogen supply device arranged to selectively supply only the hydrogen gas among the hydrogen gas and oxygen gas obtained by electrolysis and electrolysis of another part of the hydrogen gas into the water tank.

The hydrogen supply device includes a water tank for receiving and storing the purified water through the filter device, an electrolysis kit for receiving the purified water from the water tank for electrolysis, and a hydrogen supply pipe for supplying hydrogen generated in the electrolysis kit into the water tank And the outlet of the hydrogen pipe is immersed in the water inside the water tank so that the discharged hydrogen can be directly dissolved in the water tank water.

However, in the conventional water purifier, since the hydrogen gas obtained through the electrolysis is simply guided to the purified water in the water tank, and the purified water is converted to the hydrogen reduced water, the amount of dissolved hydrogen is increased to improve the quality of the hydrogenated water There was a limit.

An embodiment of the present invention is to provide a water purifier provided to enhance the quality of hydrogen-reduced water by increasing the amount of dissolved hydrogen of the hydrogen-reduced water produced through electrolysis.

In order to achieve this object, the water purifier according to the present embodiment includes a water filter provided to filter water supplied from the outside, a water tank for storing a part of the water passed through the water filter, An electrolytic apparatus for electrolyzing the other part of the water passed through the water filter to generate hydrogen and a hydrogen generator for dissolving hydrogen generated in the electrolyzer in water, Wherein the hydrogen dissolving apparatus comprises a circulation flow path for guiding the circulation of the water in the water tank, a hydrogen guiding flow path for guiding the hydrogen generated through the electrolysis device to the circulation flow path, And the hydrogen introduced into the circulation channel is mixed with water to form the water And a mixing pump provided on the circulating flow path so as to pump the air into the tank.

Wherein the hydrogen dissolving apparatus further comprises a UF hollow fiber membrane filter provided on a circulating flow path, and the UF hollow fiber membrane filter includes an inlet hole for guiding the water of the circulation channel into the water tank, On the circulating flow path.

The water tank may be sealed to maintain a vacuum state.

The water tank may be provided with a safety valve to release the vacuum state of the water tank.

The safety valve may be provided to release the vacuum of the water tank within a range of 1.3 to 10.0 PSI within the water tank.

The vacuum state of the water tank may be interlocked and released during the opening operation of the water intake cock.

The diameter of the circulation flow inlet hole for guiding the water of the circulation flow passage to the inside of the water tank may be smaller than the diameter of the circulation flow passage hole for guiding the water inside the water tank to the circulation flow passage.

According to an aspect of the present invention, the hydrogen gas produced through the electrolytic apparatus is pumped into the first water tank internal water while being mixed with the water inside the first water tank outside the first water tank through the pumping action of the mixing pump, It is possible to maximize the amount of dissolved hydrogen of the hydrogen-reduced water formed in the first tank by the forced pumping force of the mixed pump, thereby obtaining high-quality hydrogen-reduced water.

Also, the hydrogen-reduced water in the first tank is continuously circulated along the circulation flow path, and a UF hollow fiber membrane filter having a porous filtration membrane is provided on the circulation flow path. The UF hollow fiber membrane filter converts the hydrogen gas of the hydrogen-reduced water passing through the circulation channel into a finer bubble shape to further increase the amount of dissolved hydrogen in the hydrogen-reduced water, and continuously supplies the hydrogen- By filtering, it is possible to effectively solve the problem that the hydrogen-reduced water is contaminated before it is taken out to the outside.

1 is a perspective view showing the appearance of a water purifier according to an embodiment of the present invention.
FIG. 2 is a block diagram showing the entire internal structure of a water purifier according to an embodiment of the present invention.
3 is a perspective view explaining the structure of the electrolytic apparatus in the water purifier according to the embodiment of the present invention.
4 is a cross-sectional view showing the structure of an electrolytic apparatus in a water purifier according to an embodiment of the present invention.
5 is a configuration diagram showing a configuration of a hydrogen dissolving apparatus in a water purifier according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below are provided by way of example so that those skilled in the art can fully understand the present invention. The present invention is not limited to the embodiments described below, but may be embodied in other forms. In order to clearly explain the present invention, parts not related to the description are omitted in the drawings, and the width, length, thickness, etc. of the components may be exaggerated for convenience. Like reference numerals designate like elements throughout the specification.

1 and 2, the water purifier according to the present embodiment has an external appearance through a body 10 provided in a box shape, and supplies raw water of an external water source into the body 10, A water supply pipe 20 is connected.

Inside the main body 10, a water filter 30 for filtering raw water to remove various impurities and germs contained in raw water supplied from an external water supply source and a water filter 30 for storing a certain integer through the water filter 30 A first water tank 40 is provided. An end of the water supply pipe 20 is connected to the first water tank 40 and a part of the water passed through the water filter 30 is connected to the first water tank 40. [ . The water supply pipe 20 may be provided with a pump (not shown) for pumping the raw water toward the first water tank 40.

The water filter 30 includes first to fourth filters 31, 32, 33, and 34, and the first to fourth filters 31, 32, 33, and 34 are each a composite filter.

The first filter 31 includes a first filter and a second filter. The first filter includes a sediment filter for removing fine particles such as dust and sand rust to protect the other filters. , And the secondary filter is provided with a carbon filter that filters organic compounds such as residual chlorine contained in water or harmful chemical substances to improve water taste. The second filter 32 includes a carbon filter as a tertiary filter and a silver-carbon filter that performs antibacterial function and inhibition of germination by adding silver as a fourth-order filter to activated carbon , And a fifth-order filter provided with a Zeoceramic filter to purify water and provide an antibacterial function. The third filter 33 includes a sixth order filter provided by a zeo-ceramic filter and a seventh order filter provided by a carbon filter. The fourth filter 34 includes a harmful chemical An 8th order filter provided with a uf membrane filter having a surface pore size of 0.01 to 0.04 탆 to remove the substance and a bio filter having an antibacterial function by preventing the propagation of bacteria in the water, And a 9th-order filter provided on the filter.

Accordingly, most foreign matter and harmful components included in the raw water are mostly filtered in the course of passing through the first to fourth filters 31, 32, 33, and 34 in this way.

A water intake space 11 is formed in the front surface of the main body 10 so as to be opened toward the front side. A water intake cock 12 is installed on the rear inner wall of the water intake space 11 so that the water inside the first water tank 40 can be drawn out to the outside of the main body 10 for drinking.

An electrolytic device 60 for receiving a part of the purified water through the water filter 30 and electrolyzing it to generate hydrogen gas and oxygen gas; A hydrogen dissolving apparatus 70 for dissolving hydrogen gas in the gas and oxygen gas in the water inside the first water tank 40 to convert the water in the first water tank 40 into hydrogen reduced water is provided.

Most human fluids remain weakly alkaline at around 7.4 pH (pH), which is very important for maintaining life, while recent human body fluids are becoming increasingly important for maintaining the quality of life of fish, such as meat and fish, As acidification is pointed out as one of the important factors of modern adult diseases such as hypertension, diabetes, and heart disease, the pH (hydrogen ion concentration index) is weakly alkaline and ORP (oxidation-reduction potential) is about -100mV or less. Has been shown to help maintain good health by eliminating excess active oxygen in the body while maintaining the pH at an appropriate level.

The water purifier according to the present embodiment is provided so as to directly dissolve hydrogen gas in the purified water through the water filter 30 so that a large amount of active hydrogen and hydrogen can be dissolved in the purified water. Therefore, the hydrogen reduced water prepared through the water purifier can effectively reduce the oxidized body fluid by increasing the amount of hydrogen and reducing the ORP value to -100 mV or less, and at the same time, the pH value is weakly alkaline state of 8.5 or less It can be maintained sufficiently and becomes a state suitable for drinking.

The water purifier for electrolyzing the purified water is provided with a second water tank 50 for receiving and storing a part of the purified water through the water filter 30 separately from the first water tank 40, 2 water supplied from the water tank 50 is received and electrolyzed to generate oxygen gas and hydrogen gas.

A branch pipe 21 is provided in the middle of the water supply pipe 20 between the water filter 30 and the first water tank 40 so as to guide a part of the water passed through the water filter 30 to the second water tank 50 , And the outlet of the branch pipe (21) extends into the second water tank (50).

3 and 4, the electrolytic apparatus 60 is provided at the center side and has a strong hydrophilic property, and only hydrogen ions (not shown) pass through the electrolytic apparatus 60. The electrolytic apparatus 60 is installed at the bottom of the inside of the housing 51 partitioned by the second water tank 50, And a first outer plate 62 and a second outer plate 63 which are provided on both sides of the separation membrane 61, respectively.

A positive electrode 62a is formed on one side of the central portion of the first outer plate 62 and water of the second tank 50 is supplied to the lower portion of the separator And an oxygen outlet port 62c is formed in an upper portion of the first outer plate 62. The water outlet port 62b is formed in the upper portion of the first outer plate 62,

A negative electrode 63a is formed at the center of the second outer plate 63 and a hydrogen outlet port 63b is formed at an upper portion of the second outer plate 63. The first outer plate 62 and the separator 61 A negative electrode plate 64 connected to the positive electrode 62a and a negative electrode plate 65 connected to the negative electrode 63a are provided between the second outer plate 63 and the separator 61. [

The positive electrode plate 64 and the negative electrode plate 65 are each formed of a metal net having a network structure and facilitate electrolysis between the positive electrode plate 64 and the separator 61 and between the negative electrode plate 65 and the separator 61 The catalyst plates 66 and 67 having a network structure are provided.

Bolt tightening holes 62d and 63c are formed on the outer edges of the corners of the first outer plate 62 and the second outer plate 63. The electrolytic device 60 is provided with a separator 61, The first outer plate 62 and the second outer plate 63 are formed in a state in which the cathode plate 65 and the respective catalyst plates 66 and 67 are interposed between the first outer plate 62 and the second outer plate 63 63b are fixed by fastening the fixing bolts 68a to the corresponding bolt fastening holes 62d, 63c of the fastening bolts 63, and fastening them with the nuts 68b. Reference numeral 68c denotes a gap retaining member for maintaining a gap between the first outer plate 62 and the second outer plate 63. [

A connection pipe 52 extending from the outlet of the second water tank 50 is connected to the water inlet port 62b and a hydrogen guide pipe 62a of the hydrogen dissolving device 70 to be described later is connected to the hydrogen outlet port 63b. (80) is coupled to the oxygen outlet port (62c), and the oxygen discharge pipe (200) is coupled to the oxygen outlet port (62c).

A first flow rate control valve 53 is provided in the middle of the connection pipe 52 to supply a small amount of purified water supplied from the outlet of the second water tank 50 to the water inlet port 62b. Is extended toward the first water tank 40. The outlet of the oxygen discharge pipe 200 is formed in the front surface of the main body 10 so that the discharged oxygen is discharged into the indoor space outside the main body 10 in which the water purifier is installed 201). Considering the risk of ozone, the oxygen-releasing tube 200, unlike the present embodiment, has its outlet extended outdoors and is generated through electrolysis, because the oxygen formed through electrolysis may contain a small amount of ozone. All of the oxygen may be released to the outside.

The water in the second water tank 50 is supplied to the water inlet port 62b by a small amount along the connection pipe 52 so that the electric current is supplied to the positive electrode 62a and the negative electrode 63a, When the apparatus 60 is operated, the water wetted on the surface of the separator 61 on the side of the first outer plate 62 is electrolyzed and separated into hydrogen ions and hydroxide ions between the separator 61 and the first outer plate 62 do. Among the separated ions, the hydrogen ions pass through the separation membrane 61 and move toward the anode plate 65 to form hydrogen gas between the second outer plate 63 and the separation membrane 61, Port 63b and is supplied to the hydrogen-conducting pipe 80 of the hydrogen-dissolving device 70. The hydrogen- The hydroxide ions between the separation membrane 61 and the second outer plate 63 form oxygen gas which flows into the oxygen outlet port 62c and is discharged to the indoor space through the oxygen discharge pipe 200 Thereby increasing the oxygen content of the indoor space.

In the case of the water filter 30, cations and anions constituting minerals such as calcium ion / magnesium ion / sodium ion / chlorine ion / sulfate ion can not be filtered so that a good mineral can be delivered to the first water tank 40 The positive and negative ions forming the minerals may corrode the positive electrode plate 64 and the negative electrode plate 65 and may prevent the hydrogen ions from passing through the separator 61. In this case, 61 / cathode plate 65 / anode plate 64 at frequent intervals, and frequent replacement is required.

Therefore, the water purifier further comprises the ion exchange resin filter 210 in order to improve the durability of the separation membrane 61 / the anode plate 64 / the cathode plate 65, etc. constituting the electrolytic apparatus 60.

2, the ion exchange resin filter 210 is connected to the second water tank 50 so that the purified water passing through the water filter 30 is transferred to the second water tank 50 in the state of pure distilled water having no mineral component, The ion exchange resin used in the ion exchange resin filter 210 is a mixed ion exchange resin prepared by combining a cation exchange resin and an anion exchange resin.

Therefore, among the minerals contained in the purified water in the process of passing the purified water through the ion exchange resin filter 210, cations such as calcium ion / magnesium ion / sodium ion are captured by the cation resin of the ion exchange resin filter, Anions such as bisulfate ions and chlorine ions are trapped in the anion exchange resin of the ion exchange resin filter 210, where cation exchange resins and anion exchange resins release hydrogen ions and hydroxide ions, respectively, instead of capturing such cations and anions . The hydrogen ions and hydroxide ions thus released are combined to form a water phase. Through this process, the purified water passing through the ion exchange resin filter 210 is converted into pure distilled water.

The distilled water from which the mineral component has been removed is supplied to the second water tank 50 to form hydrogen gas and oxygen gas in the electrolyzer 60. In the electrolysis process of the distilled water, It is possible to effectively prevent the separation membrane 61 / the positive electrode plate 64 / the negative electrode plate 65 from being clogged or damaged.

In addition, when a large amount of purified water flows into the ion exchange resin filter 210 at the same time, the residual time of the internal water of the ion exchange resin filter 210 is reduced, The second ion exchange resin filter 210 is provided with a second ion exchange resin filter 210 which is capable of introducing a small amount of purified water into the ion exchange resin filter 210, Preferably, a flow control valve 220 is provided.

Meanwhile, the water purifier according to the present embodiment is provided to maximize the amount of dissolved hydrogen of the hydrogen-reduced water, thereby improving the quality of the generated hydrogen-reduced water more effectively.

The hydrogen dissolving apparatus 70 includes a circulation passage 90a for guiding the circulation of water in the water tank and a hydrogen passage 80a for guiding the hydrogen generated through the electrolysis apparatus 60 to the circulation passage 90a Provided on the circulation flow path 90a for circulating water circulating along the circulation flow path 90a and for mixing the hydrogen introduced into the circulation flow path 90a with water and pumping the water to the first water tank 40 side, And a mixing pump (100).

5, the circulation channel 90a is provided through a circulation pipe 90 connecting one side of the first tank 40 and the other side, and the hydrogen guide channel 80a is connected to the hydrogen guide channel 80, . The outlet of the hydrogen-conducting pipe 80 is connected to the circulating pipe 90 so that the hydrogen-conducting passage 80a communicates with the circulating passage 90a.

Therefore, the hydrogen generated in the electrolytic apparatus 60 is introduced into the circulating flow path 90a by the pumping force of the mixing pump 100 and mixed in the form of air droplets in the circulating water along the circulating flow path 90a, The water on the mixed circulation channel 90a is pumped and dissolved into the water inside the first tank 40 through the pumping force of the subsequent mixing pump 100. [ According to the operation of the hydrogen dissolving apparatus 70, the hydrogen gas is pumped into the interior water of the first water tank 40 while being mixed with the water inside the first water tank 40 from the outside of the first water tank 40, It is possible to effectively improve the hydrogen solubility of the hydrogen reduced water formed in the first tank 40 by using the forced pumping force of the pump 100. This process is continuously repeated in the process of circulating the water in the first water tank 40 along the circulation channel 90a.

The hydrogen dissolving apparatus 70 includes a UF hollow fiber membrane filter 110 provided on a circulation channel 90a so that the amount of dissolved hydrogen in the hydrogen reduced water can be further increased. So that the amount of dissolved hydrogen can be maintained unchanged by keeping the vacuum state.

The UF hollow fiber membrane filter 110 provided on the circulation channel 90a has a porous filtration membrane having pores of several tens to several hundred nanometers (nm) in size. Hydrogen contained in the hydrogen- The solubility increases as the solution is converted into a finer bubble form. The UF hollow fiber membrane filter 110 can increase the collision force of the hydrogen reduced water with respect to the filtration membrane by using the pumping force of the mixing pump 100 and promote the miniaturization of the hydrogen bubble through the UF hollow fiber membrane filter 110, And is preferably provided on the circulation flow path 90a between the intake hole 91 of the circulation flow path 90a for guiding water into the first water tank 40 and the mixing pump 100. [ In addition, the UF hollow fiber membrane filter 110 allows the hydrogen-reduced water stored in the first water tank 40 to be continuously filtered so that the hydrogen-reduced water is contaminated before it is taken out through the water intake cock 12 Can be effectively solved.

The first water tank 40 is formed in a closed cylindrical shape so as to suppress the diffusion action of highly reactive hydrogen gas to increase the amount of dissolved hydrogen of the hydrogen-reduced water and to effectively maintain the dissolved hydrogen ratio of the hydrogen- do. Connection holes 41 and 42 are provided on one side and the other side of the first water tank 40 so that the extension pipe 12a of the water intake cock 12 and the water supply pipe 20 are connected to each other. Sealings 41a and 42a are interposed between the inner circumference of these connection holes 41 and 42 and the outer circumference of the extension pipe 12a and the water supply pipe 20 for the sealing of the water supply pipe 20. Therefore, the first water tank 40 is sealed to maintain the vacuum state. Here, the vacuum state includes not only an actual vacuum state but also a state almost close to a vacuum state.

The first water tank 40, which is hermetically sealed to maintain the vacuum state, may explode when the pressure of the hydrogen flowing into the interior of the first water tank 40 continuously increases due to the pumping action of the mixing pump 100. In order to prevent this, the first water tank 40 is provided with a safety valve 120 to release the internal vacuum state. A first communicating tube 131 is provided at one side of the first water tank 40 so as to communicate with the outside for installing the safety valve 120. The communicating safety valve 120 normally communicates with the first communicating tube 131 And is automatically set to open when the pressure inside the first water tank 40 reaches a predetermined vacuum release pressure value to release the vacuum state of the first water tank 40. [ It is preferable that the vacuum release pressure value of the first water tank 40 is set within the range of 1.3 to 10.0 PSI. When the vacuum release pressure is less than 1.3 PSI, there is almost no vacuum effect. When the vacuum release pressure is more than 10.0 PSI, there is a problem of excessive pressure and there is no effect of increasing the amount of solution which can be obtained by increasing the pressure.

In the state where the vacuum is applied to the inside of the first water tank 40, the hydrogen reduced water in the first water tank 40 becomes difficult to be drawn out through the water intake cock 12 in a state where the water intake cock 12 is open. The vacuum state of the first water tank 40 is interlocked and released when the water intake cock 12 is opened for smooth discharge.

To this end, a second communicating pipe 132 is branched to communicate with the outside of the first communicating pipe 131, and a solenoid valve 133 of a three-way valve type is installed at the intersection of the first and second communicating pipes 131 and 132 do. The solenoid valve 133 communicates the inside of the first water tank 40 and the safety valve 120 while communicating the inside of the first water tank 40 and the second communicating pipe 132, The control unit 140 controls the operation of the solenoid valve 133 and the intake cock 133 so that the control unit 140 senses whether the intake cock 12 is opened or closed and drives the solenoid valve 133. [ 12 are connected to the control unit 140. Accordingly, when the opening operation of the water intake cock 12 is sensed, the controller 140 controls the solenoid valve (not shown) so that the first water tank 40 and the second communicating pipe 132 communicate with each other regardless of the pressure inside the first water tank 40 133 are operated to release the vacuum state of the first water tank 40 so that the hydrogen reduced water in the first water tank 40 can be smoothly drawn out to the outside through the water intake cock 12.

The diameter of the water intake hole 91 for guiding the water on the circulation channel 90a into the first water tank 40 in the circulation channel 90a in order to further increase the amount of dissolved hydrogen in the hydrogen- 40 smaller than the diameter of the water outlet hole 92 for guiding water in the circulation passage 90a.

Accordingly, in the structure of the circulation passage 90a, the flow rate of the hydrogen-reduced water increases in the course of passing through the inlet hole 91, and the solubility of hydrogen to the hydrogen-reduced water can be further increased.

The operation of the water purifier constructed as described above will be described below.

The water introduced into the water purifier from the external water source through the water supply pipe 20 is purified in the process of passing through the water filter 30 first. A part of the purified water is stored in the first water tank 40 while the other part is stored in the second water tank 50 while the distilled water is formed in the course of passing through the ion exchange resin filter 210, And is supplied to the electrolytic device 60. In the electrolytic device 60, hydrogen gas and oxygen gas are produced through distilled water.

The hydrogen gas generated in the electrolytic device 60 and the oxygen gas in the oxygen gas are discharged to the outside of the water purifier along the oxygen releasing tube 200 and the hydrogen gas flows along the hydrogen guiding flow path 80a of the hydrogen dissolving device 70 And is guided to the circulating flow path 90a.

The hydrogen gas guided to the circulating flow path 90a is mixed into the water in the first water tank 40 circulating along the circulating flow path 90a through the pumping operation of the mixing pump 100, 90a are pumped into the water inside the first water tank 40 via the UF hollow fiber membrane filter 110 and the water intake hole 91 through the pumping action of the subsequent mixing pump 100. [

In the course of passing through the UF hollow fiber membrane filter 110, the hydrogen gas in the water forms a finer hydrogen bubble, and the solubility of hydrogen is improved. In the process of passing through the reduced diameter intake hole 91 In addition to the pumping action of the mixing pump 100, the flow rate of water flowing into the first water tank 40 is further increased, and the solubility of hydrogen is increased. Therefore, when the water purifier according to the present embodiment is used, the amount of dissolved hydrogen of the generated hydrogen-reduced water is maximized, and high-quality hydrogen-reduced water can be obtained.

10: Body 12: Water intake cock
20: water supply pipe 30: water filter
40: first tank 50: second tank
60: electrolysis device 70: hydrogen dissolving device
80: hydrogen guide pipe 80a: hydrogen-
90: circulation pipe 90a: circulation channel
91: inlet hole 92: outlet hole
100: Mixing pump 110: UF hollow fiber membrane filter
120: safety valve 131: first communicating tube
132: second communicating tube 133: solenoid valve
140:

Claims (7)

A water tap provided to filter water supplied from the outside, a water tank for storing a part of the water passed through the water filter, a water intake cock for taking water stored in the water tank to the outside and drinking, 1. A water purifier comprising an electrolytic apparatus for electrolyzing another part of water to generate hydrogen and a hydrogen dissolving apparatus for dissolving hydrogen generated in the electrolytic apparatus in water,
The hydrogen dissolving apparatus includes a circulation passage provided to guide the circulation of water in the tank, a hydrogen guide passage provided to guide hydrogen generated through the electrolysis device to the circulation passage, and a circulation force of water circulating along the circulation passage. And a mixing pump provided on the circulation passage to pump hydrogen directed to the circulation passage with water and pump the water toward the tank. The method of claim 1,
The hydrogen dissolving apparatus further includes a UUF hollow fiber membrane filter provided on the circulation passage,
Wherein the UF hollow fiber membrane filter is provided on a circulating flow path between an inlet hole for guiding the water of the circulation channel into the water tank and the mixing pump. The method of claim 1,
Wherein the water tank is hermetically sealed so as to maintain a vacuum state. The method of claim 3, wherein
Wherein the water tank is provided with a safety valve for releasing the vacuum state of the water tank. 5. The method of claim 4,
Wherein the safety valve is provided to release the vacuum of the water tank within a pressure range of 1.3-10.0 PSI inside the water tank. The method of claim 3, wherein
Wherein the vacuum state of the water tank is interlocked and released when the water intake cock is opened. The method of claim 1,
Wherein the diameter of the circulation flow inlet hole for guiding the water of the circulation flow passage to the inside of the water tank is smaller than the diameter of the circulation flow passage hole for guiding the water inside the water storage tank to the circulation flow passage.

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