CN215103594U

CN215103594U - Visualized bottle assembly and hydrogen and oxygen generation equipment

Info

Publication number: CN215103594U
Application number: CN202120054709.5U
Authority: CN
Inventors: 张涛恭
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-01-11
Filing date: 2021-01-11
Publication date: 2021-12-10
Anticipated expiration: 2031-01-11

Abstract

The utility model discloses a visualization bottle assembly and oxyhydrogen generating equipment, the visualization bottle assembly comprises a mounting plate and a plurality of visualization bottles, the front surface of the mounting plate is provided with a plurality of mounting grooves, the back surface of the mounting plate is provided with a plurality of first connecting pipes, and the mounting grooves are provided with jacks communicated with the corresponding first connecting pipes; the front of the visual bottle is of a transparent or semitransparent structure, the front of the visual bottle is provided with an air outlet pipe, the back of the visual bottle is provided with a second connecting pipe, the visual bottle is positioned in the mounting groove, and the second connecting pipe is inserted into the jack. Through setting up a plurality of mounting grooves on the mounting panel, the back of mounting groove is provided with first connecting pipe in order to be used for export gas, and can hold a certain amount of water in the visual bottle, and the water in the visual bottle is at the in-process of export gas on the one hand, and gas enters into and produces the bubble in the visual bottle so that the user can audio-visually know the actual gas output, and the hydroenergy in the visual bottle of on the other hand can cool down the gas of output, and then improves user experience nature.

Description

Visualized bottle assembly and hydrogen and oxygen generation equipment

Technical Field

The utility model relates to a water electrolysis technical field especially relates to a visualizer bottle subassembly and oxyhydrogen generating equipment.

Background

At present, the conventional way of obtaining hydrogen in people's daily life is to utilize electrolysis water to produce hydrogen, and conventional oxyhydrogen generating equipment disposes oxyhydrogen generation subassembly and water tank usually, and the water in the water tank enters into the oxyhydrogen generation subassembly, through carrying out the electrolysis to water in order to produce hydrogen and oxygen. For example: chinese patent No. 201920076259.2 discloses an oxyhydrogen generator and an oxyhydrogen generator, wherein a user uses the oxyhydrogen generator to absorb hydrogen by connecting a hydrogen outlet of the oxyhydrogen generator through an air pipe. However, in actual use, a user cannot intuitively know the gas output of the hydrogen in the process of absorbing the hydrogen through the gas pipe; in addition, since heat is generated in the process of electrolyzing water, the temperature of the output gas is high, and the user experience is poor. Therefore, how to design an oxyhydrogen generating device capable of improving user experience is the technical problem to be solved by the utility model.

Disclosure of Invention

The utility model discloses the technical problem that will solve is: the utility model provides a visualization bottle subassembly and oxyhydrogen emergence equipment realizes that the user can observe the condition of giving vent to anger to utilize the water in the visual bottle to cool off the gas of output, with improvement user experience nature.

The technical scheme provided by the utility model is that, a visualization bottle component comprises a mounting plate and a plurality of visualization bottles, wherein a plurality of mounting grooves are arranged on the front surface of the mounting plate, a plurality of first connecting pipes are arranged on the back surface of the mounting plate, and jacks communicated with the corresponding first connecting pipes are arranged in the mounting grooves; the front surface of the visual bottle is of a transparent or semitransparent structure, the front surface of the visual bottle is provided with an air outlet pipe, the back surface of the visual bottle is provided with a second connecting pipe, the visual bottle is positioned in the mounting groove, and the second connecting pipe is inserted into the jack.

Furthermore, an air flow channel is arranged in the visible bottle and communicated with the second connecting pipe.

Furthermore, the second connecting pipe and the air outlet pipe are positioned at the upper part of the visible bottle, the upper part of the airflow channel is of a closed structure, and the upper part of the airflow channel is of an open structure.

Further, a sealing ring is arranged in the jack.

Furthermore, positioning ribs are arranged in the mounting groove and are symmetrically arranged on two sides of the groove wall of the mounting groove.

The utility model also provides an oxyhydrogen generating device, which comprises a shell, an oxyhydrogen generating assembly and a water tank, wherein the oxyhydrogen generating assembly and the water tank are arranged in the shell; the hydrogen outlet is connected with a first connecting pipe in the visualization bottle component through an air pipe.

Further, a mounting plate in the visualization bottle assembly is arranged on the shell; alternatively, the mounting plate in the visualization bottle assembly and the housing are of a unitary structure.

Furthermore, an oxygen outlet is formed in the water tank and connected with one of the first connecting pipes in the visualization bottle assembly through an air pipe.

Further, the gas-water separation device also comprises a gas-water separation component, which comprises a separation cylinder, a floating body, an upper end cover and a lower end cover; the upper end cover is provided with an air inlet pipe and an exhaust pipe, the lower end cover is provided with a water outlet, the upper end cover is arranged on an upper port of the separation cylinder, the lower end cover is arranged on a lower port of the separation cylinder, an air-water separation cavity is formed between the separation cylinder and the upper end cover as well as between the separation cylinder and the lower end cover, the floating body is arranged in the separation cylinder, and the bottom of the floating body is provided with a plugging part for plugging the water outlet;

wherein, the hydrogen export with be provided with between the first connecting pipe the gas-water separation subassembly, the oxygen export with be provided with between the first connecting pipe the gas-water separation subassembly, the hydrogen export with correspond intake-tube connection, the oxygen export with correspond intake-tube connection, the blast pipe with first connecting pipe is connected.

Furthermore, a sealing plug protruding downwards is arranged at the bottom of the floating body, and the sealing plug is the plugging part.

Further, the exhaust pipe is also connected with a backpressure valve; or the exhaust pipe is also connected with a connecting air pipe, an aeration stone is arranged in the connecting air pipe, and the connecting air pipe is connected with the first connecting pipe.

Compared with the prior art, the utility model discloses an advantage is with positive effect: through setting up a plurality of mounting grooves on the mounting panel, the back of mounting groove is provided with first connecting pipe in order to be used for export gas, and can hold a certain amount of water in the visual bottle, and the water in the visual bottle is at the in-process of export gas on the one hand, and gas enters into and produces the bubble in the visual bottle so that the user can audio-visually know the actual gas output, and the hydroenergy in the visual bottle of on the other hand can cool down the gas of output, and then improves user experience nature.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive labor.

FIG. 1 is a schematic structural view of an embodiment of the hydrogen-oxygen generating apparatus of the present invention;

FIG. 2 is a partial schematic view of an embodiment of the oxyhydrogen generation apparatus of the present invention;

FIG. 3 is a schematic view of a visualized bottle assembly in an embodiment of the hydrogen-oxygen generation device of the present invention;

FIG. 4 is a partial exploded view of a visualization bottle assembly in an embodiment of the oxyhydrogen generation apparatus of the present invention;

FIG. 5 is a sectional view of a visual bottle in an embodiment of the oxyhydrogen generation apparatus of the present invention;

FIG. 6 is a sectional view of the gas-water separation module in the embodiment of the hydrogen-oxygen generation device of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-6, the present embodiment provides an oxyhydrogen generation apparatus, which comprises a housing 1, and an oxyhydrogen generation assembly 3 and a water tank 2 disposed inside the housing, wherein the water tank 2 is provided with a circulation inlet (not labeled) and a circulation outlet (not labeled), the oxyhydrogen generation assembly 3 is provided with a water inlet (not labeled), a water return port (not labeled) and a hydrogen outlet (not labeled), the water inlet is connected to the circulation outlet, and the water return port is connected to the circulation inlet.

Wherein, in order to meet the requirement of the user for visual gas output state, the gas purifier also comprises a visualization bottle component 5.

The visualization bottle assembly 5 comprises a mounting plate 51 and a plurality of visualization bottles 52, wherein the front surface of the mounting plate is provided with a plurality of mounting grooves 511, the back surface of the mounting plate is provided with a plurality of first connecting pipes 512, and the mounting grooves are internally provided with jacks 513 communicated with the corresponding first connecting pipes; the front surface of the visual bottle is of a transparent or semitransparent structure, the front surface of the visual bottle is provided with an air outlet pipe 521, the back surface of the visual bottle is provided with a second connecting pipe 522, the visual bottle is positioned in the mounting groove, and the second connecting pipe is inserted into the jack.

Specifically, during the actual assembly process, the hydrogen outlet of the hydrogen-oxygen generating assembly 3 is connected to the corresponding first connecting pipe 512 through the gas pipe. In use, the visible bottle 52 is filled with a certain amount of water, and the hydrogen generated by the hydrogen and oxygen generating assembly 3 enters the visible bottle 52 through the first connection pipe 512. The hydrogen gas is emitted upwards from the water layer in the visible bottle 52 to generate bubbles, so that the user can conveniently observe the gas emission condition through the visible bottle 52. Meanwhile, the water in the visual bottle 52 can also play a role in cooling the hydrogen gas, so as to improve the user experience.

In order to ensure that the gas entering the sight glass can be transported into the water layer at the bottom, a gas flow channel 523 is provided in the sight glass and is communicated with the second connecting pipe. Specifically, the gas entering the visible bottle from the first connecting pipe flows downwards through the gas flow channel, enters the water layer at the bottom layer, then bubbles in the water and is output, and the gas is discharged to the outside through the gas outlet pipe. The second connecting pipe and the air outlet pipe are positioned at the upper part of the visible bottle, the upper part of the airflow channel is of a closed structure, and the upper part of the airflow channel is of an open structure.

Further, in order to improve the connection sealing performance, a sealing ring 514 is provided in the insertion hole. Specifically, after the visual bottle is placed in the mounting groove, the second connecting pipe is inserted into the insertion hole, and the second connecting pipe can be sealed by the sealing ring.

Furthermore, in order to improve the connection reliability of the visual bottle, positioning ribs 515 are disposed in the mounting groove, and the positioning ribs are symmetrically disposed on two sides of the wall of the mounting groove. Specifically, after the visual bottle is placed in the mounting groove, the positioning ribs on two sides can clamp the visual bottle, so that the use reliability is improved.

The mounting plate may be directly fixed to the housing, or may be an integral structure with the housing, which is not limited herein.

Still further, according to the needs of users, an oxygen outlet may be provided on the water tank, and the oxygen outlet is connected to one of the first connecting pipes in the visualizing bottle assembly through an air pipe.

Specifically, in the process of electrifying and electrolyzing the water in the hydrogen and oxygen generation assembly 3, the generated oxygen flows into the water tank along with the circulating water, and the oxygen outlet is arranged on the water tank, so that the generated oxygen is output through the oxygen outlet and flows into the corresponding visualization bottle, and the requirement of a user for oxygen inhalation is met.

Based on above-mentioned technical scheme, optionally, because in the electrolysis process, have more moisture to mix in wherein in oxygen or the hydrogen, in order to effectual realization gas-liquid separation, then oxyhydrogen generating equipment still disposes gas-water separation subassembly 4, gas-water separation subassembly 4's effect is used for effectively dividing the water in the air current and manages. Specifically, the gas-water separation assembly comprises a separation cylinder 41, a floating body 42, an upper end cover 43 and a lower end cover 44; an air inlet pipe 431 and an air outlet pipe 432 are arranged on the upper end cover 43, a water outlet 441 is arranged on the lower end cover 44, the upper end cover 43 is arranged on the upper port of the separation cylinder 41, the lower end cover 44 is arranged on the lower port of the separation cylinder 41, the air-water separation cavity is formed between the separation cylinder 41 and the upper end cover 43 as well as between the separation cylinder 41 and the lower end cover 44, the floating body 42 is arranged in the separation cylinder 41, and a blocking part 421 for blocking the water outlet 441 is arranged at the bottom of the floating body 42. The exhaust pipe 432 and the corresponding first connection pipe are connected together through a gas pipe, and the gas pipe 431 may be connected to a hydrogen outlet or an oxygen outlet as needed.

Specifically, for example, the hydrogen gas generated by the hydrogen-oxygen generation assembly 3 contains much moisture, and after entering the separation cylinder 41, most of the moisture will fall into the bottom of the separation cylinder 41 due to the heavy weight of the moisture, and the hydrogen gas will be discharged from the exhaust pipe 432. During the gas-water separation process, the floating body 2 blocks the water outlet 41 through the blocking portion 421 due to the gravity, so as to prevent or reduce the gas leakage from the water outlet 41.

The separation cylinder 41 may be an independent component from the upper end cap 43 and the lower end cap 44, or the separation cylinder 41 may be an integral structure with the upper end cap 43 or the lower end cap 44.

As the usage time is prolonged, a certain amount of water is accumulated at the bottom of the separation cylinder 41, and as the amount of accumulated water at the bottom is increased, the buoyancy received by the floating body 42 is greater than the gravity of the floating body 42, so that the floating body 42 floats and leaves the drain port 441 under the buoyancy, thereby opening the drain port 441. After the water outlet 441 is opened, a positive pressure state is formed in the gas-water separation cavity due to the injection of hydrogen gas into the gas-water separation cavity, and accumulated water at the bottom of the gas-water separation cavity is quickly discharged through the water outlet 441 by utilizing the air pressure in the gas-water separation cavity. In a short time, the water level in the gas-water separation chamber will drop along with it, so that the gravity of the floating body 42 is greater than the buoyancy, and the floating body 42 falls down again and abuts against the drain port 441 to automatically close the drain port 441, thereby preventing hydrogen leakage.

The air inlet pipe 431 and the air outlet pipe 432 are arranged side by side, the air outlet direction of the air inlet pipe 431 faces downwards, and the air outlet direction of the air outlet pipe 432 faces upwards. Since the air outlet directions of the air inlet pipe 431 and the air outlet pipe 432 are arranged in the opposite direction, the air flow entering the air-water separation chamber from the air inlet pipe 431 can sufficiently separate moisture.

In addition, as for the expression entity of the blocking portion 421, a sealing plug may be adopted, that is, a sealing plug protruding downward is provided at the bottom of the floating body 42, and the sealing plug is the blocking portion 421. Specifically, when the gravity of the floating body 42 is greater than the buoyancy of the floating body, the sealing plug blocks the drain opening 441 at the bottom, and the sealing plug and the drain opening 441 form a sealing surface with a better airtight effect by combining the accumulated water at the bottom. And when the buoyancy is larger than the gravity, the sealing plug moves upwards along with the floating body 42 to open the water outlet 441.

In a preferred embodiment, a pressure control module (not shown) is further connected to the exhaust pipe 432. Specifically, the pressure control module is arranged on the exhaust pipe 432 and can limit the output gas, so that the gas-water separation cavity is in a positive pressure state with a certain pressure value. In the positive pressure state, the floating body 42 in the gas-water separation chamber can further utilize the air pressure to more effectively seal and shield the water outlet 441, thereby improving the use reliability. Meanwhile, the positive pressure at a certain pressure value can also discharge the accumulated water quickly by the air pressure when the water outlet 441 is opened by the floating body 42. The representation entity of the pressure control module can be in various forms, such as: the pressure control module can be a backpressure valve connected to the exhaust pipe 432, or the pressure control module comprises a connecting air pipe and an aeration stone, the aeration stone is plugged in the connecting air pipe, and the connecting air pipe is connected with the exhaust pipe 432.

Compared with the prior art, the utility model discloses an advantage is with positive effect: through dispose a plurality of oxyhydrogen generation subassemblies in the shell, utilize a plurality of oxyhydrogen generation subassemblies to work together and satisfy the requirement of high yield, like this, just need not to adopt large-size ion exchange membrane, and produce hydrogen with a plurality of oxyhydrogen generation subassemblies that dispose small-size ion exchange membrane, under the condition that satisfies portable operation requirement, effectual increase oxyhydrogen generation facility's gas output to improve user experience nature.

Claims

1. A visualized bottle assembly is characterized by comprising a mounting plate and a plurality of visible bottles, wherein a plurality of mounting grooves are formed in the front surface of the mounting plate, a plurality of first connecting pipes are arranged on the back surface of the mounting plate, and jacks communicated with the corresponding first connecting pipes are formed in the mounting grooves; the front surface of the visual bottle is of a transparent or semitransparent structure, the front surface of the visual bottle is provided with an air outlet pipe, the back surface of the visual bottle is provided with a second connecting pipe, the visual bottle is positioned in the mounting groove, and the second connecting pipe is inserted into the jack.

2. The visualization bottle assembly of claim 1, wherein an air flow channel is disposed in the visualization bottle, the air flow channel being in communication with the second connecting tube.

3. The visualization bottle assembly of claim 2, wherein the second connecting tube and the outlet tube are located at an upper portion of the visualization bottle, the upper portion of the gas flow channel being of a closed configuration and the upper portion of the gas flow channel being of an open configuration.

4. The visualization bottle assembly of claim 2, wherein a sealing ring is disposed in the receptacle.

5. The visualization bottle assembly of claim 1, wherein the mounting slot has positioning ribs disposed therein, the positioning ribs being symmetrically disposed on both sides of a slot wall of the mounting slot.

6. An oxyhydrogen generation device, comprising a housing, and an oxyhydrogen generation assembly and a water tank arranged inside the housing, the water tank being connected with the oxyhydrogen generation assembly through a water pipe, the oxyhydrogen generation assembly having a hydrogen gas outlet, characterized by further comprising the visualizing bottle assembly as in any one of claims 1 to 5; the hydrogen outlet is connected with a first connecting pipe in the visualization bottle component through an air pipe.

7. The hydrogen and oxygen generation device according to claim 6, wherein the mounting plate in the sight glass assembly is disposed on the housing; alternatively, the mounting plate in the visualization bottle assembly and the housing are of a unitary structure.

8. The oxyhydrogen generation apparatus according to claim 6, wherein the water tank is provided with an oxygen outlet connected to one of the first connection pipes in the visualizing bottle assembly through an air pipe.

9. The oxyhydrogen generation apparatus according to claim 8, further comprising a gas-water separation assembly comprising a separation cylinder, a float, an upper end cap and a lower end cap; the upper end cover is provided with an air inlet pipe and an exhaust pipe, the lower end cover is provided with a water outlet, the upper end cover is arranged on an upper port of the separation cylinder, the lower end cover is arranged on a lower port of the separation cylinder, an air-water separation cavity is formed between the separation cylinder and the upper end cover as well as between the separation cylinder and the lower end cover, the floating body is arranged in the separation cylinder, and the bottom of the floating body is provided with a plugging part for plugging the water outlet;

10. The oxyhydrogen generation apparatus according to claim 9, characterized in that a backpressure valve is further connected to the exhaust pipe; or the exhaust pipe is also connected with a connecting air pipe, an aeration stone is arranged in the connecting air pipe, and the connecting air pipe is connected with the first connecting pipe.