KR101905332B1 - Manufacturing method of wet tissue using hydrogenated water - Google Patents

Abstract

The present invention relates to a method for manufacturing a wet tissue, and more particularly, to a method for manufacturing a wet tissue using high concentration hydrogen water, which can obtain high-quality hydrogen water through an electrolysis method while completely removing components harmful to human body through sterilization and filtering in a process for separating hydrogen using raw water. Especially, it is possible to improve the adsorption force with water molecules through a concentration process to obtain the high concentration of hydrogen water, and by impregnating a tissue fabric with aeration, germicidal power and cleaning power are improved and various skin diseases and skin aging such as improvement of an antioxidant function can be prevented.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of manufacturing a wet tissue using high-

The present invention relates to a method of manufacturing a wet tissue, and more particularly, to a method and an apparatus for effectively separating and enriching hydrogen contained in raw water to impregnate a tissue fabric with concentrated hydrogen, thereby improving the sterilizing power and cleaning power, The present invention relates to a method of manufacturing a wet tissue using high-concentration hydrogen-containing water, which enables the production of the improved water-containing tissue.

Generally, wet tissue is a wet tissue which is impregnated with purified water to contain moisture by impregnating the fabric in the manufacturing process, and is mainly used for easily wiping hands or face. In recent years, as the culture and the hygiene are emphasizing the convenience, the consumption of wipes is soaring and the supply of products is not so difficult. As a result, many small and medium sized companies are emerging.

Such a wet tissue is made of a pulp or nonwoven fabric which is not easily decomposed even though it contains moisture, and a material having disinfection, antibacterial and germicidal properties is impregnated in the pulp or nonwoven fabric. The wet tissue is used to remove contamination, Is used to detoxify objects in direct contact with

However, since the size of the water particles impregnated in the fabric of a typical wet tissue is so large that the skin can not be penetrated deeply, the cleansing effect can be obtained apparently, but the problem that the foreign material can not be removed deep into the skin deeply, there was.

If the above-mentioned impurities remain on the skin, the blood circulation is not smooth due to contraction of the capillary blood vessels of the skin, and the pores are clogged, the oxygen is not supplied to the metabolism and the other nutrient sources are not received, And the accumulation of lipid peroxidation may cause premature aging.

Korean Patent Registration No. 10-1771904.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a method of separating hydrogen using raw water, It is possible to obtain a high quality of water through the concentration process. In particular, by increasing the adsorption force with the water molecule through the concentration process, it becomes possible to obtain a high concentration of water, and by impregnating the tissue with water, The present invention provides a method for producing a wet tissue using high-concentration water for the prevention of various skin diseases and aging of the skin.

As a specific means for achieving the above object, there is provided a water supply system comprising: a raw water supply step of supplying a raw water for tap water;

A first sterilization step of sterilizing the supplied raw water;

A first filtering step of firstly filtering the impurities contained in the sterilized raw water;

A second filtering step of filtering the impurities contained in the first filtered raw water while performing second water filtering;

A third filtering step of filtering the odor components contained in the secondarily filtered soft water three times;

A fourth filtering step of filtering the fine particles contained in the tertiary filtered soft water four times;

A hydrogenated water producing step of electrolyzing the fourth-order filtered water to obtain hydrogenated water;

Increasing the amount of dissolved hydrogen contained in the obtained hydrogen water to produce a high concentration of hydrogen water;

A second sterilization step of sterilizing the bacteria remaining in the high-concentration hydrogen peroxide;

A fifth filtering step of filtering the carcass or foreign matter of the fine bacteria contained in the secondary sterilized hydrogenated water in a fifth order; And

Water impregnation step of impregnating the tissue high-density water with the resultant wet tissue to obtain a wet tissue impregnated with hydrogen water.

As described above, the method of manufacturing a wet tissue using the high-concentration hydrogen-containing water according to the present invention comprises the steps of sterilizing raw water, sterilizing and filtering the harmful microorganisms in the water, removing the body and harmful components of the microorganism and separating and concentrating the hydrogen through electrolysis It is possible to produce hydrogen and impregnate the produced hydrogen water into the tissue using the aeration, and it is possible to produce a high quality water-containing tissue. In addition, the obtained water-containing tissue is improved in sterilizing power and cleaning power, It is possible to obtain an effect that can prevent various skin diseases and aging of skin such as improvement of antioxidant function.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall process diagram showing a method of manufacturing a wet tissue using high-concentration hydrogen-containing water according to the present invention. FIG.
2 is a whole flow chart showing a method of manufacturing a wet tissue using high-concentration hydrogen-containing water according to the present invention.
FIG. 3 is a schematic view of a water producing apparatus of a wet tissue manufacturing method using high-concentration hydrogen water.
FIG. 4 is a schematic view of a hydrogen-water concentrator of a method for manufacturing a wet tissue using high-concentration hydrogen-water.
Fig. 5 is a schematic view of the apparatus for impregnating a water-containing water in the method of manufacturing a wet tissue using high-concentration hydrogen water.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall process diagram showing a method for manufacturing a wet tissue using high-concentration hydrogenated water according to the present invention; FIG. 2 is an overall flowchart showing a method for manufacturing a wet tissue using high-concentration hydrogenated water according to the present invention.

As shown in FIGS. 1 and 2, the method for manufacturing a wet tissue using high-concentration hydrogen-containing water according to the present invention includes a raw water supplying step S100, a first sterilizing step S200, a first filtering step S300, The third filtering step S500, the fourth filtering step S600, the hydrophobic generation step S700, the hydrophobic concentration step S800, the second sterilization step S900, , A fifth filtering step (S1000), and a hydrophobic impregnation step (S1100).

First, in the raw water supply step S100,

And is supplied with a normal tap water used as a raw material for obtaining hydrogen water applied in the present invention.

To this end, the water supply is provided through a normal water supply pipe 110. In the water supply pipe 110, a solenoid valve 120 is first formed to automatically regulate the amount of raw water to be supplied. Next, the low pressure switch 130 And the supply pump 140 is formed to supply the sterilized water to the first sterilization step S200.

Thereafter, the first sterilization step (S200)

The bacteria contained in the raw water supplied from the raw water supply pipe 110 are first sterilized.

In this case, the UV sterilizer 210 is provided with a UV lamp 211, which irradiates ultraviolet rays while sterilizing the bacteria contained in the raw water, .

Thereafter, the first filtering step (S300)

As described above, raw sterilized raw water is supplied and primary filtering is performed.

In this case, five micro-filters 311 capable of filtering particles of 5 microns or more are formed in the first filter unit 310, and the micro-filters 311, It is possible to use a micro filter which is used in a normal purification process instead of being newly implemented.

In the first filter unit 310, the sterilized raw water is supplied and the osmotic pressure is applied to the raw water to pass through the five micro-filters 311, .

Thereafter, the second filtering step (S400)

The primary filtered raw water is supplied and the secondary filtering is performed.

In this case, a softener filter 411 is formed at the water softener 410, and the water softener applied at this time is not a new water softener but may be any one capable of removing ordinary calcium and magnesium.

In the water softener 410, the tap water usually contains hardness components (calcium, magnesium). In the course of passing through the water softener 410 using the osmotic pressure system, calcium And magnesium are removed and converted into a soft water state.

Thereafter, the third filtering step (S500)

The third-order filtering is performed by receiving the second-order filtered annual water as described above.

In this case, the third filter unit 510 includes a carbon filter 511 having a large number of voids. The carbon filter 511 applied at this time is not newly implemented, It would be possible to use it for removing odors.

Accordingly, in the third filter unit 510, osmotic pressure is applied to the soft filter unit 510, and the odorous components (residual nitrogen, chlorine, pesticide, carcinogen, Organic compound) is adsorbed and removed.

Thereafter, the fourth filtering step (S600)

The fourth-order filtering is performed by receiving the third-order filtered annual water as described above.

In this case, five micro filters 611 capable of filtering particles of 5 microns or more and a carbon filter 612 having numerous voids are connected in series to the fourth filter unit 610, .

The fourth filter unit 610 receives the soft water and applies the osmotic pressure to completely remove fine foreign substances and odors that may occur during the passage of the soft water through the five micro filters 611 and the carbon filter 612, Makes a possible state.

Then, in step S700,

As described above, the soft water filtered in the fourth order is supplied and electrolyzed to obtain hydrogenated water.

3, the decompression valve 730 is constituted. In the water softener 710, the water reducing valve 710 is connected to the pressure reducing valve 730, Thereby reducing the supply pressure.

An electrolyzer 720 for electrolyzing the soft water is formed in the hydrogen-water generator 710.

The platinum electrode 721 and the platinum electrode 722 are separated from each other in the electrolytic bath 720. The platinum electrode 721 and the platinum electrode 722 are electrically connected to each other. Energizable dielectric films 721a and 722a are formed by coating.

The platinum electrode 721 and the platinum electrode 722 are formed of a rubber material between the platinum electrode 721 and the platinum electrode 722 through the diaphragm 723, The platinum electrode 722 reacts to prevent sparks and ozone from being generated.

That is, when electricity is supplied to the platinum electrode 721 and the platinum electrode 722 in the state where the soft water is supplied to the water producing machine 710, water is oxidized by oxygen in the + And the generated oxygen gas is discharged to the outside.

And, in - pole, water gets electrons and is reduced to generate hydrogen gas, and the generated hydrogen gas dissolves in water to produce hydrogen peroxide.

On the other hand, when water is electrolyzed (H ₂ O = H + O), the hydrogen ions and oxygen molecules are separated into hydrogen ions and oxygen molecules. At the low temperature plasma state, the low temperature plasma and super- H) becomes the hydrogen cation (H +) and the oxygen molecule (O ₂ ) accepts the surrounding anion electrons and turns into the oxygen anion (O ₂ -).

The generated hydrogen cations (H +) and oxygen anions (O ₂ -) react with the surrounding water molecules (H ₂ O) to generate sterilizing anions such as hydroxyl groups (OH-) , Oxygen anion and the like are oxidized and removed by the odor molecule which is a cation.

Thereafter, the hydrophobic concentration step (S800)

The hydrogen dissolved amount contained in the hydrogen water produced as described above is increased to obtain a high concentration of hydrogenated water.

As shown in FIG. 4, the hydrogen-rich concentrator 810 is filled with a number of aeration balls 811 therein.

A high-pressure switch 820 is formed in the hydrogen-concentrator 810, and the hydrogen-containing water obtained in the above-described manner is supplied into the hydrogen-water concentrator 810 at a high pressure.

As described above, the aeration balls 811 filled in the hydrophobic concentrator 810 may be any one selected from the group consisting of illite, zeolite, tourmaline, .

That is, 100 weight% of each of illite, zeolite and tourmaline may be applied, or two species may be applied at a ratio of 1: 1, or all three species may be used at a ratio of 1: 1: 1 .

At this time, Illight is a clay mineral with a three-layer lattice unit consisting of two octagonal Si (O) tetrahedral layers joined together by octahedral layers of Al (OH) 3 between two layers, It has the ability to develop, antimicrobial and antiviral properties. It helps prevent adult diseases, strengthens kidney function, prevents arteriosclerosis, relieves fatigue, relieves pain, and helps with joint diseases.

Also, as is known, zeolite is a mineral known as silicate aluminum hydrate of alkali and alkaline earth metals, and the color is colorless transparent or white translucent. It is also called zeolite, and it has been found to be effective as antiseptic and deodorant as well as efficacy and preservative for eliminating respiratory viruses and pathogenic microorganisms. It has a high far infrared ray emissivity as an ion exchanger and releases a large amount of anion, It is used in various materials.

Tourmaline is a mineral of the hexagonal system that has crystal structure like crystal and it is also called tourmaline. It is rich in natural minerals, so it removes wastes accumulated in the skin and body, and prevents skin aging It promotes blood circulation by expanding the capillary blood vessels in the human body. It helps to activate metabolism and gastrointestinal movement and generates heat in the body, thereby helping blood circulation. Because it contains ingredients and antioxidant ingredients, it helps remove fat from the body by removing unnecessary active oxygen. It turns the water component into a weak alkaline water, which makes the water rich in minerals and removes the chlorine odor unique to tap water. have.

That is, the hydrogen water is injected into the hydrogen concentration concentrator 810 through the high-pressure switch 820 at a high pressure. In this process, the hydrogen water supplied from the high pressure switch 820 collides with a large number of the aeration balls 811, ), The aeration and water molecules are finely decomposed in the course of passing through the pores.

Hence, hydrogen is adsorbed to each of the decomposed water molecules, so that the hydrogen dissolved amount of the hydrogenated water is further increased and a high concentration of hydrogenated water in which the minerals and anions are alive can be obtained.

In addition, in the process of decomposing water molecules as described above, the anion of the aeration ball 811 and the like are added to the body.

On the other hand, in supplying hydrogen water to the hydrogen-concentrator 810 as described above, the water may be cooled to 3 to 5 ° C so that the hydrogen adsorption can be maximally adsorbed.

Thereafter, the second sterilization step (S900)

The high-concentration hydrogenated water obtained as described above is supplied and sterilized in a second step.

In this case, a UV lamp 911 is formed in the UV sterilizer 910, and ultraviolet rays are irradiated during the passage of the high-concentration hydrogen supplied and the bacteria contained in the high- Is sterilized.

That is, in the second sterilization step (S900), as described above, the bacteria that have not yet been treated in the first sterilization step (S200), the first to fourth filtering steps (S300), S400 (S500) The new bacteria that may be generated during the generation step S700 and the hydrogen concentration step S800 are sterilized. In the course of passing the high-concentration hydrogen water through the UV sterilizer 910, ultraviolet rays are irradiated and high- The microorganisms remaining in the microorganism are completely sterilized.

Thereafter, the fifth filtering step (S1000)

As described above, the secondary sterilized high-concentration hydrogenated water is supplied to perform the fifth-order filtering.

In this case, the fifth filter unit 1010 is configured with a 0.1 micro filter 1011 capable of filtering particles of 0.1 micrometers or more.

In the fifth filter unit 1010, the second sterilized high-concentration hydrogen-containing water is supplied and the osmotic pressure is applied to the fifth filter unit 1010 to filter the microorganisms forming the particles of 0.1 micrometer or more contained in the high- So that the high-concentration hydrogen water that can be consumed by humans can be obtained.

Thereafter, the hydrophobic step (S1100)

The high-concentration hydrogen-containing water obtained as described above is impregnated into the tissue material so that the wet tissue can be obtained.

To accomplish this, an immersion step (S1110), a dewatering step (S1120), and a collection step (S1130) may be performed using the water impregnation apparatus (1100).

At this time, as shown in Fig. 5, the water impregnating device 1100 is constituted of a supply roller 1110 in which a dry tissue product 10 made of ordinary pulp or nonwoven fabric is wound and wound and supplied.

The water impregnating device 1100 is provided with an immersion tank 1120 capable of impregnating the dry tissue 10 with impure high-concentration hydrogen water.

At this time, the immersion tank 1120 is configured such that high-concentration hydrogen-containing water is supplied from the fifth filter unit 1010 to the inside of the immersion tank 1120 so that the immersion tank 1120 can be charged.

The supply tray 1121 and the discharge tray 1122 are formed at both sides of the immersion tank 1120 so as to allow the introduction of the tissue material 10 to be introduced. 1120 and a guide roller 1121a is formed at a lower end thereof and the discharge tray 1122 is disposed at the other side of the inner upper side of the immersion tank 1120, And a guide roller 1122a is formed at the lower end of the guide roller 1122a.

An aeration ball unit 1123 is formed on the inner lower side of the immersion tank 1120 so that the aeration ball unit 1123 is locked to the inner bottom of the immersion tank 1120. The upper end of the aeration ball unit 1123 is connected to the supply tray 1121, And the lower end of the discharge tray 1122, as shown in FIG.

At this time, the aeration ball unit 1123 is configured such that the aeration ball 1125 is filled in the mesh body 1124. The aeration ball 1125 applied at this time is connected to the aeration ball 811 applied to the hydrogen-water concentrator 810 Zeolite, tourmaline, and the like, which are the same as those of the zeolite, zeolite, and tourmaline, and may be a mixture of two or more of the same illite, zeolite, May be applied at a ratio of 1: 1, or all three species may be applied at a ratio of 1: 1: 1.

The inside of the immersion tank 1120 is constituted by an air supply unit 1126 that supplies air from the outside to the bottom surface of the immersion tank 1120 so as to be supplied into the immersion tank 1120.

That is, in the immersion tank 1120, during the passage of the tissue material 10 in a dry state, the tissue material 10 is impregnated with hydrogenated water.

The dewatering means 1130 includes upper and lower pressing rollers 1131 made of a rubber material having a predetermined narrower width than the thickness of the tissue material 10, The excessive pressure water impregnated into the tissue material 10 is dewatered by the pressing force of the upper and lower pressing rollers 1131 and 1132.

The water-containing impregnating device 1100 is provided with a collection roller 1140 for collecting the dehydrated tissue material 10 by winding.

Thus, in the immersion step S1110,

The user pushes the tissue cloth 10 to be fed from the feeding roller 1110 into the immersion tank 1120 and enters the gap between the feeding tray 1121 and the immersion tank 1120 when the sheet is advanced, And is discharged through the upper portion of the aeration ball unit 1123 through the guide of the guide roller 1122a of the discharge tray 1122 and between the discharge tray 1122 and the immersion tank 1120.

At this time, in the immersion tank 1120, air is supplied from the air supply unit 1126 to the aeration ball unit 1123. In this process, air supplied to the aeration ball 1125 collides with the aeration ball 1125, The air bubbles and the water molecules are finely decomposed in the course of passing through the gap between the aeration balls 1123 and the air bubbles are impregnated into the tissue material 10 passing through the upper part of the aeration ball unit 1123.

That is, in the immersion step (S1110), the tissue material 10 is impregnated with hydrogen water, the water molecules are finely decomposed in the impregnation process, and hydrogen is adsorbed to each of the decomposed water molecules, While a high concentration of hydrogen in which minerals and anions are alive is impregnated into the tissue cloth 10 due to the components radiated from the aeration ball 1125. [

Thereafter, in the dewatering step S1120,

The water impregnated with the hydrogen-water impregnated tissue fabric 10 is excessively impregnated by the pressing force in the process of passing between the upper and lower pressing rollers 1131 and 1132 of the dewatering means 1130, It is possible to obtain the wet tissue 20 impregnated with the high-concentration hydrogen-added water.

Thereafter, in the collection step S1130,

The wipes 20 impregnated with the hydrogen-containing water are collected and collected through the collection roller 1140. The thus recovered wipes 20 can be cut and packed into a required size at the time of shipment and can be commercialized and shipped.

Meanwhile, as described above, the raw water supply step S100, the first sterilization step S1200, the first filtering step S300, the second filtering step S400, the third filtering step S500, 4 filtering step S600, a hydrogen-producing step S700, a hydrophobic concentration step S800, a second sterilization step S900, a fifth filtering step S1000, a hydro- A UV sterilizer 210 connected from a supply pipe 110 applied to the first filter unit 310, the water softener 410, the third filter unit 510, the fourth filter unit 610, The water filter 710, the hydrogen water concentrator 810, the UV sterilizer 910, the fifth filter unit 1010 and the water impregnation device 1100 are connected to each other by pipes, It would be natural to work.

As described above, according to the present invention, it is possible to manufacture a wet tissue impregnated with a high concentration of hydrogen, which is maximized in the amount of dissolved hydrogen, through a series of processes.

Meanwhile, in the present invention, the wet tissues obtained as described above are suitable for skin use. Table 1 shows the state of live cells and human harmfulness as shown in Table 2.

Test strain The number of viable cells remaining (CFU / ml)
Sterility (%) Before processing After processing Super bacteria 1.5 x 10 ⁴ <10 99.9 Pseudomonas 3.0 x 10 ⁴ <10 99.9 Mutans bacteria 1.7 × 10 ⁶ <10 99.9 Candida 3.2 × 10 ⁶ <10 99.9 Sang gus 2.8 × 10 ⁶ <10 99.9 Staphylococcus aureus 1.8 × 10 ⁶ <10 99.9 Escherichia coli 1.2 × 10 ⁶ <10 99.9 Salmonella 2.1 × 10 ⁶ <10 99.9 P. aeruginosa 1.9 × 10 ⁴ <10 99.9

Test Items Test result Exam contents An irritation test clear Irritation test of cornea, iris, conjunctiva Skin irritation test clear Erythema and scar formation, edema formation test

*Test result

As described above, the wet tissue 20 manufactured by the wet tissue manufacturing method using the high-concentration hydrogen-containing water according to the present invention is suitable for use as a wet tissue, because it has excellent sterilizing power and is particularly suitable for stimulating the inner and outer skin.

Thus, the wet tissue 20 manufactured as described above is capable of penetrating deeply into the skin of the hydrogen ultra-fine bubbles when cleaning the skin. It is possible to prevent disinfection of the skin without stimulation, prevent skin diseases and prevent skin aging And the like.

S100: raw water supply step S200: first sterilization step
S300: first filtering step S400: second filtering step
S500: Third filtering step S600: Fourth filtering step
S700: Hydrogen generation step S800: Hydrophobic concentration step
S900: second sterilization step S1000: fifth filtering step
S1100: Hydrophobic water impregnation step S1110: Immersion step
S1120: Dehydration step S1130: Recovery step

Claims (5)

A raw water supply step (S100) for supplying raw water to the waterworks;
A first sterilization step S200 of sterilizing the supplied raw water;
A first filtering step (S300) of firstly filtering the impurities contained in the sterilized raw water;
A second filtering step (S400) of filtering the impurities contained in the first filtered raw water while performing second water filtering treatment;
A third filtering step (S500) of filtering odor components contained in the secondarily filtered soft water three-dimensionally;
A fourth filtering step (S600) of filtering the fine particles contained in the tertiary filtered soft water four times;
A step (S700) of generating a hydrogenated water by electrolyzing the fourth-order filtered water to obtain hydrogenated water;
Concentration step (S800) of increasing the amount of hydrogen dissolved in the obtained hydrogenated water to produce a high concentration of hydrogenated water;
A second sterilization step (S900) of sterilizing the bacteria remaining in the high-concentration hydrogen peroxide;
A fifth filtering step (S1000) for filtering the carcass or foreign matter of the fine bacteria contained in the secondary sterilized hydrogenated water in a fifth order; And
And the step (S1100) of impregnating the tissue with the high-concentration hydrogen-containing water to obtain the wet tissue 20 impregnated with the hydrogen-containing water.
The method according to claim 1,
In the raw water supply step S100,
A solenoid valve 120, a low-pressure switch 130, and a pump 140 are provided in the raw water supply pipe 110 to control supply of raw water to be supplied and to regulate supply pressure, ,
In the first sterilization step S200,
It is possible to irradiate ultraviolet rays and sterilize the bacteria contained in the raw water during the passage of the raw water by using the UV sterilizer 210 having the UV lamp 211 inside,
In the first filtering step S300,
5, a first filter unit 310 having a microfilter 311 is used to filter the foreign substances and the microorganisms of 5 microns or more contained in the raw water firstly,
The second filtering step (S400)
The raw water forming the water-hardened state is secondarily filtered by using the water softener 410 having the softener filter 411 to remove the hardness components (calcium, magnesium) contained in the raw water,
The third filtering step (S500)
(Residual nitrogen, chlorine, pesticide, carcinogen, organic compound) contained in the soft water is thirdly filtered using the third filter part 510 having the carbon filter 511,
The fourth filtering step (S600)
5 filters the foreign substances and odor components not filtered in the first to third filtering processes by using the fourth filter unit 610 in which the micro filter 611 and the carbon filter 612 are continuously formed,
The number generating step (S700)
Decomposes the hydrogenated water contained in the softened water through electrolysis,
The hydrophobic concentration step (S800)
Dissolving the obtained water molecules of water and dissolving hydrogen to increase the amount of dissolved hydrogen,
In the second sterilization step S900,
The UV sterilizer 910 having the UV lamp 911 formed therein may be used to remove the bacteria remaining in the first sterilization step and the first to fourth filtering steps and the hydrophobic water generation step and the hydrogen water concentration step The germs are finally sterilized,
The fifth filtering step (S1000)
The fifth sterilized hydrogenated water is filtered using a fifth filter 1010 having a micro filter 1011 so as to filter out foreign matter of 0.1 micrometers or more which is not filtered in the first to fourth filtering steps, Wherein the wet wipe is manufactured using a high concentration of hydrogen peroxide.
The method according to claim 1,
The number generating step (S700)
Hydrogen water generator 710 is used,
Hydrogen water generator 710,
The soft water supplied in the fourth filtering step is depressurized through the pressure reducing side 730,
The soft water supplied from the decompression side 730 decomposes hydrogen and oxygen contained in the water through an electrolytic cell 720 to obtain hydrogen water,
A platinum electrode 721 and a platinum electrode 722, on which dielectric films 721a and 722a are coated, are formed in the electrolytic bath 720,
And a diaphragm 723 made of a rubber material is formed between the platinum electrode 721 and the platinum electrode 722. The method of manufacturing a wet tissue according to claim 1,
3. The method of claim 2,
The hydrophobic concentration step (S800)
Hydrogen concentrator 810 is used,
The hydrophobic concentrator 810,
A large number of aeration balls 811 are filled therein, and hydrogen water obtained by using the high-pressure switch 820 is supplied at a high pressure,
In the hydrogen concentration concentrator 810, hydrogen water, which is supplied through aeration, is minutely decomposed and hydrogen is adsorbed on the decomposed water molecules to obtain hydrogenated water having an increased amount of dissolved hydrogen,
The aeration ball 811,
A method for manufacturing a wet tissue using high-concentration hydrogen water, characterized in that any one or more of illite, zeolite, and tourmaline is mixed.
The method according to claim 1,
The hydrophobic step (S1100)
Hydrophobic impregnation device 1100 is used,
The hydrogen-water impregnation device 1100 includes:
A feeding roller 1110 for winding up and forming the tissue fabric 10 by winding;
A supply tray 1121 and a discharge tray 1122 having guide rollers 1121a and 1122a are formed at the lower ends of both sides of the inner side and spaced apart from the discharge tray 1122, an aeration ball unit 1123 filled with a plurality of aeration balls 1125 in which any one or two or more kinds of at least one of illite, zeolite and tourmaline are mixed, An immersion tank 1120 in which an air supply 1126 is formed;
A dehydrating means 1130 formed with upper and lower pressing rollers 1131 and 1132 to dehydrate the tissue material 10 in which hydrogen water is immersed; And
And a collection roller (1140) for collecting the dehydrated tissue material (10) by winding,
The tissue material 10 is supplied from the supply roller 1110 and supplied to the inside of the immersion tank 1120 and passed through the upper part of the aeration unit 1123 to immerse the hydrogen water while using the air supply unit 1126 An infiltration step (S1110) of causing air bubbles to be generated in the lower air injection unit and air aeration unit (1123) and infiltrating the generated bubbles into the tissue material (10);
A dewatering step S1120 of obtaining a wet tissue 20 impregnated with hydrogen by performing pressure dewatering while passing the tissue impregnated with hydrogen water 10 through the upper and lower pressure rollers 1131 and 1132 of the dewatering means 1130, ; And
(S1130) of winding the dehydrated water-containing tissue on the collection roller (1140) and collecting the collected water.

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