CN212246448U - Hydrogen-rich water direct drinking system - Google Patents

Abstract

The hydrogen-rich water direct drinking system comprises a filtering unit for filtering supplied water, a hydrogen production module for preparing hydrogen and an aeration device, wherein the hydrogen production module is provided with a hydrogen flow channel for discharging the prepared hydrogen, the supplied water flows through the filtering unit and then is mixed with the hydrogen in the hydrogen flow channel through a drinking water pipe to prepare hydrogen-rich water, and the hydrogen-rich water and/or the hydrogen flow through the aeration device; this hydrogen-rich water system of directly drinking still includes intelligent AI chip and thing networked control module, intelligent AI chip with thing networked control module connects, hydrogen production module with aeration equipment all with thing networked control module is connected. This hydrogen-rich water system of directly drinking has intelligent control device, can realize this hydrogen-rich water system of directly drinking of intelligent control, and safe healthy, and convenient to use.

Description

Hydrogen-rich water direct drinking system

Technical Field

The utility model relates to a drinking water equipment field, in particular to hydrogen-rich water directly drinks system.

Background

Although the water quality determines the constitution, there are not many people who really understand the importance of water to life and health, so water is said to be a forgotten nutrient. The World Health Organization (WHO) organization counted that 80% of the diseases and deaths of human 1/3 in developing countries were attributed to water, which determines longevity.

Hydrogen-rich water, also called hydrogen-rich water in Japan, can eliminate malignant oxygen free radicals in human body, prevent various diseases, and promote human health.

The hydrogen-rich water has the following effects:

1. activating human cells, delaying senility and removing harmful substances in cell membranes or blood vessels.

2. Enhancing immunity and improving cell activity.

3. Promoting digestion and excretion function, softening blood vessel, activating mucosa cell, promoting enterokinesia, facilitating excretion, and preventing and improving constipation.

4. Has strong permeability, and can penetrate into vascular endothelial space and other tissues, remove precipitate, activate cell tissue, dredge blood vessel, and improve blood circulation function.

5. Improving gastrointestinal function, promoting blood circulation and metabolism, maintaining endocrine balance, and promoting lipodieresis.

In addition, the hydrogen-rich water has the effects of preventing and treating diabetes, cardiovascular and cerebrovascular diseases, rheumatism, brain tumor, skin diseases, headache, dizziness, blood circulation disorder, kidney diseases, female climacteric syndrome, infantile eczema, bronchus, thyroid gland, insomnia, epilepsy and anaphylaxis, and also has the effects of beautifying, losing weight and resisting aging.

The existing hydrogen-rich water production method mainly comprises the following steps: (1) the hydrogen rod or the hydrogen porcelain is put into water to react with water to directly form hydrogen-rich water, but the hydrogen-rich water formed by the method has low concentration and is easy to consume, and the hydrogen rod or the hydrogen porcelain mainly comprises chemical substances such as magnesium, aluminum and the like, so that a human body can ingest a large amount of trace elements to be harmful to the body; (2) hydrogen is directly injected into water through a high-pressure hydrogen tank to form hydrogen-rich water, but the method has high danger coefficient and is not easy to operate; (3) hydrogen is filled into a bag or a bottle, and the method is favorable for drinking but not favorable for long-term storage; (4) the hydrogen is generated by electrolyzing water and then is injected into the water, the pressure of the hydrogen generated by the method is small, the hydrogen is not beneficial to dissolving and radiating, and the service life of the hydrogen-rich water production system is influenced. In modern life, smart homes have been widely popularized and applied, and the method for preparing hydrogen-rich water has low intelligence degree and cannot meet the requirements of modern people on smart homes. Therefore, it is necessary to provide a hydrogen-rich water direct drinking system with high intelligence degree.

SUMMERY OF THE UTILITY MODEL

Therefore, a hydrogen-rich water direct drinking system which can be conveniently used for household needs to be provided, and purified hydrogen-rich water which can be directly drunk can be conveniently prepared.

The utility model provides a hydrogen-rich water directly drinks system, including the filter unit that is used for filtering the feed water, hydrogen manufacturing module and the aeration equipment that is used for preparing hydrogen, be provided with the hydrogen flow channel that is used for discharging the preparation hydrogen on the hydrogen manufacturing module, the feed water flows through the filter unit after drinking water pipe and the hydrogen in the hydrogen flow channel mixes in order to make hydrogen-rich water, hydrogen-rich water and/or hydrogen flow through the aeration equipment; this hydrogen-rich water system of directly drinking still includes intelligent AI chip and thing networked control module, intelligent AI chip with thing networked control module connects, hydrogen production module with aeration equipment all with thing networked control module is connected.

Preferably, the hydrogen-rich water direct drinking system further comprises a sealed water tank, and the drinking water pipe is communicated to the sealed water tank; the aeration device is positioned in the sealed water tank, and the hydrogen flow channel penetrates through the sealed water tank and then is communicated with the aeration device.

Preferably, the filtering unit comprises a first-stage filtering unit and a second-stage filtering unit, the second-stage filtering unit is a reverse osmosis filtering unit, and the drinking water pipe is communicated with the space between the first-stage filtering unit and the second-stage filtering unit and/or the downstream of the second-stage filtering unit.

Preferably, the primary filtering unit comprises a PP cotton filtering unit, an active carbon filtering unit and an ultrafiltration membrane filtering unit, and the secondary filtering unit is an RO reverse osmosis membrane filtering unit.

Preferably, the hydrogen-rich water direct drinking system further comprises a drinking water tank, the hydrogen flow channel is communicated with the drinking water pipe, the communication position of the drinking water pipe is called as hydrogen dissolving communication, the drinking water tank is communicated with the filtering unit and the drinking water pipe between the hydrogen dissolving communication positions, and a gas-liquid separator is further arranged on the hydrogen flow channel before the hydrogen dissolving communication.

Preferably, this hydrogen-rich water directly drinks system still includes sealed water tank, sealed water tank is used for storing hydrogen-rich water, dissolve the hydrogen intercommunication with be provided with aeration equipment between the sealed water tank.

Preferably, the hydrogen-rich water direct drinking system further comprises a concentration detection device capable of determining the concentration of hydrogen-rich water and a return pipeline, and the return pipeline is communicated to the communication position of the hydrogen flow channel and the drinking water pipe; the hydrogen-rich water system further comprises a gas-liquid mixing device and an instant heating module, and hydrogen-rich water flows to a hydrogen-rich water outlet through the gas-liquid mixing device and the instant heating module; the concentration detection device and the instant heating module are connected with the Internet of things control module.

Preferably, the hydrogen-rich water direct drinking system further comprises a water supply tank for supplying water to the hydrogen production module, the water supply tank is communicated with the hydrogen production module through a water supply pipeline, a filtering device and an instant heating module are arranged on the water supply pipeline, and a water supply pump or a one-way valve is further arranged on the water supply pipeline; a water quality detection device and a liquid level detection device are also arranged in the water supply tank; the device comprises an instant heating module, a water quality detection device and a liquid level detection device.

Preferably, the bipolar plate is made of a carbon plate, a metal plate or a composite plate; and/or the presence of a gas in the gas,

the electrodes are made of stainless steel, aluminum alloy, copper or silver.

Preferably, at least part of the gas flow channel between the two end plates is bent, hydrophilic layers are arranged on the bipolar plate, the diffusion layer and the anode of the proton exchange membrane, and hydrophobic layers are arranged on the bipolar plate, the diffusion layer and the cathode of the proton exchange membrane.

Compared with the prior art, the utility model discloses following beneficial effect has:

the utility model provides a hydrogen-rich water directly drinks system, this system can directly receive the running water pipe, as the domestic hydrogen-rich water directly drinks system, convenient to use, and have the filter unit can produce the hydrogen-rich water that clean can directly drink at any time; use intelligent AI chip and thing networked control module to control this hydrogen-rich water system of directly drinking to make this hydrogen-rich water system of directly drinking have intelligent control's function, accord with the theory of modern to intelligent house more, it is more convenient to use.

Drawings

The foregoing and other objects, features and advantages of the invention will be apparent from the following more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings. Like reference numerals refer to like parts throughout the drawings, and the drawings are not intended to be drawn to scale in actual dimensions, emphasis instead being placed upon illustrating the principles of the invention.

FIG. 1 is a schematic view of an overall hydrogen-rich water drinking system according to an embodiment of the present invention;

FIG. 2 is a schematic view of the hydrogen-rich water direct drinking system according to another preferred embodiment of the present invention;

FIG. 3 is an overall structural view of the hydrogen production module of the present invention;

fig. 4 is a schematic structural diagram of the hydrogen production module of the present invention.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings.

It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element and be integral therewith, or intervening elements may also be present. The terms "mounted," "one end," "the other end," and the like are used herein for illustrative purposes only.

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 invention belongs. The terminology used in the description herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1-4, the utility model provides a hydrogen-rich water directly drinks system can produce the hydrogen-rich water system that can directly drink for family expenses, commercial providing. The system comprises a filtering unit 7 for filtering supplied water, a hydrogen production module 1-1 for preparing hydrogen and an aeration device 6-1, wherein a hydrogen flow channel 1-11 for discharging the prepared hydrogen is arranged on the hydrogen production module 1-1, the supplied water flows through the filtering unit 7 and then is mixed with the hydrogen in the hydrogen flow channel 1-11 through a drinking water pipe to prepare hydrogen-rich water, and the hydrogen-rich water and/or the hydrogen flow through the aeration device 6-1. This hydrogen-rich water system of directly drinking still includes intelligent AI chip and thing networked control module, intelligent AI chip with thing networked control module connects, hydrogen production module 1-11 with aeration equipment 6-1 all with thing networked control module is connected. The supply water can be tap water or municipal water, etc., the filter unit 7 can be directly connected to a tap of the tap water, and the supply water enters the filter unit 7 through a water pipe to complete filtration and purification. The hydrogen production module 1-11 is provided with a hydrogen flow channel 1-11 for discharging and producing hydrogen by electrolysis, the supply water flows through the filtering unit 7 and then is communicated with the hydrogen flow channel 1-11 through a drinking water pipe 2-11 to produce hydrogen-rich water, namely the hydrogen production module 1-1 produces hydrogen, and then the hydrogen enters the water in the drinking water pipe 2-11 through the hydrogen flow channel 1-11 to be dissolved to form hydrogen-rich water, namely hydrogen-rich water. The hydrogen flow channels 1-11 are communicated with the drinking water pipes 2-11 at one position, hydrogen is dissolved into drinking water at the communicated position to form hydrogen-enriched water, the communicated position is called as hydrogen dissolving communication 2-12 for convenience of description, the hydrogen dissolving communication 2-12 can be a common three-way valve, a three-way electromagnetic valve, an ejector and other devices, and better mixing of hydrogen and drinking water can be realized.

Referring to fig. 2, in a preferred embodiment, the hydrogen-enriched water direct drinking system further comprises a sealed water tank 6-2, and the drinking water pipe 2-11 is communicated to the sealed water tank 6-2. The aeration device 6-1 is positioned in the sealed water tank 6-2, and the hydrogen flow channel 1-11 is communicated with the aeration device 6-1 after passing through the sealed water tank 6-2. The water filtered by the filtering unit 7 is directly conveyed to the sealed water tank 6-2, the hydrogen flow channel 1-11 is directly connected to the aeration device 6-1 and is aerated in the sealed water tank 6-2, the water in the sealed water tank 6-2 is mixed with hydrogen to form hydrogen-rich water, and the sealed water tank 6-2 is used for storing the hydrogen-rich water. Such aeration effect will be a little better. The sealed water tank 6-2 has a function, and the sealed water tank 6-2 has certain pressure, so that the hydrogen-rich water in the hydrogen-rich water pipeline 4-2 can be ensured to have certain pressure, and the transportation and drinking are convenient.

Referring to fig. 2 and 3, in a preferred embodiment, the hydrogen-rich water direct drinking system further comprises a sealed water tank 6-2, wherein the sealed water tank 6-2 is used for storing hydrogen-rich water, and an aeration device 6-1 is arranged between the hydrogen-dissolved communication 2-12 and the sealed water tank 6-2. The aeration device 6-1 can be a porous aeration device, such as foam metal, porous membrane, porous ceramic and the like, so that macromolecular hydrogen in the hydrogen-rich water is changed into micro-nano-scale micromolecular hydrogen, the dissolving amount of the hydrogen in the water can be increased, and the concentration of the hydrogen-rich water is increased.

Referring to fig. 1 to 3, in a preferred embodiment, the filtering unit 7 includes a first filtering unit and a second filtering unit, the second filtering unit is a reverse osmosis filtering unit 7-4, and the first filtering unit can adopt other filtering methods except reverse osmosis, so that water containing minerals, i.e. mineral water, is obtained after passing through the first filtering unit. The reverse osmosis can filter mineral ions in water, so that purified water can be obtained after passing through the reverse osmosis filtering unit 7-4. The long-term drinking of purified water causes lack of essential minerals for human body, so that it is not recommended to drink purified water for a long time. The drinking water pipe 2-11 is connected between the first filtering unit and the second filtering unit and/or downstream of the second filtering unit, so that if the supplied water is mixed with hydrogen after passing through the reverse osmosis filtering unit 7-4, hydrogen rich water of the purified water is produced, and if the supplied water is mixed with hydrogen after passing through the first filtering unit, hydrogen rich water of the mineral water can be produced. If both lines are provided, a corresponding three-way change-over valve can be provided, so that the customer can change over according to the needs of the customer.

In a preferred embodiment, the primary filtration unit comprises a PP cotton filtration unit 7-1, an activated carbon filtration unit 7-2 and an ultrafiltration membrane filtration unit 7-3. The PP cotton filtering unit 7-1 can effectively remove various particle impurities in the filtered liquid, and the activated carbon filtering unit 7-3 can adsorb fine substances in various liquids due to the porosity thereof during filtering, remove organic substances and heavy metals, remove pollutants such as synthetic detergents, bacteria, viruses, radioactivity and the like, and has comprehensive functions of absorbing odor, removing toxicity, deodorizing, preventing mildew, sterilizing, purifying and the like. The ultrafiltration membrane only allows water and small molecular substances to pass through due to a plurality of fine micropores densely distributed on the surface of the ultrafiltration membrane to form permeate liquid, and substances with the volume larger than the micropore diameter on the surface of the ultrafiltration membrane in stock solution are intercepted on the liquid inlet side of the ultrafiltration membrane to form concentrated liquid, so that the aims of purifying, separating and concentrating liquid are fulfilled. The second-stage filtering unit is an RO reverse osmosis membrane filtering unit, and the reverse osmosis membrane can remove impurities such as inorganic ions, bacteria, viruses, organic matters, colloids and the like in liquid to obtain high-quality purified water. The four-stage filtration can ensure good filtration effect, and of course, one or more stages of filtration can be added, for example, one-stage active carbon filtration unit 7-2 can be added after the reverse osmosis filtration unit.

In a preferred embodiment, the feed water may be supplied to the feed tank 3-1 through a water supply pipe 2-14 after passing through the reverse osmosis filtration unit 7-4. In the electrolytic hydrogen production method, pure water or deionized water or secondary distilled water is required to be used, and the pure water passes through the reverse osmosis filtering unit 7-4, so that the electrolytic requirement can be met. Thus, the automatic water supply of the water supply tank 3-1 can be realized by combining with a corresponding control system, and the water quality is also ensured.

In a preferred embodiment, the hydrogen-rich water direct drinking system further comprises a drinking water tank 2-1, a communication position of the hydrogen flow channel 1-11 and the drinking water pipe 2-11 is called as a hydrogen dissolving communication 2-12, the drinking water tank 2-1 is communicated with the drinking water pipe 2-11 between the filtering unit 7 and the hydrogen dissolving communication 2-12, and a gas-liquid separator 5-11 is further arranged on the hydrogen flow channel 1-11 before the hydrogen dissolving communication 2-12. The hydrogen produced will carry some water, the gas-liquid separator 5-11 can separate out the water in the hydrogen, can set up the conduit, supplement the water separated into the water tank 3-1, realize and recycle.

In a preferred embodiment, the hydrogen-rich water direct drinking system further comprises a concentration detection device 5-4 capable of detecting the concentration of hydrogen-rich water and a return pipeline 4-1, wherein the return pipeline 4-1 is communicated to a place where the hydrogen flow channel 1-11 is communicated with the drinking water pipe 2-11, namely a place where dissolved hydrogen is communicated 2-12. When the detecting device detects that the hydrogen-rich water concentration is lower than the set value (different concentration buttons arranged on the machine can preset corresponding set values such as 1500ppb, 2000ppb, 2500ppb and 3000ppb), the hydrogen-rich water can be sent to the hydrogen dissolving communication 2-12 through the return pipeline 4-1 to be mixed for two times or more times, a three-way electromagnetic valve can be arranged on the pipeline, the hydrogen-rich water flows out from the outlet for drinking when the concentration reaches the standard, and if the concentration is not enough, the hydrogen is refluxed and re-dissolved from the return pipeline 4-1, so that the automatic control can be realized until the concentration reaches the set value. Certainly, a circulating water pump can be arranged on the return pipeline 4-1 and used for pumping the hydrogen-rich water with the concentration lower than the set value to the dissolved hydrogen communication 2-12, and when the concentration meets the requirement, the circulating water pump is not started; of course, the circulating water pump may not be installed.

In a preferred embodiment, the hydrogen-rich water system further comprises a gas-liquid mixing device 5-1 and an instant heating module 5-2, and hydrogen-rich water flows to a hydrogen-rich water outlet 2-13 through the gas-liquid mixing device 5-1 and the instant heating module 5-2. The hydrogen-rich water mixed after the hydrogen dissolving communication 2-12 is pumped to a hydrogen-rich water outlet 2-13 through a gas-liquid mixing device 5-1, the gas-liquid mixing device 5-1 can adopt a gas-liquid mixing pump, secondary mixing can be carried out on the hydrogen-rich water, the concentration of the hydrogen in the hydrogen-rich water is further improved, water is sprayed out when a drinking faucet is opened due to the pressure of the hydrogen-rich water belt which is discharged through the gas-liquid mixing device 5-1, and a pressure release valve 5-8 can be arranged at the outlet of the gas-liquid mixing device 5-1 and used for decompressing the hydrogen-rich water. The instantaneous heating module 5-2 can conveniently prepare hydrogen-rich water with different temperatures, such as water with the temperature of 40-50 ℃ and water with the temperature of 80-100 ℃.

In a preferred embodiment, the hydrogen-rich water direct drinking system further comprises a water supply tank 3-1 for supplying water to the hydrogen production module 1-1, the hydrogen-rich water direct drinking system further comprises a water supply tank 3-1, the water supply tank 3-1 is communicated with the hydrogen production module 1-1 through a water supply pipeline 3-2, the water supply tank 3-1 is used for providing electrolyzed water to the hydrogen production module 1-1, in addition, the hydrogen production module 1-1 can also generate oxygen, the gas flow channel further comprises an oxygen flow channel 1-12, and the oxygen can flow back to the water supply tank 3-1 through the oxygen flow channel 1-12. The electrolytic cell has requirements on water sources, and the water sources need pure water or deionized water or secondary distilled water. The water supply tank 3-1 is also internally provided with a water quality detection device 5-5 and a liquid level detection device 5-6. The water quality detection device 5-5 is used for detecting the water quality in the water supply tank 3-1, if the water quality of the water added by a user does not reach the standard, the water quality detection device 5-5 can transmit a signal to a corresponding control circuit, the machine is not started, and the alarm requires the replacement of a water source. The liquid level detection device 5-6 can measure the water level in the water supply tank 3-1, and the liquid level detection device 5-6 can also be connected with a corresponding control circuit to control a corresponding water replenishing pump to replenish water for the water supply tank 3-1, and certainly can also manually replenish water by arranging a water filling port. The tank 3-1 is normally maintained at a water level above 2/3. The hydrogen production module 1-1 can be cooled by directly blowing air by a fan in the hydrogen production process, and other more complex heat exchange systems can be used for cooling.

The water supply pipeline 3-2 is provided with a filtering device 5-3 and an instant heating module 5-2, and the water supply pipeline 3-2 is also provided with a water supply pump 5-7 or a one-way valve 5-10. The water feeding pump 5-7 is used for supplementing water to the electrolytic cell, and the water feeding pump 5-7 can be automatically controlled by the control circuit to supply water to the electrolytic cell. Along with the work of the electrolytic cell, the water in the water tank is less and less, and once the water is short, the electrolytic cell is burnt. Therefore, when the water in the drinking water tank 2-1 is lower than a certain set value, such as 1/10 of the whole water tank, the liquid level detection device 5-6 inputs a signal into the control circuit, the machine stops working and gives an alarm (a flash lamp is arranged and flashes), a user is reminded to add water, and the user can check whether the corresponding water feeding pump 5-7 is in failure or whether the water feeding tank 3-1 is in water shortage and the like. In addition, the water feeding pumps 5 to 7 also play a role in pressurization, are beneficial to increasing the circulation of water in the electrolytic cell and play a role in reducing the temperature in the electrolytic cell. Of course, if the vertical distance between the outlet of the water supply tank 3-1 and the water inlet of the electrolytic cell is large enough to have a certain potential, the water pump 5-7 is not needed when the water in the water supply tank 3-1 can flow into the electrolytic cell with a certain pressure. If the water feeding pump 5-7 is arranged, the water feeding pump 5-7 can be set with interval starting time, the water feeding pump 5-7 is started when the machine starts to be started, and the water in the water feeding tank 3-1 is started again when the water reaches a certain temperature, such as 40 ℃, or the water is started once in half an hour. If the water feeding pump 5-7 is arranged, the one-way valve 5-10 can be omitted, and the one-way valve 5-10 is used for preventing oxygen in the electrolytic cell from flowing backwards to enter a water inlet of the electrolytic cell, so that water cannot flow in favorably. If the water feeding pump 5-7 is not arranged, the one-way valve 5-10 can be arranged or the one-way valve 5-10 can be not arranged according to the vertical distance between the outlet of the water feeding tank 3-1 and the water inlet of the electrolytic cell, because the oxygen in the electrolytic cell does not flow out from the oxygen port but enters the water inlet of the electrolytic cell from the inside of the electrolytic cell when the electrolytic cell is started, but the phenomenon that the oxygen enters the water inlet of the electrolytic cell after the electrolytic cell works for a few minutes basically disappears, and the electrolytic cell works normally. Therefore, the feed pump 5-7 and the check valve 5-10 may be provided separately or neither depending on the design of the machine system.

The filtering device 5-3 can filter impurities in the water entering the electrolytic cell, and the filtering device 5-3 can adopt ion exchange resin and the like. The temperature probe can be arranged in the water supply tank 3-1 or on the water supply pipeline 3-2 and is used for detecting the temperature of a water source, because the low temperature or the high temperature is unfavorable for the working efficiency and the service life of the electrolytic cell, when the water temperature is low or even freezes, the temperature probe transmits a low-temperature signal to a corresponding control circuit, the machine is not started, the instant heating module 5-2 is immediately started at the moment, ice is melted until the water temperature reaches about 20 ℃, the machine is started to work, and the instant heating module 5-2 stops heating at the moment.

In addition, an electromagnetic valve and a drainage pipeline can be arranged between the outlet of the water supply tank 3-1 and the filtering device 5-3, so as to protect the electrolytic cell from being polluted by unqualified water sources. The purpose of the solenoid valve is to protect the electrolytic cell from contamination by the rejected water source, because the rejected water flows into the electrolytic cell when the user adds the rejected water to the feed tank 3-1, although the machine is not started up. When the water quality detection device 5-5 detects that the added water is unqualified (such as tap water), the electromagnetic valve is closed to prevent the unqualified water from flowing into the electrolytic cell, the machine alarms to require water source replacement, and in order to ensure that the unqualified water in the water supply tank 3-1 can be completely removed, a water discharge pipeline is also arranged between the outlet of the water supply tank 3-1 and the filter device 5-3 and is used for completely removing the unqualified water in the water supply tank 3-1 and preventing the electrolytic cell from being polluted. In order to prevent the hydrogen from coming out of the electrolytic cell from carrying small amounts of metallic impurities, a filtering device 5-3 may also be provided at the hydrogen outlet.

In addition, the whole system is also provided with an intelligent AI chip and an Internet of things control module (not shown), the intelligent AI chip can realize the conversation between a person and a machine, for example, a user can inquire the machine: what is the cell temperature? How many hours the cell was operating? How long the cell has been in service? How much water is left in the water supply tank 3-1? How does the water quality in the water supply tank 3-1? How much hydrogen rich water (hydrogen rich water) is concentrated? The machine can automatically voice-broadcast the answers. The control module of the internet of things is combined with the APP, and the conditions of the machine, such as the temperature of the electrolytic cell, the working time of the electrolytic cell, the amount of water in the water supply tank 3-1, the water quality in the water supply tank 3-1, the concentration of hydrogen-rich water and other parameters, can be checked on the APP. The instantaneous heating module, the water feeding pump, the aeration device, the water quality detection device, the liquid level detection device, the concentration detection device and the hydrogen production module are all connected with the Internet of things control module, and the intelligent AI chip can be used for controlling the starting and stopping of the devices. This system is directly drunk to hydrogen-rich water still includes wireless transmission module, wireless transmission module with thing networked control module is connected, wireless transmission module is used for being connected with outside mobile electronic equipment, and this system is directly drunk to hydrogen-rich water still includes the microphone for receive people's sound signal. The AI control function is similar to the function of millet sound, can be controlled according to the voice and can also be controlled through app. Further, the mobile electronic device may be a mobile electronic device such as a mobile phone, a computer, an electronic watch, or the like, which may download the app. Please refer to the specific structure and use of the intelligent AI chip and the internet of things control module: application No.: 201910325087.2 application date: 2019-04-22, the invention name is an invention patent of a household appliance AI control system based on the technology of the Internet of things; reference may also be made to application No.: 201910324193.9 application date: 2019-04-22, entitled control system for household appliances.

Referring to fig. 3, in a preferred embodiment, the hydrogen production module 1-1 comprises a plurality of electrolytic cells, each electrolytic cell comprises a proton exchange layer 106, diffusion layers 105, bipolar plates 103 and electrodes 102 are arranged on two sides of the proton exchange layer 106, and the diffusion layers 105, the bipolar plates 103 and the electrodes 102 are arranged in sequence from inside to outside. The hydrogen production module 1-1 further comprises gas flow channels 107 and 108 and end plates 101, wherein the end plates 101 are located on the outermost sides, first ends of the gas flow channels 107 and 108 are located inside the two end plates 101, second ends of the gas flow channels 107 and 108 lead out gas by connecting pipe joints to the outside of the end plates 101, and the gas flow channels 107 and 108 located between the two end plates 101 are at least partially arranged in a bent (special shape). The pressure of the gas pipe can be increased, the user can feel the gas obviously, and the temperature of the electrolysis module can be reduced. Further, a seal ring 104 is disposed between the bipolar plate 103 and the gas diffusion layer 105.

If the bipolar plate 103 is a metal plate, a hydrophilic layer is added close to the anode end, so that the bipolar plate has a hydrophilic or super-hydrophilic function, plays a role in absorbing water and reduces the outflow of water; the cathode end is close to and is made the hydrophobic layer, has hydrophobic or super hydrophobic effect, can play the moisture content outflow of accelerating on the one hand, and the second aspect is to play the corrosion protection effect, and the third aspect, water is attached to the cathode end, can increase resistance, is unfavorable for electrically conductive and heat transfer, can influence efficiency and life-span.

The diffusion layer 105 is provided with a hydrophilic layer close to the anode end, has a hydrophilic or super-hydrophilic effect and plays a role in water absorption; the cathode end is close to and is made the hydrophobic layer, has hydrophobic or super hydrophobic effect, can play the moisture content outflow of accelerating on the one hand, and the second aspect is to play the corrosion protection effect, and the third aspect, water is attached to the cathode end, can increase resistance, is unfavorable for electrically conductive and heat transfer, can influence efficiency and life-span.

The proton exchange membrane is provided with a hydrophilic layer close to the anode end, has the hydrophilic or super-hydrophilic function and plays a role in water absorption; the cathode end is close to and is made the hydrophobic layer, has hydrophobic or super hydrophobic effect, can play the moisture content outflow of accelerating on the one hand, and the second aspect is to play the corrosion protection effect, and the third aspect, water is attached to the cathode end, can increase resistance, is unfavorable for electrically conductive and heat transfer, can influence efficiency and life-span.

The working process of the system is as follows: tap water or municipal water is connected to the filtering unit through a pipeline, clean water filtered by the filtering unit and hydrogen generated by the hydrogen production module are mixed in the sealed water tank to form hydrogen-rich water, and then the hydrogen-rich water is supplied for drinking through the hydrogen-rich water outlet. In addition, the purified water formed after filtering can be supplemented with water to the water supply tank through the water supplementing pipeline, and a user can select the hydrogen-rich water of the mineral water quality or the purified water quality according to the requirement. If hydrogen-rich water concentration reaches the setting value, then hydrogen-rich water flows out through the hydrogen-rich water export, is drunk by the user, if hydrogen-rich water concentration does not reach the setting value, then takes out to dissolving hydrogen intercommunication department again through circulating water pump, carries out the secondary or mixes many times until concentration reaches the setting value.

The utility model provides a hydrogen-rich water directly drinks system, this system can directly receive the running water pipe, and as domestic hydrogen-rich water directly drinks system, convenient to use just has the hydrogen-rich water that the filter unit can produce clean can directly drink at any time. On this basis, this system can also be as required, selects the hydrogen-rich water that generates the hydrogen-rich water of mineral water quality or the hydrogen-rich water of pure water quality. The concentration of hydrogen-rich water can be guaranteed by the return line. The bent gas flow channel can enable the gas to flow in the hydrogen module for a longer time, and the gas can take away part of the heat of the hydrogen production module, thereby being beneficial to heat dissipation. Use intelligent AI chip and thing networked control module to control this hydrogen-rich water system of directly drinking to make this hydrogen-rich water system of directly drinking have intelligent control's function, accord with the theory of modern to intelligent house more, it is more convenient to use

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above embodiments only express the specific embodiments of the utility model, and the description thereof is more specific and detailed, but not so as to limit the scope of the patent of the utility model. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (8)

1. The hydrogen-rich water direct drinking system is characterized by comprising a filtering unit for filtering supplied water, a hydrogen production module for preparing hydrogen and an aeration device, wherein the hydrogen production module is provided with a hydrogen flow channel for discharging the prepared hydrogen, the supplied water flows through the filtering unit and then is mixed with the hydrogen in the hydrogen flow channel through a drinking water pipe to prepare hydrogen-rich water, and the hydrogen-rich water and/or the hydrogen flow through the aeration device; this hydrogen-rich water system of directly drinking still includes intelligent AI chip and thing networked control module, intelligent AI chip with thing networked control module connects, hydrogen production module with aeration equipment all with thing networked control module is connected.

2. The hydrogen-rich water direct-drinking system according to claim 1, further comprising a sealed water tank, wherein the drinking water pipe is connected to the sealed water tank; the aeration device is positioned in the sealed water tank, and the hydrogen flow channel penetrates through the sealed water tank and then is communicated with the aeration device.

3. The hydrogen-rich water direct-drinking system of claim 1, wherein the filtering unit comprises a primary filtering unit and a secondary filtering unit, the secondary filtering unit is a reverse osmosis filtering unit, and the drinking water pipe is communicated with the primary filtering unit and the secondary filtering unit and/or the downstream of the secondary filtering unit.

4. The hydrogen-rich water direct drinking system of claim 3, wherein the primary filtering unit comprises a PP cotton filtering unit, an activated carbon filtering unit and an ultrafiltration membrane filtering unit, and the secondary filtering unit is an RO reverse osmosis membrane filtering unit.

5. The hydrogen-rich water direct drinking system according to claim 1, further comprising a drinking water tank, wherein a communication position of the hydrogen flow channel and the drinking water pipe is called hydrogen dissolving communication, the drinking water tank is communicated with the drinking water pipe between the filtering unit and the hydrogen dissolving communication position, and a gas-liquid separator is further disposed on the hydrogen flow channel before the hydrogen dissolving communication.

6. The hydrogen-rich water direct-drinking system according to claim 5, further comprising a sealed water tank for storing hydrogen-rich water, wherein an aeration device is provided between the hydrogen-dissolving communication and the sealed water tank.

7. The hydrogen-rich water direct-drinking system according to claim 1, further comprising a concentration detection device capable of determining a concentration of hydrogen-rich water, and a return line connected to a connection of the hydrogen flow channel and the drinking water pipe; the hydrogen-rich water system further comprises a gas-liquid mixing device and an instant heating module, and hydrogen-rich water flows to a hydrogen-rich water outlet through the gas-liquid mixing device and the instant heating module; the concentration detection device and the instant heating module are connected with the Internet of things control module.

8. The hydrogen-rich water direct-drinking system according to claim 1, further comprising a water supply tank for supplying water to the hydrogen production module, wherein the water supply tank is communicated with the hydrogen production module through a water supply pipeline, a filtering device and an instantaneous heating module are arranged on the water supply pipeline, and a water supply pump or a one-way valve is further arranged on the water supply pipeline; a water quality detection device and a liquid level detection device are also arranged in the water supply tank; the device comprises an instant heating module, a water quality detection device and a liquid level detection device.

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