KR101801777B1 - Portable bottle capable of generating hydrogen-rich water - Google Patents

Abstract

The present invention relates to a portable bottle enabling production of hydrogen water, which comprises: a main body part having a hole along a longitudinal direction to make both sides opened, and storing drinking water therein; a hydrogen generation part detachably coupled to one side of the main body part, directly coming into contact with water stored in the main body part, and including an electrolytic module for electrolyzing water to produce oxygen and hydrogen from water; and a cover part detachably coupled to the other side of the main body part and blocking the main body part to prevent water stored in the main body part from pouring.

Description

[0001] The present invention relates to a portable bottle capable of generating hydrogen-rich water,

The present invention relates to a portable bottle capable of generating hydrogen water, and more particularly, to a portable bottle capable of easily generating hydrogen and generating hydrogen water to produce hydrogen water.

In general, hydrogen peroxide is known as water that reduces harmful active oxygen to water by the strong reducing action of active hydrogen dissolved in water and increases the immunity, natural healing power and vitality of the human body.

The production of hydrogen peroxide is mainly carried out by electrolysis. When a cathode (-) and an anode (+) are placed on both sides of the diaphragm through which ions pass and a power supply is applied, positive ions are collected, Hydrogen is produced, and anion is trapped in the anode (+) to generate oxygen, which is discharged to the outside.

In recent years, a technique has been developed to incorporate the above-described electrolytic apparatus into a portable bottle so that water can be produced and consumed while carrying water. However, the portable bottle to which the electrolytic apparatus is attached has a difficulty in completely preventing leakage between the bottle and the electrolytic apparatus even if a sealing member is provided.

Thus, a water storage tank capable of storing water in the place where the electrolytic device is provided stores water caused by the leakage, and periodically empties the water storage tank. However, if the water storage tank is used, it is possible to store the leaked water, but as the water is stored, the weight of the bottle becomes heavy, and since the user must regularly discharge the water stored in the water storage tank, . Particularly, there is a problem that it is impossible to downsize and lighten the portable bottle due to the necessity of providing a water storage tank.

In addition, the hydrogen generated by the electrolysis dissolves in the water stored in the bottle. When the hydrogen gas is continuously dissolved while the bottle is shielded, the pressure inside the bottle is inevitably increased. When the pressure inside the bottle rises as described above, the air-tightness between the bottle and the electrolytic device deteriorates and leakage may occur.

And the increase in the pressure inside the bottle causes difficulties for the user not to easily separate when opening the bottle lid to drink water. In order to solve this problem, the bottle lid has been provided with a check valve to increase the internal pressure of the bottle. However, when the leak check valve is used to leak hydrogen gas or the check valve There is a tendency that a problem of hygiene is generated due to corruption, and in recent years, there is a tendency not to include a check valve.

Korean Patent Publication No. 10-2017-045582

An object of the present invention is to provide a portable bottle which can be easily carried and which can generate hydrogen to produce hydrogen water that can be consumed by producing hydrogen water.

The present invention relates to a water treatment device comprising: a body portion having a hollow formed along a longitudinal direction thereof and opened at both sides thereof and capable of storing water for drinking; And an electrolysis module detachably coupled to one side of the main body to directly contact water stored in the main body and to electrolyze the water to generate hydrogen and oxygen from the water; And a cover portion that is detachably coupled to the other side of the body portion and shields the body portion so that the water stored in the body portion is not poured, wherein the electrolysis module includes: a first electrode having one surface in contact with the water; A second electrode spaced apart from the first electrode to electrolyze the water together with the first electrode; A first cation transport membrane having a first surface disposed in close contact with the other surface of the first electrode; And has a lower porosity than the first cation transfer membrane and has a surface area larger than that of the first cation transfer membrane so that one surface of the first cation transfer membrane closely contacts the other surface of the first cation transfer membrane while the other surface is closely attached to the second electrode, 1 cation transport membrane to enhance the adhesion of the second electrode to the first electrode so as to improve the electrolytic capacity between the first electrode and the second electrode, The adhesion of the second electrode to the first electrode is enhanced by the second cation transfer membrane, and when the electrolysis module electrolyzes the water, hydrogen is generated in the first electrode, And oxygen is generated in the second electrode, thereby generating hydrogen water in which the oxygen is discharged to the outside It provides a portable bottle.

The portable bottle capable of generating hydrogen water according to the present invention has the following effects.

The first cation transfer membrane and the second cation transfer membrane further include a first cation transfer membrane and a second cation transfer membrane interposed between the first electrode and the second electrode to block the passage of water particles outside the first cation transfer membrane through which water particles pass, The airtightness of the electrolytic module can be maintained a large number of times, and leakage of water can be completely blocked.

Second, since the second cationic transfer membrane is coated with a polymer solid electrolyte on its surface, the adhesion of the first cationic transfer membrane to the first cationic transfer membrane is improved, thereby improving the adhesion between the first and second electrodes. Thus, It is possible to prevent deterioration of capability.

1 is a perspective view showing a portable bottle capable of generating hydrogen water according to an embodiment of the present invention.
2 is an exploded perspective view showing the portable bottle according to FIG.
3 is an exploded perspective view of the hydrogen generator of the portable bottle according to FIG.
Fig. 4 is a partial cross-sectional view of the hydrogen generator of the portable bottle according to Fig. 1;
5 is an enlarged view of a portion "A" shown in Fig.
Fig. 6 is a sectional view of the portable bottle shown in Fig. 1, illustrating the operation of the cover portion.
7 is a cross-sectional view of a cover portion according to another embodiment of the present invention.

1 to 6 show a portable bottle (hereinafter referred to as a portable bottle) capable of generating hydrogenated water.

A portable bottle 1000 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6. FIG. The portable bottle 1000 includes a body 100, a hydrogen generator 200, and a cover 300.

The main body 100 is opened at its both sides through the inside 110 along the longitudinal direction, and water that can be consumed by the user is stored in the inside 110. The hydrogen generator 200 is detachably coupled to one side 130 of the main body 100 and the other side 150 of the main body 100 is connected to the cover 300 Is detachably coupled.

Threads are formed on the outer circumferential surfaces of both sides 130 and 150 of the main body 100 by a predetermined length so that the hydrogen generating part 200 and the cover part 300 are screwed together. However, this is a coupling method limited to the present embodiment and can be combined in various other ways.

The hydrogen generator 200 is detachably coupled to one side 130 of the main body 100, as described above. The hydrogen generator 200 directly contacts the water stored in the main body 100, electrolyzes the water to generate hydrogen and oxygen, discharges the generated oxygen to the outside, and the hydrogen dissolves in the water do.

The hydrogen generator 200 is shown in more detail in FIGS.

First, the hydrogen generator 200 includes an electrolysis module 210. The electrolysis module 210 includes a first sealing member 211, a first electrode 212, a first cation transfer membrane 213, a membrane sealing member 214, a second cation transfer membrane 215, An electrode 216 and a second sealing member 217.

The membrane sealing member 214 and the second cation-transfer membrane 215 may leak water between the first electrode 212 and the second electrode 216 prior to the specific description of the hydrogen- But also improves the adhesion between the first electrode 212 and the second electrode 216.

The first sealing member 211 and the second sealing member 217 may prevent the first and second electrodes 2120 and 216 from leaking from the inside and the outside thereof, The adhesion of the second electrode 216 is improved.

The first sealing member 211, the membrane sealing member 214, the second cation transmitting membrane 215 and the second sealing member 214 may be formed on the first electrode 211 And the second electrode 216. In this case,

Particularly, when the adhesion between the first electrode 212 and the second electrode 216 is improved by the above-described configurations, the current transfer between the electrodes is actively activated, thereby improving the electrolysis performance of the water, So that the hydrogen concentration in the water can be further increased.

The first electrode 212 is inserted into the first sealing member 211, and one side of the first electrode 212 is in contact with the water. The first sealing member 211 is formed in the shape of a ring having a center through which the first electrode 212 is inserted so that the first electrode 212 is inserted into the groove. Since the center of the first sealing member 211 penetrates the first sealing member 211, the first electrode 212 can be directly in contact with the water stored in the main body 110 even when the first sealing member 211 is inserted into the first sealing member 211 .

The first electrode 212 is in contact with the water to electrolyze the water. Since the hydrogen produced by electrolysis through the electrolysis module 210 must be dissolved in the water, the first electrode 212 contacting the water is provided as a negative (-) electrode.

The first cation transfer membrane 213 is provided on one surface of the first electrode 212 in close contact with the other surface of the first electrode 212. Although not shown in detail in the drawings, the first cation transport membrane 213 may be formed in a mesh form or may be formed with voids. The water particles may pass through the first cation transfer membrane 213.

However, one surface of the first cation-transfer membrane 213 that is in contact with the water is coated with a non-stick material. The non-stick material may be illustratively a resin such as Teflon or an inorganic material or organic chemical having a low coefficient of friction.

One surface of the first cation transfer membrane 213 is coated so that contaminants in the water, such as minerals or solid bodies, are trapped in the mesh formed in the first cation transfer membrane 213 Or can be prevented from being adsorbed and contaminated. In addition, even if contaminated by the pollutants, it is easy to separate from the mesh, and chemical and abrasion resistance are improved. When the user is washed with diluted water, which is harmless to the human body and easy to wash, Thereby preventing damage to the surface of the cation transport membrane 213.

The non-stick material is necessarily coated on only one side of the first cation-transfer membrane 213 that is in contact with the water. If the non-stick material is coated on both sides of the first cation-transfer membrane 213 or when the non-steel material-coated surface is contacted with the water, the performance of the first cation-transport membrane 213 So that the hydrogen generation function may be deteriorated.

The membrane sealing member 214 surrounds the first cation transport membrane 213. The membrane sealing member 214 is formed in the shape of a ring through which the center is penetrated. The first cation transfer membrane 213 may be expanded upon contact with water to reflect this characteristic of the first cation transfer membrane 213 such that the membrane sealing member 214 is connected to the first cation transfer membrane 213 ).

Since the size of the surface area of the first cation transfer membrane 213 is smaller than the surface area of the first electrode 212, the first cation transfer membrane 213 may be surrounded by the first cation transfer membrane 213, The membrane sealing member 214 is in close contact with the other surface of the first sealing member 211 and the other surface of the first cation-transfer membrane 213. Therefore, leakage of water between the first sealing member 211 and the first electrode 212 can be blocked by the membrane sealing member 214.

The second cation transfer membrane 215 is provided on one surface of the first cation transfer membrane 213 and on the other surface of the membrane sealing member 214 at the same time so that the first cation transfer membrane 213, Thereby blocking the leakage between the membrane sealing members 214.

The second cation transfer membrane 215 may be formed in the form of a mesh or formed with voids as in the case of the first cation transfer membrane 212. However, the second cation transfer membrane (215) has a lower porosity than the first cation transfer membrane (215).

The second cation transfer membrane 215 has a larger surface area than that of the first cation transfer membrane 213. Therefore, even if leakage occurs between the first cation transfer membrane 213 and the membrane sealing member 214, the water particles can not pass through the second cation transfer membrane 215.

One surface of the second cation transfer membrane 215 that is in close contact with the other surface of the first cation transfer membrane 213 is coated to improve adhesion with the first cation transfer membrane 213. For example, one side of the second cation transfer membrane 215 is coated with a polymeric solid electrolyte (SPE) to enhance adhesion with the other side of the first cation transfer membrane 213.

The second electrode 216 is inserted into the second sealing member 217 so that one surface of the second electrode 216 is in close contact with the other surface of the second cation transfer membrane 215, And the water is electrolyzed together with the one electrode 212. When the water is electrolyzed by the electrolysis module 210, the oxygen is generated through the second electrode 216, so that the second electrode 216 is applied as a positive electrode.

As the adhesion between the second cation transfer membrane 215 and the first cation transfer membrane 213 is improved as described above, the first electrode 212, the first cation transfer membrane 213, the second cation transfer membrane 213, The contact state between the cation transfer membrane 215 and the second electrode 216 is improved. Therefore, even if the first cation transfer membrane 213 and the second cation transfer membrane 215 are provided at the same time, the electrolytic performance is not deteriorated.

The water stored in the main body 100 may be prevented from leaking through the membrane sealing member 214 surrounding the periphery of the first cation transfer membrane 213 and the second cation transfer membrane 215, Is prevented from leaking to the side of the hydrogen generator 200, a storage tank for storing the leaked water is not required.

Omission of the storage tank for storing the leaking water is advantageous in that the size of the hydrogen generating unit 200 can be reduced at all times and the size of the entire portable bottle 1000 can be miniaturized.

The hydrogen generator 200 may include a holder 220, a fixing bracket 230, a controller 240, an external charging module (not shown), and a power supply module 250 in addition to the electrolysis module 210 described above. .

The holder 220 has a hollow shape along the longitudinal direction, and the electrolysis module 200 is inserted into the holder 220. The holder 220 is detachably coupled to one side 130 of the main body 100 by a screw fastening method. However, this is a coupling method limited to the present embodiment and can be combined in various other ways. Therefore, on the inner circumferential surface of one side of the holder 220, a thread (not shown) formed on the outer circumferential surface of one side 130 of the main body 100 and a screw (untrained thread)

When the holder 220 is coupled to the main body 100, a first packing member 260 may be provided between the holder 220 and the main body 100. The first packing member 260 prevents the water of the portable bottle 1000 from leaking through the space between the main body 100 and the holder 220.

In the holder 220, a groove (not shown) into which the electrolysis module 200 can be inserted is formed. The other surface of the first sealing member 211 of the electrolysis module 200 and the outer surface of the second sealing member 216 are inserted into the groove and the inner surface of the groove.

The fixing bracket 230 is detachably coupled to the holder 220 and one surface of the fixing bracket 230 is closely contacted with the electrolysis module 210 to fix the electrolysis module 210 so as not to be separated from the holder 220 .

More specifically, as shown in FIG. 4, the fixing bracket 230 is inserted into the holder 220 and is fitted to the inner shape of the holder 220. The inner surface of the fixing bracket 230 is in close contact with the other surface of the second sealing member 216 to fix the electrolytic module 200.

A second packing member 270 may be provided between the fixing bracket 230 and the holder 220 when the fixing bracket 230 is assembled with the holder 220. [ The second packing member 270 is provided between the fixing bracket 230 and the holder 220 so that the water leaking between the holder 220 and the electrolysis module 210 is discharged to the holder 220, And the fixing bracket 230 can be prevented from leaking.

The controller 240 is disposed inside the holder 220 at the same time as the outside of the fixing bracket 230 and is electrically connected to the electrolysis module 210 to control the operation of the electrolysis module 210 do.

Although not shown in the drawing, the external charging module (not shown) is electrically connected to the controller 240 and transfers power to the controller 240. The external charging module (not shown) is applied to a charging adapter, an external auxiliary battery or the like.

The controller 240 may supply power to the controller 240 in a state where the external charging module (not shown) is directly connected to the external power supply unit (not shown), and may supply power stored in the external power supply unit ).

Also, the power supply module 250 receives power from the external charging module (not shown) through the controller 240. Since the power supply module 250 may be always provided through the holder 220, the power supply module 250 may store power supplied from the external charging module (not shown) and supply the power to the electrolysis module 210.

That is, the power supplied from the power supply module 250 is supplied to the electrolysis module 210 through the controller 240, and the controller 240 transmits an operation command to the electrolysis module 210 The hydrogen is generated on the side of the first electrode 212 which is a negative (-) electrode, and on the side of the second electrode 216 which is a positive (+) electrode, The oxygen is generated. The produced hydrogen is dissolved in the water and the oxygen is discharged to the outside.

Meanwhile, the hydrogen generator 200 includes at least one light emitting device (not shown) on the controller 240. The first cation transfer membrane 213, the second cation transfer membrane 215 and the first sealing member 211, the second sealing member 217 and the fixing bracket 230 may be formed of a transparent material .

Accordingly, light emitted from the light emitting device (not shown) is transmitted through the first cation transfer membrane 213, the second cation transfer membrane 215, the first sealing member 211, the second sealing member 217, And the holes formed in the fixing bracket 230, the first electrode 212, and the second electrode 216 may be transmitted to the water. The user can grasp whether the hydrogen generator 200 is operating due to the light of the light emitting device (not shown) projected on the water, and a lamp for informing an operating state of the hydrogen generator 200 installed in the main body 100 The same configuration can be omitted.

In particular, when a plurality of the light emitting devices (not shown) are provided, it is possible to determine whether the hydrogen generating unit 200 is in a different operating state according to the light of each of the light emitting devices.

The power supply module 250 is detachably coupled to the holder 220. The power supply module 250 includes a battery case 252 having at least one battery 251 therein and an open side and a battery case 252 detachably coupled to one side of the battery case 252, And a case cover 253.

That is, the battery 251 can be taken out through one open side of the battery case 252, and when the life of the battery 251 expires, the user can remove the case cover 253 and directly replace the case 253 .

The hydrogen generator 200 may further include a switch member 280. The switch member 280 is provided so that the controller 240 can directly turn on / off a command for controlling the operation of the electrolysis module 210.

The switch member 230 is provided on a side surface of the holder 220 and includes a button 281 and an elastic member 283 for returning the button 281 to an initial position. When the user applies an external force and presses the button 281 to give an operation command and if the external force of the button 281 is removed, the button 281 returns to the initial position through the elastic member 283, do.

However, the same configuration as that of the switch member 230 is limited to the present embodiment, and a condition for automatically operating the electrolysis module 220 is preset to the controller 240 so that the switch member 230 is omitted You may.

The cover part 300 is detachably coupled to the other side of the main body part 100 to shield the main body part 100 so that the water stored in the main body part 100 is not spilled.

The cover part 300 includes a cover body module 310, a deformable member 330, and a restoring member 350. The cover body module 310 has an inner space formed therein and one side thereof is opened and one side thereof is coupled with a threaded member formed on an outer circumferential surface of the other side 150 of the body portion 100 in a screw tightening manner. However, this is a coupling method limited to the present embodiment and can be combined in various other ways.

5, the cover body module 310 includes a cover body module 310, a cover body module 310, and a cover body module 310. The cover body module 310 includes a cover body module 310, And a first cover body 311 which is coupled in a screw-fastening manner. Therefore, a thread is formed on the inner circumferential surface of one side of the first cover body 311 so that the screw thread (not shown) formed on the outer circumferential surface of the other side 150 of the main body 100 can be screwed.

The cover body module 310 also includes a second cover body 313 inserted into the first cover body 311 to shield the other side of the first cover body 311. The outer circumferential surface of the second cover body 313 is inserted so as to be in close contact with the other inner circumferential surface of the first cover body 311.

The first cover body 311 is formed with a protrusion 311a protruding from the inner circumferential surface at a predetermined height and extending along the circumferential direction of the first cover body 311. The deformable member 330 is provided inside the cover body module 310, more precisely, inside the protrusion 311a of the first cover body 311.

The deformable member 330 is also provided with a protrusion 331 protruding toward one side of the first cover body 311 and extending along the circumferential direction of the first cover body 311. The protrusion 331 is formed on the protrusion So that it can not be easily separated by the protrusion 331 when the deformable member 330 is fitted into the first cover body 311.

When the cover part 300 is coupled with the body part 100, the hydrogen generator 200 always generates hydrogen, and when the hydrogen is dissolved in the water, The pressure inside the part 100 is increased.

The deformable member 330 absorbs the pressure while being deformed by the pressure when the pressure inside the main body 100 increases as described above. Accordingly, the deformable member 330 is formed of a material having shape restoring force to be deformed by pressure, and is formed of, for example, a rubber material or a silicon material. The deformable volume of the deformable member 330 is determined in consideration of the amount of hydrogen ions generated in the hydrogen generator 200 at a time.

7 shows the deformable member 330 'according to another embodiment of the present invention. Referring to FIG. 7, the deformable member 330 'includes a first protrusion 331a' protruding from the outer side surface and extending in the circumferential direction, and a second protrusion 331b 'protruding from the outer side surface, And a second protrusion 331b 'spaced apart from the first protrusion 331a` by a predetermined interval.

The protrusion 331a formed on the first cover body 331 is sandwiched between the first protrusion 331a and the second protrusion 331b and the first cover body 311 and the deformation Member 330 'is coupled.

The restoring member 350 is provided between the cover body module 310 and the deformable member 330. The restoring member 350 is compressed when the deforming member 330 is deformed and when the pressure inside the main body 100 is reduced when the cover unit 300 is separated from the main body 100, (350) is stretched to restore the deformable member (330) to an initial state.

As shown in FIG. 5, one end of the restoring member 350 is connected to the second cover body 313, and the other end of the restoring member 350 is connected to the deforming member 330.

Meanwhile, the restoring member 350 may be omitted. The restoring member 350 may be omitted so that the user can directly restore the deforming member 330 to an initial state.

FIG. 6 shows a process in which the deformable member 330 is deformed and restored. 6 (a), when the water is stored in the main body 100 and the cover part 300 is coupled, no deformation occurs in the deformable member 330. [

6 (b), the water is electrolyzed through the hydrogen generator 200 to generate the hydrogen, and when the generated hydrogen is dissolved in the water, The deformation member 330 deforms to absorb the internal pressure of the main body 100 when the pressure inside the main body 100 increases. At this time, the restoring member 350 is compressed.

6 (c), when the cover part 300 is separated from the main body 100, the pressure absorbed by the deformable member 330 is removed, and the restoring member 350 is stretched while the deformable member 330 330) to an initial state.

As described above, in the portable bottle 1000 according to the present embodiment, the cover 300 includes the deforming member 330 and the restoring member 350 to absorb the pressure inside the main body 100 It is possible to prevent a problem that the user can not open / close the cover part 300 due to the generation of water.

Conventionally, a check valve is provided in a cover portion to remove an increased pressure inside the body portion. However, the check valve may allow water stored in the body portion to flow in, and foreign substances may be deposited inside the check valve by water introduced into the check valve As a result, the performance of the check valve is deteriorated, a hygienic problem occurs, and water stored in the main body is leaked.

However, when the increased pressure inside the main body 100 is removed by the deformable member 300 and the restoring member 350 as in the present invention, it is possible to prevent performance problems, hygiene problems, and leakage problems .

Although not shown in the drawing, a check valve (not shown) may be provided in the cover part 300 together with a safety device (not shown) so that the pressure inside the body part 100 may be applied to the deformable member 330, The safety device (not shown) may determine that the pressure in the main body 100 can be absorbed, and may operate to remove the pressure inside the main body 100 using the check valve (not shown).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1000: Portable bottle
100: main body 200: hydrogen generator
210: electrolysis module 211: first sealing member
212: first electrode 213: first cation transport membrane
214: membrane sealing member 215: second cation transport membrane
216: second electrode 217: second sealing member
220: holder 230: fixed bracket
240: controller 250: power supply module
251: Battery 252: Battery Case
253: Casker 260: First packing member
270: second packing member 280: switch member
281: button 283: elastic member
300: cover part 310: cover body module
311: first cover body 313: second cover body
330: deformable member 350: restoring member

Claims (10)

A body portion having a hollow formed along its longitudinal direction to open on both sides thereof and capable of storing water for drinking;
And an electrolysis module detachably coupled to one side of the main body to directly contact water stored in the main body and to electrolyze the water to generate hydrogen and oxygen from the water; And
And a cover portion that is detachably coupled to the other side of the body portion and shields the body portion to prevent the water stored in the body portion from spilling out,
The electrolytic module includes:
A first electrode having one surface in contact with the water;
A second electrode spaced apart from the first electrode to electrolyze the water together with the first electrode;
A first cation transport membrane having a first surface disposed in close contact with the other surface of the first electrode; And
Wherein the first cation transport membrane has a lower porosity than the first cation transport membrane and has a surface area larger than that of the first cation transport membrane so that one surface of the first cation transport membrane is in close contact with the other surface of the first cation transport membrane, And a second cation transport membrane for blocking the leakage from the cation transport membrane and improving the adhesion of the second electrode to the first electrode so as to improve the electrolytic capacity between the first electrode and the second electrode, ,
The adhesion of the second electrode to the first electrode is enhanced by the second cation transfer membrane. When the electrolysis module electrolyzes the water, hydrogen is generated in the first electrode, and the hydrogen is dissolved in the water And oxygen is generated in the second electrode to generate hydrogen water in which the oxygen is discharged to the outside. The method according to claim 1,
The electrolytic module includes:
Further comprising a membrane sealing member surrounding the edge of the first cation transport membrane,
Wherein the second cation-transfer membrane is capable of generating hydrogen-water in close contact with a part or the whole of the other surface of the membrane-sealing member. The method according to claim 1,
The electrolytic module includes:
A first sealing member having a central through hole and a concave groove formed on one surface thereof and having one surface of the first electrode closely inserted into an inner surface of the groove; And
And a second sealing member penetrating through the center and having a concave groove formed on one surface thereof and having the other surface of the second electrode closely inserted into the inner surface of the groove. The method according to claim 1,
Wherein the surface of the first cationic transfer membrane in contact with the water is a non-stick (non-stick) material to prevent contamination by the contaminants in the water and to prevent damage and wear when the contaminants are adsorbed on the surface contacting the water. -stick) Portable bottle capable of producing hydrogen-water coated material. The method according to claim 1,
Wherein the surface of the second cation transport membrane is capable of producing hydrogen peroxide coated with a polymer solid electrolyte so as to improve adhesion with the first cation transport membrane. The method according to claim 1,
Further comprising: a holder detachably coupled to one side of the main body and having the electrolysis module disposed therein,
The hydrogen-
A controller which is electrically connected to the electrolysis module to control the operation of the electrolysis module and is disposed at a lower portion of the electrolysis module inside the holder; And
Further comprising at least one light emitting element provided on the controller,
Wherein the light emitted from the light emitting device is transmitted through the electrolytic module and projected into the main body to generate hydrogenated water for confirming whether the hydrogen generator is operated by the light of the light emitting device. The method of claim 6,
In the portable bottle capable of generating hydrogenated water,
Further comprising an external charging module electrically connected to the controller to supply power to the controller. The method according to claim 1,
The cover portion
A cover body module in which an inner space is formed and one side is opened and the one side is detachably coupled to the other side of the main body; And
The cover body is provided inside the cover body module. When the hydrogen gas dissolves in the water while the cover body is engaged with the body, the remaining hydrogen gas is deformed when the pressure inside the body increases, A portable bottle capable of producing hydrogen-containing water containing a deformable member to be absorbed. The method of claim 8,
The cover portion
The cover body module being provided between the cover body module and the deformable member and being compressed when the deformable member is deformed and being pulled when the pressure for deforming the deformable member is removed upon separation of the cover portion and the main body portion, And a restoring member that restores the restoration member. The method of claim 8,
Wherein the deformable member is made of a material having shape restoring force.

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