KR101972855B1 - A rechargeable hydrogen water generator with waterproof function - Google Patents

Abstract

The present invention relates to a rechargeable hydroxide water generating device with a waterproof function. In the hydroxide water generating device comprising a hydroxide water generator (200) mounted in a detachable manner on a recharging member and charged, the hydroxide water generator comprises: a hollow upper case; a plurality of electrolysis units located inside the upper case; and a plurality of electrolysis unit through holes formed on an upper surface of the upper case. In a state where an upper surface of the electrolysis unit is penetrated through the electrolysis unit through hole and exposed to the upper surface of the upper case, an electrolytic unit O-ring located along an outer circumferential surface of the electrolytic unit at a constant height of the electrolytic unit is in close contact with a stepped portion formed in a stepped shape on an inner surface of the electrolytic unit through hole, or an outer surface of the electrolytic unit and the inner surface of the electrolytic unit through hole (222) is fusion-bonded.

Description

A rechargeable hydrogen water generator with waterproof function

The present invention relates to a rechargeable hydroxide water generator equipped with a waterproof function, in the state that the hydroxide generator charged from the filling member is located in the water, the water is electrolyzed as the upper surface of the electrolysis unit is in contact with the water. The upper surface of the lamp post is exposed to the outside to emit LED light, while the electrolysis unit O-ring is positioned at the point where the electrolytic unit through hole formed in the upper case is in close contact with the lamp pillar formed on the upper case. The lamp pillar O-ring is positioned at the point where the through-hole and the lamp pillar are in close contact with each other, and the waterproof function is maintained. Furthermore, the water can be induced by the flow of bubbles generated by the electrolysis of water in one direction to induce the flow of water. It relates to a hydroxide generator that can be mixed well.

Recently, due to the rapid industrialization, the living environment is deteriorated. As a result, skin disease patients such as children's atopic patients are rapidly increasing, and as the income level increases, interest in skin care is increasing not only for women but also for men. Reflecting this reality, there is a growing interest in a device for improving skin diseases and generating functional water having skin care and sterilization functions.

Hydroxide water refers to water containing a hydroxyl group (OH ⁻ ) in water as the water is electrolyzed.

In the electrolysis device of water, when a voltage is applied to an electrode plate divided into a (-) electrode and a (+) electrode, H ₂ O, which is a water molecule, is decomposed into OH ^- and H ⁺ , and hydrogen (H ₂ ) at the (-) electrode. and a hydroxyl group (OH ^-) will occur (+) poles in the device in which the oxygen (O ₂₎ occurs.

Hydroxide water is known to be useful for treating skin diseases caused by deterioration of the living environment. As the water is electrolyzed, the hydroxyl groups generated by humans come into contact with the skin and enter the pores of the skin. Water is generated by combining with hydrogen cations constituting the cell membrane of the bacteria. As a result, the cell membrane is destroyed, and the bacteria are killed, thereby improving skin diseases.

It looks at the prior art Korea Patent Registration No. 10-1446193.

The prior art relates to an apparatus for generating hydrogen water using an electrode plate, and more specifically, a hydrogen water generating rod for generating hydrogen water by precipitating in a bottle containing a bottle of water or water; A controller having a control unit and a battery accommodating unit for supplying power to the hydrogen water generating rod and controlling hydrogen water generation time; The cable is configured to connect the hydrogen water generating rod and the regulator to apply a power and a control signal to the hydrogen water generating rod to control the electrolysis and the hydrogen generating rod. When soaked in water and applied with electricity, it is possible to drink the hydrogen water produced by electrolysis.In addition, it is stored in a bag or vehicle when traveling and business trip, and then, when needed, it is produced by drinking hydrogen water into a bottle of mineral water. It is possible to provide a hydrogen water generating device using an electrode that can help health regardless of time and place.

However, in the prior art, when considering skin diseases occurring throughout the body, such as atopic dermatitis caused by the deterioration of the living environment, there is a problem that the hydroxide water can not be appropriately applied to a wide range of skin. That is, a hydroxide generator is located in the water, such as a bath is a situation that requires a hydroxide generator that can be applied to a wide range of human skin.

Specifically, when the hydroxide generator needs to be located in the water such as a bath so that the hydroxide water can reach the entire body, the hydroxide water generator according to the prior art has to solve the problem of waterproofing or power supply.

In order to solve the problems according to the prior art described above, it is to provide a rechargeable hydroxide water generator having a waterproof function that can be placed in water such as a bath to generate hydroxide water.

Furthermore, it is an object of the present invention to provide a hydroxide generator that can be distinguished from the position of the hydroxide generator located in the water.

Furthermore, it is an object of the present invention to provide a hydroxide generator capable of affecting the flow of water so that the hydroxyl group can be mixed in a limited range of water in a wide range within a short time.

In the hydroxide generating apparatus according to the present invention to solve the problems according to the prior art described above, in the hydroxide generating apparatus including a hydroxide generator 200 which is mounted and charged in a detachable state to the filling member 100, The hydroxide generator 200, the hollow upper case 220; A plurality of electrolysis units 260 positioned inside the upper case 220; And a plurality of electrolytic unit through holes 222 formed on an upper surface of the upper case 220, and an upper surface of the electrolytic unit 260 penetrates through an electrolytic unit through hole 222 to the upper portion. In the state exposed to the upper surface of the case 220, the electrolytic unit O-ring 264 located along the circumferential surface of the outer surface of the electrolytic unit 260 at a constant height of the electrolytic unit 260 is The inner surface of the decomposition unit through-hole 222 is in close contact with the stepped portion 222a formed in a stepped shape, or the outer surface of the electrolysis unit 260 and the inner surface of the electrolysis unit through-hole 222 Fusion bonding.

Preferably, the hydroxide generator 200 is located inside the upper case 220, a plurality of lamp pillars 280, the LED lamp 282 is located inside; And a plurality of lamp pillar through holes 224 formed on an upper surface of the upper case 220, in a state in which the upper surface of the lamp pillar 280 is exposed to the upper surface of the upper case 220. The lamp pillar o-ring 284 located along the circumferential surface of the lower portion of the lamp pillar 280 is in close contact with the bottom of the lamp pillar through hole 224, or the outer surface of the lamp pillar 280 and the lamp The inner surface of the column through hole 224 is fused.

Preferably, the filling member 100 includes a pogo pin 120 protruding from the upper surface of the filling member 100, the hydroxide generator 200 is the lower end of the upper case 220 A lower case 240 in close contact with the cover; A pin connection terminal 292 having a predetermined height, one end of which is located on a lower surface of the lower case 240; And a connection terminal through-hole 242 formed at a lower surface of the lower case 240 and through which the pin connection terminal 292 penetrates, and the hydroxide generator 200 is connected to the charging member 100. When the pogo pin 120 is in contact with one end of the pin connection terminal 292, the connection terminal O-ring 294 positioned along the circumferential surface of the pin connection terminal 292 is connected to the connection terminal through hole. 242 is in close contact with, or the outer surface of the pin connection terminal 292 and the inner surface of the connection terminal through-hole 242 is fusion-bonded.

Preferably, the USB port 180 is formed on one side of the charging member 100.

Preferably, further comprising a dispersion guide plate 300 located on the upper surface of the upper case 220, the dispersion guide plate 300, a portion corresponding to the upper surface of the electrolysis unit 260 Hydroxide dispersion guide portion 340 formed in a plurality of guide holes 342 in the; And a light distribution guide part 320 of a transparent material formed in a convex shape on a portion corresponding to an upper surface of the lamp pillar 280, and a direction in which the guide hole 342 of a predetermined height penetrates is vertical. Is a direction inclined by a predetermined angle at.

Due to the above-described problem solving means, the hydroxyl groups are generated in a limited capacity of water and the hydroxyl groups are mixed in a wide range within a short time, and in such a state, the hydroxyl groups contained in the water in the situation where the human body is submerged in the water are transferred to the body. As it is in contact with the range, it can be effectively applied to the improvement of skin diseases occurring in the entire range of human skin.

Furthermore, it is possible to check the remaining charge of the battery or to identify the hydroxide generators located in the water, thereby increasing convenience in use.

Furthermore, the flow of bubbles by the oxygen or hydrogen gas generated in the hydroxide generator included in the water may be guided to influence the flow of water, so that the mixing of the hydroxyl groups generated in the hydroxide generator in water may occur. It can be done efficiently.

1 is a view showing a perspective view of a hydroxide generator according to the present invention.
2 is an exploded perspective view of the hydroxide water generator according to the present invention viewed from top to bottom.
3 is an exploded perspective view of a hydroxide water generator according to the present invention viewed from below.
4 is a cross-sectional view of a hydroxide generator according to the present invention.
5 is a view showing a state in which the hydroxide generator is mounted on the filling member in the present invention.
6 is a view showing another embodiment of the dispersion guide plate and the other dispersion guide plate shown in FIG.

Hereinafter, preferred embodiments of the method according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, the definitions of these terms should be made based on the contents throughout the specification.

It demonstrates with reference to FIG.

The hydroxide generator according to the present invention includes a filling member 100, hydroxide generator 200 and the dispersion guide plate (300).

It demonstrates with reference to FIG. 2, FIG. 3, and FIG.

The hydroxide generator 200 is mounted to the filling member 100 to be charged. Electricity is supplied through the power outlet 140, and a voltage is applied through the switch 160.

Inside the portion where the hydroxide generator 200 is mounted is formed a USB port 180 into which the USB cord is inserted while a voltage is applied. Therefore, not only the hydroxide generator but also the smartphone and the like may be charged at the same time in the state where the voltage is applied.

Further, the pogo pin 120 protruding to a predetermined height is positioned on the upper surface of the filling member 100 on which the hydroxide generator 200 is mounted. The pogo pin 120 is in contact with one end of the pin connecting terminal 292 of the hydroxide generator 200, the hydroxide is electrically connected to the pin connecting terminal 292 while the voltage is applied to the charging member 100 A battery (not shown) located inside the generator 200 is charged.

While the hydroxide generator 200 is mounted on the upper surface of the filling member 100, the probe portion of the pogo pin 120 moves downward while being in contact with one end of the pin connecting terminal 292. At one end, the battery is supplied with electricity and charged.

In the state where the pogo pin 120 is located inside the filling member 100, the probe portion of the pogo pin 120 is formed through the pogo pin through hole formed in the upper surface of the filling member 100. One end of the pin connection terminal 292 described above is exposed to the upper surface and the probe portion of the exposed pogo pin 120 is mounted while the hydroxide generator 200 is mounted on the upper surface of the charging member 100.

This will be described with reference to FIGS. 2 to 4.

It will be described the hydroxide generator 200 is mounted on the filling member 100 to be charged.

A battery (not shown) is positioned inside the hydroxide generator 200 to be charged by the charging member 100. The hydroxide generator 200 may be separated from the charging member 100 and positioned in water such as a bath, and water is electrolyzed by an electrolysis unit 260 to which a voltage is applied by a charged battery.

The hydroxide generator 200 includes an upper case 220, a lower case 240, an electrolysis unit 260, and a lamp column 280.

An electrolytic unit through hole 222 through which the electrolytic unit 260 penetrates is formed on an upper surface of the hollow upper case 220. In the state where the electrolysis unit 260 is located inside the upper case 220, the upper surface of the electrolysis unit 260 penetrates through the electrolysis unit through-hole 222 to the upper surface of the upper case 220. Exposed.

On the upper surface of the electrolysis unit 260 exposed to the upper surface of the upper case 220, an electrode plate 262 composed of a negative electrode and a positive electrode is positioned. When the electrode plate 262 is exposed in water, a voltage is applied to the electrode plate 262 to cause electrolysis of water.

The electrolysis unit 260 is located in plurality. Preferably, it may be located in a plurality so as to penetrate the plurality of electrolytic unit through holes 222 formed at regular intervals inside the cylindrical upper case 220 of the hollow.

A portion of the electrolysis unit 260 is positioned inside the upper case 220, and the electrode plate 262 is exposed to the upper surface of the upper case 220. Therefore, while the electrolytic unit through-hole 222 through which the electrolytic unit 260 penetrates and the electrolytic unit 260 are in contact with each other, a waterproof function is required so that water does not penetrate between them.

The electrolytic unit through hole 222 is formed to a predetermined height, and at a predetermined point of the inner surface of the electrolytic unit through hole 222, the stepped portion 222a is formed along the circumferential surface of the inner surface. Is formed.

Electrolysis unit 260 may be a cylindrical having a predetermined height, the electrolytic unit O-ring along the outer circumferential surface of the electrolytic unit 260 at a point of a certain height of the cylindrical electrolysis unit 260 ( 264 may be located.

Accordingly, the electrode plate 262 positioned on the upper surface of the electrolytic unit 260 penetrates through the electrolytic unit through hole 222 and is exposed to the upper surface of the upper case 220. 264 is in close contact with the stepped portion 222a so that water does not flow into the upper case 220 through the electrolytic unit through hole 222.

The electrolysis unit 260 and the electrolysis unit through hole 222 are in close contact with each other so that the waterproof function can be sufficiently exhibited. In order to push up to increase the adhesion with the electrolytic unit through hole 222, a support pillar 245 for supporting the lower surface of the electrolytic unit 260 may be located on the inner surface of the lower case 240.

The support pillar 245 may be a pillar of a material having a strong elastic force. Therefore, in the state in which the upper case 220 and the lower case 240 are coupled, the pressure of the electrolytic unit O-ring 264 may be applied to the stepped portion 222a by the elastic force of the support pillar 245.

Alternatively, a buffer member (not shown) of a flexible material may be positioned between the upper surface of the support pillar 245 and the lower surface of the electrolysis unit 260. As the upper case 220 and the lower case 240 are coupled, the stepped portion 222a and the electrolytic unit O-ring 264 are in close contact with each other, and the upper surface of the first support pillar 245 and the electrolytic unit 260 are in close contact with each other. It is positioned between the lower surface to exert a buffering action and at the same time can increase the adhesion between the step portion 222a and the electrolytic unit O-ring 264 by the elastic force of the buffer member (not shown).

Alternatively, the outer surface and the stepped portion 222a of the electrolysis unit 260 of a constant height of the electrolysis unit 260 without the above-described electrolysis unit O-ring 264 may be directly fusion-bonded to maintain a waterproof function. Of course.

Alternatively, the outer surface of the electrolytic unit 260 having a predetermined height and the inner surface of the electrolytic unit through hole 222 may be directly fusion-bonded without the above-described electrolytic unit O-ring 264, thereby maintaining a waterproof function. Of course.

An RGB LED lamp (not shown) may be positioned inside the electrolysis unit 260. The RGB LED lamp (not shown) is operated in conjunction with the operation of the electrolysis unit 260 in the water to change the color of the light may indicate the amount of battery charge or the residence time of the hydroxyl generator 200 in the water, In addition, even when positioned in the state mounted on the charging member 100 by the bed out of the water can change the color of the light can produce a subtle atmosphere. While the hydroxide generator 200 is mounted on the charging member 100, the operation of the RGB LED lamp (not shown) may be controlled by adjusting the switch 160 of the charging member 100.

In addition to the above-described RGB LED lamp (not shown), the light emitted from the electrode plate 262 as the electrolysis unit 260 is operated in water is also visually harmonized with the light emitted from the RGB LED lamp (not shown). The effect can be increased.

The lamp post 280 is demonstrated.

A plurality of lamp posts 280 are positioned inside the hollow upper case 220. The LED lamp 282 is located inside the lamp post 280. The lamp post 280 is formed at a predetermined height.

A plurality of lamp pillar through holes 224 are formed in the hollow upper case 220, and the lamp pillars 220 are connected to the lamp pillar through holes 224 as the upper case 220 and the lower case 240 are coupled to each other. The upper surface of the lamp pillar 280 is exposed to the upper surface of the upper case 220 as the lamp pillar 280 is penetrated through. LED lamp 282 light is emitted through the upper surface of the lamp post 280 exposed to the upper surface of the upper case 220.

A lamp pillar o-ring 284 may be positioned along a circumferential surface of the lower surface of the lamp pillar 280.

In the state in which the upper surface of the lamp pillar 280 is exposed to the upper surface of the upper case 220, the lamp pillar o-ring 284 is in close contact with the lower end of the lamp pillar through-hole 224 to be waterproof.

A plurality of lamp posts 280 are coupled on the lamp post support plate 286 and positioned upward. Lamp pillar support plate 286 may be a single plate shape integrally formed. In a state where the lamp post 280 is coupled to the lamp post support plate 286, the lamp pillar 280 is electrically connected to a battery (not shown) to emit light from the LED lamp 282 even in water.

The lamp pillar o-ring 284 is positioned at a portion where the lamp pillar 260 and the lamp pillar support plate 286 are coupled to each other. That is, it is formed along the circumferential surface of the lamp post 260 on the lamp post support plate 286. Accordingly, when the lamp pillar o-ring 284 is positioned between the lower end of the lamp pillar through hole 224 and the upper surface of the lamp pillar support plate 286, pressure is applied to the lamp pillar o-ring 284, and the lamp pillar o-ring is While the 284 is compressed, it is in close contact with the bottom of the lamp pillar through hole 224 to be waterproof.

Alternatively, the lower end of the lamp pillar support plate 286 and the lamp pillar through hole 224 coupled to the lower portion of the lamp pillar 280 without the lamp pillar o-ring 284 described above may be fusion-bonded to maintain a waterproof function. Of course.

Alternatively, the outer surface of the lamp pillar 280 and the inner surface of the lamp pillar through hole 224 may be fusion-coupled without the above-described lamp pillar o-ring 284, so that the waterproof function may be maintained.

The intensity or color of light emitted from the LED lamp 282 may be changed. The amount of charge of the battery (not shown) in the water may be represented by the color of light or the time the hydroxide generator 200 stays in the water may be represented by changing the color of the light for each time.

A control unit (not shown) is positioned inside the upper case 220, and the control unit (not shown) may be electrically connected to the LED lamp 282 to change the intensity or color of the light of the LED lamp 282. to be.

In addition, even when sleeping, the hydroxide generator 200 may be located next to the bed, the LED lamp 282 can be adjusted through a control unit (not shown) to emit a soft light so that a person can take a good night's sleep.

The first PCB plate 270 is coupled to the lower surface of the lamp pillar support plate 286 to supply electricity to the LED lamp 282 and the electrolysis unit 260.

The second PCB 290 is positioned below the first PCB 270. The pin connection terminal 292 electrically connected to the pogo pin 120 described above is positioned on the lower surface of the second PCB plate 290, so that the electricity supplied to the pogo pin 120 may be used to supply the second PCB plate 290. It is supplied to the first PCB plate 270 through.

It is coupled to the lower surface of the second PCB plate 290, the pin connecting terminal 292 formed in the downward direction by a predetermined length is coupled.

A connection terminal O-ring 294 surrounding the circumferential surface of the pin connection terminal 292 may be positioned at a portion of the pin connection terminal 292 to which the lower surface of the second PCB plate 290 and the pin connection terminal 292 are coupled. A connection terminal through-hole 242 through which the pin connection terminal 292 penetrates is formed at a lower surface of the lower case 240.

As the hydroxide generator 200 is mounted on the filling member 100, the pogo pin 120 contacts one end of the pin connecting terminal 292, and the connecting terminal O-ring 294 connects to the connecting terminal through-hole 242. It is close to the top of the waterproof. That is, when the lower surface of the second PCB plate 290 and the upper end of the connection terminal through-hole 242 is in close contact with each other, the connection terminal O-ring 294 is positioned between the buffering and waterproofing functions.

Alternatively, the upper surface of the second PCB plate 290 to which the upper portion of the pin connection terminal 292 is directly coupled without the above-described connection terminal O-ring 294 may be fusion-coupled to the upper end of the connection terminal through-hole 242, thereby waterproofing. Of course, the functionality can be maintained.

Alternatively, the outer surface of the pin connection terminal 292 and the inner surface of the connection terminal through-hole 242 may be fusion-coupled directly without the above-described connection terminal O-ring 294, of course, to maintain the waterproof function.

The lower end of the hollow upper case 220 is coupled while being in close contact with the upper surface of the lower case 240. The upper surface of the lower case 240 is formed with a border 246 protruding to a predetermined height, the lower case O-ring 244 may be located out of the border 246 on the upper surface of the lower case 240. . The lower end of the upper case 220 is coupled while being in close contact with the outer surface of the edge 246 of the lower case 240, the lower case between the lower side of the upper case 220 and the outer surface of the edge 246 of the lower case 240 O-ring 244 is positioned to exhibit a waterproof function.

Alternatively, the lower case O-ring 244 described above may immediately be fused and coupled to the lower surface of the upper case 220 and the upper surface of the lower case 240 or the outer surface of the edge 246 to maintain the waterproof function. to be.

The dispersion guide plate 300 is located on the upper surface of the upper case 220. A hollow mounting part 360 protruding downward is formed at the center of the lower surface of the dispersion guide plate 300. Protruding upward from the upper surface of the upper case 220, there is formed a hollow seating portion 226 to which the hollow mounting portion 360 formed on the dispersion guide plate 300 is mounted.

The upper surface of the lamp post 280 is exposed inside the hollow seat 226, so that the light of the LED lamp 282 is emitted through the top surface of the lamp post 280.

In the dispersion guide plate 300, a hydroxide hydroxide dispersion guide part 340 having a plurality of guide holes 342 is formed in a portion corresponding to the upper surface of the plurality of electrolysis units 260, and a plurality of lamps A light dispersion guide part 320 of a transparent material is formed in a convex shape in an upward direction on a portion corresponding to the upper surface of the pillar 280.

Similarly, the upper surface of the dispersion guide plate 300 corresponding to the hollow mounting portion 360 of the dispersion guide plate 300 is similarly formed with a light dispersion guide portion 320 of a transparent material having a convex shape in an upward direction. .

The light dispersion guide part 320 disperses the light emitted from the LED lamp 282. By dispersing the LED light, it can emit a non-irritating LED light in the water or in the bedroom, creating a soft and calm environment. The color or intensity of light emitted as described above may indicate a charge amount of a battery (not shown), a residence time in water, or the like.

A plurality of guide holes 342 are formed in the hydroxide dispersion guide portion 340.

Bubbles by hydrogen or oxygen gas generated as the water is electrolyzed into the guide hole 342 flow. 1 to 3, the guide hole 342 penetrates in the vertical direction. That is, bubbles by hydrogen or oxygen gas electrolyzed at the upper surface of the electrolytic unit 260 flow through the guide hole 342 formed in the vertical direction.

In another embodiment of the guide hole 342 illustrated in FIG. 6, the direction in which the guide hole 342 penetrates is a direction inclined by a predetermined angle in the vertical direction. That is, bubbles generated by electrolysis flow in the lateral direction inclined at a predetermined angle rather than in the vertical direction.

As bubbles generated in the electrode plates 262 of the plurality of electrolysis units 260 all flow in one direction, the flow of these bubbles affects the flow of water in a limited capacity of water (bath, etc.) to be more active. As the flow of water becomes active, the hydroxyl groups generated by electrolysis may be evenly distributed in water along the active water flow in a short time. The hydroxyl group effectively contacts a wide range of submerged skin, thus improving skin diseases.

In the present specification, the present invention has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention. It will be appreciated that embodiments are possible. Therefore, the protection scope of the present invention will be defined by the claims.

100: filling member
120: pogo pin
140: power outlet
160: switch
180: USB port
200: hydroxide generator
220: upper case
222: electrolytic unit through hole
224: lamp pillar through hole
226 seating part
240: lower case
242: connecting terminal through hole
244: lower case o-ring
245 support pillar
246: border
260: electrolysis unit
262: electrode plate
264: electrolysis unit O-ring
270: first PCB version
280: lamp post
282: LED lamp
284: lamp pillar O-ring
286: lamp post support plate
290: 2nd PCB version
292: pin connection terminal
294: connection terminal O-ring
300: dispersion guide plate
320: light dispersion guide portion
340: hydroxide dispersion guide portion
342: guide hole
360: mounting part

Claims (5)

In the hydroxide generator comprising a hydroxide generator 200 is mounted and detachable to the charging member 100,
The hydroxide generator 200, the hollow upper case 220; A plurality of electrolysis units 260 positioned inside the upper case 220; And a plurality of electrolytic unit through holes 222 formed on an upper surface of the upper case 220,
In the state where the upper surface of the electrolytic unit 260 penetrates through the electrolytic unit through hole 222 and is exposed to the upper surface of the upper case 220, the electrolysis unit 260 at a constant height of the electrolytic unit 260 The electrolytic unit O-ring 264 located along the outer circumferential surface of the decomposition unit 260 is in close contact with the inner surface of the electrolytic unit through hole 222, or with the outer surface of the electrolysis unit 260. The inner surface of the electrolytic unit through hole 222 is fusion bonded,
The filling member 100 includes a pogo pin 120 protruding from the upper surface of the filling member 100,
The hydroxide generator 200 is the lower case 240 in close contact with the bottom of the upper case 220; A pin connection terminal 292 having a predetermined height, one end of which is located on a lower surface of the lower case 240; And a connection terminal through-hole 242 formed on a lower surface of the lower case 240 and through which the pin connection terminal 292 penetrates.
The hydroxide generator 200 is mounted to the charging member 100 so that the pogo pin 120 contacts one end of the pin connecting terminal 292, and thus the circumferential surface of the pin connecting terminal 292 is formed. The connection terminal O-ring 294 positioned along the upper surface of the connection terminal through-hole 242 or the outer surface of the pin connection terminal 292 and the inner surface of the connection terminal through-hole 242 are fusion-coupled Hydroxide generator.
The method of claim 1,
The hydroxide generator 200 is located inside the upper case 220, a plurality of lamp pillars 280, the LED lamp 282 is located inside; And a plurality of lamp pillar through holes 224 formed on an upper surface of the upper case 220.
In the state where the upper surface of the lamp pillar 280 is exposed to the upper surface of the upper case 220, the lamp pillar O-ring 284 located along the circumferential surface of the lower portion of the lamp pillar 280 is the lamp pillar Hydroxide generating device is in close contact with the lower end of the through-hole (224), or the outer surface of the lamp pillar 280 and the inner surface of the lamp pillar through hole (224).
delete The method of claim 1,
One side of the charging member 100, the hydroxide port generator USB port 180 is formed.
The method of claim 1,
Further comprising a dispersion guide plate 300 located on the upper surface of the upper case 220,
The dispersion guide plate 300 may include a hydroxide dispersion guide unit 340 formed of a plurality of guide holes 342 in a portion corresponding to an upper surface of the electrolysis unit 260; And a light distribution guide part 320 of a transparent material formed in a convex shape on a portion corresponding to the upper surface of the lamp pillar 280,
The direction in which the guide hole 342 of a predetermined height penetrates is a direction inclined by a predetermined angle in the vertical direction.

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