WO2016148413A1

WO2016148413A1 - Device for producing hydrogen-containing water

Info

Publication number: WO2016148413A1
Application number: PCT/KR2016/001907
Authority: WO
Inventors: 박승열; 이남석; 김필종
Original assignee: 박승열; 이남석; 김필종
Priority date: 2015-03-18
Filing date: 2016-02-26
Publication date: 2016-09-22
Also published as: KR20160112120A; KR101748788B1

Abstract

Disclosed is a device for producing hydrogen-containing water. According to one aspect of the present invention, provided is a device for producing hydrogen-containing water, comprising: a storage part for holding storage water; a drinking water part, coupled to the upper portion of the storage part, for holding drinking water; an ion exchange part, interposed between the storage part and the drinking water part, for generating ozone in the storage part and generating hydrogen in the drinking water part through an ion exchange between the storage water and the drinking water; and a pressure increase prevention part, coupled to the storage part, for preventing a pressure increase in the storage part caused by oxygen which is generated by reduction of the ozone.

Description

Hydrogen-containing Water Production Equipment

The present invention relates to a hydrogen-containing water production apparatus.

The human body has a close connection with the water we drink. Specifically, since the human body regulates the osmotic pressure in the cell through the balance of metal ions, it is good to supplement the minerals necessary for the body with water containing appropriate minerals such as calcium, potassium and magnesium.

In addition, because most of the body is acidic, it is better to drink weakly alkaline water to neutralize it, which can suppress cancer, help antioxidants and enzymes in the body, boost food breakdown, digestive absorption and boost immunity. Can give

Hydrogen water, which has such advantages, is accelerating its demand as the radioactive detoxification effect of hydrogen water is revealed in 2011 when a large number of citizens faced the problem of contamination of radioactivity due to the outflow of radiation from Fukushima nuclear power plant in Japan.

Hydrogen water can be combined with free radicals in the body, converted to water, and absorbed or discharged into the body. For example, hydrogen can cross cell membranes, releasing bad free radicals inside cells. Hydrogen water has been in the spotlight as it has been found to have excellent effects on various diseases caused by excess active oxygen in the body such as cancer, diabetes, and cerebral infarction.

Background art of the present invention is disclosed in Japanese Unexamined Patent Publication No. 2010-269246 (2010.12.02, Method for producing a hydrogen-containing water for beverages).

Embodiments of the present invention, in the production of hydrogen-containing water through ion exchange, it is possible to provide a hydrogen-containing water production apparatus that can prevent the pressure in the storage portion rises by the product according to the ion exchange.

According to an aspect of the invention, the storage unit for receiving the stored water; A negative part coupled to an upper part of the storage part to receive a negative number; An ion exchange part interposed between the storage part and the negative part to generate ozone in the storage part through ion exchange between the storage water and the negative water, and generate hydrogen in the negative part; And a pressure increase preventing unit coupled to the storage unit to prevent a pressure increase in the storage unit due to oxygen generated by the reduction of the ozone. Hydrogen-containing water production apparatus comprising a can be provided.

The pressure increase prevention unit, the discharge passage extending from one side of the storage to the outside; And an adsorbent mounted on the reservoir to adsorb dissolved ozone in the reservoir.

The pressure increase prevention unit may further include an auxiliary reservoir interposed between the storage unit and the discharge passage to transfer oxygen introduced from the storage unit to the discharge passage.

A sponge may be interposed between the ion exchange unit and the adsorbent so that the ozone generated in the storage unit moves from the ion exchange unit to the adsorbent.

The storage part may be detachably formed at a lower portion of the storage part to include an opening and closing part for opening and closing the storage part, and the opening and closing part may include a receiving frame for receiving the adsorbent.

The ion exchange part may include a positive electrode installed at an open upper portion of the storage part; A negative electrode installed at an open lower portion of the negative portion; And an ion exchange membrane disposed in the negative portion so as to be interposed between the positive electrode and the negative electrode.

A first sealing part interposed between the positive electrode and the ion exchange membrane so as to prevent leakage of the stored water and installed on an inner circumferential surface of the storage part; And a second sealing part interposed between the negative electrode and the ion exchange membrane to be installed on the inner circumferential surface of the negative part to prevent the negative leakage.

A port frame formed at a lower portion of the first power terminal and accommodating the storage part, the negative part, the ion exchange part, and the pressure increase prevention part; It may further include.

The apparatus may further include a main body frame in contact with the first power terminal to supply a second power terminal for supplying power to the ion exchange unit, and the port frame detachably formed.

The storage unit may be provided with a water level sensor for measuring the water level of the storage water.

It may further include an alarm for generating an alarm in accordance with the measured value of the water level sensor.

If the measured value received from the water level sensor is less than a predetermined value, the control unit for controlling the alarm to be generated in the alarm unit, the control unit, when the first power terminal and the second power terminal is in contact, the It may include a timer for controlling the time for supplying power to the ion exchange unit.

The main body frame may include a button unit to input an operation signal to the control unit.

The port frame may be equipped with a built-in battery that can be charged power.

According to embodiments of the present invention, in the production of hydrogen-containing water through ion exchange, the pressure in the storage unit is prevented from rising due to the product of ion exchange, thereby increasing the durability of the apparatus and making the production of hydrogen-containing water stable. Can be made.

1 is a view showing a hydrogen-containing water production apparatus according to an embodiment of the present invention.

2 is a view showing a state in which the port frame is separated from the main frame.

3 is a view schematically illustrating ion exchange occurring in the ion exchange unit and a product generated in the positive electrode and the negative electrode.

4 is an enlarged view of the ion exchange unit, the first sealing unit, and the second sealing unit.

5 is a cross-sectional view taken along the dotted line of FIG. 4.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In the present application, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components, unless specifically stated otherwise. In addition, throughout the specification, "on" means to be located above or below the target portion, and does not necessarily mean to be located above the gravity direction.

In addition, the coupling does not only mean the case where the physical contact is directly between the components in the contact relationship between the components, other components are interposed between the components, the components in the other components Use it as a comprehensive concept until each contact.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

Since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to the illustrated.

Hereinafter, an embodiment of the hydrogen-containing water production apparatus according to the present invention will be described in detail with reference to the accompanying drawings, in the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and Duplicate explanations will be omitted.

Referring to Figure 1, the hydrogen-containing water production apparatus 10 according to an embodiment of the present invention, the storage unit 100, the negative portion 200, the ion exchange unit 300 and the pressure increase prevention unit 400 Including,

Storage unit 100 may be a container for receiving the storage water (W1).

The storage unit 100 may be provided with a water level sensor for measuring the water level of the storage water (W1). The level sensor may detect a level measurement value of the storage water W1 and transmit a signal of the measurement value to a controller which will be described later.

The storage unit 100 may include an opening and closing unit 110 to open and close the storage unit 100.

The opening and closing unit 110 may be detachably formed at a lower portion of the storage unit 100. Storage water W1 may be supplied to an open portion of the storage part 100 in which the opening and closing part 110 is detached.

The opening and closing part 100 may be fastened or separated, for example, to the storage part 100.

Opening and closing unit 110 may include a receiving frame 111 for receiving the adsorbent 430 to be described later.

Receiving frame 111 may be detachable to the opening and closing portion (110). Since the receiving frame 111 is detached from the opening and closing part 110, the adsorbent 430 may be easily replaced from the receiving frame 111.

The negative part 200 may be a container for receiving negative water W2. The negative part 200 may be coupled to an upper portion of the storage part 100. The negative part 200 may be detachable from the storage part 100.

A handle may be formed in the negative portion 200. The drinking part 200 may be a container in which a user may drink water by directly separating it from the storage part. The negative portion may, for example, accommodate a negative number W2 of about 2L.

Negative water (W2) accommodated in the negative portion (200) and the storage water (W1) accommodated in the storage unit 100 is for convenience of explanation, but the name is not made of other components, negative water (W2) And the storage water (W1) may be drinking water.

The ion exchange part 300 may be interposed between the storage part 100 and the negative part 200.

The ion exchange unit 300 may generate ozone in the storage unit 100 and generate hydrogen in the negative unit 200 through ion exchange between the storage water W1 and the negative water W2.

FIG. 3 is a view schematically illustrating ion exchange occurring in the ion exchange unit 300 and a product generated in the positive electrode and the negative electrode.

Referring to FIG. 3, the ion exchange unit 300 may include a positive electrode 310, a negative electrode 330, and an ion exchange membrane 350.

The positive electrode 310 may be installed at an open upper portion of the storage 100. Ozone may be generated in the positive electrode 310.

The negative electrode 330 may be installed at an open lower portion of the negative portion 200. Hydrogen may be generated in the negative electrode 330.

The ion exchange membrane 350 may be installed in the negative portion 200 to be interposed between the positive electrode 310 and the negative electrode 330. The ion exchange membrane 350 may selectively transmit ions. The ion exchange membrane 350 may not transmit negative water W2.

Hydrogen ions and oxygen ions of FIG. 3 are schematically illustrated for convenience of description, and do not necessarily transmit the ion exchange membrane 350 in a single ion state, but may be transmitted in the state of hydroxide OH ⁻ . In addition, the product generated from the positive electrode 310 and the negative electrode 330 is not limited to only ozone and hydrogen, and a product may be present by reaction with metallic ions contained in drinking water.

Referring to FIG. 3, an oxidation and a reduction reaction may be performed through electrolysis of water between the positive electrode 310 and the negative electrode 330. Hydrogen ions may be moved to the negative electrode 330, and oxygen ions may be moved to the positive electrode 310. Hydrogen may be generated at the negative electrode 330. In general, hydrogen has high solubility in water and can be dissolved in negative water (W2).

Meanwhile, in the positive electrode 310, ozone (O ₃ ) may be generated by reacting oxygen generated in the positive electrode 310 with the storage water W1 in the storage unit 100 as shown in Formula 1 below.

[Formula 1]

_{_{O 2 + H 2 O → O}} 3 + 2e - + 2H +

It is preferable that ozone does not exist as much as possible because it causes an unpleasant feeling due to a peculiar smell even in an extremely small amount. Because ozone is composed of unstable bonds compared to oxygen, it can be dissolved and dissolved in water or spontaneously reduced to become oxygen.

Since oxygen exists as a gas at room temperature, as the ion exchange is repeated, oxygen in a gaseous state is continuously generated in the storage unit 100, and the pressure in the storage unit 100 may increase. Increasing the pressure in the reservoir 100 may cause flooding of the storage water W1 and may damage the reservoir 100 or the ion exchange unit 300. Therefore, the pressure rise in the storage unit 100 must be prevented.

Pressure increase prevention unit 400 may be coupled to the storage unit (100). The pressure increase prevention unit 400 may prevent a pressure increase in the storage unit 100 due to oxygen generated by the reduction of ozone. The amount of the storage water W1 in the storage unit 100 may decrease gradually as ion exchange is repeated.

The pressure increase preventing unit 400 may include a discharge passage 410 and an adsorbent 430, and may further include an auxiliary storage 450.

The discharge passage 410 may extend from one side of the storage unit 100 to the outside.

The discharge passage 410 may provide a passage for discharging oxygen in the storage unit 100 to the outside. As the oxygen in the storage unit 100 is discharged, the pressure in the storage unit 100 may be lowered.

The material discharged through the discharge passage 410 is described as being oxygen, but is not limited thereto, and may be a material including oxygen.

One side extending to the outside of the discharge passage 410 may extend upward. One side extending to the outside of the discharge passage 410 will be described as the inlet, the other side connected to the storage unit 100 of the discharge passage 410.

The outlet may be disposed higher than the top end of the drinking water (200). Since the discharge port is disposed higher than the upper end of the negative portion 200, the discharged oxygen may be prevented from flowing into the negative water W2.

A valve may be installed at the inlet of the discharge passage 410. The valve may adjust the amount of oxygen discharged from the reservoir 100. The valve may for example be a flow regulating valve.

The discharge passage 410 may be a passage for supplying the storage water W1 to the storage unit 100 only when ion exchange does not occur. It may be used as an alternative to supply the storage water W1 to the storage unit 100 when the opening and closing unit 110 is difficult to open and close or when a defect occurs in the opening and closing unit 110.

The secondary storage 450 may be interposed between the storage 100 and the discharge passage 410. The secondary storage 450 may be a container that auxiliaryly receives the oxygen introduced from the storage 100.

The auxiliary storage 450 may provide a space for storing oxygen to prevent damage to the discharge passage 410 due to a pressure increase in the discharge passage 410 when a large amount of oxygen is generated in the storage 100. In addition, when there is a risk that the storage water W1 may overflow to the outside of the storage water due to an increase in pressure in the storage unit 100 or a failure in adjusting the supply amount of the storage water W1, the auxiliary storage 450 may store the storage unit 100. It may be a container for receiving a portion of the storage water (W1) accommodated in.

If the auxiliary storage 450 is further included, the valve may be installed in the connection passage connecting the storage unit 100 and the auxiliary storage 450, the inlet of the discharge passage 410 is to be connected to the auxiliary storage 450 Can be.

The adsorbent 430 may be mounted in the storage 100. The adsorbent 430 may adsorb dissolved ozone in the storage 100.

A cavernous body 130 may be interposed between the adsorbent 430 and the ion exchange unit 300. As the sponge 130 is interposed, ozone generated in the storage unit 100 may be rapidly moved to the lower side without remaining in the open upper portion of the storage unit 100.

Specifically, the spongy body 130 may be a medium between the positive electrode 310 of the ion exchange unit 300 and the adsorbent 430, and both ends thereof contact the positive electrode 310 and the adsorbent 430, respectively. The ozone generated in the first absorption may be preferentially absorbed and moved to be absorbed by the adsorbent 430. The sponge 130 may be formed in various shapes in the storage unit 100 as long as it contacts the positive electrode 310 and the adsorbent 430 of the ion exchange unit 300.

The adsorbent 430 may adsorb dissolved ozone to prevent user's discomfort caused by odor and delay the rate at which ozone is decomposed into oxygen. Accordingly, the pressure rise in the storage 100 may be delayed.

The adsorbent 430 may be accommodated in the receiving frame 111 of the opening and closing part 110. The adsorbent 430 may be mounted in the storage part 100 while the opening and closing part 110 closes the storage part 100 while being accommodated in the receiving frame 111.

The adsorbent 430 may be easily replaced as the receiving frame 111 is detachable from the opening and closing part 110. A through hole may be formed in the accommodation frame 111 to allow the sponge to be in contact with the adsorbent 430.

The adsorbent 430 may be made of a material including carbon. The adsorbent 430 may be formed in a block shape, and may be formed in various shapes as necessary.

4 is an enlarged view of the ion exchange unit 300, the first sealing unit 500, and the second sealing unit 600, and FIG. 5 is a cross-sectional view taken along the dotted line of FIG. 4.

4 and 5, the hydrogen-containing water producing apparatus 10 according to the exemplary embodiment of the present invention may further include a first sealing part 500 and a second sealing part 600.

The first sealing part 500 may be interposed between the positive electrode 310 and the ion exchange membrane 350. The first sealing part 500 may be installed on the inner circumferential surface of the storage part 100. The first sealing part 500 may prevent the negative water W2 from leaking out of the negative part 200.

The first sealing part 500 may be made of a material having excellent insulation and water resistance. The first sealing part 500 may be, for example, a material including silicon.

The second sealing part 600 may be interposed between the negative electrode 330 and the ion exchange membrane 350. The second sealing part 600 may be installed on the inner circumferential surface of the negative part 200. The second sealing unit 600 may prevent the storage water W1 from leaking out of the storage unit 100.

The second sealing part 600 may be made of a material having excellent insulation and water resistance. The second sealing part 600 may be, for example, a material including silicon.

For example, the negative water (W2) and the storage water (W1) has the properties of general water, the capillary phenomenon due to the surface tension of the water storage water (W1) is raised along the inner circumferential surface of the storage unit 100 or negative (W2) ) May be lowered along the inner circumferential surface of the negative part 200. In this case, the storage water W1 and the negative water W1 may be mixed with each other around the ion exchange membrane 350 or damage the ion exchange membrane 350. The first sealing unit 500 and the second sealing unit 600 may be configured to prevent such a problem.

Referring to FIG. 2, the hydrogen-containing water producing apparatus 10 according to the exemplary embodiment of the present invention may further include a port frame 800 and a main body frame 700.

The port frame 800 may be a frame for accommodating the storage unit 100, the negative unit 200, the ion exchange unit 300, and the pressure increase prevention unit 400. The port frame 800 may accommodate the secondary storage 450.

The port frame 800 may increase the user's convenience by integrating the above components. Specifically, the user can lift the pot frame 800 to drink the negative water (W2) directly or to drink according to the cup.

The first power terminal 810 may be formed under the port frame 800. The first power terminal 810 may be in contact with the second power terminal 710 of the main body frame 700, which will be described later, to receive power.

The port frame 800 may be equipped with a built-in battery that can be charged power. Since the port frame 800 does not require a continuous power supply, the port frame 800 may be used without restriction in place, thereby increasing portability and mobility.

The upper portion of the port frame 800 is open and can be opened and closed by a lid separately installed.

When there is the port frame 800, the lower portion of the port frame 800 which is in contact with the storage unit 100 may be opened to receive the storage water W1. The opening and closing unit 110 may open and close the opened lower portion of the port frame 800.

The port frame 800 may accommodate the storage unit 100, the negative portion 200, the ion exchange unit 300, and the pressure increase prevention unit 400, and may be partitioned and partitioned within the port frame 800 itself. Each of the portions may be designed to serve as the storage 100, the negative portion 200, the ion exchange unit 300, and the pressure increase prevention unit 400.

The body frame 700 may be a holder in which the port frame 800 is detachable.

The second power terminal 710 may be formed in the body frame 700. The second power terminal 710 of the body frame 700 may be in contact with the first power terminal 810 of the port frame 800 to apply power to the port frame 800 from the body frame 700.

When the first power terminal 810 and the second power terminal 710 are in contact with each other, the main body frame 700 may be electrically connected to the ion exchange unit 300 to cause ion exchange.

The body frame 700 may perform a pedestal function for supporting the components of the hydrogen-containing water production apparatus 10. The lower part of the main body frame 700 may be formed flat, and the upper and side parts may have an inner circumferential surface to which the port frame 800 is in contact with the outer circumferential surface of the port frame 800 so as to facilitate removal and mounting of the port frame 800. It may be formed in a shape.

Hydrogen-containing water production apparatus 10 according to an embodiment of the present invention may further include an alarm unit and a control unit.

The alarm unit may generate an alarm according to the water level measurement value of the water level sensor installed in the storage unit. The alarm unit may be, for example, an LED light, a siren, or the like, and may be variously configured as necessary. In another example, the alarm unit may display the water level measurement value on the screen, in which case the alarm unit may be installed in the main body frame 700.

The controller may control an alarm to be generated in the alarm unit.

The controller may receive the level measurement value from the level sensor. If the measured value received from the level sensor is less than the preset value, the controller may generate an alarm in the alarm unit. Here, the preset value may be a level of about one tenth the level of the storage water W1 at the height from the lower end to the upper part of the storage unit. However, the preset value may vary according to the needs of the user, and the present invention is not limited thereto.

The controller may be installed in the body frame 700 or the port frame 800.

The controller may include a timer.

The timer may control a time for supplying power to the ion exchange unit 300 when the first power terminal 810 and the second power terminal 710 contact each other. Specifically, the time at which the hydrogen is generated in the negative number W2 may be adjusted by the user arbitrarily set by the timer.

For example, when the power supply time is increased, the amount of hydrogen generated at the negative electrode 330 may be increased, but since hydrogen is a low density material, the hydrogen may be easily evaporated when left for a long time. Therefore, it is necessary to adjust the power supply time.

The timer and the control unit including the same may receive an operation signal from the button unit 730 installed in the main body frame 700. The button unit 730 may be operated by a user, and a plurality of button units 730 may be provided.

As another example, the controller may receive an operation signal of the button unit 730 to adjust the power supply amount.

For example, when the amount of power supply is increased, the redox reaction between the positive electrode 310 and the negative electrode 330 may be actively performed, thereby increasing the amount of hydrogen generated at the negative electrode 330.

As the button unit 730 is operated, whether or not power is supplied to the power supply module 710 may be controlled. For example, when the button unit 730 is pressed once, power is supplied to the power supply module 710 to cause ion exchange in the ion exchange unit 300 to generate hydrogen in the negative water W2. In this state, pressing the button unit 730 once more may cut off the power supply to the power supply module 710.

As a specific example of the operation of the control unit according to the button unit 730, when the user has a single button unit 730, if the user presses the button unit 730 for about 3 seconds, the control unit receives the input signal to power the port It may be applied to or blocked from the frame 800. In addition, each time the button unit 730 is pressed once, the power supply time may be lengthened by one minute or the power supply amount may be increased by about 10%. This is only an example of the operation possible by the operation of the button unit 730 is not limited thereto.

As mentioned above, although an embodiment of the present invention has been described, those of ordinary skill in the art may add, change, delete or add components within the scope not departing from the spirit of the present invention described in the claims. The present invention may be modified and changed in various ways, etc., which will also be included within the scope of the present invention.

Description of the sign

W1: storage

W2: negative

10: hydrogen-containing water production apparatus

100: storage unit

110: opening and closing part

111: receiving frame

130: spongy

200: negative part

300: ion exchange unit

310: positive electrode

330: negative electrode

350: ion exchange membrane

400: pressure rise prevention unit

410: discharge passage

430: adsorbent

450: auxiliary storage

500: first sealing part

600: second sealing part

700: body frame

710: second power supply terminal

730: button portion

800: port frame

810: first power supply terminal

Claims

A storage unit for receiving storage water;

A negative part coupled to an upper part of the storage part to receive a negative number;

An ion exchange part interposed between the storage part and the negative part to generate ozone in the storage part through ion exchange between the storage water and the negative water, and generate hydrogen in the negative part; And

A pressure increase prevention unit coupled to the storage unit to prevent a pressure increase in the storage unit due to oxygen generated by reduction of the ozone;

Hydrogen-containing water production apparatus comprising a.
The method of claim 1,

The pressure increase prevention unit,

A discharge passage extending from one side of the storage unit to the outside; And

Hydrogen-containing water production apparatus characterized in that it comprises an adsorbent mounted on the storage unit for adsorbing dissolved ozone in the storage unit.
The method of claim 2,

The pressure increase prevention unit

And an auxiliary reservoir interposed between the storage unit and the discharge passage to transfer oxygen introduced from the storage unit to the discharge passage.
The method of claim 2,

The storage unit, the hydrogen-containing water production apparatus, characterized in that the interfacial body is interposed between the ion exchange unit and the adsorbent so that the ozone generated in the storage unit is moved from the ion exchange unit to the adsorbent.
The method of claim 4, wherein

The storage unit

It is formed to be detachable in the lower portion of the storage unit includes an opening and closing unit for opening and closing the storage unit,

The opening and closing portion is a hydrogen-containing water production apparatus characterized in that it comprises a receiving frame for receiving the adsorbent.
The method of claim 1,

The ion exchange unit,

A positive electrode installed at an open upper portion of the storage part;

A negative electrode installed at an open lower portion of the negative portion; And

And an ion exchange membrane disposed in the negative portion so as to be interposed between the positive electrode and the negative electrode.
The method of claim 6,

A first sealing part interposed between the positive electrode and the ion exchange membrane so as to prevent leakage of the stored water and installed on an inner circumferential surface of the storage part; And

A second sealing part interposed between the negative electrode and the ion exchange membrane to be installed on the inner circumferential surface of the negative part to prevent the negative leakage;

Hydrogen-containing water production apparatus further comprising.
The method of claim 1,

A port frame formed at a lower portion of the first power terminal and accommodating the storage part, the negative part, the ion exchange part, and the pressure increase prevention part;

Hydrogen-containing water production apparatus further comprising.
The method of claim 8,

A main body frame in contact with the first power terminal, the second power terminal configured to supply power to the ion exchange unit, and the port frame detachably formed;

Hydrogen-containing water production apparatus further comprising.
The method of claim 9,

The storage unit is a hydrogen-containing water production apparatus, characterized in that the water level sensor for measuring the water level of the storage water is installed.
The method of claim 10,

Hydrogen-containing water production apparatus characterized in that it further comprises an alarm unit for generating an alarm in accordance with the measured value of the water level sensor.
The method of claim 11,

If the measured value received from the water level sensor is less than a predetermined value, the control unit for controlling the alarm to further generate an alarm unit,

And the control unit includes a timer for controlling a time for supplying power to the ion exchange unit when the first power terminal and the second power terminal are in contact with each other.
The method of claim 12,

The main body frame, the hydrogen-containing water production apparatus, characterized in that the button portion is provided so that the operation signal is input to the control unit.
The method of claim 9,

Hydrogen-containing water production apparatus, characterized in that the port frame is equipped with a built-in battery that can be charged power.