CN219620995U - Hydrogen-rich water machine - Google Patents

Abstract

The utility model relates to a hydrogen-rich water machine, which comprises a raw water tank, a filtering module, a pure water tank, a hydrogen production module, a mixing module, a heating module and a hydrogen water outlet end, wherein a water outlet of the raw water tank is connected with a water inlet of the filtering module through a pipeline, a water outlet of the filtering module is connected with a water inlet of the pure water tank through a pipeline, a first water outlet of the pure water tank is connected with a water inlet of the hydrogen production module through a pipeline, a hydrogen outlet of the hydrogen production module is connected with a hydrogen inlet of the mixing module through a pipeline, a second water outlet of the pure water tank is connected with a water inlet of the mixing module through a pipeline, a hydrogen outlet of the mixing module is connected with an inlet of the heating module through a first pipeline, and an outlet of the heating module is connected with the hydrogen water outlet through a second pipeline.

Description

Hydrogen-rich water machine

Technical Field

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

Background

The research in the field of hydrogen molecular medicine is in progress, and a proper amount of hydrogen is dissolved in water to prepare hydrogen-rich water, and a hydrogen-rich water machine is a machine for generating hydrogen-rich water.

In the prior art, as disclosed in publication number CN216273574U, a waterway system and hydrogen-rich equipment thereof are disclosed, and the technical scheme is as follows: comprises a raw water tank, a peristaltic pump, a water diversion tank body, a filtering device, a heating module and a hydrogen production module; the water diversion box body is provided with a drinking water tank and a pure water tank, the drinking water tank is provided with a drinking water inlet, a heating water outlet and a mixed water outlet, and the pure water tank is provided with a hydrogen production water outlet; the raw water tank is connected with the filtering device through a first water pipe, the filtering device is connected with the drinking water inlet through a second water pipe, the heating water outlet is connected with the heating module through a third water pipe, and the heating module is provided with a hot water output end for outputting hot water; the hydrogen production water outlet is connected with the peristaltic pump through the fifth water pipe, the hydrogen production module is connected with the peristaltic pump through the sixth water pipe, and the peristaltic pump is further provided with a hydrogen-rich output end for outputting hydrogen mixed liquid, so that the problem that hydrogen-rich equipment can only singly provide hydrogen-rich water and can not provide drinking water without hydrogen is solved.

However, according to the technical scheme, when a user needs to drink hydrogen-rich warm water, two paths of output water bodies are required to be mixed, and the temperature of the drinking water cannot be selected or regulated, so that the user experience is poor; on the other hand, the provision of two or more sets of output lines leads to an increase in the manufacturing cost of the water machine.

Disclosure of Invention

In order to overcome the defects of the prior art, the technical problem to be solved by the utility model is to provide a hydrogen-rich water machine which can solve the problems existing in the prior art.

To achieve the purpose, the utility model adopts the following technical scheme:

the utility model provides a hydrogen-rich water machine, which comprises a raw water tank, a filtering module, a pure water tank, a hydrogen production module, a mixing module, a heating module and a hydrogen water outlet end, wherein a water outlet of the raw water tank is connected with a water inlet of the filtering module through a pipeline, a water outlet of the filtering module is connected with a water inlet of the pure water tank through a pipeline, a first water outlet of the pure water tank is connected with a water inlet of the hydrogen production module through a pipeline, a hydrogen outlet of the hydrogen production module is connected with a hydrogen inlet of the mixing module through a pipeline, a second water outlet of the pure water tank is connected with a water inlet of the mixing module through a pipeline, a hydrogen outlet of the mixing module is connected with an inlet of the heating module through a first pipeline, and an outlet of the heating module is connected with the hydrogen water outlet end through a second pipeline.

The mixing module comprises a mixing pipeline and a mixing pump, a hydrogen outlet of the hydrogen production module is communicated with a hydrogen inlet of the mixing pipeline, a second water outlet of the pure water tank is communicated with a water inlet of the mixing pipeline, an outlet of the mixing pipeline is connected with an input end of the mixing pump, and an output end of the mixing pump is connected with an inlet of the heating module through a pipeline.

The preferable technical scheme of the utility model is that the front end of the mixing pipeline is provided with a one-way valve.

The preferable technical scheme of the utility model is that the device is also provided with a refrigerating module, the second water outlet of the pure water tank is connected with the inlet of the refrigerating module through a pipeline, and the outlet of the refrigerating module is connected with the hydrogen water outlet end through a pipeline.

The hydrogen production module comprises an electrolytic tank and a gas-liquid separator, wherein a first water outlet of the pure water tank is connected with a water inlet of the electrolytic tank through a pipeline, a hydrogen outlet of the electrolytic tank is connected with an inlet of the gas-liquid separator through a pipeline, a hydrogen outlet of the gas-liquid separator is connected with the hydrogen absorption end through a third pipeline, and a hydrogen outlet of the gas-liquid separator is connected with a hydrogen inlet of the mixing module through a fourth pipeline.

The preferable technical scheme of the utility model is that the electrolytic tank is provided with a backwater outlet, and the backwater outlet is connected with the pure water tank through a pipeline.

The preferable technical scheme of the utility model is that an electromagnetic valve is arranged in a first pipeline, a hydrogen outlet of a mixing module is connected with an inlet of the electromagnetic valve through a pipeline, a first outlet of the electromagnetic valve is connected with an inlet of a heating module through a pipeline, and a second outlet of the electromagnetic valve is connected with a hydrogen outlet end through a pipeline.

The preferable technical scheme of the utility model is that the filter module comprises a PP carbon rod filter element, an RO filter element and a carbon cotton filter element which are communicated through pipelines in sequence, wherein the water inlet of the filter module is the water inlet of the PP carbon rod filter element, and the water outlet of the filter module is the water outlet of the carbon cotton filter element.

The preferable technical scheme of the utility model is that the filter device further comprises a waste water tank, wherein the waste water tank is connected with the filter module through a fifth pipeline, and a waste water valve is arranged in the fifth pipeline.

The preferable technical scheme of the utility model is that a UV sterilizing lamp is arranged in the pure water tank.

The utility model has the beneficial effects that:

the utility model provides a hydrogen-rich water machine, which is designed by mixing hydrogen generated by a hydrogen production module and water in a pure water tank firstly, then directly communicating a mixing module 5 and a heating module 6 through a first pipeline, and directly heating the hydrogen-rich water output by the mixing module.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic structural diagram of a hydrogen-rich water machine according to a first embodiment of the present utility model;

FIG. 2 is a perspective view of a hydrogen rich water machine according to a first embodiment of the present utility model;

FIG. 3 is a second perspective view of a hydrogen rich water machine according to the first embodiment of the present utility model;

FIG. 4 is a third perspective view of a hydrogen rich water machine according to the first embodiment of the present utility model;

FIG. 5 is a perspective view of an integrated component of a hydrogen rich water machine according to a first embodiment of the present utility model;

fig. 6 is a schematic structural diagram of a hydrogen-rich water machine according to a second embodiment of the present utility model.

In the figure:

1-a raw water tank; 2-a filtration module; 21-PP carbon rod filter element; 22-RO filter core; 23-carbon cotton filter element; 3-a pure water tank; 4-a hydrogen production module; 41-an electrolytic cell; 42-a gas-liquid separator; 5-a mixing module; 51-mixing piping; 52-a mixing pump; 53-one-way valve; 6-a heating module; 7-a hydrogen water outlet end; 81-a refrigeration module; 82-a hydrogen-absorbing end; 84-waste water tank; an 85-TDS detector; 86-waste water valve.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

Example 1

As shown in fig. 1-5 (the pipeline and part of the host housing are omitted in fig. 2-4), the host comprises a raw water tank 1, a filter module 2, a pure water tank 3, a hydrogen production module 4, a mixing module 5, a heating module 6 and a hydrogen outlet end 7, the water outlet of the raw water tank 1 and the water inlet of the filter module 2 are connected through a pipeline, the water outlet of the filter module 2 and the water inlet of the pure water tank 3 are connected through a pipeline, a one-way valve 53 and a TDS detector 85 are arranged on the pipeline, the first water outlet of the pure water tank 3 and the water inlet of the hydrogen production module 4 are connected through a pipeline, the hydrogen outlet of the hydrogen production module 4 and the hydrogen inlet of the mixing module 5 are connected through a pipeline, the second water outlet of the pure water tank 3 and the water inlet of the mixing module 5 are connected through a pipeline, the hydrogen outlet of the mixing module 5 and the inlet of the heating module 6 are connected through a first pipeline, and the outlet of the heating module 6 and the hydrogen outlet end 7 are connected through a second pipeline. This design is through the hydrogen that mixes hydrogen production module production earlier and the water of pure water case, then through first pipeline direct communication mixing module 5 and heating module 6, carry out direct heating to the hydrogen-rich water of output in the mixing module, the user also can set for the temperature and adjust the temperature of hydrogen-rich water, compare prior art (CN 216273574U) disclosed technical scheme, the hydrogen-rich water machine of this embodiment does not need to set up the output pipeline of two way waters, the structure is simple relatively, can reduce the manufacturing cost of water machine, and through carrying out direct heating to the hydrogen-rich water, can adjust and control drinking water temperature better, so that hydrogen overflows from the hydrogen-rich water because of the change of temperature, promote user's use experience.

Specifically, the mixing module 5 includes a mixing pipe 51 and a mixing pump 52, the hydrogen outlet of the hydrogen production module 4 is connected to the hydrogen inlet of the mixing pipe 51, the second water outlet of the pure water tank 3 is connected to the water inlet of the mixing pipe 51, the outlet of the mixing pipe 51 is connected to the input end of the mixing pump 52, and the output end of the mixing pump 52 is connected to the inlet of the heating module 6 through a pipe. The above-mentioned mixed mechanism is simple and high-efficient, through mixing pipeline 51 confluence hydrogen and pure water, then make it produce the torrent under the drive of the pump body, the mixing pump 52 at this moment plays the effect of pressure boost simultaneously to improve the solubility of hydrogen, make it fully form the hydrogen-rich water. Preferably, the front end of the mixing pipe 51 is provided with a one-way valve 53. The arrangement of the one-way valve can prevent the fluid of the pipeline from flowing reversely, so that the hydrogen-rich water flows only in one direction, the phenomenon of countercurrent cannot occur, and the excessive pressure in the system is avoided.

Preferably, a waste water tank 84 is also included, the waste water tank 84 and the filtration module 2 being connected by a fifth pipe, in which a waste water valve 86 is arranged. In this embodiment, a fifth conduit is provided between the RO cartridge 22 and the waste water tank 84. When the hydrogen-rich water machine works normally, the waste water valve needs to be closed, and when the hydrogen-rich water machine needs to be cleaned, the waste water valve is opened.

In order to further improve the water quality of the pure water tank and to avoid bacteria and viruses from breeding polluted water sources, preferably, a UV sterilizing lamp is arranged inside the pure water tank 3.

Specifically, an electromagnetic valve is arranged in the first pipeline, a hydrogen outlet of the mixing module 5 is connected with an inlet of the electromagnetic valve through a pipeline, a first outlet of the electromagnetic valve is connected with an inlet of the heating module 6 through a pipeline, and a second outlet of the electromagnetic valve is connected with a hydrogen outlet end 7 through a pipeline. The design can be used for users to choose whether the hydrogen-rich water needs to be heated or not.

Preferably, a refrigerating module 81 is further arranged, the second water outlet of the pure water tank 3 is connected with the inlet of the refrigerating module 81 through a pipeline, and the outlet of the refrigerating module 81 is connected with the hydrogen water outlet end 7 through a pipeline. The user can drink cold water according to the own requirement.

For convenience in processing and assembly, specifically, as shown in fig. 5, the housing of the pure water tank and the housing of the filtration module are integrally formed, wherein the bottom of the housing of the pure water tank is provided with a filter element water inlet hole 31 and a water outlet hole 32.

Preferably, the filter module 2 comprises a PP carbon rod filter element 21, an RO filter element 22 and a carbon cotton filter element 23, which are communicated through pipelines in sequence, the water inlet of the filter module 2 is the water inlet of the PP carbon rod filter element 21, and the water outlet of the filter module 2 is the water outlet of the carbon cotton filter element 23. In this embodiment, the PP carbon rod filter core is used for filtering raw water, filtering silt, impurities, rust, etc., the RO filter core is used for filtering harmful substances such as pesticides, bacteria, viruses, heavy metal ions, etc. in water, and the carbon cotton filter core is used for improving taste in water. Because the filter elements have certain resistance, the pipeline between the filter elements is provided with a pump for supplying power. The water treated by the method can be better used for subsequent hydrogen production and drinking.

Example two

As shown in fig. 6, the hydrogen-rich water machine provided in this embodiment is similar to the structure of the first embodiment, and the difference is that: the hydrogen production module 4 is composed of an electrolytic tank 41 and a gas-liquid separator 42, a first water outlet of the pure water tank 3 is connected with a water inlet of the electrolytic tank 41 through a pipeline, a hydrogen outlet of the electrolytic tank 41 is connected with an inlet of the gas-liquid separator 42 through a pipeline, a hydrogen outlet of the gas-liquid separator 42 is connected with the hydrogen suction end 82 through a third pipeline, and a hydrogen outlet of the gas-liquid separator 42 is connected with a hydrogen inlet of the mixing module 5 through a fourth pipeline. In this design, the user can inhale hydrogen gas according to the demand, rather than drink hydrogen-rich water. Preferably, the electrolyzer 41 is provided with a return water outlet, which is connected to the pure water tank 3 by a pipe, so that the water of the electrolyzer is constantly circulated and replenished.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the utility model. The utility model is not to be limited by the specific embodiments disclosed herein, but rather, embodiments falling within the scope of the appended claims are intended to be embraced by the utility model.

Claims (10)

1. The utility model provides a hydrogen-rich water machine, includes host computer, its characterized in that:

the host comprises a raw water tank (1), a filtering module (2), a pure water tank (3), a hydrogen production module (4), a mixing module (5), a heating module (6) and a hydrogen water outlet end (7);

the water outlet of former water tank (1) with the water inlet of filtration module (2) passes through the pipe connection, the delivery port of filtration module (2) with the water inlet of pure water tank (3) passes through the pipe connection, the first delivery port of pure water tank (3) with the water inlet of hydrogen manufacturing module (4) passes through the pipe connection, the hydrogen outlet of hydrogen manufacturing module (4) with the hydrogen inlet of mixing module (5) passes through the pipe connection, the second delivery port of pure water tank (3) with the water inlet of mixing module (5) passes through the pipe connection, the hydrogen outlet of mixing module (5) with the entry of heating module (6) passes through first pipe connection, the export of heating module (6) with hydrogen outlet end (7) passes through the second pipe connection.

2. The hydrogen-rich water machine of claim 1, wherein:

the mixing module (5) comprises a mixing pipe (51) and a mixing pump (52);

the hydrogen production device is characterized in that a hydrogen outlet of the hydrogen production module (4) is communicated with a hydrogen inlet of the mixing pipeline (51), a second water outlet of the pure water tank (3) is communicated with a water inlet of the mixing pipeline (51), an outlet of the mixing pipeline (51) is connected with an input end of the mixing pump (52), and an output end of the mixing pump (52) is connected with an inlet of the heating module (6) through a pipeline.

3. The hydrogen-rich water machine of claim 2, wherein:

the front end of the mixing pipeline (51) is provided with a one-way valve (53).

4. The hydrogen-rich water machine of claim 1, wherein:

a refrigeration module (81) is also arranged;

the second water outlet of the pure water tank (3) is connected with the inlet of the refrigerating module (81) through a pipeline, and the outlet of the refrigerating module (81) is connected with the hydrogen water outlet end (7) through a pipeline.

5. The hydrogen-rich water machine of claim 1, wherein:

a hydrogen absorbing end (82) is also arranged;

the hydrogen production module (4) comprises an electrolytic tank (41) and a gas-liquid separator (42);

the first water outlet of the pure water tank (3) is connected with the water inlet of the electrolytic tank (41) through a pipeline, the hydrogen outlet of the electrolytic tank (41) is connected with the inlet of the gas-liquid separator (42) through a pipeline, the hydrogen outlet of the gas-liquid separator (42) is connected with the hydrogen suction end (82) through a third pipeline, and the hydrogen outlet of the gas-liquid separator (42) is connected with the hydrogen inlet of the mixing module (5) through a fourth pipeline.

6. The hydrogen-rich water machine of claim 5, wherein:

the electrolytic tank (41) is provided with a backwater outlet;

the backwater outlet is connected with the pure water tank (3) through a pipeline.

7. The hydrogen-rich water machine of claim 1, wherein:

an electromagnetic valve is arranged in the first pipeline;

the hydrogen outlet of the mixing module (5) is connected with the inlet of the electromagnetic valve through a pipeline, the first outlet of the electromagnetic valve is connected with the inlet of the heating module (6) through a pipeline, and the second outlet of the electromagnetic valve is connected with the hydrogen outlet end (7) through a pipeline.

8. The hydrogen-rich water machine of claim 1, wherein:

the filtering module (2) comprises a PP carbon rod filter element (21), an RO filter element (22) and a carbon cotton filter element (23) which are communicated through pipelines in sequence;

the water inlet of the filter module (2) is the water inlet of the PP carbon rod filter element (21), and the water outlet of the filter module (2) is the water outlet of the carbon cotton filter element (23).

9. The hydrogen-rich water machine of claim 1, wherein:

also includes a waste water tank (84);

the waste water tank (84) and the filter module (2) are connected by a fifth pipeline, and a waste water valve (86) is arranged in the fifth pipeline.

10. The hydrogen-rich water machine of claim 1, wherein:

the inside of the pure water tank (3) is provided with a UV sterilizing lamp.