KR20190114674A - Electrolytic device including multi-channel structure - Google Patents

Abstract

The present invention relates to an electrolysis device including a multi-flow channel structure. An objective of the present invention is to provide an electrolysis device having a flow channel structure, which enables different fluids including gas to be separately supplied through each of multi-flow channels and then, directly supplied to the positive electrode or negative electrode requiring the fluids while preventing a power-applied conductor from having a polarity by integrating a positive electrode or negative electrode with an insulating spacer. The electrolysis device of the present invention includes: a positive electrode assembly including an electrode spacer which is made of an insulating material and has multi-flow channels, and the positive electrode which is accommodated in an electrode accommodating unit to be integrally clamped by a bolt, electrolyzes a fluid received from one multi-flow channel and flows out the electrolyzed fluid to the other multi-flow channel; a negative electrode assembly including an electrode spacer which is made of an insulating material and has multi-flow channels, and the negative electrode which is accommodated in the electrode accommodating unit to be integrally clamped by a bolt, electrolyzes a fluid received from one multi-flow channel and flows out the electrolyzed fluid to the other multi-flow channel; a gas diffusion electrode (GDE) surface contacted with the positive electrode; and a diaphragm for ion movement installed between the GDE and the negative electrode assembly.

Description

Electrolytic device including multi-channel structure

The present invention relates to an electrolysis device including a multi-channel structure, in detail, integrating an electrode with an insulating material spacer, and in a flow path structure and an electrode that can be directly supplied to the electrode required while the fluid containing gas is supplied separately The present invention relates to an electrolysis device which has a contact structure and a flow path structure in which supplied anode water or cathode water flows under a sufficient pressure, thereby improving the electrolytic reaction efficiency.

The electrolysis device in which the electrolysis reaction is performed in the electrolysis process is largely divided into a diaphragm method and a non-membrane method, and further divided into an open cell and a closed cell method.

The electrolytic apparatus having a closed type reaction cell (anode cell and cathode cell) structure of a general diaphragm type is formed by partitioning a membrane (membrane) between the anode and the cathode constituting the reaction cell. The electrode type of the positive electrode and the negative electrode usually uses a mesh-type or perforated electrode, and is configured as close to the diaphragm as possible to reduce the voltage between the unit cells between the positive electrode and the negative electrode. Also, in order to prevent the voltage from rising to the gaseous substance generated during the electrolysis, a space is formed so that the gas can easily escape behind the electrode plate supporting the anode or the cathode.

In addition, the configuration of a unit cell composed of multiple stages includes a monopolar positive electrode and a negative electrode installed at both ends and a bipolar electrode arranged in one or more stages arranged between the positive and negative electrodes at both ends as necessary. A diaphragm is positioned between the cathode and anode electrodes arranged in multiple stages.

It is also composed of a spacer between the diaphragm and each electrode to form a space including an internal flow field. The spacer includes a flow path through which the electrolyte flows into the electrolytic cell, and forms a compartment in which an electrolytic reaction occurs at the electrode. The positive electrode, the negative electrode, and the bipolar electrode are connected to and fixed to the electrode plate by welding, bolting, or bonding.

On the other hand, there is a technique of forming a flow path directly in the spacer through the hole processing as a type of forming a direct flow path in the spacer of the spacer used as the movement path of the electrolyte. As such, when the structure directly forms a flow path in the spacer, there is a structural problem that the sealing structure is weak.

 In addition, the technique of constructing a multi-channel by inserting a separate structure in the spacer has the advantage that can improve the electrolytic reaction efficiency by supplying the electrolyte through the multi-channel, but this also has the disadvantage that the sealing structure due to the insertion of the separate structure is weak. .

In addition, the conventional electrolysis device has a structural disadvantage that when the power is supplied to the metal and the electrolyte is sufficient, the conductor placed between the positive electrode and the negative electrode becomes polar and participates in the reaction as a bipolar electrode. That is, when the fluid to flow to the individual assembly flows through the electrode of the other assembly, there is a structural problem that the reaction efficiency of the electrolytic device is lowered because unnecessary reaction occurs due to the bypass current (BI-PASS) occurs.

On the other hand, there is an electrolysis device in which the reaction gas is supplied and reacted by supplying the reaction gas with the anode water in the conventional electrolysis device. The coupling structure between the spacer or the diaphragm in contact with the positive electrode reaction cell is not installed in close contact with the positive electrode reaction space to provide sufficient pressure. There is a structural problem that the reaction efficiency is lowered.

Korean Laid-Open Patent Publication No. 10-2005-0052516 (2005.06.02.) Korea Patent Registration Publication No. 10-0981585 (2010.09.03.) Korean Laid-Open Patent Publication No. 10-2014-0035687 (2014.03.24.) Korea Registered Utility Model Publication No. 20-0463822 (2012.11.21.)

An object of the present invention for solving the above problems is to integrate the positive electrode or the negative electrode with the insulating spacer to separate and supply different fluids containing gas through each of the multiple channels while preventing the applied conductor from being polarized To provide an electrolysis device having a flow path structure that can be supplied directly to the positive electrode or negative electrode required.

Another object of the present invention is to compose the contact space of the positive electrode or the negative electrode through which the number of electrodes and gaseous fluids pass while the GDE (Gas Diffusion Electrode) contacting the positive electrode or the negative electrode is contacted with sufficient pressure to increase the reaction efficiency. It is to provide an electrolysis device having a flow structure to generate turbulence to increase the pressure of the fluid to increase the reaction efficiency.

It is another object of the present invention to provide an electrolysis device capable of forming two or three or more diaphragms by providing one or more flow path providing intermediate bonds in a unit reaction cell including a positive electrode and a negative electrode or a bipolar electrode.

The present invention, which achieves the object as described above and removes the drawbacks of the prior art, is characterized in that the multiple flow paths for inflow and outflow of fluids including gas are formed in upper and lower portions and the electrode receiving portion is formed on one side thereof. A positive electrode assembly comprising a spacer and a positive electrode which is integrally fastened by bolts and is received by the electrode accommodating part and discharges the fluid supplied from one side of the multi-channel after electrolysis to the other side of the multi-channel;

Multiple flow paths for inflow and outflow of fluids including gas are formed on the upper and lower sides, and an electrode spacer of an insulating material having an electrode accommodating part formed on one side facing the positive electrode, and housed in the electrode accommodating part and fastened integrally with bolts. A negative electrode assembly composed of a negative electrode which discharges the fluid supplied from the flow path to the other multi-channel after electrolysis;

GDE (Gas Diffusion Electrode) in surface contact with the positive electrode;

It is achieved by providing an electrolysis device comprising a multi-channel structure, characterized in that it comprises a; a diaphragm for ion transport is installed between the GDE and the negative electrode assembly.

In a preferred embodiment, the fluid inlet and the fluid outlet in contact with the outside of the positive electrode assembly includes a front cover formed in the upper and lower portions for each fluid, and a rear cover in contact with the outside of the negative electrode assembly, between the front cover and the rear cover In the assembled state by pressing the bolt all the fluid can be configured to be supplied to the lower multi-channel through the lower inlet nozzle of the front cover and the reaction fluid is discharged to the upper outlet nozzle through the upper multi-channel.

In a preferred embodiment, a positive electrode and a negative electrode are coupled to the insulating material electrode spacer in which the multi-channel is formed between the negative electrode assembly and the diaphragm, and the negative electrode assembly and the bipolar assembly are in contact with the positive electrode on one side of the bipolar assembly. It can be configured to further include GDE and septum.

In a preferred embodiment, the multi-channels formed on the upper and lower portions of the insulating material electrode spacer may be configured in four, respectively, so that the gas, the anode water, the electrolyte and the cathode water flow separately.

In a preferred embodiment, the insulating material electrode spacer may be formed in each of the branch flow path to supply the fluid directly to the positive electrode or the negative electrode of any one of the multi-channel formed in the upper and lower.

In a preferred embodiment, the positive electrode or the negative electrode is provided with a fluid storage chamber in contact with the branch flow channel branched in the multi-channel located at the top and bottom, respectively, the multi-channel flow path connecting the upper and lower chambers located in the diagonal direction May be formed to constitute an electrolysis reaction.

In a preferred embodiment, the multi-channel flow path may be configured to increase the reaction efficiency by arranging a plurality of protrusions for disturbing the flow of the fluid on the path to generate turbulence at regular intervals.

In a preferred embodiment, the positive electrode or the negative electrode is provided with a chamber for storing the fluid in the upper and lower portions in contact with the branch flow channel branched in the upper and lower multi-channel, respectively, and formed between the upper and lower chambers in the diagonal direction as a porous structure flow path It can be configured to increase the reaction efficiency.

In a preferred embodiment, the electrode spacer of the insulating material may be composed of a non-metal material.

In a preferred embodiment, the branch flow path may be composed of a plurality.

In a preferred embodiment, it may be configured to further include a flow path providing intermediate coupling between the diaphragm and the negative electrode, and further comprises a diaphragm between the negative electrode and the intermediate combiner to configure a second diaphragm between the unit positive electrode and the negative electrode.

In a preferred embodiment, it may be configured to further include a flow path providing intermediate between the diaphragm and the negative electrode, and further comprises a diaphragm between the negative electrode and the intermediate combiner to configure three diaphragms between the unit positive electrode and the negative electrode.

In a preferred embodiment, the bipolar conjugate,

An electrode spacer made of an insulating material having multiple flow paths for inflow and outflow of a fluid including a gas formed on upper and lower sides thereof, and having electrode openings formed at both sides of the opening;

Each negative electrode which is respectively stored in the two electrode receiving portion and is energized through a conductor inserted into the opening, and bolts between the two side electrodes, each of the negative electrode flowing out to the other multi-channel after electrolysis of each fluid supplied from one multi-channel and Positive electrode; can be configured.

In a preferred embodiment, the flow path providing intermediate body is formed by overlapping two insulating spacers in which a plurality of flow paths for inflow and outflow of a fluid including gas are formed on upper and lower sides thereof,

One of the flow paths selected from among the multiple flow paths formed in the upper and lower portions are each branched flow path is formed so as to directly supply fluid by sharing between the inner surface of the overlapping insulating material spacer,

The outer surface of the insulating spacer is provided with a fluid storage chamber in contact with the branch flow path branched from the multiple flow paths located at the upper and lower portions, respectively, and a multi-channel flow path connecting the upper and lower chambers located in the diagonal direction. Can be.

In a preferred embodiment, the multi-channels formed on the upper and lower portions of the insulating material electrode spacer may be configured in four, respectively, so that the gas, the anode water, the electrolyte and the cathode water flow separately.

In a preferred embodiment, it may further comprise a GDE in surface contact with the negative electrode so that the mixture of the cathode water and the gas flowing through the negative electrode assembly.

The electrolysis device according to the present invention having the above characteristics integrates a positive electrode or a negative electrode with an insulating spacer to separate different fluids including gas through each of the plurality of channels while preventing a polarized conductor from being polarized. The advantage of having a flow path structure that can be supplied directly supplied to the positive or negative electrode required,

In addition, GDE (Gas Diffusion Electrode) in contact with the positive electrode or the negative electrode is configured to be in pressure contact so as to increase the reaction efficiency by contacting with sufficient pressure, and the reaction space of the positive electrode or the negative electrode through which the number of electrodes and the gaseous fluid pass is formed with multiple channels or protrusions. Reaction of adjacent electrodes (GDE) by increasing the pressure of the fluid, increasing the specific surface area of the anode and gas, and suppressing the drift by forming turbulent flows by forming a multi-channel or porous flow path The benefits of increased efficiency,

In addition, there is an advantage in that two or three or more diaphragms can be formed by having at least one flow path providing intermediate binder in a unit reaction cell including a positive electrode and a negative electrode or a bipolar electrode;

In addition, by injecting CO 2 gas into the cathode and bipolar cathode water flowing through the negative electrode assembly and the bipolar assembly, the mixed multiphase fluid reacts with the GDE electrode to change the pH and reduce the voltage,

In addition, by providing a structure including GDE in the negative electrode, a mixture of the cathode water and the gas flowing through the negative electrode can be used to increase the electrolysis reaction on the surface of the GDE is a useful invention that the industrial use is expected to be greatly expected .

1 is a cross-sectional view showing a coupling structure of each electrode assembly according to an embodiment of the present invention,
2 is a perspective view of an electrolysis device according to an embodiment of the present invention,
3 is an exemplary view showing an assembly configuration of an electrolytic apparatus according to an embodiment of the present invention,
Figure 4 is an exemplary view showing an assembly configuration of an electrolysis device including a bipolar structure according to another embodiment of the present invention,
5 is an exemplary view showing an assembly configuration of an electrolysis apparatus including a bipolar structure and an intermediate bond according to another embodiment of the present invention.
6 is a cross-sectional view illustrating a coupling structure having the configuration of FIG. 5,
7 is a perspective view of an electrode assembly according to an embodiment of the present invention,
8 is a perspective view of a bipolar binder according to an embodiment of the present invention,
9 is a perspective view of an intermediate assembly according to an embodiment of the present invention,
10 is an exemplary view showing a branch channel formed in a multi channel according to an embodiment of the present invention,
11 is an exemplary view showing a multi-channel flow path according to an embodiment of the present invention,
12 is an exemplary view showing a flow path of a porous structure according to an embodiment of the present invention,
13 to 16 is an exemplary view showing a fluid supply line according to an embodiment of the present invention.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a cross-sectional view showing a coupling structure of each electrode assembly according to an embodiment of the present invention, Figure 2 is a perspective view of an electrolysis device according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention 4 is an exemplary view showing an assembly configuration of an electrolysis device according to an embodiment, FIG. 4 is an exemplary view showing an assembly configuration of an electrolysis device including a bipolar structure according to another embodiment of the present invention, and FIG. 5 is another embodiment of the present invention. 6 is an exemplary view showing an assembly configuration of an electrolysis device including a bipolar structure and an intermediate bond, FIG. 6 is a cross-sectional view illustrating a coupling structure having the configuration of FIG. 5, and FIG. 7 is in accordance with an embodiment of the present invention. 8 is a perspective view of an electrode assembly, FIG. 8 is a perspective view of a bipolar assembly according to an embodiment of the present invention, FIG. 9 is a perspective view of an intermediate assembly according to an embodiment of the present invention, and FIG. 10 is an embodiment of the present invention.FIG. 11 is a view illustrating a branch channel formed in another multi-channel flow path, FIG. 11 is a view illustrating a multi-channel flow path according to an embodiment of the present invention, and FIG. 12 is a view showing a flow path of a porous structure according to an embodiment of the present invention. It is an illustration.

As shown, the basic configuration of the present invention is a positive electrode and the electrode spacer of an insulating material that is an anode to generate hydrogen (H ₂ ) H ⁺ and e ^- by receiving an anode water and electrolyzed to integrally combine The positive electrode assembly 1 is provided.

In addition, a negative electrode assembly 2 having a negative electrode, which is a cathode, which generates water (H ₂ ) and OH ⁻ ions by receiving cathode water and generates water (H ₂ ) and OH ⁻ ions and an electrode spacer of an insulating material, is integrally provided.

In addition, GDE (Gas Diffusion Electrode, 3), which improves the overall electrolysis efficiency and lowers the voltage by lowering the overvoltage generated from the positive electrode by the supplied gas ((H ₂ ) while pressurizing and contacting the positive electrode, is applied. Is provided.

In addition, there is provided an ion transport membrane (membrane) 4 composed of a cationic membrane or an ion membrane depending on the number of the diaphragm to be located between the positive electrode or the negative electrode to transfer the selected ions.

The electrolysis apparatus configured as described above is assembled in the order of the positive electrode assembly, the GDE, the diaphragm, and the negative electrode assembly. The GDE is assembled directly to the anode, so that when current is supplied, the current is delivered to the GDE, and the diaphragm is assembled to be in contact with the GDE.

Although the structure of the specific anode water, cathode water, and electrolyte solution has not been described above, the cathode water, cathode water, and electrolyte components required do not specify the present invention, and the electrochemical process of supplying the required components to perform electrolysis reaction. Is a well-known technique, so a detailed description thereof will be omitted.

As described above, the positive electrode or negative electrode of the positive electrode assembly, the negative electrode assembly, and the bipolar assembly is integrally formed by fastening the positive electrode or the negative electrode with an insulating material spacer so that when the power is supplied to the metal and the electrolyte is sufficient, the conductor placed between the positive electrode and the negative electrode becomes unnecessarily polarized. It becomes an electrode to prevent it from participating in the reaction.

In addition, when the fluid to flow to the individual binder flows through the electrode of the other binder, unnecessary reaction due to the bypass current (BI-PASS) does not occur.

As described above, the electrolytic apparatus of the present invention comprises a positive electrode assembly, a negative electrode assembly, and a bipolar assembly composed of a metal electrode and a non-metal insulating spacer so that all fluids can be moved through the insulating material spacer to transfer only a current necessary for the reaction. Characterized in having a structure to.

In addition, the electrolytic apparatus configured as described above is provided with an electrode spacer made of a negative electrode and a positive electrode insulating material, and a bipolar assembly 5 through which positive and negative electrodes are coupled and energized on both sides thereof.

In addition, the electrolysis device configured as described above is another embodiment of the flow passage providing intermediate body in which two thin spacers for supplying a fluid to form a diaphragm into multiple diaphragms constitute a single fluid supply flow path at an upper side and a lower side thereof. ) Is configured.

In another embodiment, the electrolysis device configured as described above is configured such that GDE (Gas Diffusion Electrode) 3 is in contact with the negative electrode of the negative electrode assembly as well as the positive electrode to be in pressure contact with the mixture of cathode water and gas flowing through the negative electrode assembly. It is equipped to allow the reaction to occur on the GDE surface.

The present invention is integrally coupled with the positive electrode or the negative electrode using a spacer of an insulating material in order to prevent the power is applied to the conductor is polarized.

In addition, the upper and lower portions of the spacer are provided with a plurality of multiple flow paths, respectively, so that each of the hydrogen, the anode water, the cathode water, and the electrolyte are separated and supplied from the positive electrode or the negative electrode to perform an electrolysis reaction, and then through the spacer of insulating material It is configured to flow through a multi-channel connected directly.

Specifically, each structure is demonstrated.

The positive electrode assembly 1 includes an electrode spacer 11 made of an insulating material, in which multiple flow paths 111 for inflow and outflow of a fluid including gas are formed on upper and lower sides thereof, and an electrode accommodating part 112 is formed on one side thereof;

It is composed of a positive electrode 12 which is accommodated in the electrode receiving unit is integrally fastened by the bolt 13 and the fluid supplied from one side of the multi-channel flows out to the other side of the multi-channel after electrolysis.

The fluid of the positive electrode assembly configured as described above flows into the left positive water inflow channel of the lower multi-channel and exits to the right positive water discharge channel of the upper multi-channel.

The negative electrode assembly 2 has an electrode spacer 21 made of an insulating material having multiple flow passages 211 for inflow and outflow of a fluid including gas formed on upper and lower sides thereof, and an electrode accommodating portion 212 formed on one side facing the positive electrode. Wow;

It is composed of a negative electrode 22 is accommodated in the electrode receiving unit is integrally fastened by the bolt 23 and the fluid supplied from one side of the multi-channel flows to the other side of the multi-channel after electrolysis.

The fluid of the negative electrode assembly configured as described above flows into the right negative water inflow channel of the lower multi-channel and exits to the left negative water outflow channel of the upper multi-channel.

Insulating electrode spacers constituting the positive electrode assembly and the negative electrode assembly, branch passages 111a and 211a are respectively formed to supply a fluid directly to the positive electrode or the negative electrode of only one of the multiple channels formed at the top and the bottom thereof. At this time, the branch channel may be composed of a plurality. Although the figure consists of three, such numbers do not limit the number of branch flow paths.

In addition, the multi-channels formed on the upper and lower portions of the insulating material electrode spacer are each composed of four, so that the gas, the anode water, the electrolyte and the cathode water flow separately.

In addition, the positive electrode 12 or the negative electrode 22 is provided with fluid storage chambers 121 and 221 contacting the branch flow paths branched from the multiple flow paths located at the upper and lower portions, respectively, and the upper and lower chambers positioned diagonally. The multi-channel flow paths 122 and 222 connecting the livers may be formed to configure an electrolysis reaction. In the figure, although illustrated as one channel for convenience of illustration, it is actually composed of multiple channels such as two or three channels. For example, it has the same shape as the multi-channel constituting the intermediate body for providing a flow path to be described later.

In addition, the multi-channel flow path may be configured to increase the reaction efficiency by arranging a plurality of protrusions 123 and 223 for generating turbulence by disturbing the flow of fluid on the path.

In addition, the positive electrode or the negative electrode is provided with a chamber for storing each fluid in the upper and lower portions in contact with the branch flow channel branched in each of the upper and lower multi-channel flow path, the upper and lower chambers formed in the diagonal direction formed by the porous structure flow path (124, 224) It can be configured to increase the reaction efficiency.

It is sufficient that the electrode spacer made of the insulating material is made of a nonmetallic material.

In the configuration of the present invention configured as described above to properly control the flow of pressure and fluid during electrolysis through the gas to increase the reaction efficiency.

That is, since the electrolysis device of the present invention includes a gas flow, the turbulent flow formation and the pressure of the gas flow channel act as important variables. The shape change of the gas flow path induces the complex flow of the fluid (turbulence formation) and the increase in pressure. It was.

In addition, by repeatedly forming a projection in the channel of the three-channel includes a structure that prevents the smooth flow of the fluid. As a result, the gas flowing into the electrode of the positive electrode assembly flows through the three-channel flow path of the electrode, and when the fluid flows into the attached projection of each flow path, the fluid changes its behavior by the projection, and flows around the projection and the fluid flowing over the projection. The pressure is increased by being divided into a fluid, and a large amount of gas is delivered to the adjacent GDE through turbulence formation.

In addition, through the porous structure flow path, the specific surface area of the anode and the gas is increased, more turbulence is formed than the fluid flow of the channel structure, and the drift is suppressed to increase the reaction effect of the adjacent electrode GDE.

The electrolytic apparatus assembled in the order of the positive electrode assembly, GDE, diaphragm, negative electrode assembly is a fluid inlet for inflow and outflow of different fluids to a plurality of nozzles in contact with the outside of the positive electrode assembly in order to press the entire surface contact A front cover 7 having a fluid outlet formed at upper and lower portions thereof; And a rear cover 8 in contact with the outside of the negative electrode assembly.

Between the front cover and the rear cover is assembled by fastening directly with a bolt (71). By having such a fastening structure, the positive electrode assembly, GDE, the diaphragm, and the negative electrode assembly, which are overlapped inside, are pressurized and assembled. Therefore, the positive electrode assembly, the GDE, the diaphragm, and the negative electrode assembly do not need to be coupled by direct bolting.

Multiple flow paths are formed at the top and bottom of the front cover 7. In the following description, the order of the fluid flowing through and flowing through the multiple flow paths is the fluid inlet 72 and the fluid outlet 73 formed in the front cover according to an embodiment. ) The description will be based on the state of the nozzle installation. The order of inflow and outflow of the fluid may be configured by changing the order before and after according to another embodiment.

The flow order of the fluid flows through the gas inlet flows through the gas inlet from the left side, the anode inflow flows through the anode water inlet, the electrolyte inflow flows through the electrolyte inlet, and the cathode water inlet. It consists of a cathode water inflow channel, the upper multi-path flows from the left side through the cathode water outlet, the cathode water outflow channel, the electrolyte outflow channel flowing through the electrolyte outlet, the anode water outlet flows out through the anode water outlet, the gas outlet The gas flows out through the flow path is configured in order.

The bipolar assembly 5 may include a bipolar assembly between the negative electrode assembly and the diaphragm, and may further include a GDE and a diaphragm contacting the positive electrode on one side of the bipolar assembly.

The bipolar assembly includes: an electrode spacer 51 made of an insulating material, in which multiple flow paths 511 for inflow and outflow of a fluid including gas are formed on upper and lower sides thereof, and electrode receiving portions 512 are formed on both sides of which openings are formed;

Each of the two electrode accommodating parts are respectively energized through the conductors 54 inserted into the openings, and bolts are connected between the two side electrodes, and each fluid supplied from one side of the multiple flow paths is discharged to the other side of the multiple flow paths after electrolysis. Each positive electrode 52 and a negative electrode 53 are formed.

As described above, the bipolar assembly has a structure in which the positive electrodes and the negative electrodes are directly connected to each other by the bolts 55 between the received positive and negative electrodes, rather than directly connecting the spacers of the insulating material and the positive or negative electrodes.

Although some positive current is formed between the positive electrode and the negative electrode through the bolts, the positive electrode and the negative electrode are formed. However, the main electric current is caused by conducting surface contact between the positive and negative electrodes on both sides by inserting a metal conductor into the opening of the center portion of the spacer.

In addition, in the insulating electrode spacer constituting the bipolar assembly, a branch channel 511a is formed to supply a fluid directly to the positive electrode or the negative electrode of only one of the multiple channels formed at the upper and lower portions thereof. At this time, the branch channel may be composed of a plurality. Although the figure consists of three, such numbers do not limit the number of branch flow paths.

In addition, the multi-channels formed on the upper and lower portions of the insulating material electrode spacer are each composed of four, so that the gas, the anode water, the electrolyte and the cathode water flow separately.

In addition, the positive electrode 52 or the negative electrode 53 is provided with upper and lower fluid storage chambers 521 and 531 contacting the branch channel 511a branched from the multiple channels located at the top and the bottom, respectively. Multi-channel flow paths 522 and 532 connecting between the upper and lower chambers are formed to be configured to the electrolysis reaction. In the figure, although illustrated as one channel for convenience of illustration, it is actually composed of multiple channels such as two or three channels. For example, it has the same shape as the multi-channel constituting the intermediate body for providing a flow path to be described later.

In addition, the multi-channel flow path may be configured to increase the reaction efficiency by arranging a plurality of protrusions 533 which disturb the flow of the fluid on the path to generate turbulence at regular intervals.

In addition, the positive electrode or the negative electrode is provided with a chamber for storing the fluid in the upper and lower portions in contact with the branch flow channel branched in the upper and lower multi-channel, respectively, and formed in the porous structure flow path (524, 534) between the upper and lower chambers located diagonally It can be configured to increase the reaction efficiency.

It is sufficient that the electrode spacer made of the insulating material is made of a nonmetallic material.

The flow path providing intermediate assembly 6 is formed by overlapping two insulating spacers 61 in which multiple flow paths 611 for inflow and outflow of a fluid including gas are formed at upper and lower portions thereof.

At this time, any one flow path selected from the multiple flow paths 611 formed at the upper and lower portions of the branch flow paths 611a are formed to directly share the overlap between the inner surfaces of the insulating spacers.

The outer surface of the insulating spacer is provided with a fluid storage chamber 612 in contact with the branch flow path branched from the multiple flow paths located at the top and bottom, respectively, and the multi-channel flow path connecting the upper and lower chambers located in the diagonal direction 613 is formed.

In addition, the multi-channels formed on the upper and lower portions of the insulating material electrode spacer may be configured as four, respectively, so that the gas, the anode water, the electrolyte solution and the cathode water flow separately.

When further comprising a flow path providing intermediate coupling between the diaphragm and the negative electrode, it may further comprise a diaphragm between the negative electrode and the intermediate bonded to form a second diaphragm between the unit positive electrode and the negative electrode.

With this configuration, it has three flow paths, and two diaphragm configurations are possible, and the fluid flowing into the intermediate body flows into the middle portion of the lower multi-path and exits through the middle of the upper multi-channel through the multi-channel flow path. .

Assembly of the electrolysis device in this configuration consists of a positive electrode assembly, a GDE, a diaphragm, an intermediate binder, a diaphragm, a negative electrode binder. At this time, the diaphragm may be a cationic membrane and an anionic membrane.

 In addition, a diaphragm may be further included between the negative electrode and the intermediate assembly to form three diaphragms between the unit positive electrode and the negative electrode.

By such a configuration, three diaphragm configurations are possible, and four flow paths can be configured.

In one embodiment, the fluid flowing into the intermediate flow passage for the first time flows into the lower right side of the multiple flow path and exits to the left side of the upper multiple flow path. It can be configured to exit to the right of the multi-channel.

13 to 16 is an exemplary view showing a fluid supply line according to an embodiment of the present invention, a configuration according to an embodiment including a bipolar structure and two flow path providing intermediate coupling.

As shown in the drawing, each fluid flows through the lower multi-channel of the insulating spacer and flows out to the upper multi-channel. The inflow and outflow positions of the fluids described below are as shown in the description of the front cover. The lower multi-channel flows from the left into the gas inflow channel flowing through the gas inlet, the anode water inflow channel flowing through the anode water inlet, the electrolyte inflow channel flowing through the electrolyte inlet, and the cathode water inflow channel flowing through the cathode water inlet The upper multi-channel flows through the cathode water outlet through the cathode water outlet from the left side, the electrolyte outlet flow path flowing through the electrolyte outlet, the anode water outlet flows through the anode water outlet, the gas flowing through the gas outlet Inflows and outflows are based on the flow-out order.

FIG. 13 shows a flow path in which gas is directly supplied to the GDE through the multiple flow paths in contact with the multiple flow paths of the front cover and flows out after the reaction, and FIG. 14 shows the flow of cathode water through the multiple flow paths in contact with the multiple flow paths of the front cover. The flow path flows directly after supplying to the negative electrode and flows out after the reaction. FIG. 15 shows a flow path in which the anode water is supplied directly to the right side of the union for supplying the intermediate flow path between the diaphragm and the diaphragm through the multiple flow paths in contact with the flow paths. 16 shows a flow path in which the electrolyte is directly supplied to the left side of the intermediate flow path providing intermediate flow path between the diaphragm and the diaphragm through the multi-path contacted through the multi-path of the front cover.

When directly supplied through the multi-flow and branch flow path to the required point through the fluid flow as described above, the electrolysis device according to the present invention is to increase the pressure, the high efficiency of the electrolysis reaction in a low voltage state .

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

(1): positive electrode assembly (2): negative electrode assembly
(3): GDE (4): diaphragm
(5): Bipolar binder (6): Intermediate binder for flow path
(7): Front cover (8): Rear cover
(11): electrode spacer 12: positive electrode
(13): bolt 21: electrode spacer
(22): negative electrode 23: volts
(51): electrode spacer (52): positive electrode
53: negative electrode 54: conductor
55: bolt 61: spacer
(71): bolt 72: fluid inlet
(73): fluid outlet 111: multi-channel
111a: branch flow path 112: electrode housing portion
(121): chamber 122: multi-channel flow path
(123): protrusion (124,): porous structure flow path
(211): multiple flow path (211a): branch flow path
212: electrode housing 221: chamber
222: multi-channel flow path 223: projection
(224): porous structure flow path (511): multiple flow path
511a: branch flow path 512: electrode housing
521: Chamber 522: Multichannel Flow Path
523: protrusion 524: porous structure flow path
531: Chamber 532: Multichannel Flow
533: protrusion 534: porous structure flow path
611: multiple euros (611a): branch euros
612: Chamber 613: Multichannel Flow

Claims (16)

Multiple flow paths for the inflow and outflow of fluids including gas are formed in the upper and lower parts and an electrode spacer of an insulating material having an electrode accommodating portion formed on one side thereof, and the electrode accommodating portion is fastened integrally with a bolt and supplied from one side of the multiple channel. A positive electrode assembly composed of a positive electrode flowing out of the fluid to the other multi-channel after electrolysis;
Multiple flow paths for the inflow and outflow of fluids including gas are formed on the upper and lower sides, and an electrode spacer of an insulating material having an electrode accommodating part formed on one side facing the positive electrode, and housed in the electrode accommodating part and fastened integrally with bolts. A negative electrode assembly composed of a negative electrode which discharges the fluid supplied from the flow path to the other multi-channel after electrolysis;
GDE (Gas Diffusion Electrode) in surface contact with the positive electrode;
Electrolysis device comprising a multi-channel structure, characterized in that configured; including; ion separation membrane is installed between the GDE and the negative electrode assembly.
The method according to claim 1,
And a front cover having a fluid inlet and a fluid outlet contacting the outer side of the positive electrode assembly at upper and lower sides, and a rear cover contacting the outer side of the negative electrode assembly, and bolting between the front cover and the rear cover. In one state, all the fluid is supplied to the lower multi-channel through the lower inlet nozzle of the front cover and the reaction fluid is electrolysis device comprising a multi-channel structure, characterized in that configured to flow out to the upper outlet nozzle through the upper multi-channel.
The method according to claim 1,
The positive electrode and the negative electrode are coupled to the insulating material electrode spacer in which multiple flow paths are formed between the negative electrode assembly and the diaphragm. Electrolysis device comprising a multi-channel structure, characterized in that configured to include.
The method according to claim 1 or 3,
Electrolysis apparatus comprising a multi-channel structure, characterized in that the multi-channel formed on the upper and lower portions of the insulating material electrode spacer is composed of four, so that the gas, the anode water, the electrolyte and the cathode water flows separately.
The method according to claim 1 or 3,
The insulating material electrode spacer includes a multi-channel structure, characterized in that the branched channel is formed to supply the fluid directly to the positive electrode or the negative electrode of any one of the multi-channel formed in the upper and lower, respectively.
The method according to claim 5,
The positive electrode or the negative electrode is provided with a fluid storage chamber in contact with the branch flow channel branched from the multi-channel located in the upper and lower, respectively, the upper and lower, and the multi-channel flow path connecting the upper and lower chambers located in the diagonal direction is formed electrolysis Electrolysis device comprising a multi-channel structure, characterized in that the reaction is configured to occur.
The method according to claim 6,
The multi-channel flow path electrolysis device comprising a multi-channel structure, characterized in that a plurality of protrusions for disturbing the flow of fluid on the path to generate turbulence arranged at regular intervals to increase the reaction efficiency.
The method according to claim 5,
The positive electrode or the negative electrode is provided with a chamber for storing the fluid in the upper and lower contact with the branch flow channel branched in the upper and lower multi-channel respectively, and the upper and lower chambers located in the diagonal direction to form a porous structure flow path to increase the reaction efficiency Electrolysis device comprising a multi-channel structure, characterized in that configured.
The method according to claim 1,
Electrode device comprising a multi-channel structure, characterized in that the electrode spacer of the insulating material is composed of a non-metal material.
The method according to claim 5,
The branch channel has an electrolysis device comprising a multi-channel structure, characterized in that composed of a plurality.
The method according to claim 1 or 3,
An electric wire comprising a multi-channel structure, characterized in that it further comprises an intermediary for providing a flow path between the diaphragm and the negative electrode, and further comprising a diaphragm between the negative electrode and the intermediate assembly to form a second diaphragm between the unit positive electrode and the negative electrode. Decomposition device.
The method according to claim 11,
An electric wire comprising a multi-channel structure, characterized in that it further comprises a flow path providing intermediate coupling between the diaphragm and the negative electrode, and further comprising a diaphragm between the negative electrode and the intermediate assembly to form three diaphragms between the unit positive electrode and the negative electrode. Decomposition device.
The method according to claim 3,
The bipolar conjugate,
An electrode spacer made of an insulating material having multiple flow paths for inflow and outflow of a fluid including a gas formed on upper and lower sides thereof, and having electrode openings formed at both sides of the opening;
Each negative electrode which is respectively stored in the two electrode receiving portion and is energized through a conductor inserted into the opening, and bolts between the two side electrodes, each of the negative electrode flowing out to the other multi-channel after electrolysis of each fluid supplied from one multi-channel and Electrolysis device comprising a multi-channel structure, characterized in that consisting of a positive electrode.
The method according to claim 11,
The flow path providing intermediate assembly is formed by overlapping two insulating spacers in which multiple flow paths for inflow and outflow of a fluid including gas are separated on upper and lower sides thereof,
One of the flow paths selected from among the multiple flow paths formed in the upper and lower portions are each branched flow path is formed so as to directly supply fluid by sharing between the inner surface of the overlapping insulating material spacer,
The outer surface of the insulating spacer is provided with a fluid storage chamber in contact with the branch flow channel branched from the multiple flow paths located in the upper and lower, respectively, and the multi-channel flow path is connected between the upper and lower chambers located in the diagonal direction Electrolysis device comprising a multi-channel structure characterized in.
The method according to claim 14,
Electrolysis apparatus comprising a multi-channel structure, characterized in that the multi-channel formed on the upper and lower portions of the insulating material electrode spacer is composed of four, so that the gas, the anode water, the electrolyte and the cathode water flows separately.
The method according to claim 1 or 3,
Electrolysis device comprising a multi-channel structure characterized in that it further comprises a GDE in surface contact with the negative electrode so that the mixture of the cathode water and the gas flowing through the negative electrode assembly.

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