CN111036045A

CN111036045A - Compression device

Info

Publication number: CN111036045A
Application number: CN201911270153.7A
Authority: CN
Inventors: 靳北彪
Original assignee: Entropy Zero Technology Logic Engineering Group Co Ltd
Current assignee: Entropy Zero Technology Logic Engineering Group Co Ltd
Priority date: 2018-12-30
Filing date: 2019-12-12
Publication date: 2020-04-21
Also published as: CN212119505U

Abstract

The invention discloses a compression device, which comprises an electrochemical area A, an area B and a non-electronic charged particle conductor, wherein the electrochemical area A has a non-electronic conduction electrical relation with the area B through the non-electronic charged particle conductor, the electrochemical area A comprises an outer power connection area A, and the area B comprises an outer power connection area B. The compression device disclosed by the invention can realize compression and separation of gas by utilizing an electrochemical reaction, and has the advantages of simple structure, high efficiency and the like.

Description

Compression device

Technical Field

The invention relates to the field of chemical engineering, in particular to a compression device.

Background

If a device can be devised to separate a gas into electrons and non-electronically charged particles, the gas can be compressed by passing the non-electronically charged particles through a non-electronically charged particle conductor using electrical energy and reacting the electrons with the non-electronically charged particles to reduce them to the gas. For this reason, a new type of compression device needs to be invented.

Disclosure of Invention

In order to solve the above problems, the technical solution proposed by the present invention is as follows:

scheme 1: a compression device comprising an electrochemical region a in non-electronically conducting electrical relationship with a non-electronically charged particle conductor, said electrochemical region a comprising an external power connection region a, and a region B comprising an external power connection region B, and said non-electronically charged particle conductor.

Scheme 2: a compression device comprising an electrochemical region a in non-electronically conducting electrical relationship with an electrochemical region B via a non-electronically charged particle conductor, the electrochemical region a comprising an outer power connection region a, the electrochemical region B comprising an outer power connection region B, and a non-electronically charged particle conductor.

Scheme 3: on the basis of the scheme 1, the electrochemical area A is further selectively communicated with a low-pressure gas inlet channel, and the area B is communicated with a high-pressure gas outlet channel.

Scheme 4: on the basis of the scheme 2, the electrochemical area A is further selectively communicated with the low-pressure gas inlet channel, and the electrochemical area B is communicated with the high-pressure gas outlet channel.

Scheme 5: a compression device comprising an electrochemical region a, a region B and a non-electronic charged particle conductor, said electrochemical region a being in non-electronically conducting electrical relationship with said region B via said non-electronic charged particle conductor, said electrochemical region a comprising an external power connection region a, said region B comprising an external power connection region B, said electrochemical region a being arranged in communication with a low pressure gas introduction channel, said region B being arranged in communication with a high pressure gas discharge channel, the system comprising said electrochemical region a, said region B, said non-electronic charged particle conductor, said low pressure gas introduction channel and high pressure gas discharge channel defining sub-systems, the gas channels of N of said sub-systems being arranged in series communication and/or the external power connection regions of N of said sub-systems being arranged in series, said N being greater than or equal to 2.

Scheme 6: a compression device comprising an electrochemical region A, an electrochemical region B and a non-electronic charged particle conductor, said electrochemical region A being in non-electronically conducting electrical relationship with said electrochemical region B via said non-electronic charged particle conductor, said electrochemical region A comprising an outer power connection region A, said electrochemical region B comprising an outer power connection region B, said electrochemical region A being arranged in communication with a low pressure gas introduction channel, said electrochemical region B being arranged in communication with a high pressure gas discharge channel, the system comprising said electrochemical region A, said electrochemical region B, said non-electronic charged particle conductor, said low pressure gas introduction channel and high pressure gas discharge channel being defined as a subsystem, the gas channels of N of said subsystems being arranged in series communication and/or the outer power connection regions of N of said subsystems being arranged in series, and N is more than or equal to 2.

Scheme 7: in addition to any one of aspects 3 to 6, the gas in the low-pressure gas introduction passage is further set to be a simple substance gas.

Scheme 8: on the basis of the scheme 7, the elemental gas is further selectively set to be hydrogen, helium, oxygen or nitrogen.

Scheme 9: a compression device comprises electrochemical regions, a region B and a non-electronic charged particle conductor, wherein N electrochemical regions are respectively defined as an electrochemical region A₁To the electrochemical region A_nN of the regions B are defined as regions B respectively₁To region B_nSaid electrochemical area A₁To the electrochemical region A_nComprising an outer power connection region, said region B₁To the region B_nComprises an external power connection region, N non-electron charged particle conductors are respectively defined as non-electron charged particle conductors X₁To non-electronic charged particle conductor X_nN is 2 or more, electrochemical region A_yBy conduction of non-electronically charged particles X_yAnd region B_yHas a non-electronic conducting electrical relationship, y is any integer from 1 to N to form an electrochemical unit, and the electrochemical area A₁To the electrochemical region A_nIs arranged to communicate with the mixture introduction passage, the region B₁To the aboveRegion B_nIs communicated with different separated product outlet channels.

Scheme 10: a compression device comprising electrochemical regions and a non-electronic charged particle conductor, N of said electrochemical regions being defined as electrochemical regions A, respectively₁To the electrochemical region A_nN of the electrochemical regions are respectively defined as electrochemical regions B₁To the electrochemical region B_nSaid electrochemical area A₁To the electrochemical region A_nComprising an external power connection region, the electrochemical region B₁To the electrochemical region B_nComprises an external power connection region, N non-electron charged particle conductors are respectively defined as non-electron charged particle conductors X₁To non-electronic charged particle conductor X_nN is 2 or more, electrochemical region A_yBy conduction of non-electronically charged particles X_yAnd an electrochemical region B_yHas a non-electronic conducting electrical relationship, y is any integer from 1 to N to form an electrochemical unit, and the electrochemical area A₁To the electrochemical region A_nIs communicated with the mixture introducing channel, and the electrochemical area B₁To the electrochemical region B_nIs communicated with different separated product outlet channels.

Scheme 11: on the basis of the embodiment 9, the mixture introduced into the mixture introducing passage is further selectively selected to include at least one of hydrogen, helium, oxygen, or nitrogen.

Scheme 12: on the basis of the embodiment 10, the mixture introduced into the mixture introducing passage is further selectively selected to include at least one of hydrogen, helium, oxygen, or nitrogen.

Scheme 13: in addition to any one of aspects 1 to 6 and 8 to 12, it is further selectively selected that the non-electron charged particle conductor is provided as a proton exchange membrane, a solid oxide electrolyte membrane, or as a liquid electrolyte.

Scheme 14: in addition to the embodiment 7, the non-electron charged particle conductor is further selectively selected to be a proton exchange membrane, a solid oxide electrolyte membrane, or a liquid electrolyte.

In the present invention, the "non-electron-charged particle conductor" refers to a substance that does not conduct electrons but conducts protons or specific ions. For example, the non-electron-charged particle conductor may be selectively used as a proton exchange membrane or an electrolyte membrane used in a solid oxide fuel cell.

In the present invention, the term "having a non-electron conducting electrical relationship" refers to an electrical conducting relationship by non-electron charged particles, for example, a conducting relationship by a capacitor, a conducting relationship by reciprocating oscillation of non-electron charged particles, and the like.

In the present invention, the term "electrochemical region" refers to any region in which an electrochemical reaction can occur, and includes, for example, a catalyst, an ultrastructure, and/or a region at a predetermined temperature (for example, an electrode in a fuel cell), and further, for example, a metal region at a predetermined temperature.

In the present invention, by "comprising a catalyst, a microstructure, and/or an electrochemical region at a set temperature" is meant 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 "region" may be further selectively selected as an electrochemical region. The specific setting can be carried out selectively according to actual needs.

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 number is included in a certain number or more, and two or more, for example.

In the present invention, the addition of letters such as "a" and "B" to a name of a certain component is merely to distinguish two or more components having the same name.

In the present invention, necessary components, units, systems, and the like are provided where necessary according to a technique known in the chemical field.

The compression device disclosed by the invention has the beneficial effects that the compression device can realize compression and separation of gas by utilizing an electrochemical reaction, and has the advantages of simple structure, high efficiency and the like.

Drawings

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

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

FIG. 3: the structure of embodiment 3 of the invention is schematically illustrated;

FIG. 4: the structure of embodiment 4 of the invention is schematically illustrated;

FIG. 4.1: a schematic structural diagram of another embodiment of example 4 of the present invention.

Detailed Description

Example 1

A compression device, as shown in fig. 1, comprising an electrochemical region a1, a region B3, and a non-electronically charged particle conductor 4, said electrochemical region a1 being in a non-electronically conducting electrical relationship with said region B3 via said non-electronically charged particle conductor 4, said electrochemical region a1 comprising an external power connection region A5, said region B3 comprising an external power connection region B6, said electrochemical region a1 being disposed in communication with a low pressure gas introduction passageway 7, said region B3 being disposed in communication with a high pressure gas discharge passageway 8.

Example 2

A compression device, as shown in fig. 2, comprising an electrochemical region a1, an electrochemical region B2 and a non-electron charged particle conductor 4, wherein the electrochemical region a1 has a non-electron conducting electrical relationship with the electrochemical region B2 via the non-electron charged particle conductor 4, the electrochemical region a1 comprises an external power connection region A5, the electrochemical region B2 comprises an external power connection region B6, the electrochemical region a1 is disposed in communication with a low pressure gas introduction channel 7, and the electrochemical region B2 is disposed in communication with a high pressure gas discharge channel 8.

In specific implementation of the

embodiments

1 and 2 of the present invention, the non-electronic charged particle conductor 4 isolates the cavity into two parts, the electrochemical region a1 is disposed in the cavity on one side of the non-electronic charged particle conductor 4, the region B3 (the electrochemical region B2) is disposed in the cavity on the other side of the non-electronic charged particle conductor 4, the low-pressure gas introduction channel 7 is disposed in communication with the cavity in which the electrochemical region a1 is located, and the high-pressure gas discharge channel 8 is disposed in communication with the cavity in which the region B3 (the electrochemical region B2) is located.

In practical implementation of examples 1 and 2 and their alternative embodiments of the present invention, the gas introduced into the low-pressure gas introduction passage 7 may be selectively set to be hydrogen, the non-electron charged particle conductor 4 may be set to be a proton exchange membrane, the hydrogen introduced from the low-pressure gas introduction passage 7 separates electrons and protons in the electrochemical region a1, the protons pass through the proton exchange membrane to the other side, the electrons are guided to the other side of the proton exchange membrane and react with the protons to generate hydrogen, and the amount of generated hydrogen increases continuously, thereby achieving a compression function. Alternatively, the gas introduced into the low-pressure gas introduction passage may be oxygen gas, the non-electron charged particle conductor 4 may be an electrolyte (for example, an electrolyte used in a solid oxide fuel cell) capable of conducting oxygen ions, and the oxygen gas introduced from the low-pressure gas introduction passage 7 may obtain electrons in the electrochemical region to form oxygen ions, and the oxygen ions may pass through the electrolyte to the other side and lose the electrons to form oxygen gas, so that the compression function is realized as the amount of oxygen gas generated increases.

Example 3

A compression device, as shown in fig. 3, comprising an electrochemical region a1, a region B3 and a non-electronic charged particle conductor 4, wherein the electrochemical region a1 has a non-electronic conducting electrical relationship with the region B3 via the non-electronic charged particle conductor 4, the electrochemical region a1 comprises an external power connection region A5, the region B3 comprises an external power connection region B6, the electrochemical region a1 is disposed in communication with a low-pressure gas introduction passage 7, the region B3 is disposed in communication with a high-pressure gas discharge passage 8, and a system comprising the electrochemical region a1, the region B3, the non-electronic charged particle conductor 4, the low-pressure gas introduction passage 7 and the high-pressure gas discharge passage 8 is defined as a subsystem, and the gas passages of the two subsystems are disposed in series communication.

As an alternative embodiment, the present invention in example 3 can further optionally be arranged to connect the external power sources of the two subsystems in series.

Example 3 of the present invention may also optionally be practiced with the compression device including three, four, five, six, seven, eight, nine, ten, eleven, twelve, thirteen, fourteen, fifteen, sixteen, seventeen, eighteen, nineteen, or twenty or more of the subsystems as alternative embodiments, with the gas passages of all of the subsystems in series communication and/or with the external power connection regions of all of the subsystems in series communication.

In practical implementation of embodiment 3 and its convertible implementation, each subsystem can work according to the setting form and the working mode of

embodiments

1 and 2, so that the compression device has a multi-stage compression function.

In practical implementation of example 3 and the switchable embodiment thereof of the present invention, the region B3 may be selectively set as an electrochemical region according to actual needs.

As a changeable embodiment, in practical implementation of example 3 of the present invention and its changeable embodiment, the gas in the low-pressure gas introduction passage 7 may be further selectively selected to be a simple substance gas; and the elemental gas can be further selectively set to be hydrogen, helium, oxygen or set to be nitrogen.

Example 4

A compression device, as shown in FIG. 4, comprises an electrochemical region 9, a region B3 and a non-electronic charged particle conductor 4, wherein the two electrochemical regions 9 are respectively defined as an electrochemical region A₁And an electrochemical region A₂Two of the regions B3 are defined as regions B, respectively₁And region B₂Said electrochemical area A₁And the electrochemical region A₂Comprising an outer power connection region, said region B₁And said region B₂Comprising an external power supply connection region, two of said non-electron-charged particle conductors 4 being defined separatelyMeaning a non-electronic charged particle conductor X₁And a non-electronic charged particle conductor X₂Said electrochemical area A₁By conduction of non-electronically charged particles X₁And the region B₁Having a non-electronically conducting electrical relationship, said electrochemical region A₂By conduction of non-electronically charged particles X₂And the region B₂Having a non-electronically conducting electrical relationship, said electrochemical region A₁And the non-electronic charged particle conductor X₁And the region B₁Forming an electrochemical cell, the electrochemical region A₂And the non-electronic charged particle conductor X₂And the region B₂Forming an electrochemical cell, the electrochemical region A₁And the electrochemical region A₂Is provided in communication with the mixture introduction passage 10, the region B₁And said region B₂Is communicated with different separated product outlet channels.

In embodiment 4 of the present invention, the non-electronic charged particle conductor 4 is disposed in a cavity and isolated from the cavity into two parts, the electrochemical region 9 is disposed in the cavity at one side of the non-electronic charged particle conductor 4, the region B3 is disposed in the cavity at the other side of the non-electronic charged particle conductor 4, a mixture enters the cavity at one side of the electrochemical region 9 through the mixture introducing channel 10, and the mixture generates a mixture capable of passing through the non-electronic charged particle conductor X₁And a non-electronic charged particle conductor X₂The two kinds of particles generated enter one side of the region B3 and then two kinds of substances included in the mixture are generated, and as the generated substances increase, a compression function can be realized. When the method is implemented, the area B can also be used₁And said region B₂The cavity is isolated, and the gas separation can be realized besides the compression function.

In embodiment 4 of the present invention, N electrochemical regions 9 can be selectively defined as the electrochemical region a₁To the electrochemical region A_nN of the regions B3 are defined as regions B₁To region B_nSaid electrochemical area A₁To the electrochemical region A_nComprising an outer power connection region, said region B₁To the region B_nComprising an external power connection region, N of said non-electron-charged particle conductors 4 being respectively defined as non-electron-charged particle conductors X₁To non-electronic charged particle conductor X_nN is 2 or more, electrochemical region A_yBy conduction of non-electronically charged particles X_yAnd region B_yHas a non-electronic conducting electrical relationship, y is any integer from 1 to N to form an electrochemical unit, and the electrochemical area A₁To the electrochemical region A_nIs provided in communication with the mixture introduction passage 10, the region B₁To the region B_nIs communicated with different separated product outlet channels. The method can be implemented by referring to the embodiment of example 4. Wherein N is selectively set to be 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 or more than 13, and N is equal to N. The non-electronic charged particle conductor X₁To the non-electron charged particle conductor X_nAt least two of the non-electron charged particle conductors are configured to conduct different non-electron charged particles.

In the embodiment 4 and its convertible embodiment, the mixture can be selectively set as a mixture of N substances or a mixture of N +1 or more substances, and when the mixture is N +1, one of the substances can stay in the cavity on the side of the electrochemical region 9, and can be further separated by providing a lead-out opening on the wall of the cavity on the side, as shown in fig. 4.1.

In practical implementation of example 4 and the embodiment of the present invention, which can be changed, the region B can be selectively selected according to the properties of the substance₁To the region B_nIs set as the electrochemical region.

As an alternative embodiment, the mixture introduced into the mixture introducing passage 10 in example 4 and its alternative embodiment of the present invention may further selectively include at least one of hydrogen, helium, oxygen or nitrogen.

In alternative embodiments, the non-electron charged particle conductor 4 according to the invention is one or more of a proton exchange membrane, a solid oxide electrolyte membrane or a liquid electrolyte.

In the specific implementation of all the aforementioned embodiments of the present invention, those skilled in the art will have an incentive to arrange a control switch at a necessary position, for example, to arrange a control switch on the high-pressure gas outlet channel 8.

The attached drawings of the invention are only schematic, and any technical scheme meeting the written description of the application belongs to the protection scope of the 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 the modifications should be considered as the protection scope of the present invention.

Claims

1. A compression device comprising an electrochemical region a (1), a region B (3) and a non-electronic charged particle conductor (4), characterized in that: said electrochemical area A (1) having a non-electronically conducting electrical relationship with said area B (3) via said non-electronically charged particle conductor (4), said electrochemical area A (1) comprising an external power connection area A (5), said area B (3) comprising an external power connection area B (6).

2. A compression device comprising an electrochemical area a (1), an electrochemical area B (2) and a non-electronic charged particle conductor (4), characterized in that: said electrochemical area A (1) having a non-electronically conducting electrical relationship with said electrochemical area B (2) via said non-electronically charged particle conductor (4), said electrochemical area A (1) comprising an external power connection area A (5), said electrochemical area B (2) comprising an external power connection area B (6).

3. The compression apparatus of claim 1, wherein: the electrochemical area A (1) is communicated with the low-pressure gas leading-in channel (7), and the area B (3) is communicated with the high-pressure gas leading-out channel (8).

4. A compression apparatus as claimed in claim 2, wherein: the electrochemical area A (1) is communicated with the low-pressure gas leading-in channel (7), and the electrochemical area B (2) is communicated with the high-pressure gas leading-out channel (8).

5. A compression device comprising an electrochemical region a (1), a region B (3) and a non-electronic charged particle conductor (4), characterized in that: the electrochemical area A (1) and the area B (3) have a non-electronic conducting electrical relationship through the non-electronic charged particle conductor (4), the electrochemical area A (1) comprises an outer power connection area A (5), the area B (3) comprises an outer power connection area B (6), the electrochemical area A (1) is communicated with a low-pressure gas introduction channel (7), the area B (3) is communicated with a high-pressure gas discharge channel (8), a system comprising the electrochemical area A (1), the area B (3), the non-electronic charged particle conductor (4), the low-pressure gas introduction channel (7) and the high-pressure gas discharge channel (8) is defined as a subsystem, gas channels of N subsystems are communicated in series and/or the outer power connection areas of N subsystems are connected in series, and N is more than or equal to 2.

6. A compression device comprising an electrochemical area a (1), an electrochemical area B (2) and a non-electronic charged particle conductor (4), characterized in that: the electrochemical area A (1) and the electrochemical area B (2) have a non-electronic conducting electrical relationship through the non-electronic charged particle conductor (4), the electrochemical area A (1) comprises an outer power connection area A (5), the electrochemical area B (2) comprises an outer power connection area B (6), the electrochemical area A (1) is communicated with a low-pressure gas introduction channel (7), the electrochemical area B (2) is communicated with a high-pressure gas discharge channel (8), a system comprising the electrochemical area A (1), the electrochemical area B (2), the non-electronic charged particle conductor (4), the low-pressure gas introduction channel (7) and the high-pressure gas discharge channel (8) is defined as a subsystem, gas channels of N subsystems are communicated in series and/or outer power connection areas of N subsystems are arranged in series, and N is more than or equal to 2.

7. A compression device as claimed in any one of claims 3 to 6, wherein: the gas in the low-pressure gas introduction passage (7) is a simple substance gas.

8. The compression apparatus of claim 7, wherein: the simple substance gas is hydrogen, helium, oxygen or nitrogen.

9. A compression device comprising an electrochemical region (9), a region B (3) and a non-electronic charged particle conductor (4), characterized in that: n of said electrochemical zones (9) being defined as electrochemical zones A, respectively₁To the electrochemical region A_nN of the regions B (3) are defined as regions B, respectively₁To region B_nSaid electrochemical area A₁To the electrochemical region A_nComprising an outer power connection region, said region B₁To the region B_nComprises an external power connection region, N non-electron charged particle conductors (4) are respectively defined as non-electron charged particle conductors X₁To non-electronic charged particle conductor X_nN is 2 or more, electrochemical region A_yBy conduction of non-electronically charged particles X_yAnd region B_yHas a non-electronic conducting electrical relationship, y is any integer from 1 to N to form an electrochemical unit, and the electrochemical area A₁To the electrochemical region A_nIs arranged in communication with the mixture introduction passage (10), the region B₁To the region B_nIs communicated with different separated product outlet channels.

10. A compression device comprising an electrochemical region (9) and a non-electronic charged particle conductor (4), characterized in that: n of said electrochemical zones (9) being defined as electrochemical zones A, respectively₁To the electrochemical region A_nN of said electrochemical zones (9) being defined by electricityChemical region B₁To the electrochemical region B_nSaid electrochemical area A₁To the electrochemical region A_nComprising an external power connection region, the electrochemical region B₁To the electrochemical region B_nComprises an external power connection region, N non-electron charged particle conductors (4) are respectively defined as non-electron charged particle conductors X₁To non-electronic charged particle conductor X_nN is 2 or more, electrochemical region A_yBy conduction of non-electronically charged particles X_yAnd an electrochemical region B_yHas a non-electronic conducting electrical relationship, y is any integer from 1 to N to form an electrochemical unit, and the electrochemical area A₁To the electrochemical region A_nIs arranged to communicate with the mixture introduction passage (10), and the electrochemical region B₁To the electrochemical region B_nIs communicated with different separated product outlet channels.