CN112467162A - Bipolar plate, bipolar plate processing device and bipolar plate preparation method - Google Patents

Abstract

The invention provides a bipolar plate, a bipolar plate processing device and a bipolar plate preparation method, wherein the bipolar plate comprises a bipolar plate body and a bipolar plate auxiliary layer, and the resistivity of the bipolar plate auxiliary layer is smaller than that of the bipolar plate body; the bipolar plate body comprises a first surface of the bipolar plate body and a second surface of the bipolar plate body correspondingly arranged; the bipolar plate auxiliary layer at least comprises one of a bipolar plate first auxiliary layer positioned on the first surface of the bipolar plate body and a bipolar plate second auxiliary layer positioned on the second surface of the bipolar plate body. The bipolar plate processing device comprises a flat plate hot press and an auxiliary clamp; the auxiliary clamp comprises an upper flat plate, a lower flat plate and a clamping component, and the bipolar plate is fixed between the upper flat plate and the lower flat plate through the clamping component. The invention combines the bipolar plate body and the auxiliary layer of the bipolar plate, reduces the contact resistance of the bipolar plate and the electrode, increases the effective conductive area, reduces the deformation degree of the bipolar plate in the hot pressing process, improves the product quality and improves the electrical property of the energy storage system.

Description

Bipolar plate, bipolar plate processing device and bipolar plate preparation method

Technical Field

The invention belongs to the field of electrochemical energy storage, and relates to a bipolar plate, a bipolar plate processing device and a bipolar plate preparation method.

Background

With the increasing consumption of fossil energy and the increasing attention of human beings on environmental protection, new energy power generation technologies such as wind and light are gradually popularized, and in order to solve the fluctuation of power generation of energy such as wind and light, a solution approved by the market is provided for a large-scale clean energy power plant with an energy storage device of a certain scale.

The existing energy storage system mainly comprises lithium battery energy storage, lead-acid energy storage, sodium-sulfur battery energy storage, all-vanadium redox flow battery energy storage and the like. The lithium battery energy storage and the sodium-sulfur battery energy storage are difficult to popularize due to potential safety hazards; lead-acid energy storage is difficult to popularize due to low efficiency and short service life; the all-vanadium redox flow battery has the advantages of special performance, such as incomparable safety, ultra-long service life, high energy conversion efficiency and the like, particularly suitable for large-scale energy storage, and becomes one of the first-choice technologies of chemical energy storage.

The bipolar plate is a main element of the power assembly of the all-vanadium redox flow battery, and is in contact with an electrode to form a current channel when the battery stores and discharges energy. Thus, the resistance of the bipolar plate and its contact resistance with the electrode are important factors affecting the energy storage efficiency of the energy storage system. At present, most of the production processes of bipolar plates adopt a composite bipolar plate prepared by blending, extruding and molding a non-conductive material and a conductive material, and the contact surface of the bipolar plate and an electrode has the non-conductive material, so that the contact resistance of the bipolar plate and the electrode is higher, and the electrical property of an energy storage system is greatly influenced.

Therefore, the bipolar plate processing device and the bipolar plate preparation method are provided, so that the contact resistance between the bipolar plate and an electrode is effectively reduced, and the electrical property of an energy storage system is improved, which is really necessary.

Disclosure of Invention

In view of the above-mentioned shortcomings of the prior art, the present invention provides a bipolar plate, a bipolar plate processing apparatus and a bipolar plate manufacturing method, which are used to solve a series of energy storage problems of the bipolar plate in the prior art.

To achieve the above and other related objects, the present invention provides a bipolar plate comprising:

the bipolar plate body comprises a first surface of the bipolar plate body and a second surface of the bipolar plate body correspondingly arranged;

the bipolar plate auxiliary layer has a lower resistivity than the bipolar plate body, and at least one of a first auxiliary layer of the bipolar plate on a first surface of the bipolar plate body and a second auxiliary layer of the bipolar plate on a second surface of the bipolar plate body.

Optionally, the bipolar plate body comprises an electrically conductive composite bipolar plate.

Optionally, the bipolar plate body comprises an electrically conductive plastic and the bipolar plate sublayer comprises graphite paper.

Optionally, the bipolar plate auxiliary layer covers the bipolar plate body or the bipolar plate auxiliary layer exposes a surface edge region of the bipolar plate body.

Optionally, the bipolar plate has a central symmetrical structure.

The invention provides a bipolar plate processing device, comprising:

a flat plate hot press;

the auxiliary clamp comprises an upper flat plate, a lower flat plate and a clamping component, and the bipolar plate is fixed between the upper flat plate and the lower flat plate through the clamping component.

Optionally, the upper plate comprises a metal upper plate and the lower plate comprises a metal lower plate.

Optionally, the upper and lower platens have surface edge regions with gripping member mounting areas that extend beyond the upper and lower dies of the flat press.

The invention provides a preparation method of a bipolar plate, which comprises the following steps:

providing a bipolar plate body, wherein the bipolar plate body comprises a first surface of the bipolar plate body and a second surface of the bipolar plate body which is correspondingly arranged; providing a bipolar plate auxiliary layer having a resistivity less than the bipolar plate body; providing a bipolar plate processing device, wherein the bipolar plate processing device comprises a flat plate hot press and an auxiliary clamp, and the auxiliary clamp comprises an upper flat plate, a lower flat plate and a clamping component;

the bipolar plate body and the bipolar plate auxiliary layer are arranged in the auxiliary clamp, and the bipolar plate body and the bipolar plate auxiliary layer are fixed between the upper flat plate and the lower flat plate through the clamping part;

acting on the auxiliary clamp through the flat hot press by adopting a hot pressing process;

and after the hot pressing is finished, taking out the auxiliary clamp, cooling to room temperature, opening the auxiliary clamp, and taking out the machined bipolar plate.

Optionally, the heating temperature range of the hot pressing process includes 20 ℃ to 200 ℃, and the pressure range includes 1MPa to 15 MPa.

Optionally, the bipolar plate auxiliary layer comprises at least one of a bipolar plate first auxiliary layer on the first surface of the bipolar plate body and a bipolar plate second auxiliary layer on the second surface of the bipolar plate body.

Optionally, the bipolar plate body comprises an electrically conductive composite bipolar plate.

Optionally, the bipolar plate body comprises an electrically conductive plastic and the bipolar plate sublayer comprises graphite paper.

Optionally, the bipolar plate auxiliary layer covers the bipolar plate body or the bipolar plate auxiliary layer exposes a surface edge region of the bipolar plate body.

Optionally, the bipolar plate has a central symmetrical structure.

Optionally, the upper plate comprises a metal upper plate and the lower plate comprises a metal lower plate.

Optionally, the upper and lower platens have surface edge regions with gripping member mounting areas that extend beyond the upper and lower dies of the flat press.

As described above, the bipolar plate processing apparatus and the bipolar plate manufacturing method of the present invention include a bipolar plate body and a bipolar plate auxiliary layer, and the resistivity of the bipolar plate auxiliary layer is smaller than that of the bipolar plate body, so that the contact resistance between the bipolar plate and the electrode can be reduced, and the electrical performance of the energy storage system can be improved. The bipolar plate processing device adopts a hot pressing process, so that the bipolar plate body and the auxiliary layer of the bipolar plate can be combined with each other to increase the effective conductive area; furthermore, the processing device comprises an auxiliary clamp, the pressing state of the bipolar plate can be kept before and after the hot pressing process through the auxiliary clamp until the auxiliary clamp and the bipolar plate are cooled to a certain temperature, the auxiliary clamp is opened, and the processed bipolar plate is taken out, so that the deformation degree of the bipolar plate in the hot pressing process can be reduced, and the product quality is improved.

Drawings

Fig. 1a to 1c are schematic structural views of a bipolar plate according to the present invention.

Fig. 2 is a schematic structural view of a bipolar plate processing apparatus according to the present invention.

Figure 3 shows a schematic process flow diagram for preparing a bipolar plate according to the present invention.

Description of the element reference numerals

100 bipolar plate

101 bipolar plate body

102 first auxiliary layer of bipolar plate

103 second auxiliary layer of bipolar plate

200 bipolar plate processing device

211 upper die

212 lower die

213. 214 liquid pipe

215 clamping member

216 hydraulic rod

217 base

221 upper plate

222 lower flat plate

223 clamping component

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention.

Please refer to fig. 1a to fig. 3. It should be noted that the drawings provided in the present embodiment are only for illustrating the basic idea of the present invention, and the components related to the present invention are only shown in the drawings rather than drawn according to the number, shape and size of the components in actual implementation, and the type, quantity and proportion of the components in actual implementation may be changed freely, and the layout of the components may be more complicated.

Referring to fig. 1a, the present embodiment provides a bipolar plate 100, wherein the bipolar plate 100 comprises a bipolar plate body 101 and a bipolar plate auxiliary layer, and the resistivity of the bipolar plate auxiliary layer is smaller than that of the bipolar plate body 101; the bipolar plate body 101 comprises a bipolar plate body first surface and a bipolar plate body second surface correspondingly arranged; the bipolar plate auxiliary layers include a bipolar plate first auxiliary layer 102 on a first surface of the bipolar plate body and a bipolar plate second auxiliary layer 103 on a second surface of the bipolar plate body.

In the present embodiment, the bipolar plate 100 has the bipolar plate auxiliary layer with a lower resistivity on the surface thereof, so that the contact resistance between the bipolar plate 100 and an electrode (not shown) can be reduced, and the electrical performance of the energy storage system can be improved. The auxiliary layers of the bipolar plate include, but are not limited to, the first auxiliary layer 102 and the second auxiliary layer 103 of the bipolar plate. The energy storage system may include, but is not limited to, an all vanadium flow battery.

By way of example, the bipolar plate 100 may also comprise only the first auxiliary layer 102 of the bipolar plate on the first surface of the bipolar plate body or only the second auxiliary layer 103 of the bipolar plate on the second surface of the bipolar plate body, as shown in fig. 1b and 1c, and this may be provided according to the needs, and is not limited herein.

As an example, the bipolar plate body 101 may include a conductive composite bipolar plate that has a mature processing technology, is flexible to manufacture, is low in cost, has both conductivity and mechanical strength, and is particularly suitable for manufacturing all-vanadium flow batteries. Preferably, the conductive composite bipolar plate may be made of conductive plastic, and the bipolar plate auxiliary layer may be made of graphite paper, so as to reduce the contact resistance between the conductive plastic and the electrode through the graphite paper, thereby improving the electrical performance of the energy storage system.

As an example, the bipolar plate auxiliary layer covers the bipolar plate body 101 or the bipolar plate auxiliary layer exposes a surface edge region of the bipolar plate body 101. I.e. the bipolar plate first auxiliary layer 102 exposes the bipolar plate body first surface edge region or/and the bipolar plate second auxiliary layer 103 exposes the bipolar plate body second surface edge region.

Specifically, the first auxiliary layer 102 and the second auxiliary layer 103 of the bipolar plate can correspondingly cover the first surface and the second surface of the bipolar plate body. The bipolar plate first auxiliary layer 102 may also expose the bipolar plate body first surface edge region or/and the bipolar plate second auxiliary layer 103 may expose the bipolar plate body second surface edge region for subsequent sealing or welding by the exposed surface edge region of the bipolar plate body 101. In this embodiment, the bipolar plate first auxiliary layer 102 preferably exposes the edge region of the first surface of the bipolar plate body, and the bipolar plate second auxiliary layer 103 preferably exposes the edge region of the second surface of the bipolar plate body, but is not limited thereto, and may be selected as required.

By way of example, the bipolar plate 100 has a central symmetrical structure, i.e., the first auxiliary layer 102 and the second auxiliary layer 103 of the bipolar plate are symmetrically distributed with the bipolar plate body 101 as a central axis, and preferably the first auxiliary layer 102 and the second auxiliary layer 103 of the bipolar plate are made of the same material, so as to form the bipolar plate 100 with symmetry, so as to facilitate control of the bipolar plate 100 in subsequent use. The thicknesses of the bipolar plate body 101, the bipolar plate first auxiliary layer 102 and the bipolar plate second auxiliary layer 103 can be selected according to the needs, and are not limited herein.

As shown in fig. 2, the present embodiment also provides a bipolar plate processing apparatus 200, wherein the bipolar plate processing apparatus 200 includes: the bipolar plate 100 can be fixed between the upper flat plate 221 and the lower flat plate 222 through the clamping component 223, so that the bipolar plate 100 can be kept in a compressed state before and after hot pressing through the auxiliary clamp until the auxiliary clamp and the bipolar plate 100 are cooled to a certain temperature, such as room temperature, the auxiliary clamp is opened, and the bipolar plate 100 after processing is taken out, thereby reducing the deformation degree of the bipolar plate 100 in the hot pressing process and improving the product quality.

For example, the flat plate press may include an upper die 211, a lower die 212, liquid pipes 213 and 214, a clamping member 215, a hydraulic rod 216, a base 217, and the like, and the specific structure of the flat plate press is not limited thereto, and may be selected according to the need, the connection relationship and the operation thereof, which are not described herein again.

As an example, the upper plate 221 of the auxiliary clamp may include a metal upper plate, and the lower plate 222 may include a metal lower plate, but is not limited thereto. In this embodiment, the upper plate 221 and the lower plate 222 in the auxiliary clamp are preferably made of metal materials with good thermal conductivity, so that the heat provided by the flat plate hot press can be efficiently transmitted to the bipolar plate 100 through the upper plate 221 and the lower plate 222, thereby reducing heat loss and improving energy utilization rate.

As an example, the surface edge areas of the upper and lower plates 221 and 222 have clamping part mounting areas beyond the upper and lower dies 211 and 212 of the flat press.

Specifically, the fastening means 215 may be a screw fastener, a snap fastener, a pin fastener, or the like, and is not limited herein. For convenience of control, the clamping member 215 is preferably located at the clamping member mounting region of the upper plate 221 and the lower plate 222 for operation in an application, but not limited thereto, and the specific mounting position of the clamping member 215 can be selected according to the way the clamping member 215 specifically fixes the upper plate 221 and the lower plate 222.

As shown in fig. 3, this embodiment further provides a method for manufacturing a bipolar plate, which includes the following steps:

providing a bipolar plate body, wherein the bipolar plate body comprises a first surface of the bipolar plate body and a second surface of the bipolar plate body which is correspondingly arranged; providing a bipolar plate auxiliary layer having a resistivity less than the bipolar plate body; providing a bipolar plate processing device, wherein the bipolar plate processing device comprises a flat plate hot press and an auxiliary clamp, and the auxiliary clamp comprises an upper flat plate, a lower flat plate and a clamping component;

the bipolar plate body and the bipolar plate auxiliary layer are arranged in the auxiliary clamp, and the bipolar plate body and the bipolar plate auxiliary layer are fixed between the upper flat plate and the lower flat plate through the clamping part;

acting on the auxiliary clamp through the flat hot press by adopting a hot pressing process;

and after the hot pressing is finished, taking out the auxiliary clamp, cooling to room temperature, opening the auxiliary clamp, and taking out the machined bipolar plate.

Specifically, the bipolar plate may include the bipolar plate 100 described above, and the bipolar plate processing apparatus may employ the bipolar plate processing apparatus 200 described above, but is not limited thereto. In this embodiment, the bipolar plate processing apparatus 200 is used to prepare the bipolar plate 100 as an example, and therefore, details of the structure, material, and the like of the bipolar plate 100 and the bipolar plate processing apparatus 200 are not described herein.

As an example, the heating temperature range of the hot pressing process comprises 20 ℃ to 200 ℃, and the pressure range comprises 1MPa to 15 MPa; for example, the heating temperature may include 50 deg.C, 100 deg.C, 150 deg.C, etc., and the pressure may include 5MPa, 10MPa, etc.

The specific steps for preparing the bipolar plate 100 may include:

providing the conductive plastic; providing graphite paper; providing the bipolar plate processing apparatus 200;

placing the graphite paper and the conductive plastic in the auxiliary fixture, wherein the graphite paper is placed on the upper surface and the lower surface of the conductive plastic respectively, and fixing the graphite paper and the conductive plastic between the upper flat plate 221 and the lower flat plate 222 through the clamping part 215 to complete the fixation;

placing the auxiliary fixture between the upper die 211 and the lower die 212 of the flat plate hot press, and heating and pressurizing;

and after the hot pressing is finished, taking out the auxiliary clamp, opening the auxiliary clamp after the auxiliary clamp and the bipolar plate 100 are cooled to room temperature, and taking out the machined bipolar plate 100.

Specifically, the bipolar plate 100 prepared by the method has a flat surface and no obvious defects, and when the bipolar plate 100 is applied to an all-vanadium flow battery, the contact resistance between the bipolar plate and a porous electrode can be reduced by 80% compared with that of the unprocessed conductive plastic, so that the electrical property of the all-vanadium flow battery can be improved.

In summary, the bipolar plate processing device and the bipolar plate preparation method of the present invention include a bipolar plate body and a bipolar plate auxiliary layer, and the resistivity of the bipolar plate auxiliary layer is smaller than that of the bipolar plate body, so that the contact resistance between the bipolar plate and the electrode can be reduced, and the electrical performance of the energy storage system can be improved. The bipolar plate processing device adopts a hot pressing process, so that the bipolar plate body and the auxiliary layer of the bipolar plate can be combined with each other to increase the effective conductive area; furthermore, the processing device comprises an auxiliary clamp, the pressing state of the bipolar plate can be kept before and after the hot pressing process through the auxiliary clamp until the auxiliary clamp and the bipolar plate are cooled to a certain temperature, the auxiliary clamp is opened, and the processed bipolar plate is taken out, so that the deformation degree of the bipolar plate in the hot pressing process can be reduced, and the product quality is improved. Therefore, the invention effectively overcomes various defects in the prior art and has high industrial utilization value.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (17)

1. A bipolar plate, comprising:

the bipolar plate body comprises a first surface of the bipolar plate body and a second surface of the bipolar plate body correspondingly arranged;

the bipolar plate auxiliary layer has a lower resistivity than the bipolar plate body, and at least one of a first auxiliary layer of the bipolar plate on a first surface of the bipolar plate body and a second auxiliary layer of the bipolar plate on a second surface of the bipolar plate body.

2. A bipolar plate as set forth in claim 1, wherein: the bipolar plate body includes a conductive composite bipolar plate.

3. A bipolar plate as set forth in claim 1, wherein: the bipolar plate body comprises conductive plastic, and the bipolar plate auxiliary layer comprises graphite paper.

4. A bipolar plate as set forth in claim 1, wherein: the bipolar plate auxiliary layer covers the bipolar plate body or exposes the surface edge region of the bipolar plate body.

5. A bipolar plate as set forth in claim 1, wherein: the bipolar plate is in a central symmetrical structure.

6. A bipolar plate processing apparatus, comprising:

a flat plate hot press;

an auxiliary clamp, comprising an upper flat plate, a lower flat plate and a clamping component, wherein the bipolar plate of any one of claims 1 to 5 is fixed between the upper flat plate and the lower flat plate through the clamping component.

7. A bipolar plate processing apparatus as claimed in claim 6, wherein: the upper flat plate comprises a metal upper flat plate, and the lower flat plate comprises a metal lower flat plate.

8. A bipolar plate processing apparatus as claimed in claim 6, wherein: the edge areas of the surfaces of the upper flat plate and the lower flat plate are provided with clamping part mounting areas which exceed the upper die and the lower die of the flat plate hot press.

9. A preparation method of a bipolar plate is characterized by comprising the following steps: the method comprises the following steps:

providing a bipolar plate body, wherein the bipolar plate body comprises a first surface of the bipolar plate body and a second surface of the bipolar plate body which is correspondingly arranged; providing a bipolar plate auxiliary layer having a resistivity less than the bipolar plate body; providing a bipolar plate processing device, wherein the bipolar plate processing device comprises a flat plate hot press and an auxiliary clamp, and the auxiliary clamp comprises an upper flat plate, a lower flat plate and a clamping component;

the bipolar plate body and the bipolar plate auxiliary layer are arranged in the auxiliary clamp, and the bipolar plate body and the bipolar plate auxiliary layer are fixed between the upper flat plate and the lower flat plate through the clamping part;

acting on the auxiliary clamp through the flat hot press by adopting a hot pressing process;

and after the hot pressing is finished, taking out the auxiliary clamp, cooling to room temperature, opening the auxiliary clamp, and taking out the machined bipolar plate.

10. The method of manufacturing a bipolar plate according to claim 9, wherein: the heating temperature range of the hot pressing process comprises 20-200 ℃, and the pressure range comprises 1-15 MPa.

11. The method of manufacturing a bipolar plate according to claim 9, wherein: the bipolar plate auxiliary layer at least comprises one of a bipolar plate first auxiliary layer positioned on the first surface of the bipolar plate body and a bipolar plate second auxiliary layer positioned on the second surface of the bipolar plate body.

12. The method of manufacturing a bipolar plate according to claim 9, wherein: the bipolar plate body includes a conductive composite bipolar plate.

13. The method of manufacturing a bipolar plate according to claim 9, wherein: the bipolar plate body comprises conductive plastic, and the bipolar plate auxiliary layer comprises graphite paper.

14. The method of manufacturing a bipolar plate according to claim 9, wherein: the bipolar plate auxiliary layer covers the bipolar plate body or exposes the surface edge region of the bipolar plate body.

15. The method of manufacturing a bipolar plate according to claim 9, wherein: the bipolar plate is in a central symmetrical structure.

16. The method of manufacturing a bipolar plate according to claim 9, wherein: the upper flat plate comprises a metal upper flat plate, and the lower flat plate comprises a metal lower flat plate.

17. The method of manufacturing a bipolar plate according to claim 9, wherein: the edge areas of the surfaces of the upper flat plate and the lower flat plate are provided with clamping part mounting areas which exceed the upper die and the lower die of the flat plate hot press.

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