DE102022119436A1 - Electrode module for a redox flow cell and redox flow cell - Google Patents

Abstract

The invention relates to an electrode module (1, 1') for a redox flow cell (10), comprising a metallic electrode plate (2) and an electrically insulating frame (3) surrounding the electrode plate (2), the frame (3) having an outer circumference (3a) and at least one flow opening (3b), each of which is provided with a sealing structure (4) made of an elastically deformable plastic. The sealing structure (4) forms a plug-in or plug-in sealing element which is positively and releasably attached to the frame (3) and is U-shaped when viewed in cross section. The invention further relates to a redox flow cell (10).

Description

The invention relates to an electrode module for a redox flow cell, comprising a metallic electrode plate and an electrically insulating frame comprising the electrode plate, the frame having an outer circumference and at least one flow opening, each of which is provided with a sealing structure made of an elastically deformable plastic. The invention further relates to a redox flow cell.

Such electrode modules for use in redox flow cells and the structure of redox flow cells are already known.

A redox flow cell uses chemically stored energy to generate electrical energy via redox reactions, where electrolyte solutions used for energy storage flow through the redox flow cell. The electrolytes, which each flow through a half cell of the redox flow cell, are also referred to as catholyte and anolyte. Depending on the formation of a redox flow cell, catholyte, also known as posolyte, and anolyte, also known as negolyte, can be convertible into one another. In principle, a redox flow battery can be constructed from a large number of redox flow cells in a manner comparable to an accumulator. A fundamental advantage of a redox flow battery compared to an accumulator is that the capacity and electrical output of a redox flow battery can be scaled independently of each other, since the electrolyte solutions in the case of a redox flow battery are kept in tanks, the size of which depends on the geometry and Number of redox flow cells is independent.

A common feature of an electrochemical cell, as used in accumulators, and a redox flow cell is a membrane or ion exchange membrane, which is permeable in a defined manner to certain ions or molecules, but impermeable to electrons. Ions or molecules that penetrate the membrane of a redox flow cell, that is, migrate from one half-cell to the other half-cell, can donate or accept electrons at electrodes located in the half-cells, which represents oxidation or reduction. The electrodes can in particular be designed as walls of the half cells.

That's how it describes DE 10 2020 133 090 A1 an electrode plate in the form of a three-dimensionally structured electrode sheet. The electrode sheet is part of a flux plate with an electrically insulating frame that has opening cross sections and seals. These opening cross sections allow an electrolyte solution to flow through.

Applying sealing material to the frame and hardening it to form a seal that is integrally connected to the frame is time-consuming and leads to long throughput times in the production of a flow plate, also known as an electrode module.

It is the object of the invention to provide such an electrode module for a redox flow cell with an alternative sealing structure which enables faster production of the electrode module.

The object is achieved for the electrode module for use in a redox flow cell in that the electrode module comprises a metallic electrode plate and an electrically insulating frame comprising the electrode plate, the frame having an outer circumference and at least one flow opening, each with a sealing structure made of one elastically deformable plastic, and in that the sealing structure forms a plug-in or plug-in sealing element which is positively and releasably attached to the frame and is U-shaped in cross section.

The sealing structure is suitable for automatically positioning it on the frame and attaching it in the area of the peripheral edges of the frame or inserting it into existing flow openings. This simplifies the assembly process for the sealing structures and speeds up the production of an electrode module. For the automated assembly of the sealing structures, robots can be used that are suitable for attaching sealing structures to multiple positions on the frame at the same time.

The sealing structure is preferably designed in a ring shape. The ring is designed to be particularly closed. In such a case, the dimension of the sealing structure is adapted to a circumference of an opening in the frame or a circumference of the frame into which it is to be introduced or to which it is to be attached. Due to the elastic deformability of the sealing structure, it can be easily mounted on the frame by compressing or stretching, with the sealing structure springing back to its original shape after the deformation force has been removed.

The electrically insulating frame is preferably made of a plastic in the form of polypropylene (PP). Alternatively or additionally, the sealing structure is made of elastically deformable material Plastic is formed in the form of a thermoplastic elastomer (TPE). Products of the Thermoplast ^® K type from Kraiburg have proven particularly useful here.

The electrically insulating frame has a frame thickness in the range of 0.5 to 3 mm perpendicular to the electrode plate. This has the advantage that the automated attachment of a sealing structure to the frame can be carried out reliably. If the frame is made too thick, the sealing structure will be difficult to install. If the frame is made too thin, it has insufficient mechanical stability to automatically mount the sealing structure on it without damaging or distorting the frame.

The frame forms a frame edge on the outer circumference and in the area of the at least one flow opening, which is preferably covered by the sealing structure. More precisely, the connection between the two legs of a U-shaped slip-on or plug-in sealing element rests on this frame edge.

In particular, the sealing structure has a thickness in the range of 0.1 to 0.5 mm in the area of each frame edge. This ensures sufficient stability of the sealing structure during automated assembly on the frame.

An annular region adjacent to the frame edge on an upper side and an underside of the frame is preferably covered by the sealing structure. More precisely, the two legs of a U-shaped plug-in or plug-in sealing element rest on this top and bottom side. In particular, an annular sealing area with a width in the range of 0.5 to 2 mm is visible on the top or bottom of the frame, which snaps over the edge of the frame when the sealing structure is installed and the sealing structure snaps into place in the area of a flow opening, so that this can only be pulled out of the flow opening against the mounting direction with increased resistance.

The sealing structure has a thickness in the range of 0.1 mm to 0.5 mm in the area of the top and bottom of the frame. This enables good deformability of the sealing structure when inserting it into a flow opening and precise positioning on the frame, particularly when installing a plug-in sealing element, since no folded or folded areas can form on the sealing structure. But such dimensioning has also proven useful with a slip-on sealing element in order to push the legs of the U-shaped slip-on sealing element over the circumference of the frame.

In the case of a U-shaped slip-on sealing element, the attachment to the frame takes place in that the insides of the legs lie tightly against the top and bottom of the frame and the friction between the components counteracts a shift in position.

The sealing structure is preferably injection molded or extruded. This ensures cost-effective production of the sealing structure for large quantities.

A redox flow cell comprising at least two electrode modules according to the invention and at least one polymeric ion exchange membrane arranged between the two electrode modules has proven successful.

• 1 ein Elektrodenmodul in einer Draufsicht auf die Oberseite des Rahmens,
• 2 einen Schnitt II - II durch das Elektrodenmodul gemäß 1, und
• 3 eine Redox-Flusszelle in einer schematischen Darstellung.

The 1 until 3 An electrode module and a redox flow cell designed with it are intended to be explained as an example. This shows:

• 1 an electrode module in a top view of the top of the frame,
• 2 a section II - II through the electrode module 1 , and
• 3 a redox flow cell in a schematic representation.

1 shows an electrode module 1 for a redox flow cell 10 in a top view of the top 5 of an electrically insulating frame 3 made of plastic. The electrode module 1 comprises a metallic electrode plate 2 with a three-dimensional embossed structure 2a and the frame 3 encompassing the electrode plate 2. The frame 3 has an outer circumference 3a (see 2 ) and four flow openings 3b, each of which is provided with a sealing structure 4, 4 'made of an elastically deformable plastic. The sealing structure 4, 4 'forms a plug-in or plug-in sealing element which is positively and releasably attached to the frame 3 and is U-shaped when viewed in cross section, as shown in section II - II 2 recognizable. The frame thickness is indicated by RD and extends between the top 5 and the bottom 6 of the frame 3. In the area of the flow openings 3b, the frame 3 has frame edges 3c, which are covered by the respective sealing structure 4 in the form of a U-shaped insert sealing element which are inserted into the flow openings 3b and locked there due to the U-shape. In the area of the outer diameter 3a of the frame 3 there is also a frame edge 3c, which is covered by a circumferential sealing structure 4' in the form of a U-shaped slip-on sealing element.

3 shows a redox flow cell 10 or a redox flow battery with a redox flow cell 10 in a schematic representation lung. The redox flow cell 10 here comprises two electrode modules 1, 1 ', shown only schematically (for details see 1 and 2 ), a first reaction space 90a and a second reaction space 90b, each reaction space 90a, 90b being in contact with one of the electrode modules 1, 1'. The reaction spaces 90a, 90b are separated from one another by a polymeric ion exchange membrane 9. A liquid anolyte 91a is pumped from a tank 93a via a pump 92a into the first reaction space 90a and passed between the electrode module 1 and the membrane 9. A liquid catholyte 91b is pumped from a tank 93b via a pump 92b into the second reaction space 90b and passed between the electrode module 1 ' and the membrane 9. An ion exchange takes place across the membrane 9, whereby due to the redox reaction on the electrode plates 2 (compare 1 ) of the electrode modules 1, 1 'electrical energy is released.

The 3 is only intended to show schematically the functionality of a redox flow cell 10 with a membrane 9. However, structures with at least 10 or more membranes 9 are possible.

Reference symbol list

1, 1'

Electrode module

2

Electrode plate

2a

Embossed structure

3

Frame

3a

Outer circumference

3b

Flow opening

3c

frame edge

4, 4'

Sealing structure

5

Top

6

bottom

9

polymeric ion exchange membrane

10

Redox flow cell

90a, 90b

reaction space

91a

Anolyte

91b

catholyte

92a, 92b

pump

93a, 93b

tank

RD

Frame thickness

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102020133090 A1 [0005]

Claims (10)

Electrode module (1, 1') for a redox flow cell (10), comprising a metallic electrode plate (2) and an electrically insulating frame (3) surrounding the electrode plate (2), the frame (3) having an outer circumference (3a) and has at least one flow opening (3b), each of which is provided with a sealing structure (4) made of an elastically deformable plastic, characterized in that the sealing structure (4) is positively and releasably attached to the frame (3) and is U-shaped when viewed in cross section Slip-on or plug-in sealing element forms. Electrode module (1, 1 '). Claim 1 , characterized in that the sealing structure (4) is annular. Electrode module (1, 1 '). Claim 1 or 2 , characterized in that the frame is formed from a plastic in the form of polypropylene (PP) and/or that the sealing structure is formed from the elastically deformable plastic in the form of a thermoplastic elastomer (TPE). Electrode module (1, 1') according to one of the preceding claims, characterized in that the frame (3) perpendicular to the electrode plate (2) has a frame thickness (RD) in the range of 0.5 to 3.0 mm. Electrode module (1, 1') according to one of the preceding claims, characterized in that the frame (3) forms a frame edge (3c) on the outer circumference (3a) and in the area of the at least one flow opening (3b), which is separated from the sealing structure ( 4) is covered. Electrode module (1, 1 '). Claim 5 , characterized in that the sealing structure (4) in the area of each frame edge (3c) has a thickness in the range of 0.1 to 0.5 mm. Electrode module (1, 1') according to one of Claims 5 or 6 , characterized in that an annular area adjacent to the frame edge (3c) on an upper side (5) and a lower side (6) of the frame (3) is covered by the sealing structure (4). Electrode module (1). Claim 7 , characterized in that the sealing structure (4) in the area of the top (5) and the bottom (6) of the frame (3) each has a thickness in the range of 0.1 to 0.5 mm. Electrode module (1) according to one of the preceding claims, characterized in that the sealing structure (4) is injection molded or extruded. Redox flow cell (10) comprising at least two electrode modules (1, 1') according to one of Claims 1 until 9 and at least one polymeric ion exchange membrane (9) arranged between the two electrode modules (1, 1').

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