CN219289164U - Hydrogen-rich water cup - Google Patents

Abstract

The utility model relates to a hydrogen-rich water cup. The hydrogen-rich water cup comprises: the cup body forms a hollow through cavity; the cup cover is arranged at the top of the cup body and is detachably connected with the cup body; the base is arranged at the bottom of the cup body and is detachably connected with the cup body; when the cup cover is arranged on the cup body, the cup cover, the cup body and the base form a closed space; the pressure sensor is arranged on the base and is used for monitoring the pressure of the closed space; the electrolyzer is arranged on the base, the surface of the electrolyzer is directly communicated with the hollow through cavity of the cup body and is used for electrolyzing water in the cup body to generate hydrogen; the battery is connected with the electrolyzer and is used for supplying power to the electrolyzer; the input end of the controller is connected with the pressure sensor, and the first control end of the controller is connected with the battery; the controller is used for reducing the current output by the battery to the electrolyzer under the condition that the pressure of the closed space is larger than a preset pressure threshold value. The hydrogen content in the hydrogen-rich water can be improved by using the hydrogen-rich water cup.

Description

Hydrogen-rich water cup

Technical Field

The utility model relates to the technical field of electrolysis, in particular to a hydrogen-rich water cup.

Background

A hydrogen-rich water cup is a cup that electrolyzes water by an electrolyzer to generate hydrogen gas, thereby increasing the concentration of hydrogen content in the water, but how to generate water with a high concentration of hydrogen content remains a difficult problem.

At present, a mechanical pressure switch is mostly adopted to control the on-off of an electrolyzer in a hydrogen-rich water cup so as to improve the hydrogen content concentration in the water in the cup as much as possible, but the hydrogen concentration of water produced by adopting the method is limited.

Disclosure of Invention

Based on this, it is necessary to provide a hydrogen-rich water cup that can increase the hydrogen concentration in water.

A hydrogen-enriched water cup comprising:

the cup body forms a hollow through cavity;

the cup cover is arranged at the top of the cup body and is detachably connected with the cup body;

the base is arranged at the bottom of the cup body and is detachably connected with the cup body; when the cup cover is arranged on the cup body, the cup cover, the cup body and the base form a closed space;

the pressure sensor is arranged on the base and is used for monitoring the pressure of the closed space;

the electrolyzer is arranged on the base, and the surface of the electrolyzer is directly communicated with the hollow through cavity of the cup body; the electrolyzer is used for electrolyzing water in the cup body to generate hydrogen;

the battery is connected with the electrolyzer and is used for supplying power to the electrolyzer;

the input end of the controller is connected with the pressure sensor, and the first control end of the controller is connected with the battery; the controller is used for reducing the current output by the battery to the electrolyzer under the condition that the pressure of the closed space is larger than a preset pressure threshold value.

In one embodiment, an electrolyzer includes:

the cathode platinum electrolysis piece is directly communicated with the hollow through cavity of the cup body, and the input end of the cathode platinum electrolysis piece is connected with the negative electrode of the battery;

the anode platinum electrolyte sheet is arranged at one side far away from the cup cover compared with the cathode platinum electrolyte sheet, and is connected with the anode of the battery; when the anode platinum electrolyte sheet and the cathode platinum electrolyte sheet are electrified, the electrolyzed water generates hydrogen and oxygen.

In one embodiment, the electrolyzer further comprises:

the adsorption module is positioned at one side of the anode platinum electrolyte sheet far away from the cathode platinum electrolyte sheet; the adsorption module is used for adsorbing impurities generated in the electrolysis process, wherein the impurities refer to substances except hydrogen and oxygen.

In one embodiment, the electrolyzer further comprises:

the proton exchange membrane is positioned between the cathode platinum electrolyte sheet and the anode platinum electrolyte sheet; the proton exchange membrane is used for isolating hydrogen and oxygen generated in the electrolysis process.

In one embodiment, the base further comprises a housing, the side, far away from the cup cover, of the housing is provided with an exhaust hole, the anode platinum electrolyte sheet is arranged in a containing cavity formed by the housing, close to the exhaust hole, and the anode platinum electrolyte sheet is communicated with the outside air through the exhaust hole.

In one embodiment, the method further comprises:

the touch control display screen is arranged on the outer wall of the base and is connected with the output end of the controller; the touch display screen is used for displaying the pressure value of the closed space.

In one embodiment, the method further comprises:

the indicator lamp is arranged on the outer wall of the base and is connected with the second control end of the controller; the indicator lamp is used for displaying the pressure condition of the closed space under the control of the controller.

In one embodiment, the method further comprises:

the switch key is arranged on the outer wall of the base and is used for being connected in series on a common power supply loop of the battery to the controller and the electrolyzer; when the switch key is in the first state, the battery supplies power to the controller and the electrolyzer, and when the switch key is in the second state, the battery stops supplying power to the controller and the electrolyzer.

In one embodiment, the method further comprises:

the charging interface is arranged on the outer wall of the base and is connected with the battery.

In one embodiment, the preset pressure threshold is 0.2 mpa, and the controller is configured to reduce the current output from the battery to the electrolyzer if the pressure in the enclosed space is greater than 0.2 mpa.

According to the hydrogen-rich water cup, the pressure in the hydrogen-rich water cup is monitored through the pressure sensor, and under the condition that the pressure value in the hydrogen-rich water cup is larger than the preset pressure threshold value, the current output from the battery to the electrolyzer is reduced, so that the generation amount of hydrogen is reduced, the pressure rising speed of the hydrogen-rich water cup is further slowed down, the dissolution duration of the hydrogen in water is prolonged, and the critical highest solubility can be achieved.

Drawings

In order to more clearly illustrate the technical solutions of embodiments or conventional techniques of the present application, the drawings required for the descriptions of the embodiments or conventional techniques will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present application, and other drawings may be obtained according to these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1a is a front view of a hydrogen enriched water cup according to one embodiment;

FIG. 1b is a rear view of a hydrogen enriched water cup according to one embodiment;

FIG. 2 is a schematic diagram of the connection of electronic devices in a hydrogen-rich water cup according to one embodiment;

FIG. 3 is a schematic diagram of the structure of an electrolyzer in a hydrogen-enriched water cup in one embodiment;

FIG. 4 is a bottom view of a hydrogen enriched water cup according to one embodiment;

FIG. 5 is a schematic diagram of a controller in one embodiment.

Detailed Description

In order to facilitate an understanding of the present application, a more complete description of the present application will now be provided with reference to the relevant figures. Examples of the present application are given in the accompanying drawings. This application may, however, be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application.

It will be understood that the terms "first," "second," and the like, as used herein, may be used to describe various elements, but these elements are not limited by these terms. These terms are only used to distinguish one element from another element. For example, a first resistance may be referred to as a second resistance, and similarly, a second resistance may be referred to as a first resistance, without departing from the scope of the present application. Both the first resistor and the second resistor are resistors, but they are not the same resistor.

It is to be understood that in the following embodiments, "connected" is understood to mean "electrically connected", "communicatively connected", etc., if the connected circuits, modules, units, etc., have electrical or data transfer between them.

As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises" and/or "comprising," and/or the like, specify the presence of stated features, integers, steps, operations, elements, components, or groups thereof, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or groups thereof.

In one embodiment, as shown in fig. 1a, 1b, and 2, a hydrogen enriched water cup is provided that includes a cup body 102, a cup lid 104, a base 106, a pressure sensor 202, an electrolyzer 204, a battery 206, and a controller 208. The cup 102 forms a hollow through cavity; the cup cover 104 is arranged on the top of the cup body 102 and is detachably connected with the cup body 102; the base 106 is arranged at the bottom of the cup body 102 and is detachably connected with the cup body 102; when the cup cover 104 is arranged on the cup body 102, the cup cover 104, the cup body 102 and the base 106 form a closed space; the pressure sensor 202 is installed on the base 106, and the pressure sensor 202 is used for monitoring the pressure of the closed space; the electrolyzer 204 is arranged on the base 106, and the surface of the electrolyzer 204 is directly communicated with the hollow through cavity of the cup 102; the electrolyzer 204 is used to electrolyze water in the cup 102 to produce hydrogen gas; the cell is connected to the electrolyzer 204, and the battery 206 is used to power the electrolyzer 204; an input end of the controller 208 is connected with the pressure sensor 202, and a first control end of the controller 208 is connected with the battery 206; the controller 208 is configured to reduce the current output from the battery 206 to the electrolyzer 204 in the event that the pressure of the enclosed space is greater than a preset pressure threshold.

The controller may refer to, but is not limited to, an MCU (Microcontroller Unit, micro control unit), an FPGA (Field Programmable Gate Array ) and a single chip microcomputer, and it should be noted that the controller is further integrated with a BMS (Battery Management System ), that is, the controller may regulate and control an output current of a battery connected with the controller. The battery may include, but is not limited to, a polymer lithium battery. The pressure in the enclosed space may be the pressure of water in the enclosed space or the total pressure of water and gas in the enclosed space. The preset pressure threshold value can be a value smaller than the maximum safe pressure which can be borne by the cup body, namely, when the preset pressure threshold value is exceeded, although the dissolution of hydrogen in water is increased along with the increase of the pressure, the continuous pressurization can cause the pressure of a closed space to be larger than the maximum safe pressure value, so that the cup body, the cup cover, the base and the electrolyzer of the hydrogen-rich water cup are easily damaged due to high pressure, and even the situation of bursting the cup is caused in serious cases; the preset pressure threshold may also refer to an ideal pressure at which hydrogen is maximally dissolved in water, i.e., at which the rate at which hydrogen is produced by the electrolyzer is similar to the rate at which hydrogen is dissolved in water.

Specifically, after the hydrogen-rich water cup is filled with water and covered with the cup cover, a pressure sensor arranged on the base monitors pressure change in the water cup, the monitored pressure value is converted into a corresponding digital signal through an A/D converter arranged in the pressure sensor and is transmitted to the controller, the controller compares the received pressure value with a built-in reference pressure value, when the pressure value is larger than a certain set reference pressure value, it is judged that the water quantity in the hydrogen-rich water cup meets the electrolysis hydrogen production condition at the moment, and accordingly the controller outputs an electric signal to drive a battery to supply power to the electrolyzer, and the electrolyzer starts electrolysis of water to produce hydrogen. Further, in the process of preparing the electrolytic water hydrogen production by the electrolyzer, the pressure sensor monitors the pressure change in the cup in real time and transmits the monitored data to the controller; under the condition that the pressure in the cup is monitored to be greater than the preset pressure threshold, the controller determines that the speed of hydrogen generated by the electrolyzer is similar to the speed of hydrogen dissolved in water at the preset pressure threshold at the moment, namely, the hydrogen can be dissolved in water to the maximum extent at the moment, so that the controller reduces the generation speed of the hydrogen by reducing the current output by the battery to the electrolyzer, and the pressure in the cup is kept close to the preset pressure threshold. It should be noted that, after the hydrogen is gradually dissolved in the water, the preset pressure threshold may be set in multiple gradients due to the limited solubility of the hydrogen by the water, and may also be adjusted in real time according to an algorithm, and the specific implementation is not limited herein. Furthermore, in some special cases, such as when the electrolyzer is in fault, the pressure in the cup is far greater than the preset pressure threshold value, and even exceeds the maximum safety pressure which can be borne by the hydrogen-rich water cup, the pressure sensor transmits the monitored pressure in the cup to the controller, and the controller directly blocks the current input by the battery into the electrolyzer so as to close the electrolyzer, thereby avoiding the phenomenon of cup explosion caused by overlarge pressure.

In the embodiment, the pressure in the hydrogen-rich water cup is monitored through the pressure sensor, and the self-starting electrolysis is realized based on the monitored pressure value. Furthermore, the hydrogen generation rate of the electrolyzer can be regulated and controlled based on the monitored pressure value, so that the pressure in the cup is kept close to a preset pressure threshold, the hydrogen is dissolved in water to the maximum extent, and the waste caused by excessive hydrogen which cannot be dissolved in water is avoided; meanwhile, the energy consumption of the battery is saved, so that the charge and discharge times of the battery are reduced, and the service life of the battery is prolonged. Furthermore, the electrolyzer can be switched off rapidly based on the monitored pressure value, so that the damage to devices such as the electrolyzer caused by overlarge pressure in the cup due to the failure of the electrolyzer is avoided, the service lives of all the components are prolonged, and safety accidents such as cup explosion and the like are further prevented. In addition, the detachable design of the base is beneficial to replacing or maintaining the electronic devices in the base.

In one embodiment, as shown in fig. 3, the electrolyzer comprises a cathode platinum electrolyte sheet 302 and an anode platinum electrolyte sheet 304, wherein the cathode platinum electrolyte sheet 302 is directly communicated with the hollow through cavity of the cup body, and the input end of the cathode platinum electrolyte sheet 302 is connected with the cathode of the battery; the anode platinum electrolyte sheet 304 is arranged at one side far away from the cup cover compared with the cathode platinum electrolyte sheet 302, and the anode platinum electrolyte sheet 304 is connected with the anode of the battery; when the anode platinum electrolyte sheet 304 and the cathode platinum electrolyte sheet 302 are energized, the electrolyzed water generates hydrogen and oxygen.

Wherein, the direct communication of the cathode platinum electrolyte sheet and the hollow through cavity of the cup body means that the cathode platinum electrolyte sheet is in direct contact with the water in the cup after the hydrogen-rich water cup is filled with water; further, the cathode platinum electrolyte sheet is a net-shaped sheet, and the anode platinum electrolyte sheet is also a net-shaped sheet.

Specifically, after the cathode platinum electrolyte sheet and the anode platinum electrolyte sheet are electrified, water in the cup is electrolyzed to generate hydrogen, and further, the sheet type design can be better embedded into the base, so that the structure is more compact and the volume is smaller. In addition, the design of the net structure can make electrolysis more sufficient.

In one embodiment, as shown in fig. 3, the electrolyzer further comprises:

the adsorption module 306 is positioned at one side of the anode platinum electrolyte sheet far away from the cathode platinum electrolyte sheet; the adsorption module 306 is used to adsorb impurities generated during the electrolysis process, which refers to other substances than hydrogen and oxygen.

Wherein the adsorption module may be, but is not limited to, activated carbon tablets and calcium sulfite particles.

In particular, since pure water has a low mineral content, i.e., pure water is difficult to electrolyze, water used for electrolysis of a hydrogen-rich cup generally contains minerals, i.e., is conducted through related metals. Further, in the process of electrolyzing purified water containing minerals, impurities such as residual chlorine and ozone are generated in addition to hydrogen and oxygen. Through setting up the adsorption module in the one side that is located the positive pole platinum electrolysis piece and keeps away from the cathode platinum electrolysis piece, adsorb the impurity that produces, avoid the user to drink the water that contains the impurity and influence healthy.

In one embodiment, as shown in fig. 3, the electrolyzer further comprises:

a proton exchange membrane 308 located between the cathode platinum electrolyte sheet and the anode platinum electrolyte sheet; the proton exchange membrane 308 serves to isolate hydrogen and oxygen generated during electrolysis.

The proton exchange membrane is a membrane material which only allows hydrogen ions to exchange and blocks other ions from passing, hydrogen generated by electrolysis of water is isolated from oxygen due to the existence of the proton exchange membrane, the hydrogen ions lose electrons on a cathode to form hydrogen, and the oxygen ions acquire electrons on an anode to form oxygen. Further, because of the isolation of hydrogen and oxygen, the generation of ozone and residual chlorine is avoided, and the water quality is further improved.

In one embodiment, as shown in fig. 4, the base 106 further includes a housing, a vent 402 is disposed on a side of the housing away from the cup cover, and an anode platinum electrolyte sheet is disposed in a receiving cavity formed by the housing and close to the vent 402, and the anode platinum electrolyte sheet is in communication with the outside air through the vent 402.

Specifically, oxygen generated in the electrolysis process is discharged to the outside through the exhaust hole, so that the oxygen is prevented from reentering the water to participate in electrolysis to generate harmful substances such as residual chlorine, ozone and the like, and the quality of the hydrogen-rich water is further improved.

In one embodiment, as shown in fig. 1a, further comprising:

the touch display screen 108 is arranged on the outer wall of the base, and the touch display screen 108 is connected with the output end of the controller; the touch display screen is used for displaying the pressure value of the closed space.

The touch display screen may be, but is not limited to, LCD (Liquid Crystal Display) liquid crystal display, OELD (Organic Light-Emitting Diode), micro LED (Micro Light-Emitting Diode), mini LED (sub-millimeter Light-Emitting display), and the like.

Specifically, in the electrolysis process, the pressure sensor monitors the pressure in the cup in real time and displays the pressure value on the touch display screen in real time so as to inform a user of the real-time pressure in the cup; further, when a user knows the pressure in the cup, the user can control the opening or closing of the electrolyzer by touching a virtual key on the touch display screen, and the hydrogen generation rate of the electrolyzer is regulated and controlled in a manual control mode, so that the situation that the cup cover cannot be opened due to overlarge pressure in the cup is avoided; still further, the hydrogen-rich water cup can also comprise a temperature sensor, the temperature sensor is connected with the input end of the controller and used for monitoring the temperature of water in the cup and outputting the monitored temperature value to the touch display screen for display through the controller so as to inform a user of the temperature of water in the cup, so that the user can conveniently obtain the water temperature at any time, and scalding caused by excessively high water drinking by mistake is avoided.

In one embodiment, further comprising:

the indicator lamp is arranged on the outer wall of the base and is connected with the second control end of the controller; the indicator lamp is used for displaying the pressure condition of the closed space under the control of the controller.

Wherein, the pilot lamp is used for the pressure condition in the hydrogen rich water cup, and the specific implementation way can be through different coloured lights representing the pressure condition in the cup by way of example. If the pressure in the cup is in the normal range, the indicator light displays green, wherein the normal range can be set according to hydrogen-rich cups formed by different styles or different devices, and the normal range is not limited herein; and when the pressure in the cup is larger than the maximum dissolution pressure of the hydrogen, the indicator light displays yellow; and when the pressure in the cup is greater than the maximum safety pressure in the hydrogen-rich water cup, the indicator lamp is red, and through the indicator lamp, a user can know the pressure state in the cup, so that the hydrogen generation rate of the electrolyzer is further manually regulated.

In one embodiment, as shown in fig. 1a, further comprising:

the switch key 110 is arranged on the outer wall of the base, and the switch key 110 is used for being connected in series on a common power supply circuit of the battery to the controller and the electrolyzer; when the switch key 110 is in the first state, the battery supplies power to the controller and the electrolyzer, and when the switch key 110 is in the second state, the battery stops supplying power to the controller and the electrolyzer.

The first state may be a state in which the button is pressed when the switch key is a button switch, or a state in which the switch is turned on when the switch key is a toggle switch; further, the second state may be a state in which the button is in a sprung state when the switch key is a button switch, or a state in which the switch is turned to an off side when the switch key is a toggle switch. The specific switch configuration and the selection configuration may be adaptively adjusted according to the product configuration, and are not limited herein.

In the above embodiment, the user can select to control the operation of the electrolyzer by controlling the switch key.

In one embodiment, as shown in fig. 1b, further comprising:

the charging interface 112, charging interface 112 installs in the base outer wall, and charging interface 112 is connected with the battery.

The charging interface may be, but is not limited to, a magnetic charging interface, a Micro-USB (Micro Universal Serial Bus, mini universal serial bus) charging interface, and a USB type-C charging interface. The battery of the hydrogen-rich water cup is charged through the charging interface, so that the normal operation of the hydrogen-rich water cup is ensured, the battery is not required to be replaced, and the environment is protected.

In one embodiment, the preset pressure threshold is 0.2 megapascals and the controller is configured to reduce the current output from the battery to the electrolyzer if the pressure in the enclosed space is greater than 0.2 megapascals.

It should be noted that, the preset pressure threshold value of 0.2 mpa in this embodiment is a reference value set by the inventor based on the product of the present application, and is a conclusion obtained by the inventor through multiple experiments, and is not limited to this value, and further, a person skilled in the art can adaptively adjust the preset pressure threshold value according to actual product parameters and adopted devices.

The embodiments are described in the context of one example, where a controller includes: the first input end of the operational amplifier is connected with the pressure sensor, the second input end of the operational amplifier is connected with a reference electric signal SG2 representing a preset pressure threshold value, the operational amplifier can determine the difference value between the preset pressure threshold value SG2 and the pressure SG1 of the closed space collected by the pressure sensor based on the operation function of the operational amplifier, and the smaller the difference value signal output to the battery is along with the gradual reduction of the difference value, the smaller the signal received by the BMS is, and the smaller the current output to the electrolyzer by the battery is controlled. Thereby, the hydrogen concentration is increased without causing damage to the cup body

In the description of the present specification, reference to the terms "some embodiments," "other embodiments," "desired embodiments," and the like, means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, schematic descriptions of the above terms do not necessarily refer to the same embodiment or example.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (10)

1. A hydrogen-enriched water cup, comprising:

the cup body forms a hollow through cavity;

the cup cover is arranged at the top of the cup body and is detachably connected with the cup body;

the base is arranged at the bottom of the cup body and is detachably connected with the cup body; when the cup cover is arranged on the cup body, the cup cover, the cup body and the base form a closed space;

the pressure sensor is arranged on the base and is used for monitoring the pressure of the closed space;

the electrolyzer is arranged on the base, and the surface of the electrolyzer is directly communicated with the hollow through cavity of the cup body; the electrolyzer is used for electrolyzing water in the cup body to generate hydrogen;

the battery is connected with the electrolyzer and is used for supplying power to the electrolyzer;

the input end of the controller is connected with the pressure sensor, and the first control end of the controller is connected with the battery; the controller is used for reducing the current output by the battery to the electrolyzer under the condition that the pressure of the closed space is larger than a preset pressure threshold value.

2. The hydrogen enriched water cup of claim 1, wherein the electrolyzer comprises:

the cathode platinum electrolysis piece is directly communicated with the hollow through cavity of the cup body, and the input end of the cathode platinum electrolysis piece is connected with the negative electrode of the battery;

the anode platinum electrolyte sheet is arranged at one side far away from the cup cover compared with the cathode platinum electrolyte sheet, and is connected with the anode of the battery; when the anode platinum electrolyte sheet and the cathode platinum electrolyte sheet are electrified, the electrolysis water generates hydrogen and oxygen.

3. The hydrogen enriched water cup of claim 2, wherein the electrolyzer further comprises:

the adsorption module is positioned at one side of the anode platinum electrolyte sheet far away from the cathode platinum electrolyte sheet; the adsorption module is used for adsorbing impurities generated in the electrolysis process, wherein the impurities refer to substances except the hydrogen and the oxygen.

4. A hydrogen enriched water cup as claimed in claim 3 wherein the electrolyzer further comprises:

a proton exchange membrane positioned between the cathode platinum electrolyte sheet and the anode platinum electrolyte sheet; the proton exchange membrane is used for isolating hydrogen and oxygen generated in the electrolysis process.

5. The hydrogen-enriched water cup as claimed in claim 3, wherein the base further comprises a housing, a vent hole is formed in a side, far away from the cup cover, of the housing, the anode platinum electrolyte sheet is arranged in a containing cavity formed by the housing, close to the vent hole, and the anode platinum electrolyte sheet is communicated with the outside air through the vent hole.

6. The hydrogen enriched water cup of claim 1, further comprising:

the touch display screen is arranged on the outer wall of the base and is connected with the output end of the controller; the touch display screen is used for displaying the pressure value of the closed space.

7. The hydrogen enriched water cup of claim 1, further comprising:

the indicator lamp is arranged on the outer wall of the base and is connected with the second control end of the controller; the indicator lamp is used for displaying the pressure condition of the closed space under the control of the controller.

8. The hydrogen enriched water cup of claim 1, further comprising:

the switch key is arranged on the outer wall of the base and is used for being connected in series on a common power supply loop of the battery to the controller and the electrolyzer; and when the switch key is in a first state, the battery supplies power to the controller and the electrolyzer, and when the switch key is in a second state, the battery stops supplying power to the controller and the electrolyzer.

9. The hydrogen enriched water cup of claim 1, further comprising:

the charging interface is arranged on the outer wall of the base and is connected with the battery.

10. The hydrogen enriched water cup of claim 1, wherein the preset pressure threshold is 0.2 mpa, and the controller is configured to reduce the current output from the battery to the electrolyzer if the pressure of the enclosed space is greater than 0.2 mpa.

Images