CN222294213U - PEM electrolytic water hydrogen production and oxygen production flow display device - Google Patents

Abstract

The utility model relates to the technical field of PEM (PEM) electrolyzed water hydrogen production and oxygen production process display device, which comprises a back plate, wherein a base is fixedly connected to the lower part of the back plate, resin is fixedly connected to the upper part of the base, a water pump is fixedly connected to one side of the resin, a water tank is fixedly connected to the upper part of the water pump, a water tank oxygen outlet and a water injection port are respectively and fixedly connected to the upper part of the water tank, an electrolyzer oxygen inlet is fixedly connected to the upper part of the water tank, an electrolyzer is fixedly connected to one side of the electrolyzer oxygen inlet, an oxygen outlet and a hydrogen outlet are respectively and fixedly connected to the upper part of the electrolyzer, a gas-water separator is fixedly connected to the upper part of the hydrogen outlet, and the improved display device is provided with a hole plate display device which can be detached for taking down for display, is convenient for cleaning and is provided with a device for converting a water source into oxygen.

Description

PEM electrolytic water hydrogen production and oxygen production flow display device

Technical Field

The utility model relates to the technical field of PEM (proton exchange membrane) electrolytic water production, in particular to a flow display device for producing hydrogen and oxygen by PEM electrolytic water.

Background

The research shows that the hydrogen gas is used as a selective antioxidant substance, and has effective and obvious therapeutic effect on liver diseases such as liver ischemia, drug hepatitis, liver cirrhosis caused by bile duct blockage, fatty liver and the like. Products such as hydrogen production cups and the like are put forward in the market at present, so that people can take hydrogen conveniently in daily life.

The principle of the gas-water separator is that liquid water in gas is removed by five-stage separation-speed reduction, centrifugation, collision, direction change, condensation and other principles, so as to achieve the effect of purification, after moisture is condensed in the cooling process, a baffle plate in the separator changes the direction of the gas for two times, and rotates at a designed speed to generate centrifugal force to efficiently separate liquid and particles, and a drainer should discharge condensate in time.

The inventor finds that the prior art has the following problems that 1, the operation process of converting oxygen into hydrogen is complex, the operation process is more, the equipment is larger and the display is inconvenient, and 2, the conventional display board is fixedly installed and cannot be detached for cleaning, so that the scrubbing is inconvenient.

Disclosure of utility model

The utility model aims to provide a flow display device for producing hydrogen and oxygen by electrolyzing water through PEM, which aims to solve the problem that the display is inconvenient because the traditional conversion from oxygen to hydrogen is complex in the background art. In order to achieve the above purpose, the utility model provides the technical scheme that the PEM electrolytic water hydrogen production and oxygen production flow display device comprises a back plate, wherein a base is fixedly connected to the lower side of the back plate, resin is fixedly connected to the upper side of the base, a water pump is fixedly connected to one side of the resin, a water tank is fixedly connected to the upper side of the water pump, a water tank oxygen outlet and a water injection port are respectively and fixedly connected to the upper side of the water tank, an electrolytic tank oxygen inlet is fixedly connected to the upper side of the water tank, an electrolytic tank is fixedly connected to one side of the electrolytic tank oxygen inlet, an oxygen outlet and a hydrogen outlet are respectively and fixedly connected to the upper side of the electrolytic tank, a gas-water separator is fixedly connected to a gas flowmeter, one side of the back plate is movably connected with an electrolytic tank table, one side of the back plate is movably connected with a power supply, and the same side of the electrolytic tank is fixedly connected with a first binding post and a second binding post.

Further preferably, the base and the backboard are integrally connected, and the external structural size of one side of the electrolytic cell table is consistent with the internal structural size of the hole of the backboard.

Further preferably, the water tank is integrally connected with the oxygen inlet of the electrolytic tank, and the oxygen outlet of the water tank is integrally connected with the water tank.

Further preferably, the external structural dimension of one side of the resin is consistent with the internal structural dimension of one side of the water pump, and the internal structural dimension of the water pump is consistent with the internal structural dimension of the water tank.

Further preferably, the upper internal structure size of the electrolytic tank is consistent with the external structure size of the hydrogen outlet, and one side structure size of the power supply is consistent with the internal structure size of the backboard

Further preferably, the water tank is connected through a plurality of connecting pipes, the water tank is connected with the electrolytic tank, the electrolytic tank is connected with the resin, the resin is connected with the water pump, the water pump is connected with the water tank, and the electrolytic tank is connected with the gas-water separator and the gas flowmeter.

Compared with the prior art, the utility model has the beneficial effects that:

In the utility model, water is injected into the water tank to a required amount through the water injection port, the water injection port is closed, the power supply is used for supplying power to the water pump, so that water can enter the resin from the water tank through the water pump and then enter the electrolytic tank, the oxygen outlet of the electrolytic tank is a mixture of oxygen and water, and after the mixture flows into the water tank along the pipeline together, the water is arranged below the water tank, and because the densities of the oxygen and the hydrogen are different, the oxygen is naturally discharged from the oxygen outlet of the water tank above, so that the display and the observation are convenient, the operation is simple, and the display is convenient.

According to the utility model, the clamping rod at one side of the power supply is consistent with the hole of the backboard, the base is integrally connected with the backboard, the clamping rod of the electric tank table is fixedly provided with the hole of the backboard, the electric tank table is convenient to install and disassemble, the device is convenient to add, the display and the cleaning are convenient, and the later display and the treatment are more convenient.

Drawings

FIG. 1 is a schematic elevational view of the present utility model;

FIG. 2 is a schematic side view of the present utility model;

FIG. 3 is a schematic top view of the present utility model;

Fig. 4 is a schematic diagram of a back view structure of the present utility model.

The device comprises a back plate, an electrolytic tank table, a base, a power supply, a water tank, a water pump, a resin, an electrolytic tank, an oxygen outlet, a hydrogen outlet, a gas-water separator, a gas flowmeter, an oxygen inlet, a water tank oxygen outlet, a water injection port, a first binding post, a second binding post and a second binding post, wherein the back plate, the electrolytic tank table, the base, the power supply, the water tank, the water pump, the resin, the electrolytic tank, the oxygen outlet, the hydrogen outlet, the gas-water separator, the gas flowmeter, the oxygen inlet, the water tank and the water injection port, the water tank, the water injection port and the first binding post and the second binding post.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which are obtained by a worker of ordinary skill in the art without creative efforts, are within the protection scope of the present utility model based on the embodiments of the present utility model.

Referring to fig. 1 to 4, the present utility model provides a technical scheme that a flow display device for producing hydrogen and oxygen by using PEM (PEM) electrolyzed water, which comprises a back plate 1, wherein a base 3 is fixedly connected below the back plate 1, a resin 7 is fixedly connected above the base 3, a water pump 6 is fixedly connected to one side of the resin 7, a water tank 5 is fixedly connected above the water pump 6, a water tank oxygen outlet 14 and a water injection port 15 are respectively and fixedly connected above the water tank 5, an electrolytic tank oxygen inlet 13 is fixedly connected above the water tank 5, an electrolytic tank 8 is fixedly connected to one side of the electrolytic tank oxygen inlet 13, an oxygen outlet 9 and a hydrogen outlet 10 are respectively and fixedly connected above the electrolytic tank 8, a gas-water separator 11 is fixedly connected above the hydrogen outlet 10, a gas flowmeter 12 is fixedly connected above the gas-water separator 11, one side of the back plate 1 is movably connected with an electrolytic tank table 2, one side of the back plate 1 is movably connected with a power supply 4, and the same side of the electrolytic tank 8 is fixedly connected with a first binding post 16 and a second binding post 17.

In this embodiment, as shown in fig. 1, 2, 3 and 4, the base 3 and the back plate 1 are integrally connected, and the external structural dimension of one side of the electrolytic cell table 2 is consistent with the internal structural dimension of the hole of the back plate 1, and the clamping rod of the electrolytic cell table 2 is fixed with the hole of the back plate 1 due to the integral connection between the base 3 and the back plate 1, so as to achieve the stability of the back plate 1.

In this embodiment, as shown in fig. 1, 2, 3 and 4, the water tank 5 is integrally connected with the oxygen inlet 13 of the electrolytic tank, and the water tank oxygen outlet 14 is integrally connected with the water tank 5, and because the water tank 5 is integrally connected with the oxygen inlet 13 of the electrolytic tank, the water tank oxygen outlet 14 is integrally connected with the water tank 5, so that water is conveniently filled into the water tank, and the convenience in feeding of the oxygen inlet 13 of the electrolytic tank and the oxygen outlet 14 of the water tank is achieved.

In this embodiment, as shown in fig. 1, 2 and 4, the external structural dimension of one side of the resin 7 is consistent with the internal structural dimension of one side of the water pump 6, and the internal structural dimension of the water pump 6 is consistent with the internal structural dimension of the water tank 5, and the water tank 5 sucks water source through the water pump 6, and the water source is discharged into the resin 7, so that the effect of water source transmission of the water pump 6 is achieved.

In this embodiment, as shown in fig. 1, 2, 3 and 4, the upper internal structure size of the electrolyzer 8 is consistent with the external structure size of the hydrogen outlet 10, and the structure size of one side of the power supply 4 is consistent with the internal structure size of the back plate 1, and because the oxygen outlet 9 is integrally connected with the electrolyzer 8, the clamping rod on one side of the power supply 4 is consistent with the holes of the back plate 1, so that the power supply 4 can be stably fixed on the back plate 1.

In this embodiment, as shown in fig. 1, 2 and 4, the water tank 5 is connected through a plurality of connecting pipes, the water tank 5 is connected with the electrolytic tank 8, the electrolytic tank 8 is connected with the resin 7, the resin 7 is connected with the water pump 6, the water pump 6 is connected with the water tank 5, the electrolytic tank 8 is connected with the gas-water separator 11, the gas-water separator 11 is connected with the gas flowmeter 12, water is injected into the water tank 5 to a required amount through the water injection port 15, the water injection port 15 is sealed, the water pump 6 is powered by the power supply 4, water enters the resin 7 from the water tank 5 through the water pump 6 and then enters the electrolytic tank 8, the oxygen outlet 9 of the electrolytic tank 8 is a mixture of oxygen and water, and after the mixture flows into the water tank 5 along a pipeline, the water is arranged below, so as to achieve the function of connecting pipes on one side of the water tank 5.

The application method and the application advantages of the utility model are that the flow display device for producing hydrogen and oxygen by using PEM electrolysis of water has the following working procedures when in use:

As shown in fig. 1, 2, 3 and 4, the water tank 5, the water pump 6 and the resin 7 are first fixed to the display board base 3, the electrolytic tank 8 is fixed to the electrolytic tank table 2, the gas-water separator 11 and the gas flowmeter 12 are fixed to the back plate 1, and the power supply 4 is fixed to the back surface of the back plate 1. In the implementation process, water is injected into the water tank 5 to a required amount through the water injection port 15 and the water injection port 15 is closed, the power supply 4 is used for supplying power to the water pump 6, so that water enters the resin 7 from the water tank 5 through the water pump 6 and then enters the electrolytic tank 8, then flows back to the water tank 5 through the electrolytic tank oxygen inlet 13, the power supply 4 is used for supplying power to the electrolytic tank 8, oxygen and water generated at the moment flow back to the water tank 5 through the electrolytic tank oxygen inlet 13, oxygen is discharged through the oxygen outlet 9, generated hydrogen enters the gas-water separator 11 through the hydrogen outlet 10, water in the gas-water separator 11 flows back to the water tank 5 through a pipeline, and hydrogen is discharged through the gas flowmeter 12.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. A PEM electrolysis water hydrogen production and oxygen production process display device, comprising a back plate (1), characterized in that: a base (3) is fixedly connected below the back plate (1), a resin (7) is fixedly connected above the base (3), a water pump (6) is fixedly connected to one side of the resin (7), a water tank (5) is fixedly connected above the water pump (6), a water tank oxygen outlet (14) and a water injection port (15) are fixedly connected above the water tank (5), an electrolyzer oxygen inlet (13) is fixedly connected above the water tank (5), and the electrolyzer oxygen inlet An electrolytic cell (8) is fixedly connected to one side of the back plate (13); an oxygen outlet (9) and a hydrogen outlet (10) are fixedly connected to the top of the electrolytic cell (8); a gas-water separator (11) is fixedly connected to the top of the hydrogen outlet (10); a gas flow meter (12) is fixedly connected to the top of the gas-water separator (11); an electrolytic cell stand (2) is movably connected to one side of the back plate (1); a power source (4) is movably connected to one side of the back plate (1); and a first terminal (16) and a second terminal (17) are fixedly connected to the same side of the electrolytic cell (8). 2. A PEM water electrolysis hydrogen and oxygen production process demonstration device according to claim 1, characterized in that: the base (3) and the back plate (1) are connected in an integrated manner, and the external structural dimensions of one side of the electrolytic cell table (2) are consistent with the internal structural dimensions of the hole of the back plate (1). 3. A PEM water electrolysis hydrogen and oxygen production process display device according to claim 1, characterized in that: the water tank (5) and the oxygen inlet (13) of the electrolyzer are integrally connected, and the water tank oxygen outlet (14) and the water tank (5) are integrally connected. 4. A PEM water electrolysis hydrogen and oxygen production process demonstration device according to claim 1, characterized in that: the external structural dimensions of one side of the resin (7) are consistent with the internal structural dimensions of one side of the water pump (6), and the internal structural dimensions of the water pump (6) are consistent with the internal structural dimensions of the water tank (5). 5. A PEM water electrolysis hydrogen and oxygen production process demonstration device according to claim 1, characterized in that: the upper internal structure size of the electrolytic cell (8) is consistent with the external structure size of the hydrogen outlet (10), and the structure size of one side of the power supply (4) is consistent with the internal structure size of the back plate (1). 6. A PEM water electrolysis hydrogen and oxygen production process demonstration device according to claim 1, characterized in that: the water tank (5) is connected by multiple connecting pipes, and the water tank (5) is connected to the electrolytic cell (8) and the electrolytic cell (8) is connected to the resin (7), and the resin (7) is connected to the water pump (6) and the water pump (6) is connected to the water tank (5), and the electrolytic cell (8) is connected to the gas-water separator (11) and the gas-water separator (11) is connected to the gas flow meter (12).