JP7640281B2 - Electrochemical Devices - Google Patents

Description

The present invention relates to an electrochemical element.

The development of a technology for separating and recovering a specific gas from a gas mixture is being continuously advanced. In particular, in recent years, it has become necessary to suppress carbon dioxide (CO ₂ ) emissions in order to reduce global warming, and efforts have been made to separate and recover carbon dioxide from a gas mixture. As a representative example of such efforts, the Carbon Dioxide Capture, Utilization and Storage (CCUS) cycle is known. Here, for example, chemical adsorption, physical adsorption, cryogenic separation, membrane separation, and electrochemical recovery methods are known for recovering carbon dioxide. However, at present, all of these technologies have insufficient carbon dioxide recovery capabilities, require a very large amount of energy for recovery, and require large-scale facilities for recovery, and various issues remain to be considered for practical application.

Special table 2018-533470 publication

The main objective of the present invention is to provide an electrochemical element that can efficiently separate and recover a specified gas using energy-saving and small-scale equipment.

An electrochemical element according to an embodiment of the present invention includes an outer peripheral wall and a partition wall disposed inside the outer peripheral wall and defining a plurality of cells extending from a first end face to a second end face. The plurality of cells includes a first cell and a second cell, a functional electrode including a first active material is formed on a surface of the partition wall defining the first cell, and a counter electrode including a second active material is disposed inside the second cell. The total area of the first cell is more than 50% of the total area of the plurality of cells in a cross section perpendicular to the direction in which the plurality of cells extend.
In one embodiment, the first cells and the second cells are arranged alternately, and the cross-sectional area of the first cells in a cross section perpendicular to the direction in which the cells extend is larger than the cross-sectional area of the second cells.
In one embodiment, the plurality of cells are arranged in a lattice pattern with the cells each having a rectangular cross section, and the second cells are arranged so as not to be adjacent to each other. In this case, the first cells may be arranged so as to be adjacent to each other.
In one embodiment, the plurality of cells are arranged in a honeycomb shape with the cells having a hexagonal cross section, and the second cells are arranged so as not to be adjacent to each other. In this case, the first cells may be arranged so as to be adjacent to each other.
In one embodiment, the cell in which the functional electrode is formed includes a gas flow path. In one embodiment, the functional electrode is formed on the partition wall so as to surround the gas flow path.
In one embodiment, the cell in which the counter electrode is located is filled with the counter electrode.
In one embodiment, the counter electrode comprises a conductive substrate and the second active material dispersed in the substrate. In one embodiment, the substrate comprises a carbonaceous material. In one embodiment, the counter electrode further comprises an ionic liquid.
In one embodiment, the partition wall is impregnated with an ionic liquid, and the ionic liquid is the same as the ionic liquid contained in the counter electrode.
In one embodiment, the first active material comprises anthraquinone and the second active material comprises polyvinylferrocene.

According to an embodiment of the present invention, it is possible to realize an electrochemical element that can efficiently separate and recover a specified gas using energy-saving and small-scale equipment.

1 is a schematic perspective view of an electrochemical device according to one embodiment of the present invention. 2 is a schematic cross-sectional view of the electrochemical device of FIG. 1 in a direction parallel to the extension direction of the cell. 3 is an enlarged schematic cross-sectional view of a main part of the electrochemical element of FIG. 1 and FIG. 2 in a direction perpendicular to the extending direction of the cells. 4 is an enlarged schematic cross-sectional view of a main portion of an electrochemical element according to another embodiment of the present invention, taken in a direction perpendicular to the extending direction of the cells. FIG. 10 is an enlarged schematic cross-sectional view of a main portion of an electrochemical device according to still another embodiment of the present invention, taken in a direction perpendicular to the extending direction of the cells. FIG. 10 is an enlarged schematic cross-sectional view of a main portion of an electrochemical element according to still another embodiment of the present invention, taken in a direction perpendicular to the extending direction of the cells. FIG. 10 is an enlarged schematic cross-sectional view of a main portion of an electrochemical device according to still another embodiment of the present invention, taken in a direction perpendicular to the extending direction of the cells. FIG.

The following describes embodiments of the present invention with reference to the drawings, but the present invention is not limited to these embodiments.

A. Overall Configuration of Electrochemical Device An electrochemical device according to an embodiment of the present invention separates and recovers a specific gas (eg, carbon dioxide) from a gas mixture using an electrochemical process.

1 is a schematic perspective view of an electrochemical element according to one embodiment of the present invention; FIG. 2 is a schematic cross-sectional view in a direction parallel to the direction in which the cells of the electrochemical element of FIG. 1 extend; and FIG. 3 is an enlarged schematic cross-sectional view of a main part of the electrochemical element of FIG. 1 and FIG. 2 in a direction perpendicular to the direction in which the cells extend. The electrochemical element 100 of the illustrated example has an outer peripheral wall 10; and a partition wall 40 that is disposed inside the outer peripheral wall 10 and defines a plurality of cells 30, 30, ... extending from the first end face 20a to the second end face 20b. The plurality of cells 30, 30, ... include a first cell 30a and a second cell 30b. A functional electrode 50 containing a first active material is formed on the surface of the partition wall 40 that defines the first cell 30a. A counter electrode 60 is disposed inside the second cell 30b. In the embodiment of the present invention, when the total area of the cross-sectional areas of the cells in a cross section perpendicular to the direction in which the cells 30, 30, ... extend is taken as 100%, the total cross-sectional area of the first cells 30a exceeds 50% of the total area. With such a configuration, the contact area between the gas mixture at a predetermined flow rate (substantially the gas to be separated and recovered) and the functional electrode can be made very large. As a result, the predetermined gas (e.g., carbon dioxide) can be separated and recovered with extremely high efficiency. Furthermore, it becomes possible to efficiently separate and recover the predetermined gas (e.g., carbon dioxide) with a small-scale facility, and the energy required for separating and recovering the gas can be significantly reduced. In this specification, the "total area of the cross-sectional areas of the cells in a cross section perpendicular to the direction in which the cells extend" means the total area of the cross-sectional areas of the cells in the portion where the cells are defined only by the partition wall 40. In other words, it does not include the cross-sectional area of the cells in the peripheral portion where the cells are defined by the partition wall 40 and the outer peripheral wall 10. For example, if the electrochemical element is cylindrical (having a circular cross section), the total area is the total area of the largest rectangle inscribed in the circle of the cross section. Also, for example, if the electrochemical element has different cross-sectional areas on the gas inlet side and outlet side (for example, if the electrochemical element is shaped like a truncated cone), the total area is the average of the total areas of at least three locations: the inlet, the center, and the outlet. Hereinafter, the total cross-sectional area of the first cells 30a will be referred to as the "functional electrode cell cross-sectional area," and the total cross-sectional area of the cells in a cross section perpendicular to the direction in which the cells extend will be referred to as the "total cell area."

In the electrochemical element for gas separation shown in Figures 1 to 3, the first cell and the second cell are arranged alternately. The cross-sectional area of the first cell 30a in a cross section perpendicular to the direction in which the cells extend is larger than the cross-sectional area of the second cell 30b. With this configuration, the functional electrode cell cross-sectional area can be made to exceed 50% of the total cell area. For example, by appropriately setting the cross-sectional area (effectively, the cross-sectional shape) of the first cell 30a and the cross-sectional area (effectively, the cross-sectional shape) of the second cell 30b, the ratio of the functional electrode cell cross-sectional area to the total cell area can be adjusted to a desired range. For example, by setting the cross-sectional area of the first cell 30a to 150% to 500% of the cross-sectional area of the second cell 30b, the ratio of the functional electrode cell cross-sectional area to the total cell area can be made to 60% to 83%. In the illustrated example, the first cells 30a having an octagonal cross-sectional shape and the second cells 30b having a rectangular cross-sectional shape are alternately arranged except for the portion in contact with the outer peripheral wall 10. In this configuration, if the cross-sectional shape of the first cell is a regular octagon and the cross-sectional shape of the second cell is a square having the same side length as the first cell, the cross-sectional area of the first cell is about 480% of the cross-sectional area of the second cell, and the ratio of the functional electrode cell cross-sectional area to the total cell area is about 83%. By increasing this ratio, the gas flow rate in contact with the functional electrode can be increased. As a result, a very excellent gas separation and recovery efficiency can be realized. The ratio of the functional electrode cell cross-sectional area to the total cell area can be appropriately set according to the desired gas separation and recovery efficiency, the allowable range of the equipment scale, the allowable range of the energy required for gas separation and recovery, etc., as long as the number (ratio) of second cells that allows the counter electrode to function is secured. The upper limit of the ratio of the functional electrode cell cross-sectional area to the total cell area can be, for example, 85%.

A gas flow path 70 is formed in the center of the first cell 30a in a cross section perpendicular to the cell extension direction (i.e., the portion where the functional electrode 50 is not formed). The functional electrode 50 may be formed on the entire surface of the partition wall 40 (i.e., so as to surround the gas flow path 70) as in the illustrated example, or may be formed on a part of the surface of the partition wall. In consideration of the gas separation and recovery efficiency, it is preferable that the functional electrode 50 is formed on the entire surface of the partition wall 40. As described above, a counter electrode 60 is disposed inside the second cell 30b. The counter electrode 60 contains a second active material. The second cell 30b is typically filled with the counter electrode 60.

A modified example of the cell configuration in the electrochemical element for gas separation will be described with reference to Figs. 4 to 7. In the example shown in Fig. 4, cells 30, 30, ..., each having a quadrangular (e.g., square) cross-sectional shape except for the portion in contact with the outer peripheral wall 10, are arranged in a lattice pattern. The second cells 30b are arranged so as not to be adjacent to each other. In this case, the first cells 30a may be arranged so as to be adjacent to each other. In this specification, "not adjacent to each other" means that the two cells do not share the sides or vertices of the partition walls that define each cell. In the example shown in Fig. 4, the ratio of the functional electrode cell cross-sectional area to the total cell area is 75%. As a result, even better gas separation and recovery efficiency can be achieved. For example, compared to the case where the cells 30a and 30b are arranged alternately (i.e., in a checkerboard pattern), the ratio of the functional electrode cell cross-sectional area to the total cell area is 1.5 times, and the gas separation and recovery efficiency can also be 1.5 times. As in the case of the examples shown in Figures 1 to 3, the arrangement pattern of the cells 30a and 30b can be appropriately set according to the desired gas separation and recovery efficiency, the allowable range of the scale of the equipment, the allowable range of the energy required for gas separation and recovery, etc., as long as the number (proportion) of second cells that allows the counter electrode to function is secured. In this case, the first cell 30a can typically share the partition wall 40 with at least one second cell 30b. For example, the second cell 30b may be arranged as shown in Figure 6.

In the example shown in FIG. 5, cells 30, 30, ..., each having a hexagonal (e.g., regular hexagonal) cross-sectional shape, except for the portion in contact with the outer peripheral wall 10, are arranged in a honeycomb shape. The second cells 30b are arranged so as not to be adjacent to each other. In this case, the first cells 30a may be arranged adjacent to each other. In the example shown in FIG. 5, the ratio of the functional electrode cell cross-sectional area to the total cell area is about 86%. As a result, even better gas separation and recovery efficiency can be achieved. As in the case of the examples shown in FIGS. 1 to 4, the arrangement pattern of the cells 30a and 30b can be appropriately set according to the desired gas separation and recovery efficiency, the allowable range of the equipment scale, the allowable range of the energy required for gas separation and recovery, etc., as long as the number (ratio) of second cells that allows the counter electrode to function is secured. In this case, the first cell 30a may typically share a partition wall 40 with at least one second cell 30b. For example, the second cells 30b may be arranged as shown in FIG. 7.

The shape of the electrochemical element can be appropriately designed depending on the purpose. The electrochemical element 100 in the illustrated example is cylindrical (the cross-sectional shape in the direction perpendicular to the extension direction of the cell is circular), but the electrochemical element may be a columnar shape with a cross-sectional shape of, for example, an ellipse or polygon (for example, a square, pentagon, hexagon, octagon). The length of the electrochemical element can be appropriately set depending on the purpose. The length of the electrochemical element can be, for example, 5 mm to 500 mm. The diameter of the electrochemical element can be appropriately set depending on the purpose. The diameter of the electrochemical element can be, for example, 20 mm to 500 mm. In addition, when the cross-sectional shape of the electrochemical element is not circular, the diameter of the maximum inscribed circle inscribed in the cross-sectional shape of the electrochemical element (for example, a polygon) can be set as the diameter of the electrochemical element. The aspect ratio (diameter:length) of the electrochemical element is, for example, 1:12 or less, or, for example, 1:5 or less, or, for example, 1:1 or less. If the aspect ratio is within this range, the current collection resistance can be kept within an appropriate range.

The operation of the electrochemical element is generally described below. For example, the gas to be separated and recovered is carbon dioxide, the first active material of the functional electrode 50 contains anthraquinone, and the second active material of the counter electrode 60 contains polyvinylferrocene. The anthraquinone of the functional electrode can be reduced in the charging mode (the functional electrode is the negative electrode).

When a gas mixture containing carbon dioxide is passed through the gas flow path 70 of the electrochemical element, the following reaction (1) occurs between the anthraquinone in a reduced state of the functional electrode 50 and the carbon dioxide, and the carbon dioxide is captured by the anthraquinone. In this way, the carbon dioxide can be recovered.

At this time, the polyvinylferrocene of the counter electrode 60 can be oxidized. That is, the polyvinylferrocene can function as an electron source for the reduction of anthraquinone in the charging mode.

In addition, the anthraquinone in the functional electrode 50 can be oxidized in the discharge mode (when the functional electrode is the positive electrode).

When the anthraquinone that has captured carbon dioxide is oxidized in the functional electrode 50, the following reaction (2) occurs, and the carbon dioxide captured by the anthraquinone is released from the bond with the anthraquinone. In this way, the carbon dioxide can be released from the functional electrode 50 to the gas flow path 70.

At this time, the polyvinylferrocene of the counter electrode 60 can be reduced. That is, the polyvinylferrocene can function as an electron acceptor during the oxidation of anthraquinone in the discharge mode.

As described above, by switching the polarity of the functional electrode (and necessarily the counter electrode), the electrochemical element (effectively the functional electrode) can capture (capture, adsorb) and release carbon dioxide. In particular, by utilizing anthraquinone in a reduced state in the charging mode, carbon dioxide can be separated and captured (captured) from a gas mixture. For example, exhaust gas from factories and thermal power plants contains about 10% carbon dioxide, and by passing a gas mixture with the same composition as such exhaust gas through an electrochemical element according to an embodiment of the present invention, the carbon dioxide concentration can be reduced to 0.1% or less.

The components of the electrochemical element are explained in detail below.

B. Outer Wall and Partition Wall The outer wall 10 and the partition wall 40 are typically made of a porous body containing insulating ceramics. The insulating ceramic typically contains silicon carbide and silicon (hereinafter, sometimes referred to as silicon carbide-silicon composite). The ceramic contains silicon carbide and silicon in a total amount of, for example, 90% by mass or more, for example, 95% by mass or more. With such a configuration, the volume resistivity of the outer wall and the partition wall at 400° C. can be sufficiently increased, and leakage current caused by electronic conductivity can be suppressed. Therefore, only the desired electrochemical reaction can be favorably performed over the entire functional electrode 50 and the counter electrode 60. The ceramic may contain a substance other than the silicon carbide-silicon composite. An example of such a substance is strontium.

Silicon carbide-silicon composites typically contain silicon carbide particles as aggregates and silicon as a binder that bonds the silicon carbide particles. In silicon carbide-silicon composites, for example, multiple silicon carbide particles are bonded together by silicon so as to form pores (voids) between the silicon carbide particles. In other words, the partition wall 30 and the outer peripheral wall 40 that contain the silicon carbide-silicon composite can be, for example, porous.

In one embodiment, the voids of the partition 30 and the outer peripheral wall 40 are impregnated with an ionic liquid. With this configuration, the partition and the outer peripheral wall (particularly the partition) can function well as a separator between the functional electrode and the counter electrode. Furthermore, by being impregnated with an ionic liquid, electronic conductivity can be suppressed, and only a desired electrochemical reaction can be efficiently performed. As the ionic liquid, any appropriate ionic liquid can be used depending on the purpose, the configuration of the electrochemical element, and the like. The ionic liquid can typically contain an anion component and a cation component. Examples of the anion component of the ionic liquid include halides, sulfuric acid, sulfonic acid, carbonate, bicarbonate, phosphoric acid, nitric acid, hydrochloric acid, acetic acid, PF ₆ ⁻ , BF ₄ ⁻ , triflate, nonaflate, bis(triflyl)amide, trifluoroacetic acid, heptafluorobutanoic acid, haloaluminates, triazolides, and amino acid derivatives (e.g., proline from which the proton on the nitrogen has been removed). Examples of the cationic component of the ionic liquid include imidazolium, pyridinium, pyrrolidinium, phosphonium, ammonium, sulfonium, thiazolium, pyrazolium, piperidinium, triazolium, pyrazolium, oxazolium, guanadinium, and dialkylmorpholinium. The ionic liquid may be, for example, 1-butyl-3-methylimidazolium tetrafluoroborate ([Bmim] ⁺ [BF ₄ ] ^- ). When the gas species to be separated and recovered is carbon dioxide, water may be electrolyzed due to the potential window, so it is preferable to use a non-aqueous ionic liquid.

The silicon content in the silicon carbide-silicon composite is preferably 10% by mass to 40% by mass, and more preferably 15% by mass to 35% by mass. If the silicon content is too low, the strength of the outer peripheral wall and partition walls may be insufficient. If the silicon content is too high, the outer peripheral wall and partition walls may not be able to retain their shape when fired.

The average particle diameter of the silicon carbide particles is preferably 3 μm to 50 μm, more preferably 3 μm to 40 μm, and even more preferably 10 μm to 35 μm. If the average particle diameter of the silicon carbide particles is in this range, the volume resistivity of the outer peripheral wall and the partition walls can be set to the appropriate range as described above. If the average particle diameter of the silicon carbide particles is too large, the raw material may clog the molding die when molding the outer peripheral wall and the partition walls. The average particle diameter of the silicon carbide particles can be measured, for example, by laser diffraction.

The average pore diameter of the outer peripheral wall 10 and the partition wall 40 is preferably 2 μm to 20 μm, and more preferably 10 μm to 20 μm. If the average pore diameter of the outer peripheral wall and the partition wall is within this range, the ionic liquid can be impregnated well. If the average pore diameter is too large, the carbonaceous material in the counter electrode or functional electrode may flow into the partition wall, which may result in an internal short circuit. The average pore diameter can be measured, for example, by a mercury porosimeter.

The porosity of the outer peripheral wall 10 and the partition walls 40 is preferably 15% to 60%, and more preferably 30% to 45%. If the porosity is too small, the outer peripheral wall and the partition walls may deform significantly during firing. If the porosity is too large, the strength of the outer peripheral wall and the partition walls may be insufficient. The porosity can be measured, for example, by a mercury porosimeter.

The thickness of the partition wall 40 can be appropriately set depending on the purpose. The thickness of the partition wall 40 can be, for example, 50 μm to 1.0 mm, or, for example, 70 μm to 600 μm. If the thickness of the partition wall is within this range, the mechanical strength of the electrochemical element can be sufficient, and the opening area (total area of the cells in the cross section) can be sufficient, thereby significantly improving the gas separation and recovery efficiency.

The density of the partition wall 40 can be appropriately set depending on the purpose. The density of the partition wall 40 can be, for example, 0.5 g/cm ³ to 5.0 g/cm ^3. If the density of the partition wall is in this range, the electrochemical device can be made lighter and have sufficient mechanical strength. The density can be measured, for example, by the Archimedes method.

In one embodiment, the thickness of the outer peripheral wall 10 is greater than the thickness of the partition wall 40. With this configuration, it is possible to suppress the outer peripheral wall from being destroyed, broken, cracked, etc. due to external forces. The thickness of the outer peripheral wall 10 may be, for example, 0.1 mm to 5 mm, or, for example, 0.3 mm to 2 mm.

The cells 30, 30, ... have any suitable cross-sectional shape in a direction perpendicular to the cell extension direction. The cross-sectional shape and arrangement pattern of the cells are as described in Section A above.

The cell density in the direction perpendicular to the cell extension direction (i.e., the number of cells 30, 30, ... per unit area) can be appropriately set according to the purpose. The cell density can be, for example, 4 cells/cm ² to 320 cells/cm ^2. If the cell density is in such a range, the contact area between the gas mixture at a predetermined flow rate (substantially, the gas to be separated and recovered) and the functional electrode can be made very large. As a result, the predetermined gas (e.g., carbon dioxide) can be separated and recovered with extremely high efficiency. For example, while the mounting density of a flat gas separation element in which a functional electrode and a counter electrode are opposed to each other via a separator is about 0.2 m ² /L, for example, a configuration such as that shown in FIG. 3 can ensure a mounting density of about 4 m ² /L (about 20 times). As a result, it becomes possible to efficiently separate and recover a predetermined gas (e.g., carbon dioxide) with a small-scale facility, and the energy required for separating and recovering the gas can be significantly reduced. Furthermore, by ensuring such a mounting density, it may be possible to separate and recover carbon dioxide from the atmosphere (Direct Air Capture: DAC).

C. Functional Electrode As described above, the functional electrode contains a first active material and is configured to collect and release a predetermined gas (for example, carbon dioxide). A representative example of the first active material is anthraquinone. Anthraquinone can collect (capture, adsorb) and release carbon dioxide by the electrochemical reaction described in section A above. Anthraquinone may be polyanthraquinone (i.e., a polymer). Examples of polyanthraquinone include poly(1,4-anthraquinone), poly(1,5-anthraquinone), poly(1,8-anthraquinone), and poly(2,6-anthraquinone) represented by the following formula (I). These may be used alone or in combination.

The first active material may be any suitable material other than anthraquinone, so long as it is capable of collecting and releasing (particularly collecting) a predetermined gas (e.g., carbon dioxide). Examples of such materials include tetrachlorohydroquinone (TCHQ), hydroquinone (HQ), dimethoxybenzoquinone (DMBQ), naphthoquinone (NQ), tetracyanoquinodimethane (TCNQ), dihydroxybenzoquinone (DHBQ), and polymers thereof.

The functional electrode may further include a substrate. Here, the term "substrate" refers to a component that shapes the electrode (layer) and maintains its shape. Furthermore, the substrate may support the first active material. The substrate is typically conductive. Examples of the substrate include carbonaceous materials. Examples of the carbonaceous material include carbon nanotubes (e.g., single-wall carbon nanotubes, multi-wall carbon nanotubes), carbon black, KetjenBlack, carbon black Super P, and graphene. By using such a carbonaceous material as the substrate, electron transfer can be easily performed, and therefore the oxidation-reduction reaction of the first active material can be performed well. For example, when anthraquinone or polyanthraquinone is used as the first active material, the average pore diameter of the substrate is preferably 2 nm to 50 nm, more preferably 2 nm to 20 nm, and even more preferably 3 nm to 10 nm. If the average pore diameter is too small, it may not be possible to support the first active material inside. If the average pore diameter is too large, the first active material may fall off during operation of the functional electrode. The average pore diameter of the substrate may vary depending on the first active material. For example, when naphthoquinone is used as the first active material, the average pore diameter is preferably about 2/3 of the above size. The average pore diameter can be calculated, for example, using BJH analysis in the nitrogen gas adsorption method.

The content of the first active material in the functional electrode may be, for example, 10% by mass to 70% by mass, or, for example, 20% by mass to 50% by mass, relative to the total mass of the functional electrode. If the content of the first active material is within such a range, good gas recovery and release performance can be achieved.

The thickness of the functional electrode may be, for example, 20 μm to 300 μm, or may be, for example, 100 μm to 200 μm. If the thickness of the functional electrode is within this range, it is possible to ensure the desired gas flow path while maintaining good gas recovery and release performance.

The functional electrode can be formed, for example, by applying a functional electrode-forming material containing a first active material, a substrate, and a binder to the partition wall surface under reduced pressure and then subjecting it to a heat treatment.

D. Counter Electrode As described above, the counter electrode can function as an electron source for the reduction of the first active material, and can also function as an electron receiver during the oxidation of the first active material. That is, the counter electrode plays an auxiliary role for the functional electrode to function well. As described above, the counter electrode includes a second active material. As the second active material, any appropriate material can be used as long as it can provide good electron exchange with the functional electrode. Examples of the second active material include polyvinylferrocene, poly(3-(4-fluorophenyl)thiophene), and the like.

The counter electrode may further comprise a matrix, as described above in section C for the functional electrode. In one embodiment, the counter electrode comprises a second active material dispersed in the matrix. The second active material dispersed in the matrix provides
Excellent electronic conductivity can be achieved within the electrode.

The counter electrode may further contain an ionic liquid. By containing an ionic liquid in the counter electrode, the counter electrode can function three-dimensionally, and the capacity for donating and receiving electrons can be increased. The ionic liquid is as described above in section B regarding the outer wall and the partition. In one embodiment, the ionic liquid contained in the counter electrode is the same as the ionic liquid contained in the outer wall and the partition (particularly the partition). With this configuration, the electrochemical element can be manufactured simply and easily, and adverse effects on the electrochemical reaction of the functional electrode can be prevented.

The counter electrode is disposed inside the cell 30b as described above, and typically fills the cell 30b. By filling the cell 30b with the counter electrode, the electrolyte (ionic liquid) can be continuously supplied to the functional electrode for a long period of time.

The content of the second active material in the counter electrode may be, for example, 10% by mass to 90% by mass, or, for example, 30% by mass to 70% by mass, relative to the total mass of the counter electrode. If the content of the second active material is within such a range, the amount of electrolyte (ionic liquid) used can be reduced, and the second active material in the counter electrode can be effectively utilized.

When the counter electrode contains an ionic liquid, the content thereof may be, for example, 10% by mass to 90% by mass, or, for example, 30% by mass to 70% by mass, relative to the total mass of the counter electrode. If the content of the ionic liquid is within such a range, the electrolyte (ionic liquid) can be continuously supplied to the functional electrode for a long period of time.

The counter electrode can be formed, for example, by placing in a cell (typically, by filling the cell) a counter electrode-forming material that includes a second active material, a substrate, preferably an ionic liquid, and optionally a solvent or dispersion medium.

The electrochemical element according to the embodiment of the present invention can be suitably used for separating and recovering a specific gas from a gas mixture, and in particular, can be suitably used for a carbon dioxide capture, utilization, and storage (CCUS) cycle.

REFERENCE SIGNS LIST 10 Outer peripheral wall 20a First end surface 20b Second end surface 30 Cell 30a First cell 30b Second cell 40 Partition wall 50 Functional electrode 60 Counter electrode 70 Gas flow channel 100 Electrochemical element

Claims (11)

An outer perimeter wall;
a partition wall disposed inside the outer peripheral wall and defining a plurality of cells extending from the first end surface to the second end surface;
having
the plurality of cells includes a first cell and a second cell;
a functional electrode including a first active material is formed on a surface of the partition wall that defines the first cell;
a counter electrode including a second active material is disposed within the second cell;
A total area of the first cells exceeds 50% with respect to a total area of the plurality of cells in a cross section perpendicular to a direction in which the plurality of cells extend;
the first cells and the second cells are arranged alternately;
A cross-sectional area of the first cell in a cross section perpendicular to a direction in which the cells extend is larger than a cross-sectional area of the second cell .
Electrochemical element. An outer perimeter wall;
a partition wall disposed inside the outer peripheral wall and defining a plurality of cells extending from the first end surface to the second end surface;
having
the plurality of cells includes a first cell and a second cell;
a functional electrode including a first active material is formed on a surface of the partition wall that defines the first cell;
a counter electrode including a second active material is disposed within the second cell;
A total area of the first cells exceeds 50% with respect to a total area of the plurality of cells in a cross section perpendicular to a direction in which the plurality of cells extend;
The plurality of cells are arranged in a lattice pattern, with the cells having a rectangular shape in a cross section perpendicular to the direction in which the plurality of cells extend ,
The first cells are arranged adjacent to each other,
The second cells are arranged so as not to be adjacent to each other .
Electrochemical element. An outer perimeter wall;
a partition wall disposed inside the outer peripheral wall and defining a plurality of cells extending from the first end surface to the second end surface;
having
the plurality of cells includes a first cell and a second cell;
a functional electrode including a first active material is formed on a surface of the partition wall that defines the first cell;
a counter electrode including a second active material is disposed within the second cell;
A total area of the first cells exceeds 50% with respect to a total area of the plurality of cells in a cross section perpendicular to a direction in which the plurality of cells extend;
The plurality of cells are arranged in a honeycomb shape, with the cells having a hexagonal shape in a cross section perpendicular to the direction in which the plurality of cells extend ,
The first cells are arranged adjacent to each other,
The second cells are arranged so as not to be adjacent to each other .
Electrochemical element. The electrochemical element according to claim 1 , wherein the cell in which the functional electrode is formed includes a gas flow path. 5. The electrochemical element according to claim 4 , wherein the functional electrode is formed on the partition wall so as to surround the gas flow path. 6. An electrochemical element according to claim 1, wherein the cell in which the counter electrode is disposed is filled with the counter electrode. 7. The electrochemical device according to claim 6 , wherein the counter electrode comprises a conductive matrix and the second active material dispersed in the matrix. The electrochemical device of claim 7 , wherein the substrate comprises a carbonaceous material. The electrochemical device according to claim 7 or 8 , wherein the counter electrode further comprises an ionic liquid. 10. The electrochemical element according to claim 9 , wherein the partition wall is impregnated with an ionic liquid, and the ionic liquid is the same as the ionic liquid contained in the counter electrode. 11. The electrochemical device according to claim 1, wherein the first active material comprises anthraquinone and the second active material comprises polyvinylferrocene.

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