JP6804332B2 - Electrochemical devices and methods of controlling corrosion - Google Patents

Description

The present disclosure relates to an electrochemical device having improved resistance to internal corrosion.

Fuel cells, flow batteries, and other electrochemical devices are generally known and used for producing electric current. An electrochemical device generally includes an anode electrode, a cathode electrode, and a separator between the anode electrode and the cathode electrode in order to generate a current in a known electrochemical reaction between the reactants. Typically, when ionic conductive reactants are used, potential differences at different locations within the electrochemical device create a leakage current, also known as a shunt current, which reduces energy efficiency. In addition, the shunt current can accelerate the corrosion of the components of the electrochemical device.

The electrochemical device includes a plurality of electrode assemblies that define a plurality of electrochemically active regions. The non-conductive manifold comprises a common manifold passage and a plurality of tributary passages, each extending between the plurality of electrochemically active regions and the common manifold passage. Each tributary passage comprises a first area and a second area with different surface areas.

Also disclosed are methods of controlling corrosion in electrochemical devices. The method comprises supplying a flow of reactant fluid between the common manifold passage and the plurality of electrode assemblies. The reactant fluid produces a shunt current that can be maintained by the self-reaction of the reactant fluid and the corrosion reaction of the components of the electrochemical apparatus. Corrosion reactions are limited by establishing a tendency to maintain shunt current by self-reaction rather than corrosion reaction.

The various features and advantages of this disclosure will become apparent to those skilled in the art from the detailed description below. The drawings accompanying the detailed description can be easily described as follows.

The figure which shows the electrochemical apparatus of an Example. The figure which shows the typical tributary passage of the electrochemical apparatus of FIG. The figure which shows the electrochemical apparatus of another Example. The figure which shows the electrode assembly and the frame used in the electrochemical apparatus of FIG. FIG. 5 shows a bipolar plate and frame used in the electrochemical device of FIG. The figure which shows the bipolar plate flow path wall which has a tapered end. FIG. 5 showing a bipolar plate flow path wall of another embodiment having a tapered end. FIG. 5 showing a bipolar plate flow path wall of another embodiment having a tapered end.

FIG. 1 schematically shows an electrochemical device 20 of an embodiment. As will be appreciated, the electrochemical device 20 can be a fuel cell, a flow battery, or any other type of electrochemical device that utilizes one or more ionic conductive reactants. As will be described in more detail, the electrochemical device 20 has features that control or limit the corrosion of internal components within the electrochemical device 20, such as components containing carbon or metal.

In this embodiment, the electrochemical device 20 comprises a plurality of electrode assemblies 22 arranged in a stack. The electrode assembly 22 defines a plurality of electrochemically active regions 24. The electrochemically active region 24 is a zone in which the reactant participates in the oxidation / reduction reaction so as to generate an electric current. In this embodiment, the reactants are fed through the non-conductive manifold 26. For example, the non-conductive manifold 26 is a non-conductive polymer material. The electrochemical device 20 of the embodiment includes two such non-conductive manifolds 26 that help supply the flow F to the electrode assembly 22 and expel it from the electrode assembly 22. The non-conductive manifold 26 can be similar or identical, at least with respect to the features described herein.

The non-conductive manifold 26 comprises a common manifold passage 28 through which the reactants are distributed to each of the electrochemically active regions 24. A plurality of tributary passages 30 are outside or partially outside the electrochemically active region 24 and extend between the electrochemically active region 24 and the common manifold passage 28.

FIG. 2 shows one typical tributary passage 30. As shown, the tributary passage 30 comprises a first area 32 and a second area 34 with different surface areas, as indicated by the difference in hatching between the first area 32 and the second area 34. In one embodiment, the difference in surface area is due to the relative roughness of the walls of the tributary passage 30. That is, the wall surface of the first area 32 is relatively smooth, while the wall surface of the second area 34 is relatively rough.

Fuel cells, flow batteries, and other electrochemical devices, especially those that utilize ionic conductive reactants, can suffer inefficiencies due to shunt currents. In some cases, the shunt current is maintained by a corrosion reaction that corrodes the components, especially those containing carbon or metal, and ultimately reduces the life of the electrochemical device. One way to deal with shunt currents in electrochemical devices is to increase the length of the tributary passages or reduce their lateral size to increase the ionic resistance of the pathways for ionic conductive reactions. Is. However, increasing the length or reducing the lateral magnitude can reduce the flow of the reactants or increase the pressure drop of the reactants, which can adversely affect the performance of the battery or system. The electrochemical devices 20 and methods disclosed in the present application approach differently. Rather than limiting resistance, the electrochemical devices 20 and methods of the present application establish a tendency to maintain such a shunt current by the self-reaction of the reactants in preference to the corrosion reaction. In other words, the self-reaction and corrosion reaction of the reactants are competitive reactions, and the greater the tendency towards self-reaction, the more limited the corrosion reaction. For example, a self-reaction is a change in the oxidation state of a reactant. In vanadium liquid electrolyte reactants, the self-reaction is the change from V ⁴⁺ to V ⁵⁺ in a positive reactant fluid or from V ²⁺ to V ³⁺ in a negative reactant fluid. .. Similar self-reactions are expected for other reactant species such as bromine, iron, chromium, zinc, cerium, lead, or reactant species based on these combinations.

Outside the electrochemically active region, when the current density is relatively high and the surface area is relatively small in the presence of the reactant, the small surface area catalyzes the self-reaction of the reactant. There are relatively few parts available for use. Therefore, competitive corrosion reactions are more likely to occur. However, when the same current density is given over a larger surface area, there are more surface sites available to catalyze the self-reaction, and the tendency shifts primarily towards the self-reaction. As a result, the corrosion of these solid surfaces is small.

Therefore, in the electrochemical apparatus 20, the first zone 32 and the second zone 34 of the tributary channels 30 having different surface areas promote or establish a tendency to maintain the self-reaction of the reactant in preference to the corrosion reaction.

FIG. 3 shows an electrochemical device 120 of another embodiment whose cross section is shown. In this disclosure, similar reference codes indicate similar components and, where appropriate, amended reference codes that are understood to incorporate the same features and benefits of the corresponding components, with the addition of 100 or a combination thereof. The components are shown. The electrode assembly 122 includes a first porous electrode 122a, a second porous electrode 122b, and a separator layer 122c between them. The separator layer can be a polymer membrane such as an ion exchange membrane.

The electrode assembly 122 is arranged between the bipolar plates 140. Each of the bipolar plates 140 has a flow path 142 such that the reactants are carried to or from the common manifold passages 128a / 128b of the non-conductive manifold 126.

With reference to FIGS. 4 and 5, with reference to FIG. 3, the electrode assembly 122 is a non-conductive frame having a plurality of openings forming a part of the non-conductive manifold 126 and the common manifold passages 128a / 128b. It is installed in 144. The disclosed examples have six manifold holes in each part of FIGS. 4 and 5, but less than four, such as four (one + and one-at each end for inlet and outlet). Can be used as an alternative. A seal 146 is provided around the electrode assembly 122 to limit leakage of the reactants. The seal 146 can also function as a means of integrating the electrodes with a separator assembly, such as a membrane-electrode assembly (MEA). Similarly, each of the conductive bipolar plates 140 is mounted within a non-conductive frame 148 having a plurality of openings forming part of the non-conductive manifold 126 and the common manifold passages 128a / 128b.

Each of the first porous electrode 122a and the second porous electrode 122b extends to a region larger than the separator layer 122c, as indicated by the overhang portion 150 outside the electrochemically active region 24. .. Each region of the first porous electrode 122a and the second porous electrode 122b is also larger than the bipolar plate 140. The tributary passage 130 comprises a first area 132 defined by a non-conductive frame 148 and a seal 146. The tributary passage 130 can act as an inlet for the bipolar plate 140 into the flow path 142 or as an exit from the bipolar plate 140 flow path 142. The surfaces of the non-conductive frame 148 and the non-conductive seal 146 are relatively smooth. The second region 134 is defined by the non-conductive frame 148 and the conductive first or second porous electrodes 122a / 122b. Therefore, the first and second porous electrodes 122a / 122b provide a relatively larger surface area than the smooth walls of the non-conductive frame 148 and seal 146. Thus, the overhang portion 150 acts as a source or sink for the shunt currents, where outside the electrochemically active region 24 so that these shunt currents can be maintained by a self-reaction rather than a corrosion reaction. Provides a high surface area.

In a further embodiment shown in FIG. 6, the flow path 142 of the bipolar plate 140 extends between the flow path walls 142a. Each of the flow path walls 142a has a tapered end 160. In this embodiment, the tapered end 160 is tapered to point P. Alternatively, the tapered end 160 can be rounded as shown in FIG. In another alternative shown in FIG. 8, the flow path 242 is an alternating fit with open end 262 and closed end 264 alternating. The tapered ends 160/260 further facilitate the establishment of a tendency of the reactants to self-reaction in preference to the corrosion reaction. The self-reaction of the reactants is transport-restricted. The tapered end 160/260 of the channel wall 142a allows the reactant to move continuously at the inlet of the channel 142, thereby shunting the self-reaction of the reactant rather than the corrosion reaction. ..

Although the combination of features shown in the illustrated examples, all of these need not be combined to realize the benefits of the various examples of the present disclosure. In other words, a system designed according to the embodiments of the present disclosure does not necessarily include all of the features shown in any one of the drawings, or all of the parts outlined in the drawings. In addition, the selected features of one of the illustrated examples can be combined with the selected features of the other illustrated examples.

The above description is exemplary, not limiting in nature. Changes and amendments to the embodiments of the disclosure that do not necessarily deviate from the nature of the present disclosure may be apparent to those skilled in the art. The scope of legal protection given to this disclosure may only be determined by considering the following claims.

Claims (13)

Multiple electrode assemblies that define multiple electrochemically active regions,
A non-conductive manifold with a common manifold passage for transporting ionic conductive fluids,
A plurality of tributary passages extending between a plurality of electrochemically active regions and a common manifold passage, and each of the plurality of tributary passages has a first area and a second area having different surface areas. With multiple tributary passages and
With
Each of the plurality of electrode assemblies includes a first porous electrode, a second porous electrode, and a separator layer between the first porous electrode and the second porous electrode, and the first. The porous electrode and the second porous electrode of the above cover a region larger than the separator layer, respectively.
The first zone and the second zone, Ri is Do different surface roughness of the walls,
The second zone is an electrochemical device according to claim Rukoto defined in part by a conductive surface that is external to the plurality of electrochemically active area. The first porous electrode and the second porous electrode include each overhanging portion extending beyond the side portion of the separator layer, and each of the overhanging portions is of each tributary passage among the plurality of tributary passages. The electrochemical apparatus according to claim 1, wherein a second area is defined, but the first area is not defined. The first zone is an electrochemical device according to claim 1, characterized in that it is defined by a non-conductive polymer wall. The electrochemical device further comprises a bipolar plate with a plurality of channels fluidly connected to a plurality of tributary passages, the plurality of channels being characterized by being within a plurality of electrochemically active regions. The electrochemical device according to claim 1. The electrochemical apparatus according to claim 4 , wherein the plurality of flow paths run between the flow path walls, and each of the flow path walls has a tapered end portion. The electrochemical device according to claim 5, wherein the tapered end portion is tapered to the tip end. The electrochemical apparatus according to claim 5 , wherein the tapered end portion is tapered to a rounded end portion. The electrochemical device according to claim 5 , wherein the plurality of flow paths are alternating mating flow paths. The electrochemical according to claim 1, wherein the ionic conductive fluid contains one or more reactants that can easily undergo redox reactions resulting in different oxidation states to store energy. apparatus. A method of controlling corrosion in an electrochemical device, in which the electrochemical device
Multiple electrode assemblies that define multiple electrochemically active regions,
A non-conductive manifold with a common manifold passage for transporting ionic conductive fluids,
A plurality of tributary passages extending between a plurality of electrochemically active regions and a common manifold passage, and each of the plurality of tributary passages has a first area and a second area having different surface areas. With multiple tributary passages and
With
Each of the plurality of electrode assemblies includes a first porous electrode, a second porous electrode, and a separator layer between the first porous electrode and the second porous electrode, and the first. The porous electrode and the second porous electrode of the above cover a larger area than the separator layer, respectively.
A flow of reactant fluid that produces a shunt current that can be maintained by the self-reaction of the reactant fluid and the corrosion reaction of the components of the electrochemical device is provided between the common manifold passage and the multiple electrode assemblies.
Maintaining the shunt current by self-reaction in preference to the corrosion reaction to limit the corrosion of the components,
A method of controlling corrosion in an electrochemical device, which comprises: The maintenance described above includes providing a plurality of tributary passages between the common manifold passage and the plurality of electrochemically active regions of the plurality of electrode assemblies, and each of the plurality of tributary passages has a surface area. the method of claim 1 0, wherein the and a different first areas and second areas of. The above-mentioned maintenance includes providing a bipolar plate having a plurality of channels running between the channel walls, each of which comprises a tapered end. the method of claim 1 0, wherein. The above maintenance is
Provides multiple tributary channels between the common manifold passages and multiple electrochemically active regions of multiple electrode assemblies.
Provided is a bipolar plate with a plurality of channels running between the channel walls.
1. Each of the plurality of tributary passages includes a first area and a second area having different surface areas, and each of the flow path walls has a tapered end. The method described in 0 .

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