JP2020124685A - Electrolytic hydrogen water generator - Google Patents

Abstract

To provide an electrolytic hydrogen water generator capable of diffusing electrolytic hydrogen water farther in a pooled water and obtain a visual effect as if a large amount of hydrogen is released.SOLUTION: An electrolytic hydrogen water generator includes electrolysis of water by introducing a pooled water into a housing while floating or settling in the pooled water, and then releasing the generated electrolytic hydrogen water from the housing into the pooled water, equipped with diffusion assistance means to facilitate diffusion of the electrolytic hydrogen water by introducing air into the body of the housing and discharging it as an auxiliary fluid into the pooled water.SELECTED DRAWING: Figure 2

Description

The present invention relates to an electrolytic hydrogen water generator that generates electrolytic hydrogen water in a state of floating or sinking in the accumulated water and diffuses the electrolytic hydrogen water into the accumulated water.

Conventionally, an electrolyzed hydrogen water generator for producing electrolyzed water (hereinafter referred to as electrolyzed hydrogen water) in which hydrogen generated by electrolysis of water is contained in a dissolved or dispersed state for various uses such as drinking and bathing. It has been known.

Among them, an electrolytic hydrogen water generator that floats the device itself on or below the surface of the accumulated water and releases the electrolytic hydrogen water into the accumulated water is used, for example, by being immersed in the accumulated water (bath water) in a bathtub. As a result, hydrogen can be dissolved in the bath water, and if the user soaks it in a bathtub, the entire body can enjoy the effect of hydrogen water (for example, refer to Patent Document 1).

JP, 2017-205749, A

By the way, when the above-described electrolytic hydrogen water generator for stored water is used in bath water, the electrolytic hydrogen water released into the bath water, particularly hydrogen gas dispersed in the electrolytic water, is extremely invisible to the naked eye. It becomes a small bubble and becomes slightly cloudy smoke-like and slowly drifts in the bath water.

Therefore, a considerable amount of time was required for the electrolytic hydrogen water to reach the entire bath water.

Of course, if the user stirs the bath water by hand during use, or if the apparatus itself is provided with a stirring blade, it is not impossible to realize the rapid diffusion of electrolytic hydrogen water into the bath water.

However, there are many people who strongly think that hydrogen is a gaseous state among the users of the device, and even if bubbles rising like smoke are visually recognized as being sprayed by the water flow by the hand or the stirring blade. There was almost no trace of possible hydrogen release, which further impaired the user's image.

The present invention has been made in view of such circumstances, and is capable of diffusing electrolyzed hydrogen water farther in the stored water and obtaining a visual effect as if a large amount of hydrogen was released. Provided is an electrolytic hydrogen water generator capable of performing the above.

In order to solve the above-mentioned conventional problems, in the electrolytic hydrogen water producing apparatus according to the present invention, (1) introduced electrolytically by introducing the accumulated water into the housing in a state of floating or sinking in the accumulated water to generate electrolytic hydrogen water. Is a electrolytic hydrogen water generator for discharging the electrolytic hydrogen water from the casing into the stored water, the diffusion assisting means for promoting diffusion of the electrolytic hydrogen water by introducing air into the casing and ejecting air into the stored water as an auxiliary fluid. I decided to prepare.

The electrolytic hydrogen water generator according to the present invention is also characterized by the following points.
(2) The diffusion auxiliary means includes a venturi portion having a main pipe for accelerating a fluid to generate a low pressure portion by a constricted shape in the downstream direction and a branch pipe facing the low pressure portion, and the accumulated water or the Electrolyzed hydrogen water and the air are introduced from the main pipe or the branch pipe, respectively, and gas-liquid mixed to generate the auxiliary fluid.
(3) A hydrogen water discharge port for discharging electrolytic hydrogen water and an auxiliary fluid discharge port for discharging an auxiliary fluid are separately provided on the contact surfaces of the housing with the stored water, and the hydrogen water discharge port is The auxiliary fluid is formed at a position where the auxiliary fluid can be ejected into the flow region of the accumulated water that is disturbed by the air bubbles generated in the water by the ejection of the auxiliary fluid from the ejection port.
(4) The air is introduced into the branch pipe while the accumulated water is introduced into the main pipe.
(5) A mixed fluid jet is formed on a contact surface of the casing with the accumulated water, which is commonly used for discharging electrolytic hydrogen water and jetting an auxiliary fluid, and the mixed fluid jet is provided at a downstream end of the venturi portion. Connecting to the outlet, and introducing the electrolyzed hydrogen water and air from the main pipe or the branch pipe, mixing them, and ejecting them into the stored water.
(6) The electrolysis hydrogen water is introduced into the main pipe while air is introduced into the branch pipe.
(7) The Venturi part includes a first branch pipe and a second branch pipe, and while introducing the accumulated water into the main pipe, the auxiliary fluid is introduced into the first branch pipe, and the second branch pipe is introduced. Is configured to introduce electrolytic hydrogen water.
(8) The air is introduced into the main pipe while the electrolytic hydrogen water is introduced into the branch pipe.
(9) The housing is configured to float in the accumulated water, and is configured to move on the water surface by the jet of the auxiliary fluid.

According to the present invention, there is provided an electrolytic hydrogen water producing apparatus which introduces the accumulated water into the casing in a state of floating or sinking in the accumulated water to electrolyze, and releases the generated electrolytic hydrogen water from the casing into the accumulated water. Since the diffusion assisting means for promoting the diffusion of the electrolyzed hydrogen water by introducing air into the housing and ejecting it as an auxiliary fluid into the reservoir water, the electrolyzed hydrogen water can be diffused further in the reservoir water. It is possible to provide an electrolytic hydrogen water generator capable of obtaining a visual effect as if a large amount of hydrogen was released.

It is explanatory drawing of the usage aspect of the electrolytic hydrogen water production|generation apparatus which concerns on this embodiment. It is an explanatory view showing composition of an electrolysis hydrogen water generating device concerning a 1st embodiment. It is explanatory drawing which showed the structure of the electrolytic hydrogen water production|generation apparatus which concerns on 2nd Embodiment. It is explanatory drawing which showed the structure of the electrolytic hydrogen water production|generation apparatus which concerns on 3rd Embodiment. It is explanatory drawing which showed the structure of the electrolytic hydrogen water production|generation apparatus which concerns on 4th-6th embodiment. It is explanatory drawing which showed the structure of the electrolytic hydrogen water production|generation apparatus which concerns on 7th and 8th embodiment. It is explanatory drawing which showed the structure of the electrolytic hydrogen water production|generation apparatus which concerns on 9th Embodiment.

TECHNICAL FIELD The present invention relates to an electrolytic hydrogen water producing apparatus that introduces accumulated water into a housing in a state of floating or sinking in the accumulated water to electrolyze, and releases the generated electrolytic hydrogen water from the housing to the accumulated water.

Further, in particular, the electrolytic hydrogen water generator according to the present embodiment can diffuse the electrolytic hydrogen water farther in the stored water, and at the same time obtain a visual effect as if a large amount of hydrogen was released. It is characterized in that it can be done.

Here, the accumulated water in the present specification is not particularly limited. That is, the usage of the accumulated water is not limited, and may be, for example, for bathing or drinking.

As an example, the electrolytic hydrogen water producing apparatus according to the present embodiment can be understood as an apparatus for diffusing electrolytic hydrogen water into bath water stored in a bathtub, and the inside of the glass pot can be seen. It can be understood as a device about the size of a palm for generating electrolytic hydrogen water for drinking.

Further, the electrolytic hydrogen water generator according to this embodiment is used in a state of floating or sinking in the accumulated water. Here, the floating state includes a state of floating on the surface of the accumulated water and a state of floating in the water without bottoming. In addition, the subsided state includes a state of bottoming and a state of floating in water without being exposed on the water surface.

And, a characteristic point of the electrolytic hydrogen water producing apparatus according to the present embodiment is that diffusion assisting means for promoting diffusion of the electrolytic hydrogen water by introducing air into the housing and ejecting air into the stored water as an auxiliary fluid. There is a point equipped with.

Here, the auxiliary fluid is a fluid ejected to promote and assist the diffusion of electrolyzed hydrogen water. For example, when the air introduced into the housing is ejected as it is, the air is an auxiliary fluid, and the introduced air is mixed and ejected while the accumulated water introduced into the separate housing and the electrolytic hydrogen water produced are the main components. In this case, this air-containing water flow is the auxiliary fluid, and when the accumulated air or electrolytic hydrogen water is mixed and ejected while mainly using the introduced air, the atomized water-containing air flow becomes the auxiliary fluid. In particular, this embodiment is common in that the auxiliary fluid contains air in any case.

In addition, when the auxiliary fluid is ejected from the housing, it can be ejected separately from the electrolytic hydrogen water or can be ejected together with the electrolytic hydrogen water. In the following description, the fluid ejected from the casing in the mixed state of the electrolytic hydrogen water and the auxiliary fluid is also referred to as diffusive electrolytic hydrogen water for convenience.

Then, according to the electrolytic hydrogen water producing apparatus according to the present embodiment having such a configuration, since it is provided with the diffusion assisting means for promoting the diffusion of the electrolytic hydrogen water by jetting the auxiliary fluid containing air, it is as if The electrolyzed hydrogen water can be diffused farther in the stored water while producing a visual effect as if a large amount of hydrogen was being released.

In particular, compared with the method of diffusing electrolytic hydrogen water by simply convection the accumulated water like an underwater stirring blade, since it diffuses with the auxiliary fluid that contains air and is vigorously ejected, rich bubbles containing hydrogen gas are generated. It is possible for the user to visually recognize and efficiently produce the visual effect.

Further, in the electrolytic hydrogen water generator according to the present embodiment, the diffusion auxiliary means has a main pipe that accelerates the fluid to form a low pressure portion due to a constricted shape in the downstream direction, and a branch pipe that faces the low pressure portion. A venturi portion may be provided, and the accumulated water or the electrolytic hydrogen water and the air may be introduced from the main pipe or the branch pipe, respectively, and gas-liquid mixed to generate the auxiliary fluid.

That is, while supplying either one of the air and the accumulated water or the electrolytic hydrogen water to the main pipe of the venturi part, the other one is supplied to the branch pipe, and the gas-liquid mixture is performed to form the above-mentioned air-containing water stream or water-containing air stream. The auxiliary fluid or the diffusible electrolytic hydrogen water may be generated and ejected.

With such a configuration, a uniform auxiliary fluid can be prepared by efficient gas-liquid mixing, and stable diffusion of electrolyzed hydrogen water in the stored water can be performed.

Further, the electrolytic hydrogen water generating device is provided with a hydrogen water discharge port for discharging electrolytic hydrogen water and an auxiliary fluid discharge port for discharging an auxiliary fluid, separately on the contact surface of the housing with the accumulated water, and The hydrogen water discharge port may be formed at a position where it can be jetted into the flow region of the accumulated water that is disturbed by the air bubble group generated in the water due to the jet of the auxiliary fluid from the auxiliary fluid jet port.

Here, the flow region of the accumulated water disturbed by the air bubble group is not only the range in which the auxiliary fluid ejected from the auxiliary fluid ejection port flows, but also the range in which the surrounding fluid is drawn in by the flow of the auxiliary fluid (hereinafter Also referred to as a drawing flow).

With such a configuration, a part of the electrolytic hydrogen water discharged from the hydrogen water discharge port can be visually recognized as a milky bubble that drifts like a smoke, while the rest flows through the drawing flow of the auxiliary fluid. It is possible to join and diffuse the light in the same manner and improve the interest of the user.

Further, it may be configured to introduce the accumulated water into the main pipe while introducing the air into the branch pipe.

With such a configuration, an air-containing water flow uniformly containing air bubbles can be ejected as an auxiliary fluid, and the electrolytic hydrogen water can be more efficiently diffused into the reservoir water.

Further, the electrolytic hydrogen water generating device does not discharge the electrolytic hydrogen water and the auxiliary fluid separately, but the contact surface with the accumulated water of the casing which is shared for discharging the electrolytic hydrogen water and jetting the auxiliary fluid. And a downstream end of the venturi portion is connected to the mixed fluid jet, and the electrolytic hydrogen water and air are introduced from the main pipe or the branch pipe respectively and mixed and stored. It may be jetted into the water.

That is, while supplying either one of air and electrolyzed hydrogen water to the main pipe of the venturi part while supplying the other to the branch pipe, gas-liquid mixing is performed to perform the diffusive electrolysis of the air-containing water stream or the water-containing stream described above. Hydrogen water may be generated and ejected from the mixed fluid ejection port.

With such a configuration, the electrolyzed hydrogen water and the auxiliary fluid can be mixed together in advance before being jetted, and can be discharged in the state of diffusible electrolyzed hydrogen water, and the electrolyzed hydrogen water can be uniformly and uniformly stored in the stored water. It can reach farther.

Further, while introducing the electrolytic hydrogen water into the main pipe, while configuring to introduce air into the branch pipe, to the electrolytic hydrogen water containing hydrogen bubbles, it is possible to further include air in a dispersed state, gas It is possible to discharge as diffusive electrolytic hydrogen water in the form of a gas-containing water flow containing more components.

In addition, the venturi portion includes a first branch pipe and a second branch pipe, and while introducing the accumulated water into the main pipe, the auxiliary fluid is introduced into the first branch pipe and the second branch pipe is introduced into the second branch pipe. May be configured to introduce electrolytic hydrogen water.

With such a configuration, as compared with the case of ejecting diffusible electrolytic hydrogen water in the form of aerated water flow by mixing air while mainly using electrolytic hydrogen water, the ejection flow rate is further secured and the momentum is increased. It can be maintained, and electrolytic hydrogen water can reach farther in the accumulated water to realize efficient diffusion.

It is also possible to introduce the air into the main pipe and introduce the electrolytic hydrogen water into the branch pipe. With such a configuration, the diffusible electrolytic hydrogen water in the form of a water-containing air stream (fog) can be ejected, and the diffusing mode of the electrolytic hydrogen water excellent in bubble formation can be obtained.

Further, in the electrolytic hydrogen water generating device according to the present embodiment, the casing floats in the accumulated water, and may be configured to move on the water surface by the ejection of the auxiliary fluid. With such a configuration, it is possible to diffuse electrolytic hydrogen water together with rich bubbles to every corner of the accumulated water while rotating on the water surface or self-propelled.

Hereinafter, the electrolytic hydrogen water generator according to the present embodiment will be further described with reference to the drawings. In addition, below, although the usage mode of the electrolytic hydrogen water production|generation apparatus which concerns on this embodiment is demonstrated using an example of the usage in the bathtub which uses stored water as bath water, it is not limited to this as mentioned above.

FIG. 1 is an explanatory diagram of a usage mode of the electrolytic hydrogen water generator according to the present embodiment. Here, first, two types of usage of the electrolytic hydrogen water generator will be illustrated and described, and then, variations of each device due to differences in internal configuration and the like will be described with reference to another drawing.

FIG. 1( a) shows an electrolytic hydrogen water generator F of a type that is used by floating on a water surface 12 of a bath water 11 as accumulated water stored in a bath 10.

The electrolytic hydrogen water producing apparatus F discharges the electrolytic hydrogen water 14a while ejecting the auxiliary fluid 13 containing air from the lower part of the housing 20 so as to visually generate a large amount of hydrogen. While performing such an effect, the electrolytic hydrogen water 14a can be diffused into the bath water 11 as indicated by the shaded portion 14b. In the following description, the electrolytic hydrogen water generator F of the type that is floated and used as shown in FIG. 1A is also referred to as a floating type device.

Further, FIG. 1B shows, as another aspect, an electrolytic hydrogen water generator S of a type that is used below the water surface 12 of the bath water 11, that is, in the bath water 11 in a bottomed state. ..

The electrolytic hydrogen water producing apparatus S discharges the electrolytic hydrogen water 14a while ejecting the auxiliary fluid 13 containing air from the upper part of the housing 20 so as to visually generate a large amount of hydrogen. While performing such an effect, the electrolytic hydrogen water 14a can be diffused into the bath water 11 as indicated by the shaded portion 14b. In the following description, the electrolytic hydrogen water producing apparatus S of the type used in the bottomed state in the stored water as shown in FIG. 1B will also be referred to as a bottomed type apparatus. In addition, in FIG. 1B, reference numerals 48 and 49 are a float and a ventilation hose for taking in air to be supplied to the electrolytic hydrogen water generator S arranged in a bottomed state.

Next, various variations of the above-mentioned floating type apparatus and bottom type apparatus will be described while clarifying the internal configuration of the main part. The electrical configuration of the power storage unit, control unit, etc. necessary for the operation of the pump and electrolysis unit disposed inside the device is omitted for convenience of explanation, but provided in each electrolyzed hydrogen water generation device as necessary. Of course.

FIG. 2 is an explanatory diagram schematically showing the internal configuration of the electrolytic hydrogen water generator F1. The electrolytic hydrogen water generator F1 corresponds to the floating type device described above, and discharges the electrolytic hydrogen water 14a and the auxiliary fluid 13 in the form of gas-containing water separately into the bath water 11.

Focusing on the internal configuration, the electrolytic hydrogen water generator F1 is provided with two independent flow paths, an electrolytic water generation flow path 31 and an auxiliary fluid generation flow path 41, in the housing 20 floating on the water surface 12. There is.

The electrolyzed water generation flow path 31 includes a raw water intake port 32, a raw water pump 33, an electrolysis unit 34, and a hydrogen water discharge port 35, which are communicatively connected by a predetermined pipe.

The raw water intake port 32 is a part for collecting stored water, which is raw water for generating electrolytic hydrogen water, that is, the bath water 11, and is in contact with the bath water 11 that is below the water surface on the surface of the casing 20. It is formed on the surface.

A filter 32a for removing dust and dirt contained in the raw water introduced into the housing 20 is arranged at the raw water intake 32, and a raw water pump 33 and an electrolysis section 34 arranged on the downstream side. Prevents problems caused by dust and dirt.

The raw water pump 33 is a pump for feeding the raw water introduced from the raw water intake port 32 to the electrolysis section 34. The raw water pump 33 is electrically connected to a control unit (not shown) and a power storage unit, and is configured to supply the raw water to the electrolysis unit 34 at a predetermined water supply amount.

The electrolysis unit 34 is a part for subjecting the supplied raw water to electrolysis to generate electrolyzed hydrogen water.

Specifically, in the electrolysis unit 34, one or a plurality of positive electrode plates and negative electrode plates applied with relatively different potentials so that water can be electrolyzed are provided. Raw water flowing between the electrode plates is subjected to electrolysis to generate electrolyzed water, and hydrogen gas generated from the surface of the negative electrode plate is diffused in a dissolved or fine bubble state to generate electrolyzed hydrogen water. The electrolysis unit 34 is also electrically connected to a control unit and a power storage unit (not shown), and is configured to perform electrolysis at a predetermined current.

The hydrogen water discharge port 35 is a part from which the electrolytic hydrogen water generated in the electrolysis section 34 is discharged. In this electrolytic hydrogen water generator F1, an auxiliary fluid jet port and a hydrogen water discharge port 35, which will be described later, are provided separately, so that cloudy smoke-like electrolytic hydrogen water is discharged from the hydrogen water discharge port 35 as a bath water. It is discharged into 11.

On the other hand, the auxiliary fluid generation flow path 41 functions as a diffusion auxiliary unit that promotes the diffusion of the electrolytic hydrogen water 14a by introducing air into the housing and ejecting it as the auxiliary fluid 13 into the bath water 11 as accumulated water. It is provided with the accumulated water inlet 42, the main pipe pump 43, the air inlet 44, the venturi portion 45, and the auxiliary fluid ejection port 46, which are connected and connected by a predetermined pipe. There is.

The accumulated water inlet 42 is a portion for introducing accumulated water, which is the main component of the air-containing water-like auxiliary fluid, that is, the bath water 11, and the bath water 11 on the surface of the housing 20 below the water surface. It is formed on the contact surface with.

The main pipe pump 43 is a pump for feeding the accumulated water introduced from the accumulated water inlet 42 to the venturi portion 45. Similar to the raw water pump 33, the main pipe pump 43 is electrically connected to a control unit (not shown) and a power storage unit, and is configured to supply raw water to the Venturi unit 45 at a predetermined water supply amount.

The air introduction port 44 is a portion for introducing air that is a sub-component of the air-containing water-like auxiliary fluid, and is formed on the surface of the housing 20 in the floating state, which is exposed on the water surface. There is.

The venturi part 45 is a part for mixing the accumulated water introduced from the accumulated water inlet 42 and the air introduced from the air inlet 44 to generate an auxiliary fluid.

Specifically, the venturi portion 45 includes a main pipe 45a, a branch pipe 45b, and a mixing chamber 45c, and the upstream proximal end side of the main pipe 45a is connected to the accumulated water inlet 42 via the main pipe pump 43. While the downstream tip side is inside the mixing chamber 45c, the upstream base side of the branch pipe 45b is connected to the air introduction port 44 while the downstream tip side is connected to the mixing chamber 45c.

Further, the main pipe 45a is formed with a speed increasing portion 45d having a shape constricted in the downstream direction in the mixing chamber 45c. Similarly, in the mixing chamber 45c, the downstream end of the branch pipe 45b is the speed increasing portion 45d of the main pipe 45a. It is arranged so as to face the low-pressure portion generated by the acceleration of the accumulated water.

The auxiliary fluid ejection port 46 is a part where the auxiliary fluid generated in the venturi portion 45 is ejected toward the bath water 11, and the downstream end portion of the venturi portion 45 is connected. In this electrolytic hydrogen water generator F1, since the auxiliary fluid to be ejected is in the form of an air-containing water stream, the auxiliary fluid that is hard to lose the buoyancy of the bubbles and can ride on the momentum of the water stream to reach a relatively distant position in the bath water 11 Is gushed to.

In addition, as indicated by hatching on the lower surface side of the electrolytic hydrogen water generator F1, a flow region in which the bath water 11 is disturbed by the air bubbles generated in the water accompanying the ejection of the auxiliary fluid from the auxiliary fluid ejection port 46. 47 is formed.

The hydrogen water discharge port 35 described above is formed at a position where the electrolytic hydrogen water discharged from the hydrogen water discharge port 35 can reach the flow region 47.

Therefore, the electrolyzed hydrogen water discharged from the hydrogen water discharge port 35 reaches the flow in the flow region 47 and is diffused further in the bath water 11.

In addition, the auxiliary fluid contains abundant air bubbles introduced from the air introduction port 44, and the air is mixed in the venturi portion 45 in a uniform state and ejected into the bath water 11. By visually recognizing such bubbles, it is possible to obtain a visual effect as if a large amount of hydrogen was released.

Next, an electrolytic hydrogen water generator F2 according to the second embodiment will be described with reference to FIG. As shown in FIG. 3( a ), the electrolytic hydrogen water generator F 2 is also a floating type device, and the configuration of the electrolytic water generation flow channel 31 and the auxiliary fluid generation flow channel 41, and the electrolytic hydrogen water 14 a and the aerated water flow state. This is the same as the electrolytic hydrogen water generator F1 described above in that the auxiliary fluid 13 is separately discharged into the bath water 11, but the electrolytic hydrogen water is diffused over a wider area while moving on the water surface 12 of the bath water 11. The configuration is different in that it is possible. In addition, in each of the following embodiments, the same configurations as the configurations described above are denoted by the same reference numerals and the description thereof will be omitted.

That is, in the electrolytic hydrogen water generator F2, as shown in FIG. 3A, the auxiliary fluid ejection port 46 of the auxiliary fluid generation channel 41 functioning as a diffusion assisting device is vertically arranged at a position eccentric from the vertical axis L1 of the center of gravity. The housing 20 of the electrolytic hydrogen water generator F2 is configured to be rotatable or movable on the water surface 12 by forming the housing 20 with an inclination with respect to the direction.

In order to facilitate understanding, when it is assumed that the electrolytic hydrogen water generator F2 has a circular shape in plan view and the weight is substantially even and the vertical axis of the center of gravity is located at the substantially central portion in plan view, FIG. As shown in (b), the electrolytic hydrogen water generator F2, which initially existed at the position P1 on the water surface 12, performs rotation about the center of gravity vertical axis L1 in the direction of the black arrow, while at the position P2 and position. It will move to P3.

At this time, the auxiliary fluid 13 ejected from the auxiliary fluid ejection port 46 changes its ejection direction by 360 degrees due to the rotation of the electrolytic hydrogen water generator F2, and therefore the electrolytic hydrogen water ejected from the hydrogen water ejection port 35 is discharged. 14a will be evenly diffused in the bath water 11.

Further, since the ejection direction of the auxiliary fluid containing bubbles changes momentarily, it is easier for the user to pay attention, and the visual effect due to the abundant bubbles can be more efficiently exhibited.

Next, an electrolytic hydrogen water generator S3 according to the third embodiment will be described with reference to FIG. As shown in FIG. 4, the electrolytic hydrogen water generator S3 is different from the above-described electrolytic hydrogen water generator F1 in the configuration of the electrolytic water generation flow channel 31 and the auxiliary fluid generation flow channel 41, and the electrolytic hydrogen water 14a and the aerated water flow. The auxiliary fluid 13 and the auxiliary fluid 13 have the same configuration as that they are separately discharged into the bath water 11. However, the point is the bottoming type device referred to in FIG. 1(b), the float 48, The structure is different in that a ventilation hose 49 is provided.

Specifically, the electrolytic hydrogen water generator S3 is configured to have a higher specific gravity than water so that the hydrogen water discharge port 35 of the electrolytic water generation passage 31 is formed at a position where the hydrogen water discharge port 35 is formed. By forming the auxiliary fluid ejection port 46 of the auxiliary fluid generation flow path 41 on the upper part of the housing 20 as well, the biasing diffusion direction of the electrolytic hydrogen water by the auxiliary fluid is directed upward. .. Note that the hydrogen water discharge port 35 is located at a position where the electrolytic hydrogen water can be discharged into the flow region 47 formed by the auxiliary fluid 13 ejected from the auxiliary fluid ejection port 46. , F2.

Further, a ventilation hose 49 is connected to the branch pipe 45b of the venturi portion 45 forming the auxiliary fluid generation flow channel 41, and a float 48 is arranged at the tip of the ventilation hose 49 so that the tip of the ventilation hose 49 is above the water surface 12. It is configured to be exposed to the air and is used as the air introduction port 44.

According to the electrolytic hydrogen water generator S3 having such a configuration, the electrolytic hydrogen water is diffused together with the auxiliary fluid that contains air and is vigorously ejected, so that rich bubbles containing hydrogen gas are visually recognized by the user. In addition to being able to efficiently generate visual effects, it is possible to prepare a uniform auxiliary fluid by efficient gas-liquid mixing, and to stably disperse electrolyzed hydrogen water in stored water. Can be done.

In addition, some of the electrolytic hydrogen water discharged from the hydrogen water discharge port can be visually recognized as smokey milky bubbles, while the rest can be merged with the flow of the auxiliary fluid through the drawing flow and diffused. , The interest of the user can be improved.

Next, electrolytic hydrogen water generators F4 to F6 according to the fourth to sixth embodiments will be described with reference to FIG. The electrolyzed hydrogen water producing apparatuses F1, F2, S3 referred to above are examples of the electrolyzed hydrogen water producing apparatus in which the electrolyzed water producing passage 31 and the auxiliary fluid producing passage 41 are systematically separated and independent from each other. However, in the electrolytic hydrogen water producing apparatuses F4 to F6 according to the fourth to sixth embodiments, the electrolytic water producing passage 31 and the auxiliary fluid producing passage 41 have passages associated with each other. It is characteristic. In the following description of each embodiment, the flow region 47 is substantially the same as that of FIG. 2, and therefore the illustration thereof is omitted. However, the hydrogen water discharge port 35 does not include the electrolytic hydrogen water discharged from the hydrogen water discharge port 35. It is formed at a position that can be reached in the flow region 47.

First, as shown in FIG. 5(a), an electrolytic hydrogen water producing apparatus F4 according to the fourth embodiment has an air-containing water flow type auxiliary fluid having substantially the same configuration as the electrolytic hydrogen water producing apparatus F1 described above. Although it is a floating type device for ejecting water, a branch part 36 is provided between the raw water pump 33 and the electrolysis part 34 of the electrolyzed water generation flow path 31 to connect with the main pipe 45a of the venturi part 45 of the auxiliary fluid generation flow path 41. A part of the raw water introduced from the raw water intake 32 is supplied to the venturi section 45.

According to the electrolytic hydrogen water producing apparatus F4 having such a configuration, in addition to the same effect as the electrolytic hydrogen water producing apparatus F1 described above, the introduction of the bath water 11 into the casing 20 is performed by the electrolytic water producing flow path 31. And the auxiliary fluid generation flow channel 41 can be shared, and it is not necessary to separately provide a pump or the like, so that the power consumption can be reduced and the components can be made simpler.

FIG.5(b) has shown the structure of the electrolytic hydrogen water production|generation apparatus F5 which concerns on 5th Embodiment. The electrolytic hydrogen water generator F5 is a floating type device having a configuration similar to that of the electrolytic hydrogen water generator F4, but the auxiliary fluid 13 and the electrolytic hydrogen water 14a are not separately discharged, but the auxiliary fluid. The same function as that of No. 13 is different in that it is configured so that the diffusive electrolytic hydrogen water in the form of a gas-containing water flow given to the electrolytic hydrogen water 14a is ejected from the mixed fluid ejection port 51.

Specifically, the main pipe 45a of the venturi portion 45 of the auxiliary fluid generation flow passage 41 is connected to the downstream of the electrolysis portion 34 of the electrolyzed water generation flow passage 31 so that the venturi portion 45 mainly mixes electrolyzed hydrogen water with air. It is configured to generate diffusive electrolytic hydrogen water in the form of air-containing water flow.

In addition, the electrolyzed water generation flow channel 31 and the auxiliary fluid generation flow channel 41 are connected in series upstream and downstream, and mainly electrolytic hydrogen water is mixed with air to form an auxiliary fluid, thereby diffusive electrolytic hydrogen water. Is generated, and this is ejected from the mixed fluid ejection port 51.

Therefore, a uniform auxiliary fluid can be prepared by efficient gas-liquid mixing, and stable diffusion of electrolyzed hydrogen water in the stored water can be performed.

FIG.5(c) has shown the structure of the electrolytic hydrogen water production|generation apparatus F6 which concerns on 6th Embodiment. The electrolytic hydrogen water generator F6 is a floating type device having substantially the same configuration as the electrolytic hydrogen water generator F4 shown in FIG. 5A, but the downstream of the electrolysis section 34 is connected to the hydrogen water discharge port 35. This is characteristic in that it is connected to the second branch pipe 45e of the Venturi portion 45 having two branch pipes, that is, the first branch pipe 45b and the second branch pipe 45e.

With such a configuration, as compared with the case of ejecting diffusible electrolytic hydrogen water in the form of aerated water flow by mixing air while mainly using electrolytic hydrogen water, the ejection flow rate is further secured and the momentum is increased. It can be maintained, and electrolytic hydrogen water can reach farther in the accumulated water to realize efficient diffusion.

Next, electrolytic hydrogen water generators F7 and F8 according to the seventh and eighth embodiments will be described with reference to FIG. Although each of the electrolyzed hydrogen water producing devices mentioned above jets the auxiliary fluid in the form of aerated water flow or the diffusible electrolyzed hydrogen water, the electrolyzed hydrogen water producing devices according to the seventh and eighth embodiments of the present invention. F7 and F8 supply air to the main pipe 45a of the venturi portion 45, and supply the bath water 11 and electrolytic hydrogen water to the branch pipe 45b, so that water-based airflow-like auxiliary in which liquid droplets are mixed while mainly containing air It is characteristic in that it ejects fluid and diffusible electrolytic hydrogen water.

As shown in FIG. 6A, the electrolytic hydrogen water generator F7 according to the seventh embodiment is a floating type device, and the electrolytic water generation channel 31 and the auxiliary fluid generation channel 41 are different systems. 2 is similar to the electrolyzed hydrogen water producing apparatus F1 shown in FIG. 2 in the configuration of the electrolyzed water production flow path 31 and the like, but with respect to the fluid supplied to the venturi portion 45 of the auxiliary fluid production flow path 41, The structure is different in that air is introduced from the main pipe 45a and bath water is introduced from the branch pipe 45b.

In particular, the main pipe 45a is provided with an air pump 53, which sucks air from the air inlet 44 and sends air to the speed increasing portion 45d under pressure, and the low pressure portion formed in the mixing chamber 45c causes the accumulated water inlet 42 to flow. Further, the bath water 11 is sucked and introduced through the branch pipe 45b, comes into contact with the pressurized air, becomes a mist, and is ejected from the auxiliary fluid ejection port 46.

Further, according to the electrolytic hydrogen water producing apparatus F7 having such a configuration, as compared with the case of ejecting the gas-containing liquid flow type auxiliary fluid like the electrolytic hydrogen water producing apparatus F1, air is contained in abundant amount. The auxiliary fluid can be ejected, and the visual effect of bubbles can be more effectively generated for the user.

As shown in FIG. 6B, the electrolytic hydrogen water generator F8 is a floating type device, and the electrolytic hydrogen water generated in the electrolysis section 34 is introduced into the venturi section 45 and diffused from the mixed fluid ejection port 51. 5B is similar to the electrolytic hydrogen water generator F5 shown in FIG. 5B in that the electrolytic hydrogen water is ejected, but regarding the fluid supplied to the venturi portion 45, air is supplied from the main pipe 45a and electrolytic water is supplied from the branch pipe 45b. The configuration is different in that the electrolytic hydrogen water generated in the generation flow path 31 is introduced.

Specifically, the main pipe 45a is provided with an air pump 53, which sucks air from the air introduction port 44 and sends air to the speed increasing unit 45d under pressure, and at the downstream of the electrolyzing unit 34 of the electrolyzed water generation flow path 31. It is connected to the branch pipe 45b and brought into contact with the pressurized air to be atomized to be ejected from the auxiliary fluid ejection port 46. In the electrolyzed water production flow path 31 of the electrolyzed hydrogen water production apparatus F8, when introducing the raw water, the raw water pump 33 is used to pump the raw water or the electrolyzed hydrogen water into the electrolysis section 34 and the mixing chamber 45c. However, if a series of flows can be formed in the electrolyzed water generation flow path 31 at the low pressure portion generated in the mixing chamber 45c, the raw water pump 33 is not always necessary and may be omitted.

Further, according to the electrolytic hydrogen water producing apparatus F8 having such a configuration, as compared with the case of ejecting the gas-containing liquid flow type auxiliary fluid like the electrolytic hydrogen water producing apparatus F1, the air is more abundantly contained. The auxiliary fluid can be ejected, and the visual effect of bubbles can be more effectively generated for the user.

Further, even when compared with the electrolytic hydrogen water generator F7 that diffuses electrolytic hydrogen water by utilizing the flow drawn in at the auxiliary fluid jet port 46, since it is jetted as diffusive electrolytic hydrogen water from the mixed fluid jet port 51, The electrolyzed hydrogen water can reach farther in the accumulated water to realize efficient diffusion.

Next, an electrolytic hydrogen water generator F9 according to the ninth embodiment will be described with reference to FIG. The electrolyzed hydrogen water generators described so far have been ones for ejecting an auxiliary fluid in the form of gas-containing water or in the form of water-containing air stream generated by gas-liquid mixing in the venturi section 45. Is characteristic in that it ejects simpler air itself as an auxiliary fluid compared to the past.

Regarding the production of electrolyzed hydrogen water, in each of the electrolyzed hydrogen water producing apparatuses mentioned above, an example in which the raw water pump 33 is used for introducing the raw water in the electrolyzed water producing flow passage 31 is mainly used. The water producing device F9 is characterized in that the auxiliary fluid ejected from the auxiliary fluid ejection port 46 forms a flow in the electrolyzed water producing flow path by the drawing flow of the auxiliary fluid.

As shown in FIG. 7, the electrolytic hydrogen water generator F9 corresponds to a floating type device, and discharges the electrolytic hydrogen water 14a and the auxiliary fluid 13 that is air separately into the bath water 11.

Focusing on the internal configuration, the electrolytic hydrogen water generator F9 includes two independent channels, an electrolytic water generation channel 61 and an auxiliary fluid generation channel 71, inside the housing 20 floating on the water surface 12. There is.

The electrolyzed water generation flow path 61 is provided with a flowing water flow path 62, and the upstream side end opening is formed as a raw water intake port 63 on the surface of the casing 20 that is in contact with the bath water 11 below the water surface. The downstream end opening is formed on the lower surface of the housing 20 as the hydrogen water discharge port 64.

Further, the electrolysis section 34 is disposed in the running water flow path 62 in the vicinity of the hydrogen water discharge port 64, and the bath water flowing into the running water flow path 62 is electrolyzed by an electrical configuration (not shown) to discharge the hydrogen water discharge port. It is configured to discharge from 64.

On the other hand, the auxiliary fluid generation flow path 71 is provided with the ventilation flow path 54, the upstream end opening is formed as the air introduction port 44 on the upper surface of the housing 20, and the downstream side of the housing 20 is gradually narrowed. An opening is formed on the lower surface as an auxiliary fluid ejection port 46.

Further, an air pump 53 is arranged in the middle of the ventilation passage 54, and the air sucked from the air introduction port 44 is vigorously ejected from the auxiliary fluid ejection port 46 to form a drawing flow to form an electrolyzed water generation passage. The electrolytic hydrogen water discharged in the vicinity of the hydrogen water discharge port 64 through 61 is diffused together with the auxiliary fluid outlet 46, and a water flow is formed in the flowing water passage 62 to promote further electrolysis of the bath water. ing.

Further, according to the electrolytic hydrogen water producing apparatus F9 having such a configuration, the raw water pump for flowing the bath water in the flowing water channel 62 in the electrolytic water producing channel 61 is not required, and the venturi portion or the like is not required. Since the configuration is also unnecessary, the configuration can be simplified and an inexpensive electrolytic hydrogen water generator can be constructed.

As described above, according to the electrolytic hydrogen water generating apparatus according to the present embodiment, the accumulated water is introduced into the housing in a state of floating or sinking in the accumulated water and electrolysis is performed, and the generated electrolytic hydrogen water is generated in the casing. Is a device for producing electrolytic hydrogen water that is discharged from the container to the stored water by introducing air into the housing and ejecting it into the stored water as an auxiliary fluid to promote diffusion of the electrolytic hydrogen water. It is possible to provide an electrolytic hydrogen water generation device that can diffuse hydrogen water farther in the stored water and can obtain a visual effect as if a large amount of hydrogen was released.

Finally, the above description of each embodiment is an example of the present invention, and the present invention is not limited to the above embodiment. Therefore, it goes without saying that various modifications other than the above-described embodiments can be made according to the design and the like as long as they do not deviate from the technical idea of the present invention.

That is, the electrolytic hydrogen water producing apparatus according to each of the first to ninth embodiments described above, as long as it does not violate the gist of the present invention, a part of the configuration of one electrolytic hydrogen water producing apparatus is deleted, Adding a part of the configuration of another electrolytic hydrogen water generating device to the configuration of one electrolytic hydrogen water generating device, or a part of the configuration of one electrolytic hydrogen water generating device and the configuration of another electrolytic hydrogen water generating device A part of the above can be replaced, and an electrolytic hydrogen water generating device generated by deleting, adding, or replacing these also belongs to the category of the present invention.

For example, in each of the above-described embodiments, the hydrogen water discharge port 35 and the auxiliary fluid ejection port 46 are provided on the surface of the housing 20, and the electrolysis hydrogen is generated by the drawing flow accompanying the ejection of the auxiliary fluid from the auxiliary fluid ejection port 46. In the electrolytic hydrogen water generator of the type that diffuses water, specifically, in the devices such as the electrolytic hydrogen water generators F1, F2, S3, and F7, this drawn flow can form a water flow in the electrolytic water generation flow path. The raw water pump may be omitted from the configuration of the electrolyzed water generation flow passage as long as the flow is sufficient.

In addition, the downstream of the electrolyzed water generation flow path is connected to the branch pipe of the Venturi section, and the raw water pump operates only to supply the electrolyzed hydrogen water through this branch pipe, specifically, the electrolyzed hydrogen water generator. A device such as the hydrogen water producing device F8 can be used as a raw water in the constitution of the electrolyzed water production flow passage as long as the low pressure part in the venturi portion has a sufficient pressure difference to form a water flow in the electrolyzed water production flow passage. The pump can be deleted.

Further, in both of these types of electrolytic hydrogen water producing device, the electrolytic water producing flow passage 31 can be replaced with the electrolytic water producing flow passage 61 of the electrolytic hydrogen water producing device F9. With such a configuration, the flow passage resistance can be suppressed to be low due to the large opening and the flow passage cross section, the water flow is effectively generated in the electrolyzed water generation flow passage 61 by the drawing flow, and the continuous electrolysis is performed. Generation of hydrogen water can be realized.

10 Bathtub 11 Bath Water 12 Water Surface 13 Auxiliary Fluid 14a Electrolyzed Hydrogen Water 20 Housing 31 Electrolyzed Water Generation Flow Path 34 Electrolysis Section 35 Hydrogen Water Discharge Port 41 Auxiliary Fluid Generation Flow Path 45 Venturi Section 45a Main Pipe 45b Branch Pipe 45d Acceleration Section 45e Second branch pipe 46 Auxiliary fluid jet 47 Flow region 51 Mixed fluid jet F Electrolytic hydrogen water generator S Electrolytic hydrogen water generator

Claims (9)

An electrolytic hydrogen water generator that introduces accumulated water into a casing in a state of floating or sinking in the accumulated water to electrolyze, and releases the generated electrolytic hydrogen water from the casing to the accumulated water.
An electrolytic hydrogen water producing apparatus comprising a diffusion auxiliary means for promoting diffusion of the electrolytic hydrogen water by introducing air into the housing and ejecting the air into the stored water as an auxiliary fluid. The diffusion assisting means includes a venturi portion having a main pipe that accelerates a fluid to form a low pressure portion by a constriction shape in the downstream direction and a branch pipe that faces the low pressure portion, and the accumulated water or the electrolytic hydrogen water 2. The electrolytic hydrogen water generator according to claim 1, wherein the air and the air are respectively introduced from the main pipe or the branch pipe to mix gas and liquid to generate the auxiliary fluid. A hydrogen water discharge port for discharging electrolytic hydrogen water and an auxiliary fluid discharge port for discharging an auxiliary fluid are separately provided on the contact surface of the housing with the accumulated water,
The hydrogen water discharge port is formed at a position where electrolytic hydrogen water can be jetted into a flow region of accumulated water that is disturbed by an air bubble group generated in water by jetting the auxiliary fluid from the auxiliary fluid jet port. The electrolytic hydrogen water generator according to claim 1 or 2. The electrolytic hydrogen water generator according to claim 2 or 3, wherein the main water is introduced into the main pipe while the air is introduced into the branch pipe. A mixed fluid ejection port formed on the contact surface of the casing with the accumulated water, which is commonly used for ejection of electrolytic hydrogen water and ejection of an auxiliary fluid,
The downstream end of the venturi portion is connected to the mixed fluid jet, and the electrolyzed hydrogen water and air are introduced from the main pipe or branch pipe, respectively, and mixed and jetted into the stored water. 2. The electrolytic hydrogen water generator according to item 2. The electrolytic hydrogen water generator according to claim 5, wherein the electrolytic hydrogen water is introduced into the main pipe while the air is introduced into the branch pipe. The venturi portion includes a first branch pipe and a second branch pipe, and introduces the accumulated water into the main pipe while introducing the auxiliary fluid into the first branch pipe and the second branch pipe to perform electrolysis. The electrolytic hydrogen water generator according to claim 5, which is configured to introduce hydrogen water. The electrolyzed hydrogen water generator according to claim 5, wherein the air is introduced into the main pipe while the electrolyzed hydrogen water is introduced into the branch pipe. 9. The electrolytic hydrogen water generator according to claim 1, wherein the casing floats in the accumulated water, and is configured to move on the water surface by the ejection of the auxiliary fluid.

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