KR101749516B1 - Device for producing hydrogen-water - Google Patents

Abstract

An electrolytic solution supply module for supplying and flowing an electrolytic solution from an outside through an electrolytic solution supply unit. An electrolytic module detachably coupled to the electrolyte supply module and configured to electrolyze the electrolytic solution when electricity is supplied from an external power source to extract hydrogen and oxygen from the electrolytic solution; A shielding housing detachably coupled to the electrolyte supply module while protecting the electrolysis module and having a hydrogen discharge portion for discharging the hydrogen extracted from the electrolytic solution to the outside; And a hydrogen permeable portion which is detachably connected to the shielding housing so as to communicate with the hydrogen discharge portion, the hydrogen discharged through the hydrogen discharge portion during the inflow of purified water from the outside is drawn in and dissolved in the purified water, And a hydrogen mixing nozzle for discharging the hydrogen mixed gas.

Description

[0001] The present invention relates to a device for producing hydrogen-water,

More particularly, the present invention relates to a hydrogen-producing apparatus capable of electrolyzing an electrolytic solution to extract hydrogen and dissolving hydrogen extracted in purified water to produce hydrogen-containing water.

As interest in health has increased, R & D on disease prevention has been continuing. In particular, research and development are actively carried out to improve lifestyle diseases and help metabolism by utilizing hydrogen with strong reducing power.

In relation to real life, hydrogen is a colorless, odorless, and tasteless element that has strong reducing power and is widely used for removing active oxygen in the body, which is known to be a source of modern diseases such as lifestyle diseases. Powder products in which hydrogen is stored in minerals such as calcium in a high-temperature and high-pressure plasma state, products that generate hydrogen by chemical reaction with metals such as magnesium and water, high-concentration hydrogen- Etc. Recently, a number of water purifier and water purifier have been launched in Japan and Korea.

Most of the above products and technologies that apply the hydrogen reduction power in relation to the health of the human body do not accurately indicate the concentration of dissolved hydrogen dissolved in water, so that it is unclear whether the dissolved hydrogen is contained or not. It is not easy to find reasonable and superior products based on convenience and effectiveness.

Generally, known alkaline ionized water produces acidic water and alkaline water through electrolysis of water. When alkaline ionized water is used to utilize the generated reducing action of dissolved hydrogen, there is a problem that the acidic water is discarded as it is, It is difficult to maximize the effect as the hydrogen reduced water due to the concentration and the strong alkaline water whose pH is raised to about 9 to 12 can not be used in the case of irritable diseases because it is not suitable for drinking, .

In this way, various products offering strong reduction power of hydrogen-reduced water for health have been widely introduced. On the other hand, in order to maximize the reduction effect and maximize the concentration, it is possible to add a special device for increasing the concentration of dissolved hydrogen, There is a problem that the equipment becomes large and the manufacturing cost rises, so that it is required to develop a reasonable water generation module.

Korean Patent Publication No. 10-2005-0028541

An object of the present invention is to provide a hydrogen-water producing device capable of electrolyzing an electrolytic solution to extract hydrogen and dissolving extracted hydrogen in purified water to produce hydrogen-containing water.

The present invention relates to an electrolytic solution supply module in which an electrolytic solution is supplied and flows from the outside through an electrolytic solution supply unit; An electrolytic module detachably coupled to the electrolyte supply module and configured to electrolyze the electrolytic solution when electricity is supplied from an external power source to extract hydrogen and oxygen from the electrolytic solution; A shielding housing detachably coupled to the electrolyte supply module while protecting the electrolysis module and having a hydrogen discharge portion for discharging the hydrogen extracted from the electrolytic solution to the outside; And a hydrogen permeable portion which is detachably connected to the shielding housing so as to communicate with the hydrogen discharge portion, the hydrogen discharged through the hydrogen discharge portion during the inflow of purified water from the outside is drawn in and dissolved in the purified water, Wherein the purified water flowing from the outside flows through the inside of the hydrogen discharge unit and is moved by a force for drawing the hydrogen to open the hydrogen discharge unit, And a check valve unit for returning to the initial position and shielding the hydrogen discharge unit when the hydrogen discharge unit is not operated.

According to another aspect of the present invention, there is provided an electrochemical device comprising: an electrolyte supply module for supplying and flowing an electrolyte solution from an outside through an electrolyte solution supply unit; An electrolytic module detachably coupled to the electrolyte supply module and configured to electrolyze the electrolytic solution when electricity is supplied from an external power source to extract hydrogen and oxygen from the electrolytic solution; A shielding housing detachably coupled to the electrolyte supply module while protecting the electrolysis module and having a hydrogen discharge portion for discharging the hydrogen extracted from the electrolytic solution to the outside; And a hydrogen discharge unit connected to the shielding housing so as to be detachably connected to the shielding housing, wherein the purified water flowing from the outside flows and flows through the hydrogen discharging unit, and the purified water and the hydrogen flow And a mixing unit which mixes the hydrogen and discharges the hydrogen into the purified water dissolved in the water, wherein the purified water flowing from the outside flows in the hydrogen discharging unit and moves by the force of drawing the hydrogen And a hydrogen generation unit for opening the hydrogen discharge unit and returning to an initial position when the purified water does not flow to cover the hydrogen discharge unit.

The hydrogen-producing apparatus according to the present invention has the following effects.

First, since the electrolytic solution supply module, the electrolysis module, and the shielding housing are separated from each other, it is possible to easily perform maintenance even if a trouble occurs.

Secondly, since the check valve unit is provided in the hydrogen discharge part formed in the shielding housing to discharge the hydrogen, the discharge of the hydrogen is easy and the inflow of purified water through the hydrogen discharging part is prevented to stably control the water pressure inside the electrolysis module The electrolysis efficiency is increased. Particularly, breakage of the membrane due to water pressure and leakage between the electrolyte supply module and the shielding housing can be prevented.

Thirdly, a drain portion is formed in the electrolyte supply module, and impurities of the electrolyte can be discharged to the outside.

Fourthly, the oxygen discharge portion is formed in the electrolyte supply module, and the check valve unit is provided in the oxygen discharge portion, so that the discharge of oxygen can be facilitated and the external air can be prevented from being exhausted through the oxygen discharge portion.

1 is an exploded perspective view illustrating a hydrogen generation apparatus according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the apparatus for producing hydrogen water according to FIG. 1; FIG.
FIG. 3 is a cross-sectional view and a partial enlarged view of the hydrogen-producing device according to FIG. 1; FIG.
4 is a partially enlarged cross-sectional view showing the portion "A" of Fig.
5 is an exploded perspective view illustrating a hydrogen generation device according to another embodiment of the present invention.
FIG. 6 is a partial cross-sectional view of the apparatus for generating hydrogen according to FIG.
FIG. 7 is a partial cross-sectional perspective view of the apparatus for producing hydrogen water according to FIG.

1 to 7 show an apparatus for producing hydrogen water according to the present invention.

Referring to FIGS. 1 to 4, an apparatus 1000 for generating hydrogen in accordance with an embodiment of the present invention includes an electrolytic solution supply module 100, an electrolysis module 100, 200, a shielding housing 300, and a hydrogen mixing nozzle 400.

The electrolyte solution supply module 100 is supplied with an electrolyte solution from the outside through the electrolyte solution supply part 139a, and the electrolyte solution is pure water. More specifically, the electrolyte supply module 100 includes electrolyte storage containers 110 and 130, a storage container cover 139, a ball body 133, and opening and closing modules 135 and 137.

The electrolyte storage containers 110 and 130 include a first electrolyte storage part 110 coupled to the electrolysis module 200 to supply the electrolyte solution supplied from the outside to the electrolysis module 200, And a second electrolyte storage part 130 communicating with the electrolyte storage part 110 and storing the electrolyte solution for flowing to the first electrolyte storage part 110.

Referring to FIG. 1, the first electrolyte storage part 110 and the second electrolyte storage part 130 are integrally formed. The first electrolyte storage part 110 and the second electrolyte storage part 130 Through holes (not shown) are formed. Therefore, the electrolyte flows from the second electrolyte storage part 130 to the first electrolyte storage part 110 by the through holes (not shown). Referring to FIG. 2, a drain portion 111 is formed in the first electrolyte storage portion 110. Impurities of the electrolyte solution flowing into the first electrolyte storage part 110 through the drain part 111 can be discharged to the outside.

As shown in FIG. 1, the second electrolyte storage part 130 is formed in the form of a water tank having an opened top surface 131, and the electrolyte is stored in the second electrolyte storage part 130. The upper surface 131 of the second electrolyte storage part 130 is shielded by the storage container cover 139.

The electrolyte supply portion 139a is formed on one side of the storage container cover 139 and an oxygen discharge portion 139b is formed at a position spaced apart from the electrolyte supply portion 139a. Therefore, even if the storage container cover 139 shields the upper surface 131 of the second electrolyte storage part 130, the electrolyte solution is supplied to the electrolyte storage containers 110 and 130 through the electrolyte supply part 139a .

The electrolyte supply part 139a protrudes outwardly and inwardly from the upper surface of the storage container cover 139. The electrolyte supply part 139a is formed with a hollow (not illustrated) penetrating through the electrolyte solution supply part 139a along the longitudinal direction. In the electrolyte supply part 139a, a barrier (unrepresented) across the hollow (unmarked) is formed, and a hole 139a-1 is formed in the barrier (unrepresented) to supply the electrolyte.

When the storage container cover 139 is coupled with the upper surface 131 of the second electrolyte storage part 130 so as to shield the upper surface 131 of the second electrolyte storage part 130, Modules 135 and 137 are provided. The ball body 133 is rotatably hinged to one side of the storage container cover 139 while being positioned inside the second electrolyte storage part 130. More specifically, the hinge h is coupled to the lower surface of the storage container cover 139.

The opening and closing modules 135 and 137 are provided between the ball body 133 and the storage container cover 139. One side of the opening and closing modules 135 and 137 is connected to the ball body 133 and the other side is inserted into the electrolyte supply part 139a. The opening and closing modules 135 and 137 open the electrolyte supply part 139a to allow the electrolyte solution to be supplied from the outside when the ballast body 133 sinks and open the inside of the second electrolyte storage part 130 When the ball body 133 is lifted by buoyancy of the electrolyte while the electrolyte is stored, the supply of the electrolyte is stopped by shielding the electrolyte supply part 139a.

More specifically, the opening and closing modules 135 and 137 include a ball-shaped shaft 135 and a packing member 137. One side of the ball-top shaft 135 is connected to one side of the ball-top body 133 and the other side is inserted into the electrolyte solution supply unit 139a. The packing member 137 is provided at the other end of the ball-point shaft 135. The opening and closing modules 135 and 137 reciprocate in the vertical direction by the rotation of the ball-top body 133.

When the front end of the ball body 133 does not touch the inner bottom surface of the second electrolyte storage part 133, the opening and closing modules 135 and 137 move downward in association with the rotation of the ball body 133 And opens the electrolyte supply part 139a. However, when the electrolyte is filled in the second electrolyte storage part 133, when the ball body 133 rotates due to buoyancy of the electrolyte, the opening and closing modules 135 and 137 rotate the ball body 133 The packing member 137 shields the hole 139a-1 of the electrolyte supply part 139a. Therefore, excessive supply of the electrolyte solution to the electrolyte solution supply module 100 can be prevented.

The electrolysis module 200 includes a negative electrode portion 210, a positive electrode portion 230, and a separator 220. The electrolytic module 200 is coupled to the first electrolyte storage part 110 as described above. When electricity is supplied from the external power source (not shown) to the negative electrode portion 210 and the positive electrode portion 230 when the electrolyte is supplied to the first electrolyte storage portion 110, the electrolytic solution is electrolyzed, Hydrogen is extracted to the anode 210 and oxygen is extracted to the anode 230.

The oxygen extracted by the electrolysis module 200 flows into the second electrolyte storage part 130 through the first electrolyte storage part 110 and the oxygen discharge And is discharged through a portion 139b.

The oxygen discharge portion 139b is protruded outward from the upper surface of the storage container cover 139 and has a hollow (not shown) penetrating the oxygen discharge portion 139b along its longitudinal direction. A check valve unit 330, which will be described later, is provided in the oxygen discharge portion 139b. The electrolytic solution is electrolyzed through the electrolytic module 200, and the extracted oxygen is discharged to the outside through the oxygen discharge part 139b.

The oxygen flows along the first electrolyte storage part 110 and flows into the second electrolyte storage part 130. If the electrolyte supply part 139a is shielded by the opening and closing modules 135 and 137 The pressure of the inside of the second electrolyte storage part 130 increases as the oxygen becomes saturated. The oxygen in the second electrolyte storage part 130 pushes out the check valve unit 330 provided in the oxygen discharge part 139b to open the oxygen discharge part 139b, .

When the pressure inside the second electrolyte storage part 130 is lowered as the oxygen is discharged through the oxygen discharge part 139b, the check valve unit 330 returns to the initial position and the oxygen discharge part 139b, Thereby preventing the outside air from flowing into the second electrolyte storage part 130. The check valve unit 330 will be described later in more detail.

The shielding housing 300 is detachably coupled to the electrolyte supply module 100. And more specifically, is detachably coupled to the first electrolyte storage part 110. The shielding housing 300 is formed with a hydrogen discharge unit 310. As described above, the hydrogen extracted by the electrolysis module 200 is discharged to the outside via the hydrogen discharging unit 310.

The shielding housing 300 is formed with a discharge hole 301 penetrating the shielding housing 300 in the width direction and the hydrogen discharge part 310 is disposed at a position coaxial with the discharge hole 301, And is protruded from the outer surface of the housing 300. The hydrogen discharge part 310 is formed in the form of a column having a circular cross section, and a hollow (unrepresented) is formed inside the hydrogen discharge part 310 to communicate with the discharge hole 301 in the longitudinal direction of the hydrogen discharge part 310.

The check valve unit 330 is inserted into the hollow (unmarked) of the hydrogen discharge unit 310. The check valve unit 330 is opened so that the discharge hole 301 is communicated with the hollow (unmarked) so that the hydrogen can be discharged. Also, when the hydrogen is not discharged, the discharge hole 301 is shielded to prevent purified water from flowing through the discharge hole 301 through the hydrogen discharge unit 310.

If the purified water flows through the discharge hole 301, a gap may be formed between the first electrolyte storage part 110 and the shielding housing 300. Particularly, since the first electrolyte storage part 110 and the shielding housing 300 are connected only by bolt assembly, when the purified water flows into the discharge hole 301, the electrolysis module 200 The leakage of water may occur due to the gap between the first electrolyte storage part 110 and the shielding housing 300 and the electrolysis efficiency may be lowered.

As described above, only by providing the check valve unit 330 in the hydrogen discharge part 310, the gap between the first electrolyte storage part 110 and the shielding housing 300 and the leakage And the electrolysis efficiency can be increased.

1 and 4, the check valve unit 330 includes an opening / closing shaft 331, an elastic member 332, a stopper member 334, and a flow passage member 333. One side of the opening and closing shaft 331 closely contacts the discharge hole 301 to shield the discharge hole 301 or to separate the discharge hole 301 from the discharge hole 301. More specifically, the opening and closing shaft 331 includes a shaft head 331a which is in close contact with the discharge hole 301 and a shaft body 331b which protrudes from one surface of the shaft head 331a. The cross-sectional surface of the shaft body 331b is formed to be smaller than the cross-sectional surface of the shaft head 331a.

The elastic member 332 is provided so as to surround the other side of the opening and closing shaft 331 so that the opening and closing shaft 331 is compressed by the external force to open the discharge hole 301. When the external force is removed, 331 are tensioned so as to shield the discharge hole 301. More specifically, the elastic member 332 is provided to surround the shaft body 331b of the opening / closing shaft 331. Therefore, one side of the elastic member 332 is tangent to one side of the shaft head 331a.

On the other hand, the external force applied to compress or tension the elastic member 332 is a force for introducing the hydrogen while the purified water flows. As will be described later, a hydrogen mixing nozzle 400 is coupled to the hydrogen discharge unit 310. The water mixed with the hydrogen is supplied to the hydrogen mixing nozzle 400 through the hydrogen discharge unit 310 while the purified water flows from the externally purified water to the hydrogen mixing nozzle 400. At this time, Is compressed. The hydrogen mixing nozzle 400 will be described later in more detail.

The stopper member 334 is fitted to the tip of the hydrogen discharge part 310 to fix the flow path member 333. And a flow path 334a through which the hydrogen is discharged is formed therein. A plurality of protrusions 334b protruding along the circumferential direction of the stopper member 334 and spaced from each other along the longitudinal direction of the stopper member 334 are formed on the outer surface of the stopper member 334. [

The protrusions 334b are protruded in a direction opposite to the direction in which the stopper member 334 is inserted into the hollow of the hydrogen discharge unit 310 so that the stopper member 334 is connected to the hydrogen discharge unit 310 Thereby preventing the hydrogen from leaking out between the stopper member 334 and the hollow (not shown).

The flow path member 333 is provided between the opening and closing shaft 331 and the elastic member 332 and the stopper member 334. The other side of the opening and closing shaft 331 is inserted into the passage member 333 and the other side of the elastic member 332 is fixed in contact with the passage member 333. The flow path member 333 has a flow path (unrepresented) through which the hydrogen flows from the outside to the inside.

When the check valve unit 330 is installed in the oxygen discharge unit 139b, the shaft head 331a of the opening and closing shaft 331 is inserted into a hole (not shown) formed in the storage container cover 139 , And the stopper member 334 is fitted to the tip of the oxygen discharge portion 139b. When the pressure inside the second electrolyte storage part 130 increases due to the saturation of the oxygen, the opening / closing shaft 331 is pushed out by the increased pressure, and the elastic member 333 is compressed. When the pressure of the second electrolyte storage part 130 becomes lower than the atmospheric pressure while the oxygen is discharged to the outside, the force for pushing the opening / closing shaft 331 disappears and the elastic member 333 is pulled, Shields the holes (not shown) formed in the storage container cover 139.

As described above, the hydrogen mixing nozzle 400 is detachably coupled to the hydrogen discharging unit 310. When water purified from the outside flows into the hydrogen mixing nozzle 400, the purified water is introduced into the hydrogen mixing nozzle 400, The hydrogen is discharged from the hydrogen discharge unit 310 while flowing in the hydrogen discharge unit 310. The hydrogen and the purified water are mixed with each other to dissolve the hydrogen in the purified water,

The hydrogen mixing nozzle 400 is coupled to the hydrogen discharge unit 310 by the connector 10 as shown in FIG. One side of the connector 10 is coupled to the hydrogen discharge unit 310 and the other side of the connector 10 is coupled to the hydrogen mixing nozzle 400.

The hydrogen mixing nozzle 400 includes a first body 410 into which purified water externally flows, and a second body 420 formed integrally with the first body 410, And a third body 430 extending from the second body 420 and coupled to the connector 10.

A first flow path 411 through which the purified water flowing from the outside flows flows is formed in the first body 410. The second body 420 extends from the tip of the first body 410 and is formed integrally with the first body 410. The second body 420 is formed integrally with the first body 410 so that the purified water, And a second flow path 421 communicating with the first flow path 411 is formed.

The third body 430 extends from the second body 420 on one side of the second body 420 and extends in the direction in which the first body 410 and the second body 420 extend And extend in an intersecting direction. A third flow path 431 through which the hydrogen flows is formed in the third body 430 and the third flow path 431 is formed to communicate with the second flow path 421. The tip of the third body 430 is inserted into the connector 10 so that the hydrogen mixing nozzle 400 is connected to the hydrogen discharge unit 310.

4, the first body 410 includes a protruding body 440 protruding from the front end of the first body 410 toward the second flow path 421 and extending in a predetermined length direction . The outer surface 441 of the protruding body 440 is inclined from the first body 410 toward the second body 420. The protruding body 440 is gradually reduced in size from the first body 410 toward the second body 420 so that the outer surface 441 of the protruding body 440 is gradually reduced, .

The protruding body 440 extends longer than the position where the third flow path 431 communicating with the second flow path 421 is formed at the tip of the protruding body 440. Therefore, when the hydrogen flowing along the third flow path 431 flows into the second flow path 421, the hydrogen flows into the second flow path 421 after hitting the outer surface 441 of the protruding body 440, To form a vortex with the purified water flowing through the water. Accordingly, the hydrogen and the purified water can be mixed more effectively.

The first flow path 411 extends to the inside of the protruding body 440. The size of the cross section of the first flow path 411 to the set point along the direction in which the purified water flows is formed to be the same, and from the set point to the tip of the projecting body 440, Is gradually reduced in size.

The pressure of the purified water flowing through the first flow path 411 is lower than the atmospheric pressure when the flow of the purified water flows through the protruding body 440 and the check valve unit 330, The discharge hole 301 is opened while the elastic member 332 of the third body 430 is compressed and the opening and closing shaft 331 moves toward the hydrogen mixing nozzle 400, To the third flow path (431).

On the other hand, when there is no inflow of the purified water into the hydrogen mixing nozzle 400 from the outside, the elastic member 332 of the check valve unit 330 is pulled, and the opening / closing shaft 331 is moved to the discharge hole 301 And is in close contact with the discharge hole 301 to shield the discharge hole 301. At this time, the operation of the electrolysis module 200 also stops (refer to "B" in FIG. 4)

5 to 7 show a hydrogen generation apparatus 1000 'according to another embodiment of the present invention. Hereinafter, the hydrogen-water generating apparatus 1000 'will be described with reference to FIGS. 5 to 7. FIG.

Prior to a specific description of the hydrogen generating apparatus 1000 ', the hydrogen generating apparatus 1000' has the same configuration as the hydrogen generating apparatus 1000 according to the embodiment described above. Specifically, the electrolytic solution supply module 100, the electrolytic module 200, and the shielding housing 300 are the same as those of the hydrogen generating apparatus 1000 according to the embodiment described above. Therefore, the same reference numerals are used and detailed descriptions are omitted. The electrolytic solution supply module 100, the electrolytic module 200, the shielding housing 300, and the mixing unit 500 are included in the apparatus 1000 '. Therefore, the mixing unit 500 will be described below.

The mixing unit 500 is detachably coupled to the shielding housing 300 to communicate with the hydrogen discharge unit 310. When the purified water from the outside is introduced into the mixing unit 500, the mixing unit 500 flows the purified water inside the mixing unit 500 so that the hydrogen discharged from the hydrogen discharging unit 310 dissolves the purified water The hydrogen and the purified water are mixed and discharged as hydrogen peroxide.

The mixing unit 500 includes an inlet 511 through which the purified water is introduced into one side of the mixing unit 500 while being in surface contact with the shielding housing 300, And a mixing channel 501 for connecting the inlet 511 and the outlet 513 with the purified water and flowing the hydrogen while mixing the water, A second mixer body 530 which is in tight contact with the other surface of the first mixer body 510 to shield the mixing channel 501 and a second mixer body 530 which is coupled to the other surface of the first mixer body 510, And a sealing member 550 provided between the mixer body 530 and preventing the purified water flowing through the mixing passage 501 and the hydrogen from leaking.

The mixing channel 501 is bent a plurality of times at a predetermined interval along the height direction of the first mixer body 510 to form a plurality of 'S' shaped concaves. More specifically, a plurality of horizontal mixing passages 501a extending in the horizontal direction and spaced apart from each other by a set interval along the height direction, vertical mixing passages 501b connecting one end of each of the adjacent horizontal mixing passages 501a, And a bending mixing flow path 501c connecting the other ends of the adjacent horizontal mixing flow paths 501a without being connected by the first vertical mixing flow path 501b.

When the direction of the hydrogen introduced into the mixing unit 500 from the purified water and the purified water is switched from the horizontal mixing induction 501a to the vertical mixing passage 501b, Not only collides with the inner wall of the discharge port 501b but also the time required to flow to the discharge port 513 becomes longer to dissolve more in the purified water to further increase the hydrogen concentration.

On the other hand, a hydrogen mixing nozzle 515 is provided at the tip of the mixing passage 501 connected to the inlet 511. More specifically, the hydrogen mixing nozzle 515 is disposed at a position nearer to a position where the hydrogen discharge unit 310 is inserted into the first mixer body 510 with respect to the inlet unit 511. The hydrogen mixing nozzle 515 is detachably provided at the tip of the mixing passage 501 and can be changed in size according to the flow rate of the purified water flowing through the inlet 511.

In the hydrogen mixing nozzle 515, a flow path (untraded) through which the purified water flows can be formed. The cross-sectional size of the flow path (untraded) gradually decreases along the direction in which the purified water flows . Therefore, when the purified water flowing through the inlet portion 511 passes through the hydrogen mixing nozzle 515, the pressure is lower than the atmospheric pressure, and the check valve unit 330, which is provided in the hydrogen discharge portion 310, The discharge hole 301 is opened and the hydrogen is sucked into the mixing passage 501 and mixed with the purified water. The hydrogen and the purified water are mixed while flowing in the mixing flow path 501. When the hydrogen is dissolved in the purified water and discharged into the discharge hole 513, the hydrogen is discharged as hydrogen water.

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, 1000`: Hydrogen generator
100: electrolyte supply module 110: first electrolyte storage part
111: drain part 130: second electrolyte storage part
133: Ball Top Body 135: Ball Top Shaft
137: packing member 139: storage container cover
139a: electrolyte supply part 139b: oxygen discharge part
200: electrolysis module 210: negative electrode part
220: separator 230: positive electrode part
300: shielding housing 310: hydrogen outlet
330: check valve unit 331: opening / closing shaft
332: elastic member 333: flow member
334: stopper member 400: hydrogen mixing nozzle
410: first body 411: first flow path
420: second body 421: second flow path
430: third body 431: third channel
440: protruding body 441: outer surface
500: mixing unit 510: first mixer body
530: second mixer body 550: sealing member
501: Mixing flow path 511:
513: discharge part 515: hydrogen mixing nozzle

Claims (15)

An electrolyte supply module in which an electrolyte is supplied and flows from the outside through the electrolyte supply portion;
An electrolytic module detachably coupled to the electrolyte supply module and configured to electrolyze the electrolytic solution when electricity is supplied from an external power source to extract hydrogen and oxygen from the electrolytic solution;
A shielding housing detachably coupled to the electrolyte supply module while protecting the electrolysis module and having a hydrogen discharge portion for discharging the hydrogen extracted from the electrolytic solution to the outside; And
And the hydrogen discharged through the hydrogen discharging portion during the inflow of purified water from the outside is introduced into the shielding housing so as to communicate with the hydrogen discharging portion and is dissolved in the purified water, And a hydrogen mixing nozzle for discharging hydrogen,
The purified water flowing from the outside flows through the hydrogen discharge unit and moves by the force for drawing the hydrogen to open the hydrogen discharge unit. When the purified water does not flow, the hydrogen return unit returns to the initial position, A check valve unit for shielding the discharge portion is provided,
The electrolyte supply module includes:
A first electrolyte storage part coupled to the electrolytic module and supplying the electrolytic solution supplied from the outside to the electrolytic module; and an electrolytic solution, which is in communication with the first electrolytic solution storage part and flows to the first electrolytic solution storage part, An electrolyte storage container including a second electrolyte storage part to be stored;
A storage container cover detachably coupled to the second electrolyte storage part and having the electrolyte supply part for supplying the electrolyte solution from the outside;
A ball body rotatably hinged to one side of the reservoir cover while being positioned inside the second electrolyte reservoir and floated by buoyancy of the electrolyte when the electrolyte is filled in the second electrolyte reservoir;
And the other end is inserted into the electrolyte supply part. When the ballast body sinks, the electrolyte supply part is opened to supply the electrolyte solution from the outside, and when the ballast body is lifted by the buoyancy of the electrolyte solution And an open / close module which shields the electrolyte supply part and stops supply of the electrolyte solution from the outside. An electrolyte supply module in which an electrolyte is supplied and flows from the outside through the electrolyte supply portion;
An electrolytic module detachably coupled to the electrolyte supply module and configured to electrolyze the electrolytic solution when electricity is supplied from an external power source to extract hydrogen and oxygen from the electrolytic solution;
A shielding housing detachably coupled to the electrolyte supply module while protecting the electrolysis module and having a hydrogen discharge portion for discharging the hydrogen extracted from the electrolytic solution to the outside; And
The water purifier according to any one of claims 1 to 3, further comprising: a hydrogen discharge unit that is connected to the shielding housing so as to communicate with the hydrogen discharge unit; And a mixing unit for discharging the hydrogen as hydrogen-dissolved water in the purified water,
The purified water flowing from the outside flows through the hydrogen discharge unit and moves by the force for drawing the hydrogen to open the hydrogen discharge unit. When the purified water does not flow, the hydrogen return unit returns to the initial position, And a check valve unit for shielding the discharge portion. The method of claim 2,
The mixing unit includes:
And an outlet for discharging the hydrogen gas is provided at a predetermined interval from the inlet, and the inlet and the outlet are connected to each other to connect the inlet and the outlet, A first mixer body having a mixing flow path formed by mixing and flowing;
A second mixer body which is closely coupled to the first mixer body to shield the mixing channel; And
And a sealing member provided between the first mixer body and the second mixer body to prevent leakage of the purified water and the hydrogen. The method of claim 3,
The mixing unit includes:
And a hydrogen mixing nozzle which is detachably provided at the tip of the mixing passage for adjusting the pressure according to a flow rate of the purified water flowing through the inlet. The method of claim 2,
The electrolyte supply module includes:
A first electrolyte storage part coupled to the electrolytic module and supplying the electrolytic solution supplied from the outside to the electrolytic module; and an electrolytic solution, which is in communication with the first electrolytic solution storage part and flows to the first electrolytic solution storage part, An electrolyte storage container including a second electrolyte storage part to be stored;
A storage container cover detachably coupled to the second electrolyte storage part and having the electrolyte supply part for supplying the electrolyte solution from the outside;
A ball body rotatably hinged to one side of the reservoir cover while being positioned inside the second electrolyte reservoir and floated by buoyancy of the electrolyte when the electrolyte is filled in the second electrolyte reservoir;
And the other end is inserted into the electrolyte supply part. When the ballast body sinks, the electrolyte supply part is opened to supply the electrolyte solution from the outside, and when the ballast body is lifted by the buoyancy of the electrolyte solution And an open / close module which shields the electrolyte supply part and stops supply of the electrolyte solution from the outside. The method according to claim 1 or 5,
The open /
A ball tower shaft having one side connected to the ball tower body and the other side inserted into the electrolyte solution supply unit; And
And a packing member provided at the other end of the ballpoint shaft,
Wherein the opening / closing module reciprocates vertically in conjunction with rotation of the ball-top body. The method according to claim 1 or 5,
In the storage container cover,
And a discharge hole is formed at a position spaced apart from the electrolyte supply part by a predetermined interval, and the upper surface of the storage container cover is provided with a discharge port, which is protruded from the upper surface of the storage container cover at a position coaxial with the discharge hole, An oxygen discharge portion for discharging oxygen to the outside is further formed,
Inside the oxygen discharging portion,
When the oxygen extracted by the electrolytic module flows into the second electrolyte storage part, the oxygen is moved by the pressure higher than the atmospheric pressure inside the second electrolyte storage part to open the oxygen discharge part, And a check valve unit which is moved by a pressure lowered to atmospheric pressure inside the second electrolyte storage part by discharging oxygen inside the storage part to shield the oxygen discharge part. The method of claim 2,
Wherein the shielding housing is provided with a discharge hole penetrating the shielding housing in the width direction,
Wherein the hydrogen discharge unit is protruded from an outer surface of the shielding housing at a position coaxial with the discharge hole, and a hollow communicating with the discharge hole is formed in the hydrogen discharge unit. An electrolyte supply module in which an electrolyte is supplied and flows from the outside through the electrolyte supply portion;
An electrolytic module detachably coupled to the electrolyte supply module and configured to electrolyze the electrolytic solution when electricity is supplied from an external power source to extract hydrogen and oxygen from the electrolytic solution;
A shielding housing detachably coupled to the electrolyte supply module while protecting the electrolysis module and having a hydrogen discharge portion for discharging the hydrogen extracted from the electrolytic solution to the outside; And
And the hydrogen discharged through the hydrogen discharging portion during the inflow of purified water from the outside is introduced into the shielding housing so as to communicate with the hydrogen discharging portion and is dissolved in the purified water, And a hydrogen mixing nozzle for discharging hydrogen,
The purified water flowing from the outside flows through the hydrogen discharge unit and moves by the force for drawing the hydrogen to open the hydrogen discharge unit. When the purified water does not flow, the hydrogen return unit returns to the initial position, A check valve unit for shielding the discharge portion is provided,
Wherein the shielding housing is provided with a discharge hole penetrating the shielding housing in the width direction,
Wherein the hydrogen discharge unit is protruded from an outer surface of the shielding housing at a position coaxial with the discharge hole, and a hollow communicating with the discharge hole is formed in the hydrogen discharge unit. The method according to claim 8 or 9,
The check valve unit is inserted into the hollow,
The check valve unit includes:
An opening / closing shaft having one side in close contact with the discharge hole and shielding the discharge hole or spaced apart from the discharge hole to open the discharge hole;
An elastic member which is provided to surround the other side of the opening and closing shaft and is compressed so that the opening and closing shaft opens the discharge hole by an external force and the opening and closing shaft is pulled to shield the discharge hole when the external force is removed;
A stopper member inserted into the tip of the hydrogen discharge unit and having a flow path through which the hydrogen flows; And
Closing shaft, and a stopper member, the other end of the opening / closing shaft is inserted, the front end of the elastic member is fixed so that the elastic member can be compressed, and the opening / And a flow path member through which the hydrogen flows when being opened. The method of claim 7,
The check valve unit includes:
An opening / closing shaft having one side in close contact with the discharge hole and shielding the discharge hole or spaced apart from the discharge hole to open the discharge hole;
An elastic member which is provided to surround the other side of the opening and closing shaft and is compressed so that the opening and closing shaft opens the discharge hole by an external force and the opening and closing shaft is pulled to shield the discharge hole when the external force is removed;
A stopper member inserted into the tip of the oxygen discharge unit and having a flow path through which the oxygen flows; And
Closing shaft, and a stopper member, the other end of the opening / closing shaft is inserted, the front end of the elastic member is fixed so that the elastic member can be compressed, and the opening / And a flow path member through which the oxygen flows when being opened. The method of claim 4,
Wherein the hydrogen mixing nozzle comprises:
A first body in which purified water externally flows and flows and has a first flow path through which the purified water flows;
A second body extending from a tip of the first body and formed integrally with the first body and having a second flow path communicating with the first flow path; And
And a third body extending from the second body and having a third flow path communicating with the second flow path, the tip end of the third body being connected to the hydrogen discharge unit. The method of claim 12,
Wherein the hydrogen mixing nozzle comprises:
Further comprising a protruding body protruding from the tip of the first body by a predetermined length toward the second flow path,
Wherein the size of the cross-section of the protruding body gradually decreases along the direction in which the purified water flows, so that the outer surface of the protruding body is inclined. The method of claim 4,
Wherein the hydrogen mixing nozzle is disposed between the inflow portion and the hydrogen discharge portion inserted into the first mixer body. The method of claim 4,
Wherein a flow path is formed in the hydrogen mixing nozzle so that the purified water can flow therethrough,
Wherein a size of a cross-sectional surface of the flow path which is parallel to a direction intersecting with the flow direction of the purified water is gradually decreased along a direction in which the purified water flows.

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