CN112842034A - Electrolysis hydrogen-rich water cup - Google Patents

Abstract

The invention provides an electrolytic hydrogen-rich water cup, wherein a hydrogen production mechanism and a cup cover are respectively connected to two ends of a cup body. The hydrogen production mechanism comprises a shell, a power supply assembly and a hydrogen production generator. The power supply assembly is arranged in a power supply cavity of the shell, the hydrogen production generator is arranged in an installation cavity of the shell, the exchange membrane is arranged between the anode electrolytic sheet and the cathode electrolytic sheet of the hydrogen production generator, the anode electrolytic sheet and the cathode electrolytic sheet are respectively electrically connected with the power supply assembly, the exchange membrane separates the packaging shell into a hydrogen production cavity and a waste gas cavity, and the hydrogen production cavity is communicated with an external space. The waste discharge structure is arranged on the packaging shell and used for discharging waste gas generated in the waste gas cavity. The electrolytic hydrogen-rich water cup can separate the anode electrolytic sheet from the cathode electrolytic sheet by arranging the exchange membrane, hydrogen generated by the anode electrolytic sheet can enter the cup body, waste gas such as ozone, chlorine and the like generated by the cathode electrolytic sheet is sealed in the waste gas cavity, and in addition, the waste gas in the waste gas cavity can be discharged by arranging the waste discharge structure.

Description

Electrolysis hydrogen-rich water cup

Technical Field

The invention relates to the field of water cups, in particular to an electrolytic hydrogen-rich water cup.

Background

Hydrogen has strong selective antioxidation effect, and can remarkably reduce cerebral infarction caused by cerebral ischemia reperfusion injury. On the other hand, people have higher and higher requirements on drinking water, so that the drinking water is safe, and the people pay more and more attention to the health of the drinking water. Among them, there is a hydrogen-rich water cup on the market, it can make drinking water rich in hydrogen, and hydrogen-rich water can effectively clear away the free radical, makes sub-health problem obtain obviously alleviating to reduce various chronic disease risks, improve the ability of resisting the disease, the healthy vitality when recovering young, hydrogen can hinder the free radical to destroy the cell, can combine with malignant free radical to become nontoxic harmless water and discharge outside the body. However, the hydrogen-rich water cups in the prior art have various small problems due to the uneven comprehensive quality, and particularly, the hydrogen-rich water cups in the prior art cannot well treat waste gas generated in the electrolysis process.

It is therefore desirable to provide an electrolytic hydrogen-rich cup that solves the above problems.

Disclosure of Invention

The invention provides an electrolytic hydrogen-rich water cup, which solves the problem that waste gas generated in the electrolytic process cannot be well treated by the hydrogen-rich water cup in the prior art.

In order to solve the technical problems, the technical scheme of the invention is as follows: an electrolytic hydrogen-rich water cup comprises a cup body, a hydrogen production mechanism and a cup cover, wherein two ends of the cup body are provided with openings, and the hydrogen production mechanism and the cup cover are respectively connected to two ends of the cup body;

the hydrogen production mechanism comprises a shell, a power supply assembly and a hydrogen production generator;

the shell comprises a power supply cavity and an installation cavity which are communicated with each other;

a power supply assembly disposed within the power supply cavity;

the hydrogen production generator is arranged in the mounting cavity and comprises a packaging shell, an anode electrolytic sheet, a cathode electrolytic sheet and an exchange membrane arranged between the anode electrolytic sheet and the cathode electrolytic sheet, the anode electrolytic sheet and the cathode electrolytic sheet are respectively and electrically connected with the power supply assembly, the packaging shell is divided into a hydrogen production cavity and a waste gas cavity by the exchange membrane, and the hydrogen production cavity is communicated with an external space;

and the waste discharge structure is arranged on the packaging shell and used for discharging waste gas generated in the waste gas cavity.

In the invention, the waste discharge structure comprises an air release valve and an exhaust channel, the exhaust channel is arranged in the packaging shell in a penetrating manner, the air release valve is connected to one end, close to the waste gas cavity, of the exhaust channel, and the other end of the exhaust channel is communicated with the outside.

The negative electrode electrolytic sheet is provided with a plurality of negative electrode through holes, the negative electrode electrolytic sheet is close to a gathering groove for gathering waste gas is arranged on one surface of the exchange membrane, and one end of the gathering groove is in butt joint with the air release valve through the communicating groove.

Further, the positive electrode electrolytic sheet, the negative electrode electrolytic sheet and the exchange membrane are relative the radial cross section of the cup body is the slope setting, just the positive electrode electrolytic sheet, the negative electrode electrolytic sheet and the exchange membrane is close to the one end of snuffle valve is higher than the relative other end.

In the invention, the electrolytic hydrogen-enriched water cup also comprises an elastic sealing structure, wherein an output hole for connecting a gas transmission pipe is arranged on the cup cover, and the elastic sealing structure is arranged in the cup cover at a position opposite to the output hole;

the elastic sealing structure comprises a support, a sealing barrel and an elastic piece, the support is fixedly connected to the inner side of the cup cover and opposite to the output hole, a flange used for sealing the output hole is arranged on the side face of the sealing barrel, the first end of the sealing barrel is connected in the output hole in a sliding mode, an opening is formed in the end portion of the first end of the sealing barrel, an air hole is formed in the side face of the first end, the end portion of the second end of the sealing barrel is closed, and the elastic piece is connected between the second end of the sealing barrel and the support and used for extruding the sealing barrel to enable the flange to seal the output hole;

when the gas transmission pipe is clamped in the output hole, the gas transmission pipe extrudes the sealing barrel, so that the flange is far away from the output hole, and the space in the cup cover is communicated with the gas transmission pipe through the vent hole.

Further, the opening part is provided with the first piece of pairing, be provided with the first hole of pairing on the first piece of pairing be provided with on the gas-supply pipe with the first second that pairs the piece and correspond pairs the piece, the second is paired and is provided with the second on the piece and is joined in marriage the hole, the gas-supply pipe rotates the joint and is in the output hole, the gas-supply pipe includes first rotation position and second rotation position on rotating the orbit, works as the gas-supply pipe is located when first rotation position, first pair hole with the second is joined in marriage the hole and is counterpointed, works as the gas-supply pipe is located when the second rotates the position, first pair hole with the second is paired the hole dislocation.

In the invention, a plurality of anode through holes are arranged on the anode electrolytic sheet, and convex rings are arranged on both surfaces of the anode electrolytic sheet.

In the invention, the power supply assembly comprises an electrical appliance box, the electrolytic hydrogen-enriched water cup further comprises a sealing plug and a bottom cover, the bottom cover is used for packaging the electrical appliance box in the installation cavity, a water absorption layer is arranged in the electrical appliance box, a ventilation hole is formed in the bottom cover, a hollow-out cavity is formed in the water absorption layer, the hollow-out cavity is opposite to the ventilation hole, and the sealing plug is connected to the ventilation hole in a sealing mode.

In the invention, two sealing rings are concentrically arranged between the packaging shell and the shell, a first sealing gasket is arranged at the top of the shell, a notch groove is arranged on the periphery of the shell, an external thread used for being connected with the cup body is arranged on the inner side wall of the notch groove, a connecting hole is arranged at the top of the shell, the hydrogen production cavity is communicated with the external space through the connecting hole, an internal thread is arranged on the inner side wall of the connecting hole, and a second sealing gasket is arranged at the inner bottom of the connecting hole.

In the invention, the electrolysis hydrogen-enriched water cup further comprises a connecting piece, and the cup body is connected with the hydrogen production mechanism through the connecting piece.

Compared with the prior art, the invention has the beneficial effects that: the electrolytic hydrogen-rich water cup can separate the anode electrolytic sheet from the cathode electrolytic sheet by arranging the exchange membrane, hydrogen generated by the anode electrolytic sheet can enter the cup body, waste gas such as ozone, chlorine and the like generated by the cathode electrolytic sheet is sealed in the waste gas cavity, and in addition, the waste gas in the waste gas cavity can be discharged by arranging the waste discharge structure.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required in the embodiments are briefly introduced below, and the drawings in the following description are only corresponding to some embodiments of the present invention.

FIG. 1 is a schematic structural diagram of a preferred embodiment of an electrolytic hydrogen-rich water cup of the present invention.

FIG. 2 is a cross-sectional view of a hydrogen production mechanism for electrolyzing a hydrogen-enriched water cup in accordance with the present invention.

FIG. 3 is a schematic view of the structure of a gas release valve of an electrolytic hydrogen-rich water cup of the present invention.

FIG. 4 is a schematic structural view of a cup cover of an electrolytic hydrogen-rich water cup of the present invention.

FIG. 5 is a cross-sectional view of the positive electrolyte sheet of an electrolytic hydrogen-rich water cup of the present invention.

FIG. 6 is a top view of the positive electrolyte sheet of an electrolytic hydrogen-rich water cup of the present invention.

FIG. 7 is a schematic structural diagram of a negative electrode electrolytic sheet for electrolyzing a hydrogen-rich water cup according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the present invention, directional terms such as "up", "down", "front", "back", "left", "right", "inner", "outer", "side", "top" and "bottom" are used only with reference to the orientation of the drawings, and the directional terms are used for illustration and understanding of the present invention, and are not intended to limit the present invention.

The terms "first," "second," and the like in the terms of the invention are used for descriptive purposes only and not for purposes of indication or implication relative importance, nor as a limitation on the order of precedence.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly, e.g., the connection may be a detachable connection or a connection in a unitary structure; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The tap water is sterilized by adding chlorine, the negative electrode electrolytic sheet electrolyzes water molecules to form hydrogen ions in the electrolytic process of the chlorine-containing tap water, the positive electrode electrolytic sheet provides electrons with strong reduction effect, the electrons are combined with the hydrogen ions to generate hydrogen atoms, and the two hydrogen atoms are combined into hydrogen molecules. The strong oxidation effect of the positive electrode electrolysis is mainly to change hydroxide ions into oxygen atoms, two oxygen atoms are combined into oxygen molecules, and the oxygen molecules and the oxygen atoms are combined to form ozone. If the water contains chloride ions, the strong oxidation effect of electrolysis can oxidize the chloride ions into chlorine, the chlorine is dissolved in the water to become hypochlorite, and products such as the chlorine, the ozone and the like can harm the health of people. The hydrogen-rich water cups in the prior art have various small problems due to the uneven comprehensive quality, and particularly the waste gas generated in the electrolysis process cannot be well treated by the hydrogen-rich water cups in the prior art.

The following is a preferred embodiment of an electrolytic hydrogen-rich water cup provided by the present invention to solve the above technical problems.

Referring to fig. 1 and fig. 2, fig. 1 is a schematic structural diagram of a preferred embodiment of an electrolytic hydrogen-rich water cup according to the present invention. FIG. 2 is a cross-sectional view of a hydrogen production mechanism for electrolyzing a hydrogen-enriched water cup in accordance with the present invention.

In the drawings, elements having similar structures are denoted by the same reference numerals.

The invention provides an electrolytic hydrogen-rich water cup which comprises a cup body 11, a hydrogen production mechanism 12 and a cup cover 13, wherein two ends of the cup body 11 are provided with openings, and the hydrogen production mechanism 12 and the cup cover 13 are respectively connected to two ends of the cup body 11.

The hydrogen production mechanism 12 includes a housing 21, a power supply assembly, and a hydrogen production generator, and the housing 21 includes a power supply cavity and an installation cavity that are communicated with each other.

The power supply module is arranged in the power supply cavity and comprises a battery 261, an electrical box 262, a circuit board and various elements electrically connected to the circuit board, the circuit board and the battery are connected to the electrical box 262, the electrolytic hydrogen-enriched water cup further comprises an on-off key 2B, the on-off key 2B is located on the side wall of the shell 21 and is electrically connected to the circuit board, and the hydrogen production mechanism further comprises a charging interface used for charging the power supply module.

The hydrogen generator is arranged in the installation cavity and comprises a packaging shell, an anode electrolytic sheet 221, a cathode electrolytic sheet 222 and an exchange membrane 223 arranged between the anode electrolytic sheet 221 and the cathode electrolytic sheet 222, wherein the anode electrolytic sheet 221 and the cathode electrolytic sheet 222 are respectively electrically connected with the power supply assembly, the packaging shell is divided into a hydrogen production cavity and an exhaust gas cavity by the exchange membrane 223, for example, in fig. 2, the upper space of the anode electrolytic sheet 221 is the hydrogen production cavity, the lower space of the cathode electrolytic sheet 222 is the exhaust gas cavity, and the hydrogen production cavity is communicated with the external space, wherein the packaging shell comprises a packaging upper cover 25 and a packaging lower cover 24, the area of the exchange membrane 223 is larger than the areas of the anode electrolytic sheet 221 and the cathode electrolytic sheet 222, the packaging upper cover 25 and the packaging lower cover 24 clamp and fix the anode electrolytic sheet 221 and the cathode electrolytic sheet 222, and clamp and fix the exchange membrane 223, the structure is stable, and the packaging.

The waste discharge structure is arranged on the packaging shell and used for discharging waste gas generated in the waste gas cavity.

The electrolytic hydrogen-rich water cup of the invention can separate the anode electrolytic sheet 221 and the cathode electrolytic sheet 222 by arranging the exchange membrane 223, water is subjected to electrolytic reaction at the cathode electrolytic sheet 222 to generate hydrogen and oxygen and strongly oxidize chloride ions in the water to form chlorine, wherein the hydrogen can lose electrons at the cathode electrolytic sheet 222 to become hydrogen ions, the hydrogen ions can reach the anode electrolytic sheet 221 through the exchange membrane 223 in a hydration form, the hydrogen ions are recombined at the anode electrolytic sheet 221 to form hydrogen, the oxygen and the chlorine cannot pass through, the hydrogen generated at the anode electrolytic sheet 221 can enter the cup body, the waste gas such as ozone and chlorine generated at the cathode electrolytic sheet 222 is sealed in a waste gas cavity, and in addition, a waste discharge structure is arranged, so the waste gas in the waste gas cavity can be discharged.

Referring to fig. 2, the exhaust structure of the present invention includes an air release valve 271 and an exhaust channel 272, the exhaust channel 272 is penetratingly disposed in the enclosure, the air release valve 271 is connected to one end of the exhaust channel 272 close to the exhaust chamber, and the other end of the exhaust channel 272 is connected to the outside, so that the exhaust gas can be exhausted through the air release valve 271 when the exhaust gas reaches a certain pressure threshold.

The air release valve in this embodiment may be configured as shown in FIG. 3, or a corresponding electrically controlled air release valve may be used. As shown in fig. 3, the relief valve 271 includes a valve housing 31, a valve core 32 slidably disposed in the valve housing 31, one end of the valve core 32 is connected with a baffle 34, the relief valve has a smaller volume, and therefore the baffle 34 should be as large as possible, so that a communication hole 341 is disposed on the baffle 34, the baffle 34 has a larger volume and is slidably connected with the inner wall of the valve housing 31, the right end of the valve housing 31 has a notch for a tooth-shaped structure to allow ventilation, and can be slidably connected with the valve core 32, a spring 33 is disposed between the valve core 32 and the inner wall of the valve housing 31, and the baffle 34 is used for blocking the valve inlet 311 at one end of the valve housing. When the exhaust gas reaches a certain pressure threshold, the flap 34 is pressed to open the valve inlet 311 for exhausting.

Referring to fig. 7, a plurality of negative through holes 2222 are formed in the negative electrode sheet 222 to increase the contact area and improve the electrolysis efficiency, a collecting groove 2221 for collecting the exhaust gas is formed in one surface of the negative electrode sheet 222 close to the exchange membrane 223, and one end of the collecting groove 2221 is in butt joint with the air release valve 271 through a communicating groove 2223 for discharging the exhaust gas. One end of the negative electrode electrolytic sheet 222 is further provided with a negative electrode connection hole 2224 for electrically connecting with a power supply component through a negative electrode copper pillar.

In this embodiment, the positive electrode electrolyte sheet 221, the negative electrode electrolyte sheet 222 and the exchange membrane 223 are disposed in an inclined manner relative to the radial cross section of the cup body 11, and one end of the positive electrode electrolyte sheet 221, the negative electrode electrolyte sheet 222 and the exchange membrane 223 close to the air release valve 271 is higher than the other end, i.e. the right end of the positive electrode electrolyte sheet 221, the negative electrode electrolyte sheet 222 and the exchange membrane 223 is higher than the left end in fig. 2, which is beneficial for the gas to be gathered to the air release valve 271 at the right end.

Referring to fig. 4, the electrolytic hydrogen-enriched water cup in the embodiment further includes an elastic sealing structure, an output hole 131 for connecting a gas pipe is arranged on the cup cover 13, and the elastic sealing structure is arranged in the cup cover 13 at a position opposite to the output hole 131;

the elastic sealing structure comprises a support 132, a sealing cylinder 41 and an elastic piece 42, the support 132 is fixedly connected to the inner side of the cup cover 13 at a position opposite to the output hole 131, a flange 413 for sealing the output hole 131 is arranged on the side surface of the sealing cylinder 41, the first end of the sealing cylinder 41 is connected in the output hole 131 in a sliding mode, the end part of the first end of the sealing cylinder 41 is provided with an opening, the side surface of the first end is provided with a vent hole 411, the end part of the second end is closed, and the elastic piece 42 is connected between the second end of the sealing cylinder 41 and the support 132 and used for squeezing the sealing cylinder 41 to enable;

when the gas pipe 51 is clamped into the output hole 131, the gas outlet pipe presses the sealing barrel 41, so that the flange 413 is far away from the output hole 131, and the space in the cup cover 13 is communicated with the gas pipe 51 through the vent hole 411, so that hydrogen in the water cup can be absorbed through the gas pipe 51.

Further, a first mating piece 412 is disposed at the opening, a first mating hole is disposed on the first mating piece 412, a second matching piece 511 corresponding to the first matching piece 412 is arranged on the air pipe 51, a second matching hole is arranged on the second matching piece 511, the air pipe 51 is rotationally clamped in the output hole 131, the air pipe 51 comprises a first rotating position and a second rotating position on a rotating track, when the air pipe is positioned at the first rotating position, the first matching hole and the second matching hole are aligned, when the air pipe is positioned at the second rotating position, the first matching hole and the second matching hole are staggered, thereby realizing the conduction and the closing of the output hole 131 by rotating the air pipe 51 when the air pipe 51 is connected in the output hole 131, having low cost and convenient operation, the shape and distribution of the first and second pairs of holes may be varied, and may be similar to the shape and distribution of the positive through holes 612 in fig. 6, for example.

Specifically, a clamping groove 133 is formed in the inner wall of the output hole 131, the clamping groove 133 extends in the circumferential direction of the inner wall and has a set length, a convex hull 512 used for being clamped with the clamping groove 133 is arranged on the outer side wall of the air pipe 51, when the air pipe 51 rotates in the output hole 131, the convex hull 512 slides in the clamping groove 133, and the convex hull 512 corresponds to the first rotating position and the second rotating position when sliding to two end points of the clamping groove 133.

The positive electrode electrolyte sheet 221 may have a flat plate shape as shown in fig. 2, or may have a convex-concave structure as shown in fig. 5.

Referring to fig. 5 and 6, the positive electrode sheet 62 is provided with a plurality of positive electrode through holes 612, and the two surfaces of the positive electrode sheet 61 are provided with the protruding rings 611, so that the contact area between the positive electrode sheet 61 and water can be increased, and the electrolysis efficiency can be improved. One end of the positive electrode electrolytic sheet 61 is further provided with a positive electrode electrical connection hole 613 for electrically connecting with a power supply assembly through a positive electrode copper column

Referring to fig. 2, in this embodiment, the electrolytic hydrogen-enriched water cup further includes a sealing plug 2A and a bottom cover 29, the bottom cover 29 is used to encapsulate the electrical appliance box 262 in the installation cavity, a water-absorbing layer 28 is disposed in the electrical appliance box 262, so as to further ensure a dry environment in the electrical appliance box 262, a vent hole is disposed on the bottom cover 29, a hollow-out cavity is disposed in the water-absorbing layer 28, as shown in fig. 2, the hollow-out cavity of the water-absorbing layer 28 is located at the bottom, the hollow-out cavity is opposite to the vent hole, the sealing plug 2A is connected to the vent hole in a sealing manner, and when the sealing.

In the invention, two sealing rings 251 are concentrically arranged between the packaging shell and the shell 21, so that the packaging shell and the shell 21 are in good sealing connection, a first sealing gasket 214 is arranged at the top of the shell 21, a notch 213 is arranged at the periphery of the first sealing gasket, an external thread for connecting with the cup body 11 is arranged on the inner side wall of the notch 213, a connecting hole 211 is arranged at the top of the shell 21, the hydrogen production cavity is communicated with the external space through the connecting hole 211, an internal thread 212 is arranged on the inner side wall of the connecting hole 211, a second sealing gasket 215 is arranged at the inner bottom of the connecting hole 211, the internal thread 212 can be used for being connected with the bottle mouth of a conventional mineral water bottle, and the bottle mouth is in.

In this embodiment, the hydrogen-enriched water electrolysis cup further comprises a connecting piece 14, the cup body 11 and the hydrogen production mechanism 12 are connected through the connecting piece 14, so that different cup bodies 11 and different hydrogen production mechanisms 12 can be conveniently matched for use, and the interchangeability is high.

When the electrolytic hydrogen-rich water cup is used, the hydrogen production mechanism 12 is connected with the cup body 11, drinking water is poured into the cup body, then the hydrogen production mechanism is started by pressing the switch key 2B, the negative electrode electrolytic sheet 222 electrolyzes water molecules to form hydrogen ions, the hydrogen ions can reach the positive electrode electrolytic sheet 221 in a hydration form through the exchange membrane 223, the hydrogen ions are recombined in the positive electrode electrolytic sheet 221 to form hydrogen, oxygen and chlorine cannot pass through the hydrogen ions, the hydrogen generated by the positive electrode electrolytic sheet 221 can enter the cup body, the hydrogen is dissolved in the drinking water to be drunk by a user, waste gases such as ozone and chlorine generated by the negative electrode electrolytic sheet 222 are sealed in a waste gas cavity, and then the waste gases in the waste gas cavity can be discharged through the waste discharge structure.

On the other hand, the user can also suck hydrogen by inserting the gas pipe into the output hole 131.

Thus, the hydrogen production process of electrolyzing the hydrogen-enriched water cup of the preferred embodiment is completed.

The electrolysis hydrogen-rich water cup of this preferred embodiment can separate positive pole electrolysis piece and negative pole electrolysis piece through setting up exchange membrane, can get into the cup body at the hydrogen that positive pole electrolysis piece produced, seals at waste gas intracavity at waste gas such as ozone, chlorine that negative pole electrolysis piece produced, through setting up waste discharge structure in addition to the waste gas in the waste gas intracavity can be discharged.

In summary, although the present invention has been described with reference to the preferred embodiments, the above-described preferred embodiments are not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, therefore, the scope of the present invention shall be determined by the appended claims.

Claims (10)

1. An electrolytic hydrogen-rich water cup is characterized by comprising a cup body, a hydrogen production mechanism and a cup cover, wherein two ends of the cup body are provided with openings, and the hydrogen production mechanism and the cup cover are respectively connected to two ends of the cup body;

the hydrogen production mechanism comprises a shell, a power supply assembly and a hydrogen production generator;

the shell comprises a power supply cavity and an installation cavity which are communicated with each other;

a power supply assembly disposed within the power supply cavity;

the hydrogen production generator is arranged in the mounting cavity and comprises a packaging shell, an anode electrolytic sheet, a cathode electrolytic sheet and an exchange membrane arranged between the anode electrolytic sheet and the cathode electrolytic sheet, the anode electrolytic sheet and the cathode electrolytic sheet are respectively and electrically connected with the power supply assembly, the packaging shell is divided into a hydrogen production cavity and a waste gas cavity by the exchange membrane, and the hydrogen production cavity is communicated with an external space;

and the waste discharge structure is arranged on the packaging shell and used for discharging waste gas generated in the waste gas cavity.

2. The electrolytic hydrogen-rich water cup according to claim 1, wherein the waste discharge structure comprises an air release valve and an air discharge channel, the air discharge channel is arranged in the packaging shell in a penetrating manner, the air release valve is connected to one end of the air discharge channel close to the waste gas cavity, and the other end of the air discharge channel is communicated with the outside.

3. The electrolytic hydrogen-rich water cup according to claim 2, wherein a plurality of negative through holes are arranged on the negative electrolytic sheet, a gathering groove for gathering waste gas is arranged on one surface of the negative electrolytic sheet close to the exchange membrane, and one end of the gathering groove is in butt joint with the gas release valve through a communicating groove.

4. The electrolytic hydrogen-rich water cup according to claim 3, wherein the positive electrode electrolytic sheet, the negative electrode electrolytic sheet and the exchange membrane are disposed in an inclined manner relative to the radial cross section of the cup body, and one end of the positive electrode electrolytic sheet, one end of the negative electrode electrolytic sheet and one end of the exchange membrane close to the gas release valve are higher than the other opposite end.

5. The electrolytic hydrogen-rich water cup according to claim 1, further comprising an elastic sealing structure, wherein an output hole for connecting a gas pipe is arranged on the cup cover, and the elastic sealing structure is arranged in the cup cover at a position opposite to the output hole;

the elastic sealing structure comprises a support, a sealing barrel and an elastic piece, the support is fixedly connected to the inner side of the cup cover and opposite to the output hole, a flange used for sealing the output hole is arranged on the side face of the sealing barrel, the first end of the sealing barrel is connected in the output hole in a sliding mode, an opening is formed in the end portion of the first end of the sealing barrel, an air hole is formed in the side face of the first end, the end portion of the second end of the sealing barrel is closed, and the elastic piece is connected between the second end of the sealing barrel and the support and used for extruding the sealing barrel to enable the flange to seal the output hole;

when the gas transmission pipe is clamped in the output hole, the gas transmission pipe extrudes the sealing barrel, so that the flange is far away from the output hole, and the space in the cup cover is communicated with the gas transmission pipe through the vent hole.

6. The electrolytic hydrogen-rich water cup according to claim 5, wherein a first matching piece is arranged at the opening, a first matching hole is arranged on the first matching piece, a second matching piece corresponding to the first matching piece is arranged on the gas pipe, a second matching hole is arranged on the second matching piece, the gas pipe is rotatably clamped in the output hole, the gas pipe comprises a first rotating position and a second rotating position on a rotating track, when the gas pipe is positioned at the first rotating position, the first matching hole and the second matching hole are aligned, and when the gas pipe is positioned at the second rotating position, the first matching hole and the second matching hole are staggered.

7. The electrolytic hydrogen-rich water cup according to claim 1, wherein a plurality of positive through holes are arranged on the positive electrolytic sheet, and convex rings are arranged on both sides of the positive electrolytic sheet.

8. The electrolytic hydrogen-rich water cup according to claim 1, wherein the power supply module comprises an electrical box, the electrolytic hydrogen-rich water cup further comprises a sealing plug and a bottom cover, the bottom cover is used for packaging the electrical box in the installation cavity, a water absorption layer is arranged in the electrical box, a vent hole is arranged on the bottom cover, a hollow-out cavity is arranged in the water absorption layer, the hollow-out cavity is opposite to the vent hole, and the sealing plug is connected to the vent hole in a sealing manner.

9. The electrolytic hydrogen-rich water cup according to claim 1, wherein two sealing rings are concentrically arranged between the packaging shell and the shell, a first sealing gasket is arranged at the top of the shell, a notch is arranged at the periphery of the shell, an external thread for connecting with the cup body is arranged on the inner side wall of the notch, a connecting hole is formed in the top of the shell, the hydrogen production cavity is communicated with an external space through the connecting hole, an internal thread is arranged on the inner side wall of the connecting hole, and a second sealing gasket is arranged at the inner bottom of the connecting hole.

10. The electrolytic hydrogen-rich water cup according to claim 1, further comprising a connecting member, wherein the cup body and the hydrogen production mechanism are connected through the connecting member.

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