JP3212271U - Pot capable of producing hydrogen water - Google Patents

Abstract

A pot capable of producing hydrogen water is provided. The pot has a water injection space 11 and a power supply space 12, and has a barrier 13 for separating the water injection space 11 and the power supply space 12 inside, and the power supply space 12 includes a first power supply space 121 and a first power supply space 121. The second feed space 122 is formed in the barrier 13, the filter hole 131 is opened in the barrier 13, and the filter hole 131 is connected to the second feed space 122 and the water injection space 11. 10, the electrolytic unit 20 having the first electrolytic plate 21, the filter film 22, and the second electrolytic plate 23 installed in the second power feeding space 122, and the first electrolysis unit 20 installed in the second power feeding space 122. A power supply unit 30 electrically connected to the current-carrying rod 24 of the plate 21 and the current-carrying rod 24 of the second electrolytic plate 23 is provided. [Selection] Figure 4

Description

  The present invention relates to a pot, and more particularly to a pot capable of producing hydrogen water.

  Hydrogen water is also called hydrogen rich water in the market. Hydrogen water has been regarded as a good antioxidant for many years because it contains a high concentration of hydrogen ions. In addition, hydrogen water has further characteristics such as weak alkalinity, electronegative, and small molecules, and is regarded as potable water that is beneficial to health.

There are hydrogen water generators on the market that allow hydrogen water to be produced at home. This includes a pedestal 50, a container 60, an electrolysis unit 70, and an upper lid 80 (see FIG. 1).
The pedestal 50 has a recess 51, a control panel 52, and a conductive end 53 that is adjacent to the recess 51 and is mounted on the recess 51. The control panel 52 is connected between the conductive end 53 and an external power source. Used to control disconnection. The container 60 is installed in the recess 51 of the base 50 and has an opening 61. The electrolysis unit 70 is installed at the bottom of the container 60 and contacts the conductive end 53 in a separable manner. The upper lid 80 covers the opening 61 in a separable form.

  In use, after the container 60 is filled with liquid water, the control panel 52 is operated to make the conductive end 53 conductive to an external power source. When the conductive end 53 is brought into contact with liquid water in the electrolytic vessel 60 of the electrolysis unit 70, water containing high-concentration hydrogen ions can be obtained after a certain period of time.

  However, such a hydrogen water generator has a large volume and is inconvenient to carry. When carrying and drinking hydrogen water, it becomes portable by taking out the hydrogen water from the container 60 and putting it in the container. After having finished drinking outside, you can drink hydrogen water again if you make hydrogen water again with the hydrogen water generator after returning home, but this is very inconvenient and takes time. Further, when hydrogen water is produced by a hydrogen water generator, an external power source is essential, so it is difficult to carry it.

  Therefore, the present inventor considered that the above-described drawbacks can be improved, and as a result of intensive studies, the present inventor has arrived at a proposal of the present invention that effectively improves the above-described problems with a rational design.

  In view of such a conventional situation, an object of the present invention is to provide a pot capable of producing hydrogen water. According to the present invention, the user can carry the hydrogen water production apparatus so that the user can replenish the hydrogen water at any time.

  The feature of the pot capable of producing hydrogen water according to the present invention to solve the above-described problems and achieve the above-described object is that it has a water injection space and a power supply space, and the water injection space and the power supply space are separated inside. The power supply space includes a first power supply space and a second power supply space, the second power supply space is formed in the barrier, a filter hole is formed in the barrier, and the filter hole is the second power supply space. And a pedestal communicated with the water injection space, a first electrolytic plate installed in the second power feeding space, a filter film, and a second electrolytic plate, from the first electrolytic plate and the second electrolytic plate An electrolysis unit in which the current-carrying rod extends to the inside of the second power-feeding space, and a power feed that is installed in the second power-feeding space and electrically connected to the current-carrying rod of the first electrolytic plate and the current-carrying rod of the second electrolytic plate A unit.

  In a preferred embodiment, the second feeding space is divided into the first space and the second space by the filter film. The filter film is impermeable, and the first space communicates with the filter hole. The first electrolytic plate is placed in the first space, and the second electrolytic plate is placed in the second space.

  In a preferred embodiment, the energizing rod in the first electrolytic plate is penetrated through the filter film, the second electrolytic plate and the cover, and the energizing rod in the second electrolytic plate is penetrated through the cover. The second space is communicated with the outside of the pedestal by connecting the exhaust pipe to the communication pipe and the exhaust hole.

  In a preferred embodiment, the direction in which the water injection space is connected to the power supply space is defined as an extending direction, and the second power supply space is formed by surrounding the barrier toward the water injection space along the extending direction. A plurality of filter holes are formed in the barrier, the second feeding space is closed by the cover, and the communication pipe penetrates the cover and communicates with the second feeding space and the first feeding space. The pedestal is provided with an exhaust hole communicating with the first feeding space and the outside of the pedestal.

  In a preferred embodiment, a pot wall is installed in the water injection space, and a water storage space is defined in the pot wall. The water storage space is used for filling water and communicated with the second power supply space.

  In a preferred embodiment, in the pot capable of producing hydrogen water, the power supply unit has a first power supply plate and a second power supply plate, the first power supply plate has a charging unit and a power transmission unit, and the charging unit is an external power source. Used for receiving power. The second power supply plate has a power reception unit and two holes, the power reception unit is electrically connected to the power transmission unit, and the power transmission unit is used to transmit the power of the first power supply plate to the power reception unit. Electric power is conducted to the hole by the power receiving unit, the two holes are electrically connected to the current-carrying rods in the first electrolytic plate and the second electrolytic plate, respectively, and power is transmitted from each current-carrying rod to the first electrolytic plate and the second electrolytic plate. Conducted by two electrolytic plates.

  In a preferred embodiment, the charging unit is a USB charging port.

The user first charges the first power feeding plate using an external power source, and electrolyzes water using the power stored in the first power feeding plate. When a user goes out with a pot capable of producing hydrogen water of the present invention, the hydrogen water can be produced simply by filling liquid water.
In addition, since power is supplied from the power supply unit according to the present invention, it is not necessary to connect to an external power source separately. When the power of the power supply unit is consumed, the power supply can be restored normally by replenishing the power by the charging unit.

It is an external appearance perspective view which shows the pot which can manufacture the conventional hydrogenous water. 1 is an external perspective view showing a pot capable of producing hydrogen water according to a preferred embodiment of the present invention. 1 is an exploded view showing a pot capable of producing hydrogen water according to a preferred embodiment of the present invention. It is a use condition figure which shows the pot which can manufacture the hydrogen water based on preferable embodiment of this invention. It is a use condition figure which shows the pot which can manufacture the hydrogen water based on preferable embodiment of this invention.

  Hereinafter, an embodiment of a pot capable of producing hydrogen water according to the present invention will be described with reference to the drawings. The embodiment described below does not limit the contents of the present invention described in the claims of the utility model registration. In addition, all the configurations described below are not necessarily essential requirements of the present invention.

Hereinafter, the pot capable of producing hydrogen water of the present invention will be described in more detail with reference to FIGS. The pot capable of producing hydrogen water of the present invention is composed of the following members.
(A) Pedestal 10
A water injection space 11 and a power supply space 12 are provided, and a pedestal 10 has a barrier 13 for separating the water injection space 11 and the power supply space 12. The feeding space 12 includes a first feeding space 121 and a second feeding space 122. A second feeding space 122 is formed in the barrier 13 and a filter hole 131 is opened. The filter hole 131 communicates with the second power feeding space 122 and the water injection space 11. In the present embodiment, the pedestal 10 has a hollow cylindrical shape, the direction in which the power feeding space 12 is connected to the water injection space 11 is defined as the extending direction X, and the barrier 13 is directed along the extending direction X toward the water pouring space 11. The second power supply space 122 is formed by surrounding.
The barrier 13 penetrates the plurality of filter holes 131, and the second feeding space 122 is closed by the cover 15. The communication pipe 151 penetrates the cover 15, and the communication pipe 151 communicates with the first power supply space 121 and the second power supply space 122. The pedestal 10 is provided with an exhaust hole 16 communicating with the first feeding space 121 and the outside of the pedestal 10. In the present embodiment, a pot wall 111 in which a water storage space 112 is defined is installed in the water injection space 11, and the water storage space 112 is used for filling water and communicated with the second power feeding space 122.
(B) Electrolysis unit 20
The first electrolytic plate 21, the filter film 22, and the second electrolytic plate 23 are sequentially installed in the second power feeding space 122. The filter film 22 divides the second power feeding space 122 into a first space 122A and a second space 122B, and the filter film 22 is impermeable. The first space 122A communicates with the filter hole 131, the first electrolytic plate 21 is placed in the first space 122A, and the second electrolytic plate 23 is placed in the second space 122B.
From the first electrolytic plate 21 and the second electrolytic plate 23, current-carrying rods 24 are each extended into the first power supply space 121. In the present embodiment, the energizing rod 24 on the first electrolytic plate 21 passes through the filter film 22, the second electrolytic plate 23 and the cover 15, and the energizing rod 24 on the second electrolytic plate 23 is provided through the cover 15. . By connecting the exhaust pipe 25 to the communication pipe 151 and the exhaust hole 16, the second space 122 </ b> B is communicated with the outside of the base 10.
(C) Power feeding unit 30
The power feeding unit 30 is installed in the first power feeding space 121, and is electrically connected to the current-carrying rod 24. In the present embodiment, the power supply unit 30 includes a first power supply plate 31 and a second power supply plate 32, and the first power supply plate 31 includes a charging unit 311 and a power transmission unit 312. The charging unit 311 is a USB charging port and is used for receiving power from an external power source.
The second power feeding plate 32 includes a power reception unit 321 and two holes 322, and the power reception unit 321 is electrically connected to the power transmission unit 312. The power transmission unit 312 is used to transmit the power of the first power feeding plate 31 to the power reception unit 321, and the power is conducted to the hole 322 by the power reception unit 321. The two holes 322 are electrically connected to the current-carrying rods 24 in the first electrolytic plate 21 and the second electrolytic plate 23, respectively, and power is supplied from the current-carrying rods 24 to the first electrolytic plate 21 and the second electrolytic plate 23. Conducted.

The above is the structure of the present invention and the connection relationship thereof. Then, the usage method of this invention is demonstrated.
As shown in FIGS. 4 and 5, when the user manufactures hydrogen water using a pot capable of manufacturing hydrogen water according to the present invention, when the water is injected into the water storage space 112, the water is a plurality of filters. Although it passes through the hole 131 and enters the first space 122A of the second power feeding space 122, the water is blocked by the filter film 22 and therefore does not enter the second space 122B.
First, when a user electrically connects an external power source to the charging unit 311 of the first power feeding plate 31 and transmits power from the charging unit 311 to the first power feeding plate 31 to store the power, the power transmitting unit 312 receives the power. By being electrically connected to 321, the second power feeding plate 32 is electrically conductive. The energizing rods 24 of the first electrolytic plate 21 and the second electrolytic plate 23 are connected to each other through the two holes 322, and power is conducted from the second power feeding plate 32 to the first electrolytic plate 21 and the second electrolytic plate 23. Is done.
Under the influence of the anode and the cathode between the first electrolytic plate 21 and the second electrolytic plate 23, the water in contact with the first electrolytic plate 21 is electrolyzed to H + and O−. H + of H + and O− generated by the first electrolytic plate 21 enters the water storage space 112 along the extending direction X from the filter hole 131 and combines with the water in the water storage space 112 to store the water. The water in the space 112 becomes hydrogen water. O− passes through the filter film 22 and enters the second space 122 </ b> B. Through the communication pipe 151, O− flows from the exhaust pipe 25 to the exhaust hole 16 and is discharged out of the base 10.

Accordingly, the user first charges the first power feeding plate 31 using an external power source, starts the electrolysis unit 20 with the power stored in the first power feeding plate 31, and the electrolysis unit 20 causes the inside of the water storage space 112 to be stored. Water is electrolyzed.
The user can go out with a pot capable of producing hydrogen water of the present invention. When going out, hydrogen water can be produced simply by filling liquid water. In addition, since power is supplied from the power supply unit 30 in the present invention, it is not necessary to connect to an external power source separately. When the power of the power supply unit 30 is consumed, the power supply is restored to normal only by replenishing the power by the charging unit 311.

  The embodiments disclosed herein are for the purpose of explaining, not limiting the present invention, and the spirit and scope of the present invention are not limited by such embodiments. The scope of the present invention should be construed according to the claims for utility model registration, and all technologies within the equivalent scope should be construed as being included in the scope of claims for utility model registration.

50 pedestal 51 recess 52 control panel 53 conductive end 60 container 61 opening 70 electrolysis unit 80 upper lid 10 pedestal 11 water injection space 111 pot wall 112 water storage space 12 power supply space 121 first power supply space 122 second power supply space 122A first space 122B first Two spaces 13 Barrier 131 Filter hole 15 Cover 151 Communication pipe 16 Exhaust hole 20 Electrolytic unit 21 First electrolytic plate 22 Filter film 23 Second electrolytic plate 24 Current bar 25 Exhaust pipe 30 Power supply unit 31 First power supply plate 311 Charging unit 312 Power transmission Portion 32 Second power feeding plate 321 Power receiving portion 322 Hole X Extension direction

Claims (7)

It has a water injection space and a power supply space, and has a barrier for separating the water injection space and the power supply space inside, the power supply space is composed of a first power supply space and a second power supply space, The second power supply space is formed, a filter hole is opened in the barrier, and the filter hole is in communication with the second power supply space and the water injection space,
A first electrolytic plate installed in the second power feeding space; a filter film; and a second electrolytic plate. A current-carrying rod is connected to the second power feeding from the first electrolytic plate and the second electrolytic plate. An electrolysis unit each extending into the space;
A power supply unit installed in the second power supply space and electrically connected to the power supply rod of the first electrolytic plate and the power supply rod of the second electrolytic plate;
Pot that can produce hydrogen water.   The second feeding space is divided into a first space and a second space by the filter film, the filter film is impermeable, the first space communicates with the filter hole, and the first electrolytic plate. 2. The pot capable of producing hydrogen water according to claim 1, wherein the pot is placed in the first space, and the second electrolytic plate is placed in the second space.   The direction in which the water injection space is connected to the power supply space is defined as an extending direction, and the second power supply space is formed by enclosing the barrier toward the water injection space along the extending direction. Has a plurality of filter holes, the cover closes the second power feeding space, and a communication pipe penetrates the cover, and the communication pipe communicates with the second power feeding space and the first power feeding space. 2. The pot capable of producing hydrogen water according to claim 1, wherein the pedestal is provided with an exhaust hole communicating with the first feeding space and the outside of the pedestal.   The energizing rod in the first electrolytic plate penetrates the filter film, the second electrolytic plate and the cover, the energizing rod in the second electrolytic plate penetrates the cover, and the exhaust pipe is connected to the communication pipe. 4. The pot capable of producing hydrogen water according to claim 3, wherein the second space communicates with the outside of the pedestal by being connected to the exhaust hole.   A pot wall is installed in the water injection space, a water storage space is defined in the pot wall, and the water storage space is used to fill water and communicates with the second power feeding space. A pot capable of producing the hydrogen water according to claim 1.   The power supply unit includes a first power supply plate and a second power supply plate, the first power supply plate includes a charging unit and a power transmission unit, the charging unit is used to receive an external power source, and the second power supply plate is A power receiving unit and two holes, wherein the power receiving unit is electrically connected to the power transmission unit, and the power transmission unit is used to transmit the power of the first power feeding plate to the power reception unit; Power is conducted to the hole by the portion, the two holes are electrically connected to the current-carrying rods of the first electrolytic plate and the second electrolytic plate, respectively, and power is transmitted from each of the current-carrying rods to the first The pot capable of producing hydrogen water according to claim 1, wherein the pot is conductive to the electrolytic plate and the second electrolytic plate.   The pot according to claim 6, wherein the charging unit is a USB charging port.

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