KR102679532B1 - Bubble hydrogen water generating system - Google Patents

Abstract

According to an embodiment of the present invention, a bubble hydrogen water generation system that generates bubble hydrogen water by dissolving hydrogen in a bubble state in water includes a pump module, an electrolysis module that generates hydrogen by electrolyzing midstream water, and the pump module. An ejector module that receives water, receives hydrogen from the electrolysis module, and moves the received water and hydrogen together in one direction, and receives water and hydrogen from the ejector module, and mixes the received water and hydrogen in a bubble form to form a bubble. It includes a bubble generating module that generates and discharges hydrogen water, wherein the bubble generating module has an inlet on one side through which water and hydrogen discharged from the ejector module are input, an outlet on the other side through which the generated bubbled hydrogen water is discharged, and A main body module extending upward from the inlet and including a discharge part for discharging the introduced water and hydrogen upward, a cover part coupled to the main body module at the upper side of the main body module to form a receiving space together with the main body module, A flow rate increasing module extends upward from the discharge part to increase the flow rate of water and hydrogen coming out of the discharge part, and a discharge pipe protruding upwardly in the receiving space is provided, and water whose flow rate is increased from the flow rate increasing module It includes a nozzle module that allows hydrogen to move through the corresponding discharge pipe and be discharged into the receiving space.

Description

Bubble hydrogen water generation system {BUBBLE HYDROGEN WATER GENERATING SYSTEM}

The present invention relates to a bubble hydrogen water generation system, and more specifically, to a bubble hydrogen water generation system that generates hydrogen water containing nanoscale hydrogen bubbles.

Recently, hydrogen has been attracting great attention due to its various uses, including as a clean energy source, and methods for producing such hydrogen efficiently are being studied in various ways and in depth not only domestically but also internationally.

However, in general, it is difficult for hydrogen or oxygen to dissolve in water more than a certain amount, and most of them become gas and fly away. For this reason, there is already a method of adding various additives to water to retain hydrogen or oxygen in water, but this leads to pure water. A problem arises where it is difficult to make hydrogen or oxygen gas remain in water (ordinary water without additives) for a long time.

In order to solve this problem, this specification will describe a bubble hydrogen water generator that allows hydrogen or oxygen to exist in the form of nanoscale bubbles in water by using the tension of the water itself.

[Prior literature]

Registered Patent 10-2242012

The present invention relates to a bubble hydrogen water generator, and more specifically, to a bubble hydrogen water generator that generates hydrogen water containing nanoscale hydrogen bubbles.

According to an embodiment of the present invention, a bubble hydrogen water generation system that generates bubble hydrogen water by dissolving hydrogen in a bubble state in water includes a pump module, an electrolysis module that generates hydrogen by electrolyzing midstream water, and the pump module. An ejector module that receives water, receives hydrogen from the electrolysis module, and moves the received water and hydrogen together in one direction, and receives water and hydrogen from the ejector module, and mixes the received water and hydrogen in a bubble form to form a bubble. It includes a bubble generating module that generates and discharges hydrogen water, wherein the bubble generating module has an inlet on one side through which water and hydrogen discharged from the ejector module are input, an outlet on the other side through which the generated bubbled hydrogen water is discharged, and A main body module extending upward from the inlet and including a discharge part for discharging the introduced water and hydrogen upward, a cover part coupled to the main body module at the upper side of the main body module to form a receiving space together with the main body module, A flow rate increasing module extends upward from the discharge part to increase the flow rate of water and hydrogen coming out of the discharge part, and a discharge pipe protruding upwardly in the receiving space is provided, and water whose flow rate is increased from the flow rate increasing module It includes a nozzle module that allows hydrogen to move through the discharge pipe and be discharged into the receiving space, and the nozzle module is provided with a screw member extending from the end of the discharge pipe and having a screw shape, and the hydrogen and water with an increased flow rate are provided. After passing through the inner wall and discharge pipe of the nozzle module, it collides with the screw member and hydrogen bubbles dissolved in water are discharged into the receiving space.

The bubble generating module further includes a connection adapter where one side is coupled to the flow rate increasing module and the other side is coupled to the nozzle module to connect the flow rate increasing module and the nozzle module to each other, and hydrogen with an increased flow rate is primarily routed through the discharge pipe. It is converted into bubble form by colliding with the inner wall and screw member of the discharge pipe, and then the water with the increased flow rate collides with the inner wall and screw member of the discharge pipe for the second time, and the bubble hydrogen water mixed with the hydrogen converted into bubble form is discharged into the receiving space. .

The bubble hydrogen water generation system according to an embodiment of the present invention further includes a nano bubble generation module that regenerates bubble hydrogen water by further decomposing the water and hydrogen of the bubble hydrogen water discharged from the bubble generation module into nano-shaped sizes. A hole in the discharge part of the main body module is formed on one side of the upper surface of the main body module forming the receiving space, and a hole in the outlet part is formed on the other side, and hydrogen continuously flows into the receiving space and flows into the upper surface of the receiving space. It is placed at the bottom of the receiving space so that bubble hydrogen water continuously flows in. As hydrogen continuously flows into the receiving space and a certain amount of hydrogen is continuously discharged through the outlet, the bubble hydrogen water in the receiving space is While the water pressure is maintained constant, it is discharged to the outlet, and the width of the internal moving passage of the discharge pipe of the nozzle module becomes smaller toward the top.

The width of the internal moving passage of the flow rate increasing module becomes smaller toward the top, and the internal moving passage of the connection adapter extends upward while maintaining the same width as the width of the upper end of the internal moving passage of the flow rate increasing module, The width of the inlet portion of the discharge pipe of the nozzle module is larger than the width of the internal moving passage of the connection adapter, and becomes smaller toward the top.

The bubble hydrogen water generator included in the bubble hydrogen water generation system of the present invention discharges hydrogen and water into the receiving space through a flow rate increase module, connection adapter, and nozzle module, and the discharged hydrogen and bubble hydrogen water are discharged from the upper and lower sides. Since they are separated from each other and placed inside the receiving space, the bubble hydrogen water is discharged through the outlet while maintaining a constant pressure with minimal pulsation.

1 is a block diagram of a bubble hydrogen water generation system according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of a bubble hydrogen water generating device according to an embodiment of the present invention.
Figure 3 is a cross-sectional view of a bubble hydrogen water generating device according to an embodiment of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts unrelated to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to be "connected" to another part, this includes not only the case where it is "directly connected," but also the case where it is "electrically connected" with another element in between. . In addition, when a part "includes" a certain component, this does not mean excluding other components, unless specifically stated to the contrary, but may further include other components. Refer to the attached drawings below. The present invention will now be described in detail.

Figure 1 is a block diagram of a bubble hydrogen water generating system 1000 according to an embodiment of the present invention.

The bubble hydrogen water generation system 1000 according to an embodiment of the present invention includes a distilled water source 50, an electrolysis module 100, an ejector module 300, a pump module 400, a water source, and a bubble hydrogen water generator. It may include (200).

The distilled water source 50 may provide distilled water to the electrolysis module 100.

The electrolysis module 100 can generate hydrogen and oxygen by electrolyzing distilled water received from the distilled water supply source 50. The electrolysis module 100 may be a hydrogen generating device used in registered patent 10-2413307.

The pump module 400 may draw water from a water source 500 (for example, a water pipe or a water tank) and provide it to the ejector module 300.

The ejector module 300 can receive water from the pump module 400 and hydrogen from the electrolysis module 100 and move the received water and hydrogen together in one direction. To be more specific, water with increased pressure may flow into the pump module 400 into the ejector module 300, and relatively low-pressure hydrogen may flow from the electrolysis module 100. At this time, the diameter of the water inlet pipe of the ejector module 300 gradually decreases, so that the pressure of water becomes lower than the inlet pressure of hydrogen, and accordingly, the introduced hydrogen mixes with water and moves through the outlet of the ejector module 300. It can be. That is, the ejector module 300 may serve to move the received water and hydrogen together. The ejector module 300 of the present invention may be a known module, for example, a known venturi ejector.

The bubble hydrogen water generator 200 can mix water and hydrogen discharged from the ejector module 300 in the form of bubbles to generate bubble hydrogen water and discharge it.

Hereinafter, the bubble hydrogen water generating device 200 will be described in detail with reference to FIGS. 2 and 3.

Figure 2 is an exploded perspective view of the bubble hydrogen water generating device 200 according to an embodiment of the present invention, and Figure 3 is a cross-sectional view of the bubble hydrogen water generating device 200 according to an embodiment of the present invention.

Referring to Figures 2 and 3, the bubble hydrogen water generator 200 includes a main body module 201, a cover part 202, a flow rate increase module 203, a connection adapter 204, and a nozzle module 205. can do.

The main body module 201 may include an inlet 211, an outlet 212, and an outlet 213.

As shown in FIG. 2 , the cover portion 202 may be coupled to the main body module 201 on the upper side of the main body module 201 to form a receiving space (SP) together with the main body module 201 . The accommodation space (SP) may be a space in which the bubble hydrogen water formed by the present invention is accommodated before being discharged.

The inlet 211 is provided on one side of the main body module 201, and water and hydrogen discharged from the ejector module 300 can be introduced into the inlet 211. The pipe of the inlet portion 211 may be formed to extend in one direction as shown in FIG. 2.

The outlet portion 213 is provided on the other side of the main body module 201, and the bubbled hydrogen water generated by the present invention can be discharged from the receiving space SP to the outside through the outlet portion 213.

As shown in FIGS. 2 and 3, the discharge part 212 extends upward from the inlet part 211 and can discharge water and hydrogen introduced into the inlet part 211 upward. The water and hydrogen discharged to the top can be moved to the flow rate increase module 203.

A hole for the discharge part 212 of the main body module 201 may be formed on one side of the upper surface of the main body module 201 forming the receiving space SP, and a hole for the outlet part 213 may be formed on the other side. That is, the outlet portion 213 and the discharge portion 212 may be located at the bottom when viewed as a whole of the bubble hydrogen water generating device 200 of the present invention. Water and hydrogen can be moved to the flow rate increase module 203 through the hole of the discharge part 212, and the bubble hydrogen water generated in the receiving space (SP) can be discharged to the outside through the hole of the outlet part 213. You can.

The flow rate increasing module 203 extends upward from the discharge unit 212 to increase the flow rate of water and hydrogen coming out of the discharge unit 212. The flow rate increasing module 203 may be directly connected to the discharge unit 212 and extend upward.

The width of the internal moving passage of the flow rate increasing module 203 may decrease toward the upper side as shown in FIGS. 2 and 3, and as the width of the diameter of the internal moving passage decreases toward the upper side, the width of the internal moving passage may decrease. The flow rates of water and hydrogen can be increased. As an example of the present invention, the flow rate increasing module 203 may be a venturi adapter capable of increasing the flow rate of fluid.

One side of the connection adapter 204 is coupled to the flow rate increase module 203 and the other side is coupled to the nozzle module 205, so that the flow rate increase module 203 and the nozzle module 205 can be connected to each other.

The internal moving passage of the connection adapter 204 may extend upward while maintaining the same width as the width of the upper end of the internal moving passage of the flow rate increasing module 203, as shown in FIGS. 2 and 3.

Water and hydrogen whose flow rate increases through the flow rate increase module 203 can be moved to the nozzle module 205 through the connection adapter 204, and the connection adapter 204 is connected between the flow rate increase module 203 and the nozzle module. It may be interposed to connect the internal moving passage of the flow rate increase module 203 and the discharge pipe (internal moving passage) of the nozzle module 205. At this time, the width of the inlet of the discharge pipe of the nozzle module 205 is larger than the width of the internal moving passage of the connection adapter 204, as shown in FIGS. 2 and 3, and may become smaller toward the top.

The nozzle module 205 may be provided with a discharge pipe through which water and hydrogen move at an increased flow rate, and a screw member extending from the end of the discharge pipe and having a screw shape as shown in FIG. 2. In Figures 2 and 3, the screw member is shown in the form of a finely cut cross-section to show the internal structure in more detail. As an example of the present invention, the nozzle module 205 may include a spray nozzle such as a known mist nozzle or cone spray jet nozzle, and the types of the nozzle module 205 may be modified in various ways.

The discharge pipe, which is the internal moving passage of the nozzle module 205, may protrude upward from the receiving space (SP), and water and hydrogen pass through the flow rate increase module 203 and the connection adapter 204 and pass through the discharge pipe into the receiving space. It can be discharged as (SP).

Hydrogen and water whose flow rate is increased from the flow rate increase module 203 can move through the discharge pipe of the nozzle module, and the width of the discharge pipe becomes smaller toward the top, colliding with the inner wall of the discharge pipe while the speed is increased, and passing through the discharge pipe. After colliding with the screw member, the hydrogen bubbles dissolved in water may be discharged into the receiving space (SP) in the form of bubbles.

Hydrogen with an increased flow rate is lighter than water, so it first collides with the inner wall and screw member of the discharge pipe and is converted into bubbles, and then the water with an increased flow rate collides with the inner wall and screw member of the discharge pipe secondarily. Hydrogen converted into bubble form is dissolved in water to generate bubble hydrogen water, and the generated bubble hydrogen water can be discharged into the receiving space (SP) through the nozzle module.

To be more specific, as water and hydrogen move through the internal moving passage of the connection adapter 204 and into the discharge pipe of the nozzle module 205, the width of the moving passage suddenly increases, and accordingly, the nozzle module 205 moves. In the discharge pipe of (205), a vortex phenomenon may occur in water and hydrogen, and the water and hydrogen molecules that generate these vortices each have microscopically different masses as they move inside the nozzle member, accelerating their collision with each other. The direction of movement of water and hydrogen can also change in different directions due to the vortex phenomenon. In this state, the direction changes as it encounters the inner wall or screw member of the discharge pipe, and in the system of the present invention in which water and hydrogen continuously flow into the nozzle module, the moment the direction of movement of water changes, the kinetic energy momentarily becomes 0 or changes. At this time, hydrogen is dissolved in water in the form of bubbles, creating bubble hydrogen water, which can be discharged into the receiving space (SP).

Hydrogen (not dissolved in water) discharged by the nozzle module 205 continuously flows in, and because it is relatively light in weight, it can be placed at the top inside the receiving space (SP) and is distributed through the nozzle module 205. The generated bubble hydrogen water also flows continuously and is relatively heavy, so it can be placed on the lower side inside the receiving space (SP). And as described above, hydrogen continuously flows into the receiving space (SP), and a certain amount of hydrogen is continuously discharged through the outlet portion 213. Through this process, the water pressure of the bubbled hydrogen water in the receiving space (SP) It can also be discharged through the outlet 213 in a constant state.

In general, in a system where hydrogen gas and water fluid continuously flow, the inflow amount of water and the inflow amount of hydrogen have irregular values, so a pulsation phenomenon occurs due to gas interference, preventing the gas and fluid from moving at a constant pressure. However, in the present invention, As described above, hydrogen and water are discharged into the receiving space (SP) through the flow rate increase module 203, connection adapter 204, and nozzle module 205, and the discharged hydrogen and bubble hydrogen water are disposed on the upper and lower sides, respectively. Since it is placed inside the receiving space (SP) in a separated state, the bubble hydrogen water can be discharged through the outlet portion 213 while maintaining a constant pressure with minimized pulsation phenomenon.

In some cases, the bubbled hydrogen water discharged through the outlet unit 213 may pass through the nanobubble generation module 600. Since the nano-bubble generation module 600 is a well-known device that generates water and hydrogen in the form of nano-scale bubbles, a detailed description of the nano-bubble generation module 600 will be omitted.

The bubble hydrogen water discharged through the outlet 213 may generally be bubble hydrogen water in the form of micro-scale bubbles. As this bubble hydrogen water passes through the nano-bubble generation module 600, it is broken down into smaller pieces than before. Nanobubble hydrogen water can be created in which hydrogen is dissolved in water in a bubble state. The nanobubble generating module 600 may be a microbubble generator disclosed in well-known registered patent 10-2100074.

The above-described embodiments are for illustrative purposes, and those skilled in the art will recognize that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. You will understand. Therefore, the above-described embodiments should be understood in all respects as illustrative and not restrictive. For example, each component described as single may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope sought to be protected through this specification is indicated by the patent claims described later rather than the detailed description, and should be interpreted to include the meaning and scope of the claims and all changes or modified forms derived from the equivalent concept.

100: electrolysis module 202: cover part
200: Bubble hydrogen water generator 203: Flow rate increase module
201: main body module 204: connection adapter

Claims (4)

In the bubble hydrogen water generation system that generates bubble hydrogen water by dissolving hydrogen in a bubble state in water,
pump module;
An electrolysis module that generates hydrogen by electrolyzing midstream water;
An ejector module that receives water from the pump module and hydrogen from the electrolysis module and moves the received water and hydrogen together in one direction;
a bubble generating module that receives water and hydrogen from the ejector module, mixes the received water and hydrogen in the form of bubbles to generate bubble hydrogen water, and discharges it; and
It includes a nano-bubble generation module that regenerates the bubble hydrogen water by further decomposing the water and hydrogen of the bubble hydrogen water discharged from the bubble generation module into nano-shaped sizes,
The bubble generation module is
It includes an inlet part through which the water and hydrogen discharged from the ejector module are injected on one side, an outlet part through which the generated bubbled hydrogen water is discharged on the other side, and an outlet part extending upward from the inlet part and discharging the injected water and hydrogen upward. a main body module;
a cover part that is coupled to the main body module at an upper side of the main body module and forms a receiving space together with the main body module;
a flow rate increasing module extending upward from the discharge unit to increase the flow rate of water and hydrogen coming out of the discharge unit;
a nozzle module provided with a discharge pipe protruding upwardly from the receiving space and allowing water and hydrogen whose flow rate is increased from the flow rate increasing module to move through the discharge pipe and be discharged into the receiving space; and
The bubble generating module has one side coupled to the flow rate increasing module and the other side coupled to the nozzle module, and includes a connection adapter that connects the flow rate increasing module and the nozzle module to each other,
The nozzle module is provided with a screw member extending from the end of the discharge pipe and having a screw shape,
After the hydrogen and water with increased flow velocity pass through the inner wall and discharge pipe of the nozzle module, they collide with the screw member, and hydrogen bubbles dissolved in water are discharged into the receiving space.
Hydrogen with an increased flow rate first collides with the inner wall and screw member of the discharge pipe and is converted into bubble form, and then water with an increased flow rate collides with the inner wall and screw member of the discharge pipe secondarily and mixes with the hydrogen converted into bubble form. The bubbled hydrogen water is discharged into the receiving space,
A hole in the discharge part of the main body module is formed on one side of the upper surface of the main body module forming the receiving space, and a hole in the outlet part is formed on the other side,
Hydrogen continuously flows into the receiving space and is placed on the upper side of the receiving space, and bubble hydrogen water continuously flows into the receiving space and is placed on the lower side of the receiving space.
As hydrogen continues to flow into the receiving space and a certain amount of hydrogen is continuously discharged through the outlet, the bubble hydrogen water in the receiving space is discharged from the outlet while the water pressure is maintained constant.
A bubble hydrogen water generating system, characterized in that the width of the internal moving passage of the discharge pipe of the nozzle module becomes smaller toward the top. delete delete According to claim 1,
The width of the internal moving passage of the flow rate increasing module becomes smaller toward the top, and the internal moving passage of the connection adapter extends upward while maintaining the same width as the width of the upper end of the internal moving passage of the flow rate increasing module, A bubble hydrogen water generating system, characterized in that the width of the inlet portion of the discharge pipe of the nozzle module is larger than the width of the internal moving passage of the connection adapter and becomes smaller toward the top.