KR20200017815A - Generating electricity using the salinity gradient - Google Patents

Abstract

An embodiment of the present invention is to provide a salinity difference power generator which applies a stacked structure of an ion exchange membrane in a cylindrical role type to enhance assemblability and productivity of a salinity difference power generation unit, and improves an electrode structure to easily form a salinity difference power generation module and thus, enhance power generation efficiency of the salinity difference power generation unit. According to an embodiment of the present invention, the salinity difference power generator includes the salinity difference power generation unit which has a first solution and a second solution having different salt concentration each introduced thereinto through different flow paths to generate salinity difference power generation electricity. The salinity difference power generation unit includes: a main body unit which is long in a first direction that is a height direction and formed in a rounded shape in a second direction that is a circumferential direction; an electrode unit which contains a first electrode long in the first direction from a central part of the main body unit and a second electrode separated from the first electrode at a predetermined interval to be formed in a rounded shape along the second direction; and an ion exchange membrane unit which includes a cation exchange membrane and an anion exchange membrane stacked in a rounded shape along the second direction around the first electrode between the first electrode and the second electrode, and has a first flow path where the first solution is flowing and a second flow path where the second solution is flowing at a predetermined location to be partitioned each other from the first direction and the second direction.

Description

Salinity Power Generation Unit {GENERATING ELECTRICITY USING THE SALINITY GRADIENT}

The present invention relates to a saltwater generator apparatus.

Salinity gradient power generation is a system that recovers the salt concentration difference energy generated in the process of mixing two fluids having different concentrations (for example, seawater and fresh water) in the form of electrical energy. In particular, reverse electrodialysis (RED, Reverse Electrodialysis) is separated and moved through the cation exchange membrane and the anion exchange membrane, respectively, due to the concentration difference of the ionized salt contained in sea water and fresh water. At this time, a chemical potential difference is generated between the cation exchange membrane and the anion exchange membrane, and electrons are reduced by the redox reaction using the potential difference generated by the ion exchange membrane at the electrodes (positive and negative electrodes) positioned at both ends of the ion exchange membrane. Movement phenomenon occurs and generates electric energy.

As such, the reverse electrodialysis method is a power generation method that directly converts chemical energy generated as ions dissolved in sea water (salt water) into fresh water through an ion exchange membrane to electric energy, compared with conventional power generation methods such as wind and solar power. Therefore, there is almost no load variation and the power generation device has a utilization rate of 90% or more. However, in order for the reverse electrodialysis salinity generator to show the power generation performance at a small scale at the laboratory level, the assembly method of the existing unit salinity generator stack is very complicated and modular. There is a limit in maximizing efficiency and increasing capacity because it is not easily made.

An embodiment of the present invention is to apply the laminated structure of the ion exchange membrane in the form of a cylindrical roll to improve the assembly and productivity of the salinity difference generator portion, and improve the electrode structure to easily form the salinity difference generator module by It is to provide a salinity generator that can improve the power production efficiency.

The salinity difference generator according to an embodiment of the present invention includes a salinity difference generator for generating the salinity difference generation electricity by introducing the first solution and the second solution having different salt concentrations through different flow paths, respectively The power generation unit is spaced apart at a predetermined interval from the first electrode and the first electrode, which is formed in a shape that is long in the first direction in the height direction and rounded in the second circumferential direction, and is formed in the first direction at the center of the body part. And an electrode part including a second electrode formed in a round shape along a second direction, and a cation exchange membrane and an anion stacked in a round shape along a second direction with respect to the first electrode between the first electrode and the second electrode. A first flow path through which the first solution flows and a second flow path through which the second solution flows, in a first direction or in a second direction; Is Li include ion exchange film portion which is partitioned.

The body part supports the electrode part and the ion exchange membrane part, and is coupled to the first frame and the upper part of the first frame forming the main path of the first flow path and the second flow path, and forms a partial path of the first flow path and the second flow path. A first cover, a second cover coupled to a position corresponding to the first cover at a lower portion of the first frame, forming a second path of the first flow path and the second flow path, and an outer shape supporting the inner coupling of the first frame It may include a second frame formed with.

The first electrode may be formed in a cylindrical shape along the first direction and provided at an inner central portion of the first frame. It may further include an electrode case for protecting the first electrode, and a contact portion provided between the outer circumferential surface of the first electrode and the electrode case to increase the contact area with the third solution.

The second electrode may be formed in a disc shape having a curvature and disposed outside the ion exchange membrane portion at intervals from the first electrode. A fourth flow path may be formed at intervals on the outer circumferential surface of the second electrode, and may further include an electrode cover part connected to an outlet of the third flow path to guide the third solution flowing along the fourth flow path to flow out. have.

The first solution may be seawater, and the first solution may be a high concentration solution of at least 3.0 wt% salt. The second solution may be fresh water, and the second solution may be a low concentration solution of 0.1 wt% or less of the low concentration salt. The third solution may include one or more of a high concentration of saline and ferrocyanide (Fe (CN) 6] ⁴ -based solution or an electrolyte solution.

The ion exchange membrane portion may be rolled up and stacked in a roll form. It may further include an electrode spacer provided between the outer peripheral surface of the ion exchange membrane portion and the second electrode. And a sealing part provided in the ion exchange membrane part to seal portions other than the first flow path and the second flow path. It may further include a pollution prevention layer formed on the surface of the ion exchange membrane portion. The contaminant prevention layer may be formed on the surface of the anion exchange membrane. Spacers provided in the cation exchange membrane and the anion exchange membrane, respectively, may be formed integrally with each other to form a flow path between the first solution and the second solution while maintaining a gap with the adjacent exchange membrane. The spacer may be formed of a patterned ion exchange membrane having a flow path pattern on the surface of the cation exchange membrane and the anion exchange membrane. The ion exchange membrane portion may be provided with the cation exchange membrane and the anion exchange membrane integrally with the gasket. Gaskets may be in the form of adhesive tapes and may be fully sealed with adhesive. Here, the tape may include a paraffin film, a double-sided adhesive tape.

The first flow path may flow into the upper portion of the first direction, flow along the second direction, and flow out of the lower portion of the first direction. The first flow passage forms a storage space having an upper opening and a lower sealing portion in a first direction, the inflow storage channel for guiding the inflow of the first solution in the first direction, and connected to the inflow storage channel to be formed along the second direction. A first channel for guiding the inflow of the solution and a space separate from the inlet storage channel to form a storage space having a lower opening and a sealed upper portion in a first direction, the first channel being connected to the first channel And an outlet storage channel for guiding the outlet flow of the first solution along the direction.

The second flow path may flow into the upper portion of the first direction, flow along the second direction, and flow out to the lower portion of the first direction. Since the flow directions of the first solution and the second solution should be orthogonal to each other based on the point of meeting in the separator, the first solution flowing along the first flow path flows in the second direction in the separator and flows along the second flow path. The second solution may flow in the first direction. Such a flow relationship between the first solution and the second solution may also be applied to the case where the second solution flows in the first flow path and the first solution flows in the second flow path.

Meanwhile, the first flow path may flow into the upper portion of the first direction, flow along the second direction, and flow out of the upper portion of the first direction. The first flow passage forms a storage space having an upper opening and a lower sealing portion in a first direction, the inflow storage channel for guiding the inflow of the first solution in the first direction, and connected to the inflow storage channel to be formed along the second direction. 1 a first channel for guiding the inflow of the solution and a space separated from the inlet storage channel to form a storage space with an upper opening in the first direction and a sealed lower portion, the first channel being connected to the first channel And an outlet storage channel for guiding the outlet flow of the first solution along the direction.

It is easy to arrange, replace and modularize salinity power generation parts by improving the electrode structure of the salinity power generation part and the ion exchange membrane laminated structure used in salinity power generation device, so it is easy to maintain and improve the power production efficiency. have.

1 is a view showing a salinity generator according to a first embodiment of the present invention.
2 is an exploded perspective view illustrating the coupling relationship of FIG. 1.
3 is a diagram illustrating a relationship in which an ion exchange membrane part is stacked around a first electrode to form a first flow path and a second flow path.
4 is a view showing a contaminant prevention layer bonded to the anion exchange membrane.
5 is a diagram illustrating a coupling relationship between first electrodes.
FIG. 6 is a diagram illustrating a salinity generator according to a second embodiment of the present invention.
7 is an exploded perspective view illustrating the coupling relationship of FIG. 6.
8 is a diagram illustrating a salinity generator according to a third embodiment of the present invention.
9 is an exploded perspective view illustrating the coupling relationship of FIG. 8.
FIG. 10 is a diagram illustrating a salinity generator according to a fourth embodiment of the present invention.
11 is a view showing the charge-discharge relationship of the salinity difference generator according to a fourth embodiment of the present invention.
12 is a view showing a module coupling relationship of the saltwater generator apparatus according to the first embodiment of the present invention.
FIG. 13 is a diagram illustrating another module coupling relationship of the salt water generator according to the first embodiment of the present invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a,” “an,” and “the” include plural forms as well, unless the phrases clearly indicate the opposite. As used herein, the term "comprising" embodies a particular characteristic, region, integer, step, operation, element, and / or component, and other specific characteristics, region, integer, step, operation, element, component, and / or group. It does not exclude the presence or addition of.

Although not defined otherwise, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. Commonly defined terms used are additionally interpreted as having a meaning consistent with the related technical literature and the presently disclosed contents, and are not interpreted as ideal or very formal meaning unless defined.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

1 is a view showing a salinity generator according to a first embodiment of the present invention, Figure 2 is an exploded perspective view showing the coupling relationship of FIG. 3 is a view showing a relationship in which an ion exchange membrane part is stacked around a first electrode to form a first flow path and a second flow path, and FIG. 4 is a view illustrating a pollution prevention layer bonded to the anion exchange membrane. 5 is a diagram illustrating a coupling relationship between first electrodes.

1 to 5, in the salinity generator according to the first embodiment of the present invention, the first solution and the second solution having different salt concentrations are respectively introduced through different flow paths to generate the salinity difference electricity generation. It includes the salinity car power generation unit to produce, improves the assembly and stacking structure of the salinity car power generation unit used in the salinity car power generation device, so that it is easy to arrange, replace and modularize the salinity car power generation unit, and it is easy to maintain and improve the power production efficiency. can do. The salinity difference generator includes a body part, an electrode part, and an ion exchange membrane part 240, and is included in the second solution according to the salinity difference between the first solution flowing through the first flow path and the second solution flowing through the second flow path. The ionic material may selectively move the ion exchange membrane unit 240 to produce electricity.

The main body may be formed in a shape that is long in the first direction in the height direction and rounded in the second direction in the circumferential direction. The body part may include a first frame 100, a first cover 20, a second cover 30, and a second frame 10.

The first frame 100 supports the electrode part and the ion exchange membrane part 240, and may form a main path of the first flow path through which the first solution flows and the second flow path through which the second solution flows. have. The first flow path may flow into the upper portion of the first direction, flow along the second direction, and flow out of the lower portion of the first direction. The first flow path has an inflow hole 102 having a portion of the upper portion thereof opened along the first direction, and forms a storage space sealed at the bottom thereof, and guides the inflow of the first solution in the first direction to store the first solution introduced therein. A first channel having a first opening 241 connected to the inlet storage channel, the first opening 241 connected to the inlet storage channel, and guiding the inflow of the first solution along the second direction; A portion of the lower portion of the lower portion having an outlet hole opened along the direction to form a sealed space at the upper portion thereof, and connected to the first channel to guide the outlet flow of the first solution along the first direction. have. The second flow path may flow into the upper portion of the first direction through the second opening 242, flow along the first direction, and flow out of the lower portion of the first direction. Here, the first solution may be seawater, and the first solution may be a high concentration solution having a high concentration of salt of 3.0 wt% or more. The second solution may be fresh water, and the second solution may be a low concentration solution of 0.1 wt% or less of the low concentration salt. That is, the first solution may use a solution having a concentration of 0.1 wt% or less, and the second solution may use any solution having a concentration of 3.0 wt% or more. On the contrary, the first solution may use a solution having a concentration of 0.1 wt% or less, and the second solution may use any solution having a concentration of 3.0 wt% or more.

The first cover 20 may be coupled to the upper portion of the first frame 100 and form a partial path between the first flow path and the second flow path. Outside the first cover 20, the first solution inlet part 24 into which the first solution is introduced, the second solution inlet part 22 into which the second solution is introduced, and the electrode solution inlet part into which the electrode solution is introduced ( 26). Here, the electrode solution which is the third solution may be the first solution. The third solution may include at least one of a high concentration saline solution and a ferrocyanide ([Fe (CN) 6] ^4- ) based solution or an electrolyte solution.

Inside the first cover 20, the first solution inflow hole in which the first solution is introduced into the first flow path, the second solution inflow hole in which the second solution is introduced, and the electrode solution is introduced into the first cover 20. Solution inlet hole may be provided.

The second cover 30 may be coupled to a position corresponding to the first cover 20 at the lower portion of the first frame 100 and may form the remaining paths of the first flow path and the second flow path. Outside the second cover 30, the first solution outlet 34 through which the first solution flows out, the second solution outlet 32 through which the second solution flows out, and the electrode solution outlet through which the electrode solution flows out ( 36). Inside the second cover 30, the first solution outlet hole is guided to outflow the first solution to the outside, the second solution outlet hole is guided to outflow the second solution, and the electrode solution is guided to outflow Solution outlet holes may be provided.

The second frame 10 may be formed to have an outer shape that supports the inner coupling of the first frame 100. The second frame 10 has a shape in which an upper portion and a lower portion are opened, and side surfaces thereof are partially opened to protect the first frame 100. The second frame 10 may be assembled in a single or multiple combined structure for ease of assembly and automation along the length direction of the stack.

The electrode unit may include a first electrode 220, a second electrode 260, an electrode case 224, and a contact unit 226.

The first electrode 220 may be formed in a cylindrical shape extending in the first direction from the center of the main body portion to be provided at the inner center. That is, the first electrode 220 may be formed in a cylindrical shape along the first direction to be provided at the inner center of the first frame 100.

The second electrode 260 may be spaced apart from the first electrode 220 at predetermined intervals and formed in a round shape in the second direction.

The electrode case 224 may have a shape of protecting the first electrode 220 and may be formed in a cylindrical shape surrounding the first electrode 220 on the outside of the first electrode 220. The electrode case 224 may include an opening 224a extending along the first direction.

Considering that the first electrode 220 and the second electrode 260 are provided at the inner center and the outer side, the first electrode 220 and the second electrode 260 may be formed to maximize the structure of the first electrode 220 in order to balance the electrode area.

The contact part 226 may be provided between the outer circumferential surface of the first electrode 220 and the electrode case 224 to increase the contact area with the third solution flowing through the third flow path. The contact portion 226 increases the contact area with the third solution to secure the reaction area, and thus, the contact part 226 may have various shapes as long as the electrode area can be balanced between the first electrode 220 at the center and the second electrode 260 at the outside. Can be formed. The contact part 226 may be formed in a folded shape or a curved plate shape on the outer circumferential surface of the first electrode 220, and may be provided in a pin shape or a nautical structure. In addition, the first electrode 220 may be formed in a form or a mesh structure. And the contact portion 226 may be provided in plurality. For example, the contact portion 226 may include a first contact portion 226a provided on the outside of the first electrode 220 and a second contact portion 226b provided on the outside of the first contact portion 226a. . By providing a plurality of contact portions 226, the contact area with the first solution can be further increased. In addition, the first electrode 220 may be integrally formed with the contact portion 226, and thus may be configured to be detachable from the first electrode 220, thereby facilitating the cleaning of the first electrode 220. have.

The second electrode 260 may be formed in a disc shape having a curvature and may be provided outside the ion exchange membrane part 240 at intervals from the first electrode 220. An electrode cover part may be formed on the outer circumferential surface of the second electrode 260 at intervals to guide the third solution, which is connected to the outlet of the third flow path and flows in and flows out along the fourth flow path. 230) may be further included. On the outside of the electrode cover part 230, an electrode solution flowing out of the electrode solution outlet 36 is provided at a position corresponding to the electrode solution inlet 232 and the electrode solution inlet 232 that flow into the fourth flow path. The electrode solution flowing along the flow path may include an electrode solution outlet 234 that flows out. The electrode cover part 230 may be coupled to the second frame 10. The electrode cover part 230 may be formed in one piece, and may be formed in a form that is divided into a plurality and coupled to the second frame 10 as necessary.

The ion exchange membrane unit 240 may include a cation exchange membrane 2410 (CEM) stacked between the first electrode 220 and the second electrode 260 in a round shape in a second direction about the first electrode 220. A plurality of separator layers including a Cation Exchange Membrane) and an anion exchange membrane 2401 (AEM; Anion Exchange Membrane) may be included. In addition, the ion exchange membrane unit 240 may be provided in the cation exchange membrane 2410 and the anion exchange membrane 2401, respectively, and a spacer may be formed as a flow path between the first and second solutions while maintaining a gap with the adjacent exchange membrane. That is, the separator layer in the ion exchange membrane unit 240 may include an anion exchange membrane 2401, a first solution spacer 2402, a cation exchange membrane 2410, and a second solution spacer 2412. Here, the anion exchange membrane 2401 and the cation exchange membrane 2410 coupled with the first solution spacer 2402 therebetween may be provided in reverse order. That is, the separator layer may be provided in the order of the anion exchange membrane 2401, the first solution spacer 2402, the cation exchange membrane 2410, and the second solution spacer 2412, and the cation exchange membrane 2410 and the first solution spacer. 2402, anion exchange membrane 2401, and second solution spacers 2412. The separator layer is a combination of a cation exchange membrane 2410, a first solution spacer 2402, a cation exchange membrane 2410, and a second solution spacer 2412, and may be provided in a plurality of sets. In this case, the separator layer is formed by combining a combination of the anion exchange membrane 2401, the first solution spacer 2402, the cation exchange membrane 2410, and the second solution spacer 2412 in a spiral manner, The cylindrical stacks can be formed while laminating in sets. The first solution spacer 2402 is provided between the anion exchange membrane 2401 and the cation exchange membrane 2410, and both side walls of the first opening 241, which is a passage through which the first solution flows, may be provided as a gasket or an adhesive layer. The second solution spacer 2412 is provided between the anion exchange membrane 2401 and the cation exchange membrane 2410, and both side walls of the first opening 241, which is a passage through which the first solution flows, may be provided as a gasket or an adhesive layer. Accordingly, in the state where the cylindrical stack is formed, the first solution flows through the first opening 241 along the second direction, which is the circumferential direction of the cylindrical stack, and the second solution flows through the second opening 242 in the height direction of the cylindrical stack. Can flow along the first direction. As described above, the cation exchange membrane 2410 and the anion exchange membrane 2401 in the ion exchange membrane unit 240 may be provided integrally with the gasket. In addition, the spacer may be formed as a patterned ion exchange membrane having a flow path pattern on the surface of the cation exchange membrane 2410 and the anion exchange membrane 2401. Therefore, the ion exchange membrane unit 240 may be implemented both by adding a spacer to the flat membrane-shaped ion exchange membrane and when using a patterned ion exchange membrane alone.

The ion exchange membrane part 240 may be formed in a shape having one cut surface at a predetermined position in a rolled state in a roll shape. When the cut surface of the ion exchange membrane portion 240 is minimized, inconvenience of assembly process due to cutting and complexity of the structure may be minimized, thereby securing stack assembly productivity. The first flow path in which the first solution flows and the second flow path in which the second solution flows may be partitioned apart from each other in the first direction or the second direction. The ion exchange membrane unit 240 may use a very thin hydrophilic porous film having a non-ion conductivity when the cation exchange membrane 2410 and the anion exchange membrane 2401 are stacked as a membrane contamination reduction layer or a pollution prevention layer 2401a1 or 2401a2 of the separator. have. In addition, by using a porous support, ions can diffuse toward the ion exchange membrane and reduce the deposition of anionic contaminants. And even if contaminants are stacked, they may fall off well after physical treatment.

In addition, when a support having a structure in which capillary phenomenon is generated in addition to the spacer or the pattern is used, a small power pack capable of continuously charging and discharging without an external pump may be configured. In addition, by using a porous support, ions can diffuse toward the ion exchange membrane and reduce the deposition of anionic contaminants. And even if contaminants are stacked, they may fall off well after physical treatment. Here, the support may comprise paper, such as tissue paper, hydrophilic fabrics, nonwoven composites. For example, a capillary phenomenon can be applied to a rechargeable cylindrical stack since a support capable of supplying a solution without the help of a pump can be used instead of a general spacer.

The electrode spacer 250 may be further provided between the outer circumferential surface of the ion exchange membrane unit 240 and the second electrode 260. The device may further include a sealing part provided in the ion exchange membrane part 240 to seal portions other than the first flow path and the second flow path. The sealing part may include a method of bonding the cut surface of the ion exchange membrane part 240 to seal a portion other than the first flow path and the second flow path so that a corresponding solution flows only through each flow path. Therefore, the sealing part is also applicable to the fourth flow path. By applying the sealing part, the first solution, the second solution, and the like are maintained in a sealing state, respectively, and can move through the corresponding flow path in the main body part. In addition, the ion exchange membrane unit 240 may further include a contaminant prevention layer 2401a1 and 2401a2 formed on the surface of the ion exchange membrane. The contaminant prevention layers 2401a1 and 2401a2 may be formed of a porous support. The pollutant prevention layers 2401a1 and 2401a2 may use a porous support that is not impregnated with an ion exchange conductive material. In the case of the contaminant preventing layers 2401a1 and 2401a2, they may be added during the assembly of the separator, or may be integrally formed in the production process of the separator. The contaminant prevention layers 2401a1 and 2401a2 may be formed of a hydrophilic porous substrate or a coating layer having a pore size of 10 to 50 nm and a thickness of less than 1 μm. In order to minimize the impact on the membrane performance, the thickness of the contaminant preventing layers 2401a1 and 2401a2 is advantageous as it is minimized. Contaminant prevention layers 2401a1 and 2401a2 may be formed on the surface of the anion exchange membrane 2401. By forming the pollutant preventing layers 2401a1 and 2401a2 that prevent adhesion of contaminants on the surface of the anion exchange membrane 2401 as a porous support, ions can be diffused toward the ion exchange membrane and the stack of anionic contaminants can be reduced. And even if some of the contaminants are laminated, they may fall off well after physical treatment. Therefore, a greater effect can be obtained in the prevention of the surface contamination of the anion exchange membrane 2401 and in the post-treatment process. And it is possible to improve the overall ion exchange reaction of the ion exchange membrane and further increase the power generation efficiency of the salinity difference generator. Conventionally, there was a possibility of stacking a large number of anionic contaminants according to anion exchange characteristics, and once laminated, there was a problem that the ion bonds did not fall off well even after treatment.

As described above, the salinity difference generator according to the first embodiment of the present invention improves a plurality of ion separation membranes into a spiral stacked structure by using a pair of a cation exchange membrane 2410 and an anion exchange membrane 2401. In a cylindrical salinity generator, cross-flow is possible through a flow path corresponding to a first solution or a second solution along a plurality of ion exchange membranes. And by forming the salinity generator in the form of a cylindrical stack is not only very advantageous for modularization for large capacity, but also has the advantage of very simple replacement and regeneration. In addition, since the assembly of the salinity generator unit is simple, the production cost can be lowered. In addition, the post-processing during the operation of the cylindrical stack is easy to facilitate the treatment of contaminants and to reduce the energy used. Here, the post-treatment may use a physical method of air sparging. And the post-treatment may use a cleaning (CIP; Cleaning In Place) using diluted sodium hydroxide (NaOH), sodium carbonate (Na2CO3) or acid in a chemical manner. The post-treatment can also be used in a combination of physical and chemical methods.

6 is a view showing a salinity generator according to a second embodiment of the present invention, Figure 7 is an exploded perspective view showing the coupling relationship of FIG. 6 and 7, the salinity generator according to the second embodiment of the present invention forms a salinity generator in the form of a cylindrical stack like the salinity generator according to the first embodiment of the present invention. However, there is a difference in that the flow path of the first solution and the flow path of the electrode solution are differently formed in the structure having one cut surface of the ion exchange membrane portion 240a.

First, the first cover 20a may be coupled to an upper portion of the first frame 100a and form a partial path between the first flow path and the second flow path. Outside the first cover 20a, the first solution inlet 24a1 through which the first solution flows in, the first solution outlet 24a2 through which the first solution flows out, and the second solution inlet through which the second solution flows in 22a, and an electrode solution inlet 26a into which an electrode solution as a third solution flows. Here, the electrode solution inlet 26a may be formed as a first inlet 26a1 and a second inlet 26a2. The first inlet 26a1 may include the first inlet 26a11, and the second inlet 26a2 may include the second inlet 26a21. The first inlet part 26a1 may be connected to the electrode solution inlet 232a of the electrode cover part 230a. Accordingly, the electrode solution may be supplied to the first inlet 26a1 and the electrode solution inlet 232a, respectively.

The second cover 30a is coupled to a position corresponding to the first cover 20a at a lower portion of the first frame 100a, and a second solution outlet portion through which the second solution flows out of the second cover 30a. And may include 32a.

The first flow path of the salinity generator according to the second embodiment of the present invention may flow into the upper portion of the first direction, flow along the second direction, and flow out of the upper portion of the first direction. The first flow path has an inflow hole 102a1 having a portion of the upper portion thereof opened along the first direction, and forms a storage space sealed at the bottom thereof. The inflow storage channel and the inflow storage channel guide the inflow of the first solution in the first direction. A first channel connected to the first channel for guiding the inflow of the first solution in a second direction, and an outlet hole 102a2 provided in a space separated from the inlet storage channel and having a portion of an upper portion thereof opened in the first direction; The lower portion forms a sealed storage space, and may include an outlet storage channel connected to the first channel to guide the outlet flow of the first solution along the first direction.

As described above, the salinity difference generator according to the second embodiment of the present invention changes the outflow structure of the electrode solution flowing into the first electrode as the internal electrode and the outflow structure of the first solution to connect the plurality of stacks to the module. When configuring, it is easy to configure the connection line can be advantageous to the modular process control of the overall salinity generator.

FIG. 8 is a diagram illustrating a salinity generator according to a third embodiment of the present invention, and FIG. 9 is an exploded perspective view illustrating the coupling relationship of FIG. 8. 8 and 9, the salinity difference generator according to the third embodiment of the present invention forms the salinity difference generator in the form of a cylindrical stack like the salinity difference generator according to the first embodiment of the present invention. However, there is a difference in that the flow path of the first solution and the electrode solution flow path are differently formed in the structure having two cut surfaces of the ion exchange membrane part 240b. The cut surfaces of the ion exchange membrane portion 240b may be provided at positions facing each other. In addition, the second electrodes 260b1 and 260b2, the electrode spacers 250b1 and 250b2, and the electrode cover parts 230b1 and 230b2 are respectively divided into two, corresponding to the structure having two cut surfaces of the ion exchange membrane part 240b. There is also a difference. The second electrodes 260b1 and 260b2 may include a twenty-first electrode 260b1 and a twenty-second electrode 260b2. The electrode spacers 250b1 and 250b2 may include a first electrode spacer 250b1 and a second electrode spacer 250b2. The electrode cover parts 230b1 and 230b2 may include a first electrode cover part 230b1 and a second electrode cover part 230b2.

First, the first cover 20b may be coupled to an upper portion of the first frame 100b and form a partial path between the first flow path and the second flow path. Outside the first cover 20b, the first solution inlet part 24b into which the first solution is introduced, the second solution inlet part 22b into which the second solution is introduced, and the electrode into which the third electrode solution is introduced Solution inlet 26b.

The second cover 30b is coupled to a position corresponding to the first cover 20b at the lower portion of the first frame 100b, and the first solution outlet part in which the first solution flows out of the second cover 30b. 34b, a second solution outlet 32b through which the second solution flows out, and an electrode solution outlet 36b through which the electrode solution flows out.

On the outside of the first electrode cover part 230b1, the electrode solution flowing out of the electrode solution outlet 36b corresponds to the first electrode solution inlet 232b1 and the first electrode solution inlet 232b1, which flow into the fourth flow path. It may include a first electrode solution outlet (234b1) is provided at a position to flow along the fourth flow path flows out to the outside. Outside the second electrode cover part 230b2, the electrode solution flowing out of the electrode solution outlet 36b corresponds to the second electrode solution inlet 232b2 and the second electrode solution inlet 232b2, which flow into the fourth flow path. It may include a second electrode solution outlet 234b2 which is provided at a position and flows along the fourth flow path to the outside. That is, the electrode solution inlet may be formed as a first inlet and a second inlet. The electrode solution outlet may be formed as a first outlet and a second outlet. The first inlet and the second inlet may be connected to the electrode solution outlet 36b of the second cover 30b, respectively. Therefore, the electrode solution may be respectively supplied to the first inlet and the second inlet through the electrode solution outlet 36b.

The first flow path of the salinity generator according to the third embodiment of the present invention may flow into the upper portion of the first direction, flow along the second direction, and flow out of the lower portion of the first direction. However, the length of the first solution flowing along the second direction may be shortened. The first flow path has an inflow hole 102b having a portion of the upper portion thereof opened along the first direction, and forms a storage space sealed at the bottom thereof. The inflow storage channel and the inflow storage channel guide the inflow of the first solution in the first direction. A first channel connected to the first channel for guiding the inflow of the first solution along the second direction, and in a space separate from the inflow storage channel, the outlet portion having a portion of the lower portion opened along the first direction and sealed at the top thereof. And an outlet storage channel connected to the first channel to guide the outlet flow of the first solution along the first direction. Here, the cut surface of the ion exchange membrane portion may be divided into a first cut surface, a second cut surface. The inflow storage channel and the outflow storage channel may be provided at positions opposite to each other in correspondence with the first and second cut surfaces of the ion exchange membrane portion, respectively. That is, the inlet storage channel may be provided on the first cut surface, and the outflow storage channel may be provided on the second cut surface.

As described above, in the salinity difference generator according to the third embodiment of the present invention, the salinity difference is changed by changing the outflow structure of the first solution and the outflow structure of the electrode solution flowing into the second electrodes 260b1 and 260b2 which are external electrodes. The power generation performance of the power generator can be improved. As the cutting surface of the ion exchange membrane portion 240b increases, the assembly process may be complicated. However, when the thickness of the ion exchange membrane is increased, the moving distance of the first solution increases, and the performance decreases due to the salinity difference with the second solution, and the concentration polarization increases. The phenomenon may be intensified. Therefore, as the thickness of the ion-exchange membrane is increased, two cases in which the cut surface of the ion-exchange membrane portion 240b is more than one is advantageous for improving the power generation performance of the salinity generator.

FIG. 10 is a diagram illustrating a salinity generator according to a fourth embodiment of the present invention, and FIG. 11 is a diagram illustrating a charge / discharge relationship of the salinity generator according to a fourth embodiment of the present invention. 10 and 11, the salinity generator according to the fourth embodiment of the present invention forms a salinity difference generator in the form of a cylindrical stack like the salinity generator according to the first embodiment of the present invention. However, in the structure having two cut surfaces of the ion exchange membrane portion 240c, the third flow path and the fourth flow path direction of the electrode solution which is the second flow path and the third solution of the second solution are formed in the same direction in the first direction, so that the salt filling is performed. It can be done easily. And the flow path of the first solution has a difference configured to facilitate the ion salinity difference and the electrode reaction as in the conventional. The cut surfaces of the ion exchange membrane portion 240c may be provided at positions facing each other. In addition, the second electrode 260c, the electrode spacer, and the electrode cover part are formed in two parts and the shape of the second electrode 260c is formed differently corresponding to the structure having two cut surfaces of the ion exchange membrane part 240c. There is also a difference in the form of a compact charging type.

First, the first cover 20c may be coupled to an upper portion of the first frame 100c and may form some paths of the first flow passage, the second flow passage, the third flow passage, and the fourth flow passage. The outer side of the first cover 20c may include a first solution inlet 24c into which the first solution is introduced, and an electrode solution inlet 26c into which the third electrode solution is introduced.

The second cover 30c is coupled to a position corresponding to the first cover 20c at the lower portion of the first frame 100c, and the first solution outlet part through which the first solution flows out of the second cover 30c. 34c).

The first flow path of the salinity generator according to the third embodiment of the present invention may flow into the upper portion of the first direction, flow along the second direction, and flow out of the lower portion of the first direction. However, the length of the first solution flowing along the second direction may be shortened. The first flow path has an inflow hole 102c having a portion of the upper portion thereof opened along the first direction, and forms a storage space sealed at the bottom thereof. The inflow storage channel and the inflow storage channel guide the inflow of the first solution in the first direction. A first channel connected to the first channel for guiding the inflow of the first solution in a second direction, and in a space separate from the inlet storage channel, the outlet portion having a portion of the lower portion opened in the first direction and sealed at the upper portion thereof. And an outlet storage channel connected to the first channel to guide the outlet flow of the first solution along the first direction. Here, the cut surface of the ion exchange membrane portion 240c may be divided into a first cut surface and a second cut surface. In addition, the inflow storage channel and the outflow storage channel may be provided at positions facing each other corresponding to the first and second cut surfaces of the ion exchange membrane portion 240c, respectively. That is, the inlet storage channel may be provided on the first cut surface, and the outflow storage channel may be provided on the second cut surface.

As described above, the salinity difference generator according to the fourth embodiment of the present invention is formed into a small power pack capable of charging and discharging the salinity difference generator by changing the shape of the inflow and outflow structure of the first solution and the second electrode 260c. can do. In order to form a rechargeable cylindrical stack, a flow path may be formed using a capillary phenomenon inducing support that may use a capillary phenomenon instead of a spacer in the ion exchange membrane part 240c. For example, it is possible to implement a flow rate supply by capillary action without the aid of a pump by capillary action, such as a tissue tissue. In addition, the shape of the second electrode 260c which is the external electrode may be differently formed. On the other hand, the first cover 20c which is the upper cover can be easily opened and closed. Salt filling and separation of the first solution may be separately provided through the first cover 20c. Through the second cover 30c which is the lower cover, only the first solution may be discharged.

By forming the salt cell car generator according to the fourth embodiment of the present invention as a rechargeable cylindrical stack, it is possible to repeatedly charge and discharge the salt charge and the salt discharge to produce electricity. In addition, the electrode solution, which is the third solution, may be designed to have a separator stack of 2.5V or more in order to induce a water reaction when using a low concentration solution. And salt solution can be used. In addition, for the implementation of the continuous charge / discharge system according to the fourth embodiment of the present invention, the solution supplied to the first flow path uses a low concentration solution, and the second flow path is supplied to the second flow path, the third flow path, and the fourth flow path. The third solution used as the solution and the electrode solution may use a high concentration of salt solution.

12 is a view showing a module coupling relationship of the salinity generator according to the first embodiment of the present invention. Referring to FIG. 12, a module of a salinity generator may be formed by connecting a plurality of cylindrical stacks having two cutting surfaces and connecting individual cylindrical stacks with a connecting line of the first solution and a connecting line of the second solution. .

FIG. 13 is a view showing another module coupling relationship of the salinity generator according to the first embodiment of the present invention. Referring to FIG. 13, in a plurality of cylindrical stacks having two cutting surfaces, the main body layer including the ion exchange membrane part, the upper solution inlet layer, and the lower solution outlet layer based on the main body layer are separately stacked. It may be formed in the form. In addition, the modules of the salinity generator can be formed by connecting the individual cylindrical stacks provided in the main body layer through the connection line of the first solution, the connection line of the second solution, and the connection line of the electrode solution. As described above, by modularizing the salinity generator, it is possible to increase the power generation capacity while minimizing the connecting parts required to connect each individual cylindrical stack, thereby miniaturizing the salinity generator system and securing the economics of the module. .

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims, the detailed description of the invention, and the accompanying drawings. Naturally, it is within the scope of the present invention.

20; First cover 30; Second cover
220; First electrode 230; Electrode cover
240; Ion exchange membrane section 250; Electrode spacer
260; Second electrode

Claims (21)

A first solution and a second solution having different salt concentrations are introduced through different flow paths, respectively, to produce a salinity difference power generation unit;
The salinity generation unit
A main body formed in a shape that is long in the first direction in the height direction and rounded in the second circumferential direction;
An electrode part including a first electrode formed to be elongated in the first direction at a central portion of the main body part and a second electrode spaced at a predetermined interval from the first electrode and formed in a round shape in the second direction; and
And a cation exchange membrane and an anion exchange membrane stacked in a round shape along the second direction with respect to the first electrode between the first electrode and the second electrode, wherein the first solution flows at a predetermined position. An ion exchange membrane part in which one flow path and a second flow path through which the second solution flows are isolated from each other in the first direction or the second direction.
Salinity generator comprising a. In claim 1,
The main body portion
A first frame supporting the electrode part and the ion exchange membrane part and forming a main path between the first flow path and the second flow path,
A first cover coupled to an upper portion of the first frame and forming a partial path between the first flow path and the second flow path,
A second cover coupled to a position corresponding to the first cover at a lower portion of the first frame and forming a remaining path between the first flow path and the second flow path, and
A second frame having an outer shape for supporting an inner coupling of the first frame
Salinity generator comprising a. In claim 2,
The first electrode is formed in a cylindrical shape along the first direction is provided in the inner central portion of the first frame, the salinity generator device for forming a third flow path for the third solution flows. In claim 3,
An electrode case for protecting the first electrode, and
And a contact portion provided between an outer circumferential surface of the first electrode and the electrode case to increase a contact area with the third solution. In claim 3,
And the second electrode is formed in a disc shape having a curvature and is provided outside the ion exchange membrane portion at intervals from the first electrode. In claim 5,
A fourth flow path is formed on the outer circumferential surface of the second electrode at intervals, and an electrode cover part which is connected to the outlet of the third flow path and guides the third solution to flow in the fourth flow path flows out to the outside. Salinity generator further comprising. In claim 1,
The first solution is a salinity difference generator is a high concentration solution of high concentration salt 3.0wt% or more. In claim 1,
The second solution is a salinity difference generator is a low concentration of less than 0.1wt% salt concentration. In claim 3,
The third solution is a saltwater difference generator device. In claim 3,
The third solution is a salinity difference generator comprising at least one of a high concentration of saline, ferrocyanide-based solutions or electrolyte solutions. In claim 1,
The ion exchange membrane unit of the salinity difference generator is wound in a roll form stacked. In claim 11,
And a electrode spacer provided between the outer circumferential surface of the ion exchange membrane portion and the second electrode. In claim 12,
And a sealing part provided in the ion exchange membrane part to seal portions other than the first flow path and the second flow path. In claim 13,
Salinity difference generator further comprising a pollution prevention layer formed on the surface of the ion exchange membrane portion. The method of claim 14,
And a spacer which is provided in the cation exchange membrane and the anion exchange membrane, respectively, and maintains an interval between neighboring exchange membranes and is integrally formed with a spacer that is a flow path between the first solution and the second solution. The method of claim 15,
The spacer
Salinity difference generator is formed of a patterned ion exchange membrane having a flow path pattern on the cation exchange membrane and the anion exchange membrane surface. In claim 1,
And the first flow path flows in an upper portion of the first direction and flows along the second direction, and then flows out of the lower portion of the first direction. The method of claim 17,
The first flow path is
An inlet storage channel forming a storage space in which an upper portion is opened and a lower portion is sealed along the first direction, and guides the inflow of the first solution in the first direction,
A first channel connected to the inlet storage channel to guide the inlet flow of the first solution along the second direction, and
It is provided in a space isolated from the inlet storage channel to form a storage space is opened in the first direction and sealed in the upper direction, the outlet of the first solution connected to the first channel in the first direction Outflow storage channel to guide flow
Salinity generator comprising a. In claim 1,
And the second flow path flows in the upper portion of the first direction and flows along the first direction, and then flows out of the lower portion of the first direction. In claim 1,
And the first flow path flows in an upper portion of the first direction and flows along the second direction, and then flows out of the upper portion of the first direction. The method of claim 20,
The first flow path is
An inlet storage channel forming a storage space in which an upper portion is opened and a lower portion is sealed along the first direction, and guides the inflow of the first solution in the first direction,
A first channel connected to the inlet storage channel to guide the inlet flow of the first solution along the second direction, and
It is provided in a space isolated from the inlet storage channel to form a storage space is opened in the first direction and sealed in the lower portion, the outlet of the first solution connected to the first channel in the first direction Outflow storage channel to guide flow
Salinity generator comprising a.

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