KR101978380B1 - Electrode cell for electrolysis and module for manufacturing ionic water - Google Patents

Abstract

The present invention aims at producing sterilized water or hydrogenated water at a high concentration by scavenging sterilized water or hydrogenated water and scaling up electrode cells as required, And an electrode module positioned in the flow path, wherein the electrode module includes: a first electrode; And a second electrode positioned on the upper side of the first electrode, wherein a separation membrane for dividing the flow path is disposed between the first electrode and the second electrode, and a functional water generating module including the electrode cell for electrolysis, .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electrode cell for electrolysis and a functional water-

The present invention relates to an electrode cell for electrolysis and a functional water generating module.

When electrolyzing water (H ₂ O) or an aqueous solution, oxygen (O ₂ ), ozone (O ₃ ) and the like are generated in the anode electrode and hydrogen (H ₂ ) is generated in the cathode electrode. As a result, sterilized water in which oxygen or ozone is dissolved is generated from the anode electrode, and hydrogen water in which hydrogen and the like are dissolved is generated from the cathode electrode. The sterilized water can be used for washing or sterilizing, and the drinking water can remove active oxygen and the like in the body by drinking.

A device for generating functional water by electrolyzing water or an aqueous solution and supplying functional water through a motor and a pump is called a functional water producing device. The module in which the function number is generated in the function number generation device is referred to as a function number generation module. And generally consists of a chamber in which water or an aqueous solution is stored and an electrode module accommodated in an inner space of the chamber.

Korean Patent No. 10-1120942 (hereinafter referred to as prior art) discloses an apparatus for producing a functional water-containing hydrogenated water.

In the prior art, an electrolyzer 106 (corresponding to an electrolytic cell for electrolysis) having electrodes 107 and 108 spaced from each other is incorporated in the cold / hot water storage container 101 storing water or an aqueous solution.

As a result, there is a problem that the sterilizing water and the hydrogen water are simultaneously generated and mixed in the anode and the cathode even when the sterilizing water and the hydrogen water have different functions. Furthermore, the prior art does not have means for increasing the production rate of functional water by scaling up the electrode cells as needed.

In order to solve the above-mentioned problems, there is provided an electrode cell for electrolysis which can be produced by disinfecting water or hydrogen water separately.

Furthermore, it is an object of the present invention to provide an electrode cell for electrolysis capable of producing high-concentration sterilized water or high-concentration water by scaling up an electrode cell as needed.

And a functional water generating module including the electrode cell for electrolysis.

The electrolytic cell for electrolysis of the first embodiment includes: a housing having a channel formed therein; And an electrode module positioned in the flow path, wherein the electrode module includes: a first electrode; And a second electrode positioned on the upper side of the first electrode, and a separation membrane for dividing the flow path may be disposed between the first electrode and the second electrode.

The first electrode and the second electrode may be electrically connected to an external power source, and the polarities of the first electrode and the second electrode may be variable.

A plurality of holes may be formed in the first and second electrodes.

The separation membrane may be an ion exchange membrane or a polymer electrolyte membrane.

The electrode cell for electrolysis of the second embodiment may further include a third electrode spaced upward from the second electrode in the electrode module of the first embodiment.

The first electrode, the second electrode, and the third electrode may be electrically connected to an external power source, and the polarities of the first electrode, the second electrode, and the third electrode may be varied.

A spacer may be positioned between the second electrode and the third electrode.

A plurality of holes may be formed in the first to third electrodes.

The functional water generating module including the electrode cell of the first or second embodiment comprises: a chamber in which water or an aqueous solution is disposed; And an electrode cell for electrolysis positioned in the form of a partition wall in the chamber, wherein the electrode cell for electrolysis comprises: a housing having a channel formed therein; And an electrode module positioned in the flow path, wherein the electrode module includes: a first electrode; And a second electrode located on the upper side of the first electrode, and a separation membrane for dividing the flow path may be disposed between the first electrode and the second electrode.

The electrode module may further include a third electrode spaced upward from the second electrode.

In the present invention, since the first electrode and the second electrode are separated by the separation membrane, sterilizing water and hydrogen can be respectively generated.

Further, the multi-function water (functional water in which ozone and hydrogen are mixed and dissolved) can be produced by the third electrode as needed, and the electrode cell for electrolysis is scaled up to generate high concentration sterilizing water or high concentration water .

Further, it is possible to provide a functional water generating module including an electrode cell for electrolysis having the above-mentioned effect.

1 is a perspective view showing an electrode cell for electrolysis of the first embodiment.
2 is an exploded perspective view showing the electrolytic cell for electrolysis according to the first embodiment.
3 is a cross-sectional view showing the electrode cell for electrolysis of the first embodiment.
4 is a perspective view showing the electrode cell for electrolysis of the second embodiment.
5 is an exploded perspective view showing the electrolytic cell for electrolysis of the second embodiment.
6 is a cross-sectional view showing the electrode cell for electrolysis of the second embodiment.
7 is a conceptual perspective view showing a function water generating module including the electrode cell for electrolysis of the first embodiment.
Fig. 8 is a conceptual perspective view showing the function water generating module including the electrode cell for electrolysis of the second embodiment. Fig.

Hereinafter, some embodiments of the present invention will be described with reference to exemplary drawings. In describing the components in the drawings, the same components are denoted by the same reference numerals whenever possible, even if they are displayed on other drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected, coupled, or connected to the other component, It is to be understood that another element may be " connected ", " coupled ", or " connected " between elements.

Hereinafter, the structure of the electrolytic electrode cell 1000 of the first embodiment will be described with reference to the drawings. 2 is an exploded perspective view showing an electrolytic cell for electrolysis according to the first embodiment. Fig. 3 is a cross-sectional view of the electrolytic cell according to the first embodiment of the present invention. Fig. Sectional view showing an electrode cell for use in the present invention.

The electrode cell 1000 for electrolysis of the first embodiment may include the housing 100 and the electrode module 200 and may be electrically connected to a power source (not shown).

The housing 100 may be a plastic molded product as a casing of the electrode cell 1000 for electrolysis. The housing 100 may be made of a material in which plastic and metal are combined. The housing 100 may be in the form of a block in which the flow path 110 is formed. In the housing 100, the electrode module 200 may be positioned. The electrode module 200 may be positioned inside the housing 100. The electrode module 200 may be positioned in the flow path 110 of the housing 100. In this case, the electrode module 200 may be positioned in the form of a partition wall in the flow path 110 formed in the housing 100. The housing 100 and the electrode module 200 may be combined in an assembly form.

The flow path 110 may be formed at the center of the housing 100. The flow path 110 may be formed to pass through the upper and lower directions of the housing 100. In the flow path 110, the electrode module 200 may be positioned. In the flow path 110, the electrode module 200 may be positioned in the form of a partition. In this case, the first and second electrodes 20 and 40 may have a plurality of holes 22 and 42, so that the flow path 110 is not closed. In the flow path 110, the separation membrane 30 may be positioned in the form of a partition. Therefore, the flow path 110 can be separated into the upper part and the lower part based on the separator 30.

The housing 100 may include a lower housing 10 and an upper housing 70.

The lower housing 10 may be located at the lower portion of the upper housing 70. The lower housing 10 may have a block shape or a plate shape with a lower flow path 110 formed at the center thereof. The lower housing 10 and the upper housing 70 can be engaged. The lower housing 10 and the upper housing 70 can be screwed or riveted. In this case, a screw (not shown) or a pin (not shown) may be received in a plurality of lower engaging holes 11 formed at the edge of the lower housing 10. A stepped portion 13 may be formed along the inner surface of the flow path 110 of the lower housing 10. In this case, the electrode module 200 can be supported by the step of the step portion 13. [ As a result, the electrode module 200 can be positioned in the form of a partition wall with respect to the flow path 110. In this case, a plurality of holes 22 and 42 may be formed in the first and second electrodes 20 and 40. As a result, the water or aqueous solution can move through the plurality of holes 22, Therefore, the flow path 110 is not closed by the first and second electrodes 20 and 40 in the form of the barrier ribs. In a modification (not shown), the first and second electrodes 20 and 40 may not be positioned in the form of a barrier. In this case, even though the plurality of holes 22 and 42 are not formed in the first and second electrodes 20 and 40, the flow path 110 is not closed by the first and second electrodes 20 and 40.

The upper housing 70 may be located at the upper portion of the lower housing 10. The upper housing 70 may be in the form of a block or plate having an upper flow path 110 formed at the center thereof. The upper housing 70 and the lower housing 10 can be engaged. The upper housing 70 and the lower housing 10 can be screwed or riveted. In this case, a screw (not shown) or a pin (not shown) may be received in a plurality of upper engaging holes 71 formed at the edge of the upper housing 70. In the upper housing 70, a plurality of terminal holes 72 may be formed. Terminal holes 72 may be formed on the four sides of the upper housing 10. Therefore, the number of the terminal holes 72 can be four in total. In this case, the two terminals 23 and 43 protrude through the two terminal holes 72 out of the four terminal holes 72, and can be electrically connected to a power source to be described later. However, it is not preferable that the two terminals 23 and 43 are housed in one terminal hole 72 and protrude because an electrical short circuit may occur.

The electrode module 200 may be located in the flow path 110. The electrode module 200 may be housed in the housing 100 and positioned in the flow path 110. The edge portion of the lower surface of the electrode module 200 is supported by the step of the step portion 13 of the lower housing 10 and the edge portion of the upper surface of the electrode module 200 can be positioned in contact with the upper housing 70 have. In this case, the electrode module 200 can be fixed by the compressive force generated by the engagement of the upper housing 70 and the lower housing 10. The electrode module 200 may be positioned in the form of a partition wall with respect to the flow path 110.

The electrode module 200 may include a first electrode 20, a separation membrane 30, and a second electrode 40.

The first electrode 20 may be positioned below the electrode module 200. The first electrode 20 may be located on the lower side of the separation membrane 30. The edge of the lower surface of the first electrode 20 can be supported by the step of the step 13 of the lower housing 10. The first electrode 20 may be positioned in the form of a partition wall with respect to the flow path 110. The first electrode 20 may be in the form of a flat plate having a plurality of holes 22 formed therein. The water or the aqueous solution in the flow path 110 can be moved through the plurality of holes 22 of the first electrode 20. The first electrode 20 may be electrically connected to a power source.

The first electrode terminal 23 may be located on one side of the first electrode 20. The first electrode terminal 23 may extend upward and protrude through one of the four terminal holes 72 of the upper housing 70. The first electrode terminal 23 may be formed integrally with the first electrode 20. The first electrode terminal 23 may be electrically connected to the power source by a conductive line (not shown), a connector (not shown), a printed circuit board (PCB), or the like. As a result, power can be supplied to the first electrode 20.

The intensity, direction, and wavelength of the current supplied to the first electrode 20 can be varied. In particular, the polarity of the first electrode 20 may be variable. That is, the user can control the polarity of the first electrode 20. Accordingly, the first electrode 20 may be an anode or a cathode depending on circumstances. When the first electrode 20 is an anode, an anion (e.g., OH-) may lose electrons and be oxidized. That is, the first electrode 20 obtains electrons and the anions lose electrons. As a result, oxygen or ozone is generated in the first electrode 20, and sterilized water can be generated. When the first electrode 20 is a cathode, a cation (for example, H +) can be reduced by obtaining electrons. That is, the first electrode 20 loses electrons, and the positive ions obtain electrons. As a result, hydrogen or the like may be generated in the first electrode 20 to generate hydrogen.

The separation membrane 30 may be positioned between the first electrode 20 and the second electrode 40. That is, the separation membrane 30 may be located above the first electrode 20 and below the second electrode 40. [ The separation membrane 30 may be in the form of a rectangular film. The separator 30 may include an insulating material. As a result, it is possible to prevent an electrical short between the first electrode 20 and the second electrode 40 from occurring. The separation membrane 30 may be positioned in the form of a partition wall with respect to the flow path 110. As a result, only the material permeated through the separation membrane 30 can move downward from the upper part of the flow path 110 or move upward from the lower part of the flow path 110. That is, the separation membrane 30 can selectively close the flow path 110, unlike the electrodes 20 and 40. As a result, the flow path 110 is divided into an upper portion and a lower portion with respect to the separator 30.

The separator 30 may be a selectively transmissive film. The separation membrane 30 may be an ion exchange membrane. The separation membrane 30 may be a cation exchange membrane. The cation exchange membrane can have a cation group (for example, a hydrogen cation (H +)) through an anionic group on the membrane backbone. The separation membrane 30 may be an anion exchange membrane. The anion exchange membrane may have a cation group at the membrane backbone to allow anion (for example, hydroxide anion (OH-)) to pass through. The separation membrane may be a polymer electrolyte membrane. For example, in the first embodiment, a Nafion separation membrane may be used. The polymer electrolyte membrane selectively permeates hydrogen ions. Hydrogen ions move in the membrane by hopping between the polymeric materials using SO ₃ - ions as a stepping bridge. As a result, the electrolysis time and efficiency can be increased.

The second electrode 40 may be positioned on the upper side of the electrode module 200. The second electrode 40 may be located on the upper side of the separation membrane 30. The upper edge of the second electrode 40 may be in contact with the lower surface of the upper housing 70. The second electrode 40 may be positioned in the form of a barrier against the flow path 110. The second electrode 40 may be in the form of a flat plate on which a plurality of holes 42 are formed. The water or aqueous solution in the flow path 110 can move through the plurality of holes 42 of the second electrode 40. The second electrode 40 may be electrically connected to a power source.

The second electrode terminal 43 may be positioned on one side of the second electrode 40. The second electrode terminal 43 may extend upward to pass through one of the four terminal holes 72 of the upper housing 70. The second electrode terminal 43 may be formed integrally with the second electrode 40. The second electrode terminal 43 may be electrically connected to the power source by a conductive line (not shown), a connector (not shown), a printed circuit board (PCB), or the like. As a result, power can be supplied to the second electrode 40.

The intensity, direction, and wavelength of the current supplied to the second electrode 40 may vary. In particular, the polarity of the second electrode 40 may be variable. That is, the user can control the polarity of the second electrode 40. Accordingly, the second electrode 40 may be an anode or a cathode depending on circumstances. When the second electrode 40 is an anode, an anion (e.g., OH-) may lose electrons and be oxidized. That is, the second electrode 40 obtains electrons and anions lose electrons. As a result, oxygen or ozone may be generated in the second electrode 40 to generate oxidation water. When the second electrode 40 is a cathode, a cation (for example, H +) can be reduced by obtaining electrons. That is, the second electrode 40 loses electrons, and the positive ions obtain electrons. As a result, hydrogen or the like may be generated in the second electrode 40 to generate hydrogen.

The power source may be located outside the electrode cell 1000 for electrolysis. The power source may be electrically connected to the first and second electrodes 20 and 40. The power source can supply a current by applying power (voltage) to the first and second electrodes 20 and 40. In this case, the intensity, direction, and wavelength of the current supplied to the first and second electrodes 20 and 40 can be controlled and varied. In particular, the polarities of the first and second electrodes 20 and 40 can be controlled and varied. The power source may be electrically connected to the first and second electrode terminals 23 and 43 of the first and second electrodes 20 and 40. The power source may be electrically connected to the first and second electrode terminals 23 and 43 by a conductive line (not shown), a connector (not shown), a printed circuit board (PCB), or the like.

The operation, functions, and effects of the electrolytic electrode cell 1000 of the first embodiment will be described below.

The electrolytic cell 1000 for electrolysis according to the first embodiment electrolyzes water or an aqueous solution in the flow path 110. In the electrolysis, on the anode, anions (for example, hydroxide ions) lose electrons and are oxidized to generate oxygen or ozone. As a result, sterilized water in which oxygen, ozone or the like is dissolved is produced. In the cathode, positive ions (for example, hydrogen ions) obtain electrons and are reduced to generate hydrogen or the like. As a result, hydrogen gas, in which hydrogen or the like is dissolved, is generated.

Since the first and second electrodes 20 and 40 are separated by the separator 30, the sterilizing water or the hydrogen may be generated by separating the electrolytic cell 1000 of the first embodiment.

(1) When the first electrode 20 is a cathode and the second electrode 40 is a cathode

Ions having selective permeability in water or an aqueous solution in the flow path 110 can freely move through the flow path 110 through the separation membrane 30. The flow path 110 is divided into a lower portion where the first electrode 20 (cathode) is located and an upper portion where the second electrode 40 (anode) is located with respect to the separator 30.

When power is applied, hydrogen ions are reduced in the first electrode 20 (cathode) to generate hydrogen gas, and hydroxide ions are oxidized in the second electrode 40 (anode) to generate sterilized water. The hydrogen generated in the first electrode 20 and the oxygen or ozone generated in the second electrode 40 can not pass through the separation membrane 30, Sterilized water is generated at the lower portion of the flow path 110 where the hydrogen electrode is located at the second electrode 40 (anode).

When the separation membrane 30 is a cation separation membrane, positive ions (particularly, hydrogen ions) on the channel 110 are attracted to the electromagnetic attraction of the first electrode 20 to permeate the separation membrane 30, . ≪ / RTI > In this case, the cation transmitted through the separation membrane 30 can be reduced to hydrogen or the like by the first electrode 20. However, anions (particularly, hydroxide ions) in the lower portion of the flow path 110 can not penetrate the separation membrane 30 even if they are attracted to the electromagnetic attraction of the second electrode 40. As a result, anions (particularly, hydroxide ions) in the lower part of the flow path 110 can not be oxidized by the second electrode 40 in the upper part of the flow path 110. Furthermore, when a polymer electrolyte membrane (for example, a Nafion separation membrane) is used, hydrogen ions can be selectively transmitted. As described above, since the hydrogen ions hop on the SO ₃ - ions of the polymer electrolyte membrane as stepping stones, the efficiency of hydrogen generation in the first electrode 20 (the lower flow path 110) can be increased.

When the separator 30 is an anion separation membrane, the anions (particularly, hydroxide ions) below the flow path 110 are attracted by the electromagnetic attraction of the second electrode 40 (anode) As shown in FIG. In this case, the anion that has passed through the separation membrane 30 can be oxidized with oxygen or ozone by the second electrode 40 (anode). However, the cation (particularly, hydrogen ion) on the upper portion of the flow path 110 can not penetrate the separation membrane 30 even if it is attracted to the electromagnetic attraction of the first electrode 20. As a result, cations (particularly, hydrogen ions) in the upper portion of the flow path 110 can not be reduced by the first electrode 20 in the lower portion of the flow path 110.

(2) When the first electrode 20 is an anode and the second electrode 40 is a cathode

The polarity of the first and second electrodes 20 and 40 is opposite to the above-mentioned condition (1). (1) Operation, function and effect occur in reverse to the conditions. As a result, sterilizing water is produced in the lower portion of the flow path 110 where the first electrode is located, and hydrogen water is produced in the upper portion of the flow path 110 where the second electrode is located.

(3) Effect of reversing the first and second electrodes 20 and 40 - Scale removal mode

When the polarities of the first and second electrodes 20 and 40 are periodically changed, oxidation and reduction reactions may be alternated at the respective electrodes. In this case, not only hydrogen and hydroxide ions but also scales (particularly calcite) generated by various cations or anions included in water or an aqueous solution are removed in the process of alternating the polarities of the first and second electrodes 20 and 40 .

The configuration of the electrolytic electrode cell 2000 of the second embodiment will be described below. 5 is an exploded perspective view showing the electrode cell for electrolysis according to the second embodiment. Fig. 6 is a cross-sectional view of the electrolysis cell according to the second embodiment of the present invention. Fig. Sectional view showing an electrode cell for use in the present invention.

The electrode cell 2000 for electrolysis of the second embodiment has the same technical idea as the electrode cell 1000 for electrolysis of the first embodiment except that it also includes the spacer 50 and the third electrode 60 . Therefore, the description of the parts having the same technical ideas as those of the electrolytic cell 1000 of the first embodiment will be omitted.

The spacer 50 may be placed in contact with the lower surface of the third electrode 60 and the upper surface of the second electrode 40, The spacer 50 may be in the form of a hollow rectangular plate formed along four sides of the third electrode 60 and the second electrode 40 plate. Therefore, the flow path 110 is not closed by the spacer 50. Further, the third electrode 60 and the second electrode 40 are spaced apart from each other by the spacer 50 in an electrically short-circuited state.

The third electrode 60 may be positioned on the upper side of the electrode module 200. The third electrode 60 may be located above the second electrode 40. A spacer 50 may be positioned between the third electrode 60 and the second electrode 40. The edge of the upper surface of the third electrode 60 can contact the bottom surface of the upper housing 70. The third electrode 60 may be positioned in the form of a barrier against the flow path 110. The third electrode 60 may be in the form of a flat plate having a plurality of holes 62 formed therein. The water or aqueous solution in the flow path 110 can move through the plurality of holes 62 of the third electrode 60. The third electrode 60 may be electrically connected to a power source.

The third electrode terminal 63 may be positioned on one side of the third electrode 60. The third electrode terminal 63 may extend upward and pass through one of the four terminal holes 72 of the upper housing 70. The third electrode terminal 63 may be integrally formed with the third electrode 60. The third electrode terminal 63 may be electrically connected to the power source through a conductive line (not shown), a connector (not shown), a printed circuit board (PCB), or the like. As a result, power can be supplied to the third electrode 60.

The intensity, direction, and wavelength of the current supplied to the third electrode 60 can be varied. In particular, the polarity of the third electrode 60 may be variable. That is, the user can control the polarity of the third electrode 60. Accordingly, the third electrode 60 may be an anode or a cathode depending on circumstances. When the third electrode 60 is an anode, anions (particularly, OH-) lose electrons and can be oxidized. That is, the third electrode 60 obtains electrons and anions lose electrons. As a result, oxygen or ozone may be generated in the third electrode 60 to generate sterilized water. When the third electrode 60 is a cathode, a cation (particularly, H +) can be reduced by obtaining electrons. That is, the third electrode 60 loses electrons, and the cation gets electrons. As a result, hydrogen or the like may be generated in the third electrode 60 to generate hydrogen.

The operation, functions, and effects of the electrolytic electrode cell 2000 of the second embodiment will be described below.

The electrode for electrolysis 2000 of the second embodiment can perform all the functions that the electrode for electrolysis 1000 of the first embodiment can perform. This function may be performed by applying power only to the first and second electrode cells 20 and 40 without applying power to the third electrode cell 60. Therefore, the same operations, functions, and effects as those of the first embodiment will be omitted.

As described above, generally, in an anode during an electrolysis, anions (particularly, hydroxide ions) lose electrons and are oxidized to generate oxygen or ozone. As a result, sterilized water in which oxygen, ozone or the like is dissolved is produced. In the cathode, positive ions (particularly, hydrogen ions) obtain electrons and are reduced to generate hydrogen and the like. As a result, hydrogen gas, in which hydrogen or the like is dissolved, is generated.

The electrode cell 2000 for electrolysis according to the second embodiment can be produced by separating sterilized water and hydrogenated water according to the use conditions (the function of the electrolytic cell 1000 of the first embodiment) Function can also be created. Furthermore, when the second and third electrodes 40 and 60 located at the upper portion of the flow path 110 have the same polarity, high concentration sterilizing water or high concentration hydrogen water can be produced.

(1) the condition that the polarity of the second electrode 40 and the polarity of the third electrode 60 are opposite

Ions having selective permeability in water or an aqueous solution in the flow path 110 can freely move through the flow path 110 through the separation membrane 30. The flow path 110 is divided into a lower part where the first electrode 20 is located and an upper part where the second and third electrodes 40 and 60 are positioned with respect to the separation membrane 30.

When the second electrode 40 is an anode and the third electrode 60 is a cathode or the second electrode 40 is a cathode and the third electrode 60 is an anode, In the case where the polarity of the electrode 60 is opposite, oxygen or ozone is generated at the anode and sterilizing water is generated, and hydrogen or the like is generated at the cathode to generate hydrogen. As a result, oxygen, ozone, and hydrogen are generated at the same time at the upper portion of the flow path 110 where the second and third electrodes 40, 60 are located, so that multiple function water (mixed water of sterilized water and hydrogenated water) is generated. In this case, the first electrode 20 may be a surplus electrode to which power is not applied.

(2) When the first electrode 20 is the cathode and the second and third electrodes 40 and 60 are the anode

When the power source is applied, hydrogen ions are reduced in the first electrode 20 (cathode) to generate hydrogen gas, and hydroxyl ions are oxidized in the second and third electrodes 40 and 60 (anode) to generate sterilized water. Hydrogen generated in the first electrode 20 and cathode and oxygen or ozone generated in the second and third electrodes 40 and 60 can not pass through the separation membrane 30, The sterilizing water is generated in the lower part of the flow path 110 where the second electrode 40 (anode) is located. Further, at the upper portion of the flow path 110, the third electrode 60 is present in comparison with the first embodiment, and the high concentration sterilizing water can be produced by the increased potential difference or the output amount.

When the separation membrane 30 is an anion separation membrane, anions (particularly, hydroxide ions) below the flow passage 110 are attracted by the electromagnetic attracting force of the second and third electrodes 40 and 60 (anode) And can move to the upper portion of the flow path 110. In this case, the anion that has passed through the separation membrane 30 can be oxidized with oxygen or ozone by the second and third electrodes 40 and 60 (anode). However, even if the positive ions (particularly hydrogen ions) on the flow path 110 are attracted to the electromagnetic attraction of the first electrode 20 (negative electrode), they can not pass through the separation membrane 30, Can not be reduced by the first electrode (20). Therefore, it is preferable to use an anion-exchange membrane in order to produce high-concentration sterilized water.

(3) When the first electrode 20 is an anode and the second and third electrodes 40 and 60 are cathodes

When power is applied, hydroxide ion is oxidized to generate sterilized water at the first electrode (20, anode), and oxygen ions are reduced at the second and third electrodes (40, 60, cathode) to generate hydrogen. Oxygen or ozone generated in the first electrode 20 and hydrogen generated in the second and third electrodes 40 and 60 can not pass through the separation membrane 30 and therefore the flow path in which the first electrode 20 110, hydrogen is generated at the upper portion of the flow path 110 where the sterilizing water is supplied to the second and third electrodes 40, 60 (cathode). Further, at the upper portion of the flow path 110, the third electrode 60 is present in comparison with the first embodiment, and the high-concentration hydrogen can be produced by an increased potential difference or an output amount.

When the separation membrane 30 is a cation separation membrane, positive ions (particularly, hydrogen ions) under the flow channel 110 are attracted by the electromagnetic attracting force of the second and third electrodes 40 and 60 (cathode) And can move to the upper portion of the flow path 110. In this case, the cation transmitted through the separation membrane 30 can be reduced to hydrogen or the like by the second and third electrodes 20 and 60 (cathode). However, anions (particularly, hydroxide ions) on the upper portion of the flow path 110 can not penetrate the separation membrane 30 even if they are attracted to the electromagnetic attraction of the first electrode 20 (anode). As a result, anions (particularly, hydroxide ions) on the upper portion of the flow path 110 can not be oxidized by the first electrode 20 (anode) in the lower portion of the flow path. Therefore, it is preferable to use a cation separation membrane to produce high-concentration hydrogen peroxide. Furthermore, when a polymer electrolyte membrane (for example, a Nafion separation membrane) is used, hydrogen ions can be selectively transmitted. As described above, since the hydrogen ions hop through the SO ₃ - ions of the polymer electrolyte membrane as stepping stones, the efficiency of hydrogen generation in the upper flow path 110 where the second and third electrodes 40 and 60 are located can be increased have.

Hereinafter, the structure, operation, functions, and effects of the function generating module 3000 using the electrode cells of the first and second embodiments will be described with reference to the drawings. FIG. 7 is a conceptual perspective view showing a functional water generating module including the electrolytic electrode cell of the first embodiment, and FIG. 8 is a conceptual perspective view showing a functional water generating module including the electrolytic electrode cell of the second embodiment. to be.

The function number generation module 3000 may include the chamber 300 and the electrode cell 1000 of the first embodiment or the electrode cell 2000 of the second embodiment.

The chamber 300 may be hollow. The chamber 300 may contain water or an aqueous solution therein. The chamber 300 may be a casing of the function generating module 3000. The electrode cell 1000 of the first embodiment or the electrode cell 2000 of the second embodiment may be disposed inside the chamber 300. [ In the interior of the chamber 300, the electrode cell 1000 of the first embodiment or the electrode cell 2000 of the second embodiment may be placed in the form of a partition. As a result, the second electrode 40 or the second and third electrodes 40 and 60 are located on the upper side, and the first electrode 20 is located on the lower side and can be separated based on the separation membrane 30. That is, the chamber 300 can be divided into the lower chamber 80 and the upper chamber 90 with respect to the separation membrane 30.

The function number generation module 3000 may be included as a module 3000 that generates function numbers in various machines, apparatuses, devices, systems, and the like. For example, the function number generation module 3000 can constitute a part of a disposable mist container (not shown) for prevention of skin aging and nutrition. In this case, the water or the aqueous solution of the upper chamber 90 of the function number generation module 3000 can be injected to the outside through a nozzle (not shown) by a driving part (not shown) such as a pump or a motor, The water or aqueous solution of the lower chamber 80 may be stored in a space defined by the separating film 30 and the side wall and bottom surface of the lower chamber 80. This is because the separator 30 of the first and second embodiments passes only positive ions or anions or specific ions.

In the case of including the electrode cell 1000 of the first embodiment, 1) sterilized water can be produced or 2) hydrogen water can be generated in the upper chamber 80 as described above. In addition, 3) scale can be removed by alternately changing the polarity of the electrode. On the other hand, in the case of including the electrode cell 2000 of the second embodiment, in the upper chamber 80, besides the above-mentioned functions, 1) multiple function water can be produced, 2) high concentration sterilizing water can be produced, or 3) high concentration hydrogen water can be generated.

As a result, the user can freely select and spray the sterilized water, 2) the hydrogenated water (when the electrode cell 1000 of the first embodiment is included), or 1) the multifunctional water, 2) 3) High-concentration hydrogen water can be freely electrified and sprayed. (Including the electrode cell 2000 of the second embodiment)

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all of the components may be selectively coupled to one or more of them. Furthermore, the terms "comprises", "comprising", or "having" described above mean that a component can be implanted unless otherwise specifically stated, But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Lower housing
11: lower fitting hole 13: stepped portion
20: first electrode
22: first hole 23: first terminal
30: Membrane
40: second electrode
42: second hole 43: second terminal
50: Spacer
60: Third electrode
62: third hole 63: third terminal
70: upper housing
71: upper fitting hole 72: terminal hole
80: lower chamber 90: upper chamber
100: housing 110:
200: electrode module 300: chamber
1000, 2000: electrode cell 3000: function number generating module

Claims (10)

A housing having a channel formed therein; And
And an electrode module positioned in the flow path,
The electrode module includes:
A first electrode;
A second electrode located above the first electrode;
A third electrode located above the second electrode;
A spacer disposed between the second electrode and the third electrode, the spacer being made of an insulating rubber material and having a hollow passing through a lower surface from an upper surface thereof; And
And a separator disposed between the first electrode and the second electrode and dividing the flow path into an upper portion and a lower portion,
Wherein the first electrode is located at a lower portion of the flow path, the second electrode and the third electrode are located at an upper portion of the flow path, and the first electrode, the second electrode, and the third electrode are electrically connected The polarities of the first electrode, the second electrode, and the third electrode are variable,
Wherein the separation membrane is an ion exchange membrane,
Wherein the electrode module is divided into a first region in which the first electrode is disposed and a second region in which the second electrode and the third electrode are disposed, When the electrode and the third electrode are of opposite polarities, power is not applied to the first electrode,
When a positive power is applied to the second electrode and the third electrode disposed in the second region, a negative power is applied to the first electrode,
When the power source of the cathode is applied to the second electrode and the third electrode arranged in the second region, the power of the anode is applied to the first electrode,
The polarity of the power source applied to the first region and the polarity of the power source applied to the second region are changed to a predetermined period to generate oxidation and reduction reactions alternately,
Wherein the first electrode includes a first electrode terminal protruding upward from one side,
The second electrode includes a second electrode terminal protruding upward from one side,
The third electrode includes a third electrode terminal protruding upward from one side,
A first terminal hole passing through the first electrode terminal, a second terminal hole passing through the second electrode terminal, and a third terminal hole passing through the third electrode terminal are formed on the upper surface of the housing,
Wherein the first terminal hole, the second terminal hole, and the third terminal hole are spaced from each other on an upper surface of the housing.
delete The method according to claim 1,
And a plurality of holes are formed in the first and second electrodes.
The method according to claim 1,
Wherein the separation membrane is an ion-exchange membrane or a polymer electrolyte membrane.
delete delete delete The method according to claim 1,
And a plurality of holes are formed in the first to third electrodes.
A chamber in which water or an aqueous solution is located; And
And an electrode cell for electrolysis located in the chamber in the form of a partition wall,
Wherein the electrode cell for electrolysis comprises:
A housing having a channel formed therein; And
And an electrode module positioned in the flow path,
The electrode module includes:
A first electrode;
A second electrode disposed on the first electrode,
A third electrode located above the second electrode;
A spacer disposed between the second electrode and the third electrode, the spacer being made of an insulating rubber material and having a hollow passing through a lower surface from an upper surface thereof; And
And a separator disposed between the first electrode and the second electrode and dividing the flow path into an upper portion and a lower portion,
Wherein a separation membrane for dividing the flow path into an upper portion and a lower portion is disposed between the first electrode and the second electrode, the first electrode is located at a lower portion of the flow path, and the second electrode and the third electrode are disposed at an upper portion Wherein the first electrode, the second electrode, and the third electrode are electrically connected to an external power source, the polarities of the first electrode, the second electrode, and the third electrode are variable,
Wherein the separation membrane is an ion exchange membrane,
Wherein the electrode module is divided into a first region in which the first electrode is disposed and a second region in which the second electrode and the third electrode are disposed, When the electrode and the third electrode are of opposite polarities, power is not applied to the first electrode,
When a positive power is applied to the second electrode and the third electrode disposed in the second region, a negative power is applied to the first electrode,
When the power source of the cathode is applied to the second electrode and the third electrode arranged in the second region, the power of the anode is applied to the first electrode,
The polarity of the power source applied to the first region and the polarity of the power source applied to the second region are changed to a predetermined period to generate oxidation and reduction reactions alternately,
Wherein the first electrode includes a first electrode terminal protruding upward from one side,
The second electrode includes a second electrode terminal protruding upward from one side,
The third electrode includes a third electrode terminal protruding upward from one side,
A first terminal hole passing through the first electrode terminal, a second terminal hole passing through the second electrode terminal, and a third terminal hole passing through the third electrode terminal are formed on the upper surface of the housing,
Wherein the first terminal hole, the second terminal hole, and the third terminal hole are spaced apart from each other on an upper surface of the housing. delete

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