CN219940266U

CN219940266U - Multifunctional hydrogen water cup

Info

Publication number: CN219940266U
Application number: CN202320747297.2U
Authority: CN
Inventors: 李树权; 周华军
Original assignee: Lanxi County Hydrogen Drinking Water Machine Processing Factory
Current assignee: Lanxi County Hydrogen Drinking Water Machine Processing Factory
Priority date: 2023-04-07
Filing date: 2023-04-07
Publication date: 2023-11-03
Anticipated expiration: 2033-04-07

Abstract

The utility model belongs to the field of articles for daily use, and particularly relates to a multifunctional hydrogen water cup. It comprises the following steps: the water cup comprises a cup barrel body, a cup base and a cup cover, wherein the cup base and the cup barrel body form a cup body for containing water; the upper end and the lower end of the cup barrel body are both provided with openings, the upper end opening is detachably arranged with the cup cover, and the lower end opening is detachably and hermetically connected with the cup base; a PEM water electrolysis assembly, a switch controller and a power supply are arranged in the cup base; a suction pipe is arranged in the cup body; the suction pipe is provided with an atomization component and/or a gas-liquid separation component. The utility model firstly realizes the function diversification of the hydrogen water cup through the structure adjustment, and on the basis, the structure of the existing PEM electrolytic water assembly is improved, thereby realizing the effective and thorough hydrogen-oxygen separation, improving the quality of the hydrogen water and effectively utilizing the generated hydrogen and oxygen.

Description

Multifunctional hydrogen water cup

Technical Field

The utility model belongs to the field of articles for daily use, and particularly relates to a multifunctional hydrogen water cup.

Background

Hydrogen-rich water, also known as plain water, is water in which a certain amount of hydrogen is dissolved. It has certain health care effect on human body, and is usually prepared by an electrolysis technology, and the water is small molecular group water rich in hydrogen molecules. Hydrogen water may have a certain effect on scavenging free radicals and promoting cell health, and thus has a certain benefit on whitening. And the hydrogen water is alkaline, which is favorable for maintaining the acid-base constitution of the body to a certain extent, maintaining the balance of the internal environment and possibly helping to repair the metabolic function. Part of electrolyte can be supplemented after long-term drinking of hydrogen water. In addition, the hydrogen water can increase the sensitivity of calcium ions to a certain extent, and has a certain promotion effect on the absorption of calcium. Therefore, proper drinking of hydrogen water is beneficial to human body.

Currently, most hydrogen water is relatively expensive only by purchasing packaged, finished bottled water, and its actual hydrogen content is relatively low due to hydrogen solubility issues. For this reason, home-type hydrogen water machines, hydrogen water cups, and the like have been developed in the market, which can produce hydrogen water by a small-sized water electrolysis apparatus. However, most hydrogen water machines and hydrogen water cups are difficult to effectively realize hydrogen-oxygen separation especially in the field of hydrogen water cups, and the functions of the hydrogen water cups are relatively single, so that diversified experience and use of users cannot be effectively met. Such as being unable to be used for hydrogen absorption or hydrogen water atomization, etc.

Disclosure of Invention

The utility model provides a multifunctional hydrogen water cup, which aims to solve the problems that the existing hydrogen water cup is single in function, cannot meet diversified use requirements, is poor in hydrogen-oxygen separation effect, and contains a large amount of oxygen in the actually obtained hydrogen water.

The main purpose of the utility model is that:

1. realizing the functional improvement of the hydrogen cup;

2. the oxyhydrogen separation can be effectively realized;

3. high quality hydrogen water can be obtained.

In order to achieve the above purpose, the present utility model adopts the following technical scheme.

A multi-functional hydrogen water cup comprising:

the water cup comprises a cup barrel body, a cup base and a cup cover, wherein the cup base and the cup barrel body form a cup body for containing water;

the upper end and the lower end of the cup barrel body are both provided with openings, the upper end opening is detachably arranged with the cup cover, and the lower end opening is detachably and hermetically connected with the cup base;

a PEM water electrolysis assembly, a switch controller and a power supply are arranged in the cup base;

a suction pipe is arranged in the cup body;

the suction pipe and/or the cup cover are/is provided with an atomization component and/or a gas-liquid separation component.

As a preferred alternative to this,

the suction pipe extends from the upper end of the cup cover to the cup barrel body below the cup cover, and the top end of the cup cover is provided with a dust cover which can be opened and closed.

As a preferred alternative to this,

the atomizing assembly and/or the gas-liquid separation assembly are directly formed on the suction pipe and/or the cup cover or can be detachably arranged on the suction pipe and/or the cup cover.

As a preferred alternative to this,

the PEM electrolyzed water assembly comprises a sealing carrier plate, wherein the sealing carrier plate is provided with an electrode mounting groove, an electrode assembly is arranged in the electrode mounting groove, the electrode assembly is hermetically arranged in the electrode mounting groove, and a cathode, a proton membrane and an anode are sequentially stacked from top to bottom;

the sealing carrier plate is provided with a conical hole, the aperture of the conical hole is small at the upper part and big at the lower part, the sealing floating ball is limited to break away from the conical hole by inwards turning, and the sealing floating ball can move upwards under the action of buoyancy to realize the plugging of the conical hole.

As a preferred alternative to this,

the PEM water electrolysis assembly further comprises a separation plate and a water blocking side plate, wherein the separation plate is vertical, a rib plate is arranged on the outer side of the separation plate, the rib plate is connected to the inner wall of the cup base and is in sealing contact and fixedly connected with the inner surface of the cup base, the space in the cup base is divided into two mutually isolated parts, the water blocking side plate for sealing and sealing the upper end of the space is arranged at the upper end of one part of the space, and a sealing carrier plate is arranged at the upper side of the other side of the space for sealing;

the electrode mounting groove is obliquely arranged, one end close to the separation plate is higher than one end far away from the separation plate, and the conical hole is formed in one end, far away from the separation plate, of the sealing carrier plate.

As a preferred alternative to this,

the upper end of the separator is provided with a hydrogen dissolver which is arranged right above the electrode assembly

As a preferred alternative to this,

the cup base is provided with an air outlet hole, and a one-way dredging film is arranged in the air outlet hole

The beneficial effects of the utility model are as follows:

the utility model firstly realizes the function diversification of the hydrogen water cup through the structure adjustment, and on the basis, the structure of the existing PEM electrolytic water assembly is improved, thereby realizing the effective and thorough hydrogen-oxygen separation, improving the quality of the hydrogen water and effectively utilizing the generated oxygen.

Drawings

FIG. 1 is a schematic diagram of the structure of a multifunctional hydrogen water cup of the present utility model;

FIG. 2 is a schematic view of the structure of the base of the multifunctional hydrogen water cup of the present utility model;

FIG. 3 is a schematic view of the axial structure of the base of the multifunctional hydrogen water cup of the present utility model;

FIG. 4 is a schematic view of a semi-sectional axial side structure of a cup base in the multifunctional hydrogen water cup of the present utility model;

FIG. 5 is a schematic diagram of the exploded construction of a PEM electrolyzed water assembly of the base of the multi-functional hydrogen water cup of the present utility model;

FIG. 6 is a schematic diagram of an improved structure of the multifunctional hydrogen water cup of the present utility model;

FIG. 7 is a partial perspective view of the top end of the suction tube of FIG. 6;

FIG. 8 is a second schematic diagram of the improved structure of the multifunctional hydrogen water cup of the present utility model;

FIG. 9 is a schematic diagram of two hydrogen absorbing structures of the multifunctional hydrogen water cup of the present utility model;

FIG. 10 is a schematic diagram of the hydrogen absorption process assistance of the two schematic diagrams of the hydrogen absorption structure shown in FIG. 9;

FIG. 11 is a schematic view of another hydrogen absorbing structure of the multi-functional hydrogen cup of the present utility model;

in the figure: 100 cup bases, 101PEM electrolytic water components, 1011 separation plates, 10111 water passing channels, 10112 hydrogen dissolvers, 10113 rib plates, 1012 sealing carrier plates, 10121 conical holes, 10122 sealing floating balls, 1013 electrode components, 10131 cathodes, 10132 anodes, 10133 proton membranes, 102 switching controllers, 1021 switching keys, 103 power supplies, 1031 battery covers, 104 capillary pore plates, 105 water separation plates, 106 air outlet holes, 107 water blocking side plates, 200 cup barrels, 300 cup covers, 301 suction pipes, 3011 atomization plugs, 302 dust covers, 304 gas-liquid separation plugs and 3041 gas-liquid separation membranes.

Detailed Description

The utility model is described in further detail below with reference to specific examples and figures of the specification. Those of ordinary skill in the art will be able to implement the utility model based on these descriptions. In addition, the embodiments of the present utility model referred to in the following description are typically only some, but not all, embodiments of the present utility model. Therefore, all other embodiments, which can be made by one of ordinary skill in the art without undue burden, are intended to be within the scope of the present utility model, based on the embodiments of the present utility model.

In the description of the present utility model, it should be understood that the terms "thickness," "upper," "lower," "horizontal," "top," "bottom," "inner," "outer," "circumferential," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the present utility model. In the description of the present utility model, the meaning of "a plurality" means at least two, for example, two, three, etc., unless explicitly defined otherwise, the meaning of "a number" means one or more.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Examples

A multifunctional hydrogen water cup as shown in fig. 1, which specifically comprises:

the cup comprises a cup barrel 200, a cup base 100 and a cup cover 300, wherein the cup base 100 is of a barrel-shaped structure;

the upper end and the lower end of the cup barrel body 200 are both opened, the upper end opening is detachably arranged with the cup cover 300, the cup cover 300 can be used for closing the upper cup cover 300 of the cup barrel body 200, and the cup cover 300 and the cup barrel body 200 are connected through threads in the embodiment;

the lower end opening of the cup barrel 200 is detachably and hermetically connected with the cup base 100, specifically, the cup base 100 is used for sealing the lower end opening of the cup barrel 200 and forms a cup body for containing water together with the cup barrel 200;

the cup base 100 is internally provided with a PEM water electrolysis assembly 101, a switch controller 102 and a power supply 103, wherein the power supply 103 is electrically connected with the switch controller 102 to supply power to the PEM water electrolysis assembly 101, and the switch controller 102 is electrically connected with the PEM water electrolysis assembly 101 and is communicated by waterproof wires;

the power supply 103 is a fixed storage battery or a detachable primary or secondary battery, and the power supply 103 used in the embodiment is a detachable primary battery and a corresponding battery cover 1031 is arranged on the cup base 100;

the cup base 100 is also provided with a water-stop plate 105, the water-stop plate 105 is used for realizing water-stop of the switch controller 102 and the power supply 103, as in the embodiment, a first water-stop plate 105 is arranged above the power supply 103, the switch controller 102 is arranged on the water-stop plate 105, the switch controller 102 is also provided with a second water-stop plate 105, and the two water-stop plates 105 are used for water-stop the switch controller 102 and the power supply 103, so that the problems of humidity, electric leakage and the like are avoided;

the outer side of the cup base 100 is also provided with a switch button 1021, the switch button 1021 is electrically connected with the switch controller 102 by adopting a waterproof wire, and the switch button 1021 is used for controlling the switch controller 102 and controlling whether the power supply 103 supplies power to the PEM water electrolysis assembly 101 so as to enable the PEM water electrolysis assembly to work;

in the above-described structure, the first and second heat exchangers,

after the PEM electrolyzed water assembly 101 is electrified, water contained in the cup body is electrolyzed to produce hydrogen, so that the water body is converted into hydrogen-rich water.

Further, the method comprises the steps of,

the PEM electrolyzed water assembly 101 comprises a sealing carrier plate 1012, wherein the sealing carrier plate 1012 is provided with an electrode installation groove which is communicated up and down, an electrode assembly 1013 is arranged in the electrode installation groove, the electrode assembly 1013 is sequentially stacked with a cathode 10131, a proton membrane 10133 and an anode 10132 from top to bottom, the electrode assembly 1013 forms a sealing on the electrode installation groove, so that the sealing carrier plate 1012 and the electrode assembly 1013 realize the effect of sealing against water, and the sealing carrier plate is divided into an upper space and a lower space which are isolated from each other;

the sealing carrier plate 1012 is provided with a conical hole 10121 which is communicated up and down, the aperture of the conical hole 10121 is small at the upper part and big at the lower end opening part, the conical hole is turned inwards and tightened to form an annular plate, the annular plate is used for restraining a sealing floating ball 10122 arranged in the annular plate, the sealing floating ball 10122 can move up and down in the conical hole 10121 under restraint and cannot be separated from the conical hole 10121, and the sealing floating ball 10122 can move upwards under the buoyancy effect to realize the blocking of the conical hole 10121;

the cup base 100 is provided with an air outlet hole 106, the air outlet hole 106 is communicated to a space below the motor assembly, and a one-way dredging film is arranged in the air outlet hole 106 and used for reducing water overflow and allowing air to pass through;

after the cup base 100 and the cup barrel 200 are connected and installed, pouring drinking water into the formed cup body, enabling the drinking water to flow to a space below the sealing carrier plate 1012 through the conical hole 10121, enabling the sealing floating ball 10122 to plug the conical hole 10121 after the water level below the sealing carrier plate 1012 rises, controlling the liquid level below the sealing carrier plate 1012, starting the switch controller 102 through the switch button 1021, enabling the power supply 103 to supply power so that the PEM electrolytic water assembly 101 starts to work, enabling a water body below the sealing carrier plate 1012 to lose electrons to form hydrogen ions and oxygen molecules, enabling the oxygen molecules to escape through the air outlet hole 106, enabling the hydrogen ions to form hydrogen in the water body above the sealing carrier plate 1012 through the proton membrane 10133 and the cathode 10131, and enabling the hydrogen to be dissolved in water so as to enable the drinking water to be converted into hydrogen-rich water;

specifically, when the PEM electrolyzed water assembly 101 is in use, if a user has a certain requirement for oxygen, such as a daily oxygen inhalation requirement of a part of users, the oxygen inhalation tube can be connected to the gas storage bottle through the gas outlet hole 106 alone or through a pipeline, so as to collect, use, recover and store the high-purity oxygen generated by the PEM electrolyzed water assembly 101.

In the structure, due to the exhaust problem, the one-way dredging film is easy to damage or pollute and block, water leakage, unsmooth exhaust and even accumulation formation of a high-pressure oxygen environment are caused, and the replacement of the one-way dredging film is generally complicated, so that the scheme is further improved;

as shown in fig. 2, 3, 4 and 5, the specific PEM electrolyzed water assembly 101 further includes a partition plate 1011 and a water blocking side plate 107, the partition plate 1011 is vertically and fixedly disposed at the upper end of the water stop plate 105, in this embodiment, the partition plate 1011 is disposed at the upper end of the second water stop plate 105, and the outer side thereof is provided with a rib 10113, the rib 10113 is connected to the inner wall of the cup base 100 and is fixedly connected with the inner surface of the cup base 100 in a sealing contact manner, so as to divide the space in the cup base 100 into two mutually isolated parts, wherein a part of the upper space end is provided with the water blocking side plate 107 for sealing and closing the part of the upper space end, and the other side upper sides of the partition plate 1011 and the rib 10113 are provided with a sealing carrier plate 1012 for closing, the electrode mounting groove is obliquely disposed, the end close to the partition plate 1011 is higher than the end far from the partition plate 1011, and the embedded electrode assembly 1013 is also obliquely disposed due to the structural characteristics of the electrode mounting groove, i.e. the end close to the partition plate 1011 is higher than the end far from the partition plate 1011, and the tapered hole 10121 is disposed at the end far from the partition plate 1011;

the lower end of the partition board 1011 is provided with a water passing channel 10111, the water passing channel 10111 is still closed up and down, the water passing channel 10111 is formed by a water blocking side plate 107, the partition board 1011, a rib plate 10113, a sealing carrier plate 1012 and an electrode assembly 1013 arranged on the sealing carrier plate 1012, which are mutually isolated, and only a circulation channel of a conical hole 10121 is arranged, in the improved scheme, an air outlet hole 106 is arranged below the water blocking side plate 107 and is higher than the liquid sealing water level of the conical hole 10121, and the liquid sealing water level is the water level of the sealing floating ball 10122 floating up to seal the conical hole 10121 under the action of water buoyancy;

the capillary orifice plate 104 attached to the inner wall of the cup base 100 and the side wall of the partition plate 1011 is arranged below the water blocking side plate 107, the top end of the capillary orifice plate 104 is lower than the air outlet hole 106, and the bottom end is higher than the liquid sealing water level, the effect achieved by the actual capillary orifice plate 104 is that a certain sealing effect is formed above the space on one side where the water blocking side plate 107 is arranged after the partition plate 1011 is separated, the sealing effect is not absolute sealing, but the problem of water leakage occurs under the condition that water is filled and toppled in the whole multifunctional hydrogen cup, and meanwhile, oxygen can be supplied to realize gas exchange, unlike the scheme before improvement, the structural stability of the capillary orifice plate 104 is far higher than that of a unidirectional dredging film, the cost is lower, the rate of water flowing through capillary pores is extremely low, the water leakage occurrence is not easy to form, on the other hand, through the cooperation with the structure after improvement, the capillary orifice plate 104 is not in direct contact with the water in the normal use process of the multifunctional hydrogen cup, the service life is not easy to be generated, the oxygen generated in the space below the electrolytic water assembly 101 is convenient to discharge, the certain high-pressure water blocking effect can be formed, but the water scale production effect is similar to the scheme before improvement, and the water production principle is obvious.

Further, the method comprises the steps of,

the upper end of division board 1011 is equipped with the hydrogen dissolving ware 10112, and hydrogen dissolving ware 10112 sets up directly over electrode assembly 1013, hydrogen dissolving ware 10112 is the perforated plate body, and the contact time of hydrogen and water can be prolonged to the setting of perforated plate body, improves the dissolution effect of hydrogen.

And yet further still, the process is carried out,

the utility model improves the use mode of the multifunctional hydrogen water cup and is embodied in the structure;

as shown in fig. 6, a part of a cup cover 300 is provided with a suction pipe 301 fixedly connected with the part, the suction pipe 301 extends into a cup barrel body 200 below the cup cover 300 from the upper end of the cup cover 300, when the cup is used, water in the cup barrel body 200 can be sucked through the suction pipe 301, and the top end of the cup cover 300 is provided with a dust cover 302 which can be opened and closed;

the top end of the suction pipe 301 is also provided with an atomization assembly, and the atomization assembly can be any conventional atomization assembly applicable to the technical scheme of the utility model;

specifically, as shown in fig. 7, the atomization component used in the embodiment is an atomization plug 3011, and an atomization flow channel is arranged in the atomization plug 3011, so that atomization of liquid can be realized, and when a user sucks hydrogen-rich water through the suction pipe 301, the hydrogen-rich water can form hydrogen-rich water mist through the atomization plug 3011;

in addition, besides the passive atomization mode, the mode that a user actively absorbs hydrogen water to realize atomization through the atomization plug 3011 can be used together with other conventional atomization structures, such as a detachable atomization plug 3011 or an active atomization mode;

the active atomization mode is also very easy to realize, for example, the small electric lifting device or the small electric heating device can be adopted, for example, the small electric lifting device can be a micro pump, such as a tested Hilingec C13 micro pump, and is arranged in the cup cover, the arrangement mode can refer to the arrangement mode of a PEM electrolytic water component in the cup seat, after the arrangement, the hydrogen water is lifted upwards by the suction pipe 301, and after the upper end of the suction pipe 301 is also provided with the atomization plug 30111, the lifted hydrogen-rich water can realize atomization spraying, thereby realizing active atomization, improving the use effect and the use field, and when the small electric heating device is adopted for realizing, for example, a small electric heating rod is arranged in the suction pipe, the hydrogen-rich water in the suction pipe 301 is heated and gasified, and then condensed and atomized through the atomization plug 3011, and the two active atomization (lifting atomization and heating atomization) are also commonly arranged in equipment such as a humidifier, and have no difficulty in technology, and realize the technical effect, and save labor force due to the fact that the repeated operation is not needed;

in addition, as shown in fig. 8, the suction pipe 301 is adaptively provided with a gas-liquid separation component, and the gas-liquid separation component can adopt a conventional unidirectional dredging film and the like for realizing gas-liquid separation, so that a user can drink hydrogen-rich water and obtain hydrogen-rich atomized water, and can directly absorb hydrogen, the embodiment specifically adopts a gas-liquid separation plug 304, the gas-liquid separation plug 304 is sleeved at the top end of the suction pipe 301, and the unidirectional dredging film is adopted as a gas-liquid separation film 3041 in the gas-liquid separation plug, and the unidirectional dredging film can realize gas-liquid separation to a certain extent, so that the user directly absorbs hydrogen;

specifically, as shown in fig. 9, in addition to the above-mentioned adoption of the gas-liquid separation membrane 3041 as a unidirectional dredging membrane as shown in fig. 8 and 9, the adoption of a short tube or a hose as a suction tube 301 can also be realized as shown in the right diagram of fig. 9, so that the lower end inlet of the short tube or the hose is higher than the liquid level and is separated from the liquid level, and the surplus hydrogen above the liquid level in the cup body can be directly sucked to meet the hydrogen sucking requirement of a user, the scheme shown in the right diagram of fig. 9 can be adopted to suck the hydrogen more quickly and efficiently, and the short tube or the hose should extend into the cup cover 300 to avoid extending into the cup body 200 when the arrangement mode is adopted, namely, the short tube or the hose is prevented from extending into the cup body 200 as shown in the right diagram of fig. 9, and the length of the suction tube is controlled, so that the multifunctional hydrogen water cup can be further conveniently used, and the liquid level of the multifunctional hydrogen water cup is not higher than the cup 200 when the water is used, so that the lower end inlet is positioned in the cup body 300 or the cup body is not required to be used as a suction tube 301, and the user can install the suction tube 300 with the water in the cup body or the cup body;

as shown in fig. 10, the left and right diagrams respectively correspond to the left and right diagrams in fig. 9, and respectively illustrate the hydrogen absorbing process of the two arrangement modes in fig. 9, as shown in fig. 10, since the suction pipe 301 extends below the liquid level, and the upper end of the suction pipe 301 is provided with the gas-liquid separation membrane 3041, when hydrogen is absorbed, hydrogen dissolved in water is absorbed, and the absorption of the hydrogen is realized through one-way dredging membrane gas-liquid separation, the arrangement mode is convenient for a user to absorb hydrogen and drink hydrogen, only the gas-liquid separation plug 304 is required to be disassembled, the suction pipe 301 can be conveniently taken down to drink hydrogen, and the suction pipe can be assembled, and the dual-purpose conversion efficiency is high, as shown in the right diagram in fig. 9 and the right diagram in fig. 10, when a short pipe or a hose with the lower end positioned in the cup cover 300 is adopted as the suction pipe 301, the hydrogen in the cavity of the container is mainly absorbed, namely the hydrogen is directly absorbed, at the moment, the gas-liquid separation membrane 3041 is also arranged at a position lower than the lower end of the suction pipe in fig. 11, so that the convenience is improved, and the portable hydrogen absorbing effect is realized when the suction pipe is not required to drink hydrogen through the cup cover;

specifically, the atomization component and the gas-liquid separation component used in the utility model can be directly formed on the suction pipe 301, and can also be installed on the suction pipe 301 by adopting a detachable component as in the embodiment, the multifunctional hydrogen water cup can meet the use requirements of users on multiple aspects such as hydrogen water, hydrogen absorption, hydrogen atomization and the like, has good structural stability and use effect, is far superior to the existing hydrogen water cup on the market, and can simultaneously meet the three requirements of users on drinking hydrogen water, obtaining hydrogen-rich atomized water and directly absorbing hydrogen through the cooperation of the components, can additionally and effectively utilize oxygen, and has the characteristic of multifunctionalization.

The above description is only a preferred embodiment of the present utility model, and the protection scope of the present utility model is not limited to the above examples, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. It should be noted that modifications and adaptations to the present utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims

1. A multi-functional hydrogen water cup, comprising:

a suction pipe is arranged in the cup body;

2. A multi-functional hydrogen water cup according to claim 1, wherein,

3. A multi-functional hydrogen water cup according to claim 1 or 2, wherein,

4. A multi-functional hydrogen water cup according to claim 1, wherein,

5. A multi-functional hydrogen water cup according to claim 4, wherein,

6. A multi-functional hydrogen water cup according to claim 5, wherein,

the upper end of the separator is provided with a hydrogen dissolver which is arranged right above the electrode assembly.

7. The multifunctional hydrogen water cup according to claim 1, wherein the cup base is provided with an air outlet hole, and a one-way dredging film is arranged in the air outlet hole.