CN211719445U - Capacitor - Google Patents

Abstract

The utility model discloses a capacitor, including casing, electrochemistry region, conductor region and non-electron charged particle conduction thing, electrochemistry region the conductor region with non-electron charged particle conduction thing sets up in the casing, just the electrochemistry region warp non-electron charged particle conduction thing with conductor region has the non-electron and switches on the electricity relation, the electrochemistry region is established to electrode A, conductor region establishes to electrode B. The utility model discloses an electric capacity that electric capacity is big is made to the barrier between the usable small electric charge of electric capacity, and has advantages such as simple structure, capacious.

Description

Capacitor

Technical Field

The utility model relates to an electric capacity field especially relates to an electric capacity.

Background

The conventional capacitor is a barrier to either electrons and metal ions losing electrons, a barrier to ions and metal ions losing electrons, or a barrier between positive and negative ions, and at least one kind of bulky charge exists in the barrier. Therefore, a new capacitor needs to be invented.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problem, the utility model provides a technical scheme as follows:

scheme 1: a capacitor comprising a housing, an electrochemical region, a conductive region, and a non-electronic charged particle conductor, the electrochemical region, the conductive region, and the non-electronic charged particle conductor being disposed within the housing, and the electrochemical region being in non-electronically conducting electrical relationship with the conductive region via the non-electronic charged particle conductor, the electrochemical region being provided as electrode a, and the conductive region being provided as electrode B; or, the capacitor comprises a housing, an electrochemical region, a conductive region and a non-electronic charged particle conductor, the electrochemical region, the conductive region and the non-electronic charged particle conductor are arranged in the housing, the electrochemical region and the conductive region are in non-electronic conduction electrical relation via the non-electronic charged particle conductor, the electrochemical region is an electrode A, the conductive region is an electrode B, and the housing is filled with hydrogen.

Scheme 2: a capacitor comprising a housing, an electrochemical region, a conductive region, and a non-electronic charged particle conductor, the electrochemical region, the conductive region, and the non-electronic charged particle conductor being disposed within the housing, the electrochemical region being disposed in contact with the non-electronic charged particle conductor, the non-electronic charged particle conductor being disposed in contact with the conductive region, the electrochemical region being electrode a, the conductive region being electrode B; alternatively, the capacitor includes a case, an electrochemical region, a conductive region, and a non-electron charged particle conductor, the electrochemical region, the conductive region, and the non-electron charged particle conductor are provided in the case, the electrochemical region is provided in contact with the non-electron charged particle conductor, the non-electron charged particle conductor is provided in contact with the conductive region, the electrochemical region is an electrode a, the conductive region is an electrode B, and the case is filled with hydrogen.

Scheme 3: a capacitor comprising a housing, an electrochemical region, a conductor region, and a dielectric, the electrochemical region, the conductor region, and the dielectric being disposed within the housing and the electrochemical region being in non-electronically conducting electrical relationship with the conductor region via the dielectric, the electrochemical region being disposed as electrode a and the conductor region being disposed as electrode B; or, the capacitor comprises a housing, an electrochemical region, a conductor region and a dielectric, the electrochemical region, the conductor region and the dielectric being disposed within the housing and the electrochemical region being in non-electronically conducting electrical relationship with the conductor region via the dielectric, the electrochemical region being provided as electrode a, the conductor region being provided as electrode B, and hydrogen being filled within the housing.

Scheme 4: a capacitor comprising a housing, an electrochemical region, a conductor region, and a dielectric, the electrochemical region, the conductor region, and the dielectric being disposed within the housing and the electrochemical region being disposed in contact with the dielectric, the dielectric being disposed in contact with the conductor region, the electrochemical region being disposed as electrode a, the conductor region being disposed as electrode B; or, the capacitor comprises a shell, an electrochemical region, a conductor region and a dielectric, wherein the electrochemical region, the conductor region and the dielectric are arranged in the shell, the electrochemical region is arranged in contact with the dielectric, the dielectric is arranged in contact with the conductor region, the electrochemical region is arranged as an electrode A, the conductor region is arranged as an electrode B, and hydrogen is filled in the shell.

In all of the aforementioned embodiments of the present invention, the substance X that generates positive charged particles and electrons in contact with the electrochemical region may be further selectively selected to be a small molecular simple substance, and the substance may be further selectively selected to be hydrogen, lithium, sodium, potassium, helium, neon, argon, krypton, mercury, or a liquid metal.

In the present invention, the "small molecule simple substance" refers to a simple substance having an atomic diameter smaller than that of potassium.

In the present invention, the term "non-electron charged particles" refers to charged particles other than electrons, such as protons or ions.

In the present invention, the term "non-electron-charged particle conductor" refers to a substance that does not conduct electrons but conducts protons or specific ions, i.e., an electrolyte in a conventional electrochemical device, and the non-electron-charged particle conductor can be selectively provided as a proton exchange membrane, for example.

In the present invention, the term "having a non-electron-conducting electrical relationship" refers to an electrical conducting relationship formed by non-electron charged particles.

In the present invention, the term "electrochemical region" refers to any region where electrochemical reaction can occur, for example, a catalyst, an ultrastructure, and/or a region at a predetermined temperature, and for example, a metal region at a predetermined temperature.

In the present invention, the electrochemical region may be selectively set as a conductive region.

In the present invention, the term "comprising a catalyst, a microstructure and/or an electrochemical region at a set temperature" means that the electrochemical region comprises either a catalyst or a microstructure or is at a set temperature or the electrochemical region comprises two or three of these three conditions.

In the present invention, the term "microstructure" refers to a microstructure capable of initiating an electrochemical reaction under a predetermined condition.

In the present invention, the letters "a" and "B" are added after a certain name of a component to distinguish two or more components or materials with the same name.

In the present invention, necessary components, units, systems, etc. should be provided where necessary according to the known technology in the field of capacitors.

The utility model has the advantages that the capacitor disclosed by the utility model can utilize the small electric charge to build the capacitor with large capacity, and has the advantages of simple structure, large capacity and the like.

Drawings

FIG. 1: the structure of embodiment 1 of the utility model is schematically shown;

FIG. 2: the structure of embodiment 2 of the utility model is schematically shown;

FIG. 3: the structure of embodiment 3 of the utility model is schematically shown;

FIG. 4: the structure of embodiment 4 of the utility model is schematically shown;

FIG. 5: the structure of embodiment 5 of the utility model is schematically shown;

FIG. 6: the utility model discloses embodiment 6's structural schematic diagram;

FIG. 7: the structure of embodiment 7 of the utility model is schematically shown;

FIG. 8: the utility model discloses embodiment 8's schematic structure diagram.

Detailed Description

Example 1

A capacitor, as shown in fig. 1, comprising a housing 1, an electrochemical region 2, a conductive region 3 and a non-electronic charged particle conductor 4, wherein the electrochemical region 2, the conductive region 3 and the non-electronic charged particle conductor 4 are arranged in the housing 1, the electrochemical region 2 has a non-electronic conducting electrical relationship with the conductive region 3 via the non-electronic charged particle conductor 4, the electrochemical region 2 is an electrode a, the conductive region 3 is an electrode B, and a substance X is filled in the housing.

Example 2

A capacitor as shown in FIG. 2 comprises a case 1, an electrochemical region 2, a conductive region 3 and a non-electron charged particle conductor 4, wherein the electrochemical region 2, the conductive region 3 and the non-electron charged particle conductor 4 are disposed in the case 1, the electrochemical region 2 has a non-electron conducting electrical relationship with the conductive region 3 via the non-electron charged particle conductor 4, the electrochemical region 2 is an electrode A, the conductive region 3 is an electrode B, and the case 1 is filled with hydrogen.

In practical implementation of the embodiments 1 and 2 of the present invention, the non-electronic charged particle conductor 4 is made to isolate the casing 1 (excluding specific non-electronic charged particle isolation) into two cavities, the electrochemical region 2 is disposed in one of the cavities, the conductor region 3 is disposed in the other cavity, and the cavity in which the electrochemical region 2 is disposed is filled with the substance X, preferably, the substance X is set to hydrogen.

In an alternative embodiment, in examples 1 and 2 of the present invention, the conductive region 3 may be selectively provided as a porous structure, and the conductive region 3 may be selectively provided as an electrochemical region having the same function as the electrochemical region 2.

The operation of the capacitor will now be described with the substance X as hydrogen: when the substance X is hydrogen, the non-electron charged particle conductor 4 is a proton exchange membrane, so that the hydrogen is charged into the cavity where the electrochemical region 2 is located, the hydrogen separates electrons and protons, and the separated protons reach the cavity side where the conductor region 3 is located through the proton exchange membrane and form a capacitance relationship with an electron barrier.

In addition, the capacitor can work by adopting the following working process: when the substance X is hydrogen, the non-electron charged particle conductor 4 is a proton exchange membrane, hydrogen gas is filled in the cavity where the electrochemical region 2 is located, the hydrogen separates electrons and protons, the separated protons reach the interface between the conductor region 3 and the non-electron charged particle conductor 4 through the proton exchange membrane, and then the electrons are led out to the conductor region 3, and the protons and the electron barriers form a capacitance relationship at the interface between the non-electron charged particle conductor 4 and the conductor region 3.

Example 3

A capacitor, as shown in fig. 3, comprising a housing 1, an electrochemical region 2, a conductive region 3 and a non-electronic charged particle conductor 4, wherein the electrochemical region 2, the conductive region 3 and the non-electronic charged particle conductor 4 are disposed in the housing 1, the electrochemical region 2 is disposed in contact with the non-electronic charged particle conductor 4, the non-electronic charged particle conductor 4 is disposed in contact with the conductive region 3, the electrochemical region 2 has a non-electronic conducting electrical relationship with the conductive region 3 via the non-electronic charged particle conductor 4, the electrochemical region 2 is an electrode a, and the conductive region 3 is an electrode B.

Example 4

A capacitor as shown in FIG. 4, comprising a case 1, an electrochemical region 2, a conductive region 3 and a non-electron charged particle conductor 4, wherein the electrochemical region 2, the conductive region 3 and the non-electron charged particle conductor 4 are provided in the case 1, the electrochemical region 2 is provided in contact with the non-electron charged particle conductor 4, the non-electron charged particle conductor 4 is provided in contact with the conductive region 3, the electrochemical region 2 has a non-electron conducting electrical relationship with the conductive region 3 via the non-electron charged particle conductor 4, the electrochemical region 2 is an electrode A, the conductive region 3 is an electrode B, and hydrogen is filled in the case 1.

The embodiment 3 and the embodiment 4 of the present invention make the non-electronic charged particle conductor 4 will when specifically implementing the casing 1 is isolated as two cavities, one of the electrochemical region 2 is set up in the cavity and with the non-electronic charged particle conductor 4 is in contact with the setting, the conductor region 3 is set up in another the cavity and with the non-electronic charged particle conductor 4 is in contact with the setting the cavity where the electrochemical region 2 is located is filled with the substance X, preferably makes the substance X set to hydrogen.

In an alternative embodiment, in examples 3 and 4 of the present invention, the conductive region 3 may be selectively provided as a porous structure, and the conductive region 3 may be selectively provided as an electrochemical region having the same function as the electrochemical region 2.

The operation of the capacitor will now be described on the basis that the substance X is hydrogen: when the substance X is hydrogen, the non-electron charged particle conductor 4 is a proton exchange membrane, so that the hydrogen is charged into the cavity where the electrochemical region 2 is located, the hydrogen separates electrons and protons, and the separated protons reach the cavity side where the conductor region 3 is located through the proton exchange membrane and form a capacitance relationship with an electron barrier.

In addition, the capacitor can work by adopting the following working process: when the substance X is hydrogen, the non-electron charged particle conductor 4 is a proton exchange membrane, hydrogen gas is filled in the cavity where the electrochemical region 2 is located, the hydrogen separates electrons and protons, the separated protons reach the interface between the conductor region 3 and the non-electron charged particle conductor 4 through the proton exchange membrane, and then the electrons are led out to the conductor region 3, and the protons and the electron barriers form a capacitance relationship at the interface between the non-electron charged particle conductor 4 and the conductor region 3.

Example 5

A capacitor, as shown in fig. 5, comprising a housing 1, an electrochemical region 2, a conductor region 3 and a dielectric 5, said electrochemical region 2, said conductor region 3 and said dielectric 5 being arranged within said housing 1, and said electrochemical region 2 being in a non-electronically conducting electrical relationship with said conductor region 3 via said dielectric 5, said electrochemical region 2 being provided as an electrode a and said conductor region 3 being provided as an electrode B.

Example 6

A capacitor, as shown in fig. 6, comprising a case 1, an electrochemical region 2, a conductor region 3 and a dielectric 5, wherein said electrochemical region 2, said conductor region 3 and said dielectric 5 are disposed in said case 1, and said electrochemical region 2 has a non-electron conducting electrical relationship with said conductor region 3 via said dielectric 5, said electrochemical region 2 is an electrode a, said conductor region 3 is an electrode B, and said case 1 is filled with hydrogen.

In practical implementation, the embodiments 5 and 6 of the present invention make the dielectric medium 5 isolate the housing 1 (may not include specific non-electronic charged particles) into two cavities, one of the cavities in which the electrochemical region 2 is disposed is, the conductor region 3 is disposed in the other cavity, and the cavity in which the electrochemical region 2 is disposed is filled with the substance X, preferably, the substance X is set to be hydrogen.

In an alternative embodiment, in examples 5 and 6 of the present invention, the conductive region 3 may be selectively provided as a porous structure, and the conductive region 3 may be selectively provided as an electrochemical region having the same function as the electrochemical region 2.

The working of the capacitors described in examples 5 and 6 and their switchable embodiments will now be described with reference to the case where the substance X is hydrogen: when the substance X is hydrogen, the hydrogen is charged into the cavity in which the electrochemical region 2 is located, the hydrogen separates electrons and protons, and the separated electrons reach the cavity side in which the conductor region 3 is located through an external circuit and form a capacitive relationship with the proton barrier.

Examples 5 and 6 and their switchable implementations the capacitors described above can also be implemented using the following working procedure: hydrogen is charged into the cavity where the electrochemical region 2 is located, electrons and protons are separated from the hydrogen, the separated electrons reach the conductor region 3 through an external circuit, the protons pass through the dielectric medium to reach one side of the cavity where the conductor region 3 is located and form a capacitance relation with the electron barriers on the conductor region 3, and when the working process is adopted, the dielectric medium 5 is set as a proton exchange membrane.

Examples 5 and 6 and their switchable implementations the capacitors described above can also be implemented using the following working procedure: when the operation process is adopted, the dielectric medium 5 is set as a proton exchange membrane.

Example 7

A capacitor, as shown in fig. 7, comprising a housing 1, an electrochemical region 2, a conductor region 3 and a dielectric 5, wherein the electrochemical region 2, the conductor region 3 and the dielectric 5 are arranged in the housing 1, the electrochemical region 2 is arranged in contact with the dielectric 5, the dielectric 5 is arranged in contact with the conductor region 3, the electrochemical region 2 is provided as an electrode a, and the conductor region 3 is provided as an electrode B.

Example 8

A capacitor, as shown in fig. 8, comprising a case 1, an electrochemical region 2, a conductor region 3 and a dielectric 5, wherein the electrochemical region 2, the conductor region 3 and the dielectric 5 are disposed in the case 1, the electrochemical region 2 is disposed in contact with the dielectric 5, the dielectric 5 is disposed in contact with the conductor region 3, the electrochemical region 2 is an electrode a, the conductor region 3 is an electrode B, and the case 1 is filled with hydrogen.

In practical implementation, the embodiment 7 and the embodiment 8 of the present invention make the dielectric 5 will the housing 1 is isolated into two cavities, one of the electrochemical regions 2 is disposed in the cavity and in contact with the dielectric 5, the conductor region 3 is disposed in another one of the electrochemical regions 2 is disposed in the cavity and in contact with the dielectric 5, and the cavity where the electrochemical region 2 is disposed is filled with the substance X, preferably the substance X is set to hydrogen.

In a practical implementation mode of the present invention, examples 7 and 8 are carried out in a manner such that the conductive region 3 can be selectively provided with a porous structure, and the conductive region 3 can be selectively provided with an electrochemical region having the same function as the electrochemical region 2.

The principle of the capacitance described in examples 7 and 8 and their switchable embodiments will now be explained using the example where the substance X is hydrogen: when the substance X is hydrogen, the hydrogen is charged into the cavity in which the electrochemical region 2 is located, the hydrogen separates electrons and protons, and the separated electrons reach the cavity side in which the conductor region 3 is located through an external circuit and form a capacitive relationship with the proton barrier.

Examples 7 and 8 and their switchable implementations the capacitors described above can also be implemented using the following working procedure: when the operation process is adopted, the dielectric medium 5 is set as a proton exchange membrane.

Examples 7 and 8 and their switchable implementations the capacitors described above can also be implemented using the following working procedure: hydrogen is charged into the cavity where the electrochemical region 2 is located, electrons and protons are separated from the hydrogen, the separated electrons reach the conductor region 3 through an external circuit, the protons pass through the dielectric medium to reach one side of the cavity where the conductor region 3 is located and form a capacitance relation with the electron barriers on the conductor region 3, and when the working process is adopted, the dielectric medium 5 is set as a proton exchange membrane.

The attached drawings of the specification of the utility model are only schematic, and any technical scheme that satisfies the writing record of this application all belongs to the scope of protection of this application.

Obviously, the present invention is not limited to the above embodiments, and many modifications can be derived or suggested according to the known technology in the field and the technical solutions disclosed in the present invention, and all of these modifications should also be considered as the protection scope of the present invention.

Claims (4)

1. A capacitor, characterized by: the capacitor comprises a housing (1), an electrochemical region (2), a conductor region (3) and a non-electronic charged particle conductor (4), wherein the electrochemical region (2), the conductor region (3) and the non-electronic charged particle conductor (4) are arranged in the housing (1), the electrochemical region (2) has a non-electronic conducting electrical relationship with the conductor region (3) via the non-electronic charged particle conductor (4), the electrochemical region (2) is set as an electrode A, and the conductor region (3) is set as an electrode B; or, the capacitor comprises a housing (1), an electrochemical region (2), a conductor region (3) and a non-electronic charged particle conductor (4), wherein the electrochemical region (2), the conductor region (3) and the non-electronic charged particle conductor (4) are arranged in the housing (1), the electrochemical region (2) and the conductor region (3) have a non-electronic conduction electrical relationship through the non-electronic charged particle conductor (4), the electrochemical region (2) is an electrode A, the conductor region (3) is an electrode B, and the housing (1) is filled with hydrogen.

2. A capacitor, characterized by: the capacitor comprises a shell (1), an electrochemical region (2), a conductor region (3) and a non-electronic charged particle conductor (4), wherein the electrochemical region (2), the conductor region (3) and the non-electronic charged particle conductor (4) are arranged in the shell (1), the electrochemical region (2) is arranged in contact with the non-electronic charged particle conductor (4), the non-electronic charged particle conductor (4) is arranged in contact with the conductor region (3), the electrochemical region (2) is set as an electrode A, and the conductor region (3) is set as an electrode B; or, the capacitor comprises a housing (1), an electrochemical region (2), a conductor region (3) and a non-electronic charged particle conductor (4), wherein the electrochemical region (2), the conductor region (3) and the non-electronic charged particle conductor (4) are arranged in the housing (1), the electrochemical region (2) and the non-electronic charged particle conductor (4) are arranged in contact, the non-electronic charged particle conductor (4) and the conductor region (3) are arranged in contact, the electrochemical region (2) is an electrode A, the conductor region (3) is an electrode B, and the housing (1) is filled with hydrogen.

3. A capacitor, characterized by: the capacitor comprises a shell (1), an electrochemical region (2), a conductor region (3) and a dielectric medium (5), wherein the electrochemical region (2), the conductor region (3) and the dielectric medium (5) are arranged in the shell (1), the electrochemical region (2) and the conductor region (3) have a non-electronic conducting electrical relationship through the dielectric medium (5), the electrochemical region (2) is set as an electrode A, and the conductor region (3) is set as an electrode B; or, the capacitor comprises a shell (1), an electrochemical region (2), a conductor region (3) and a dielectric medium (5), wherein the electrochemical region (2), the conductor region (3) and the dielectric medium (5) are arranged in the shell (1), the electrochemical region (2) and the conductor region (3) have a non-electronic conduction electrical relationship through the dielectric medium (5), the electrochemical region (2) is set as an electrode A, the conductor region (3) is set as an electrode B, and the shell (1) is filled with hydrogen.

4. A capacitor, characterized by: the capacitor comprises a shell (1), an electrochemical region (2), a conductor region (3) and a dielectric medium (5), wherein the electrochemical region (2), the conductor region (3) and the dielectric medium (5) are arranged in the shell (1), the electrochemical region (2) is arranged in contact with the dielectric medium (5), the dielectric medium (5) is arranged in contact with the conductor region (3), the electrochemical region (2) is set as an electrode A, and the conductor region (3) is set as an electrode B; or, the capacitor comprises a shell (1), an electrochemical region (2), a conductor region (3) and a dielectric medium (5), wherein the electrochemical region (2), the conductor region (3) and the dielectric medium (5) are arranged in the shell (1), the electrochemical region (2) is arranged in contact with the dielectric medium (5), the dielectric medium (5) is arranged in contact with the conductor region (3), the electrochemical region (2) is an electrode A, the conductor region (3) is an electrode B, and hydrogen is filled in the shell (1).

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