FR2888047A1 - Bipolar plate for ion exchange membrane fuel cell, has two layers made of porous electricity conducting material, separated by polymer sealing membrane, where layers are electrically connected by conducting fibers traversing membrane - Google Patents

Abstract

The plate (1) has two layers (10, 11) made of porous electricity conducting material, separated by a polymer sealing membrane (12), where the plate is separated from another bipolar plate by an electrode membrane (2). The layers are electrically connected by conducting fibers (13) traversing the sealing membrane. The layers are shaped to form coolant circulation channels. An independent claim is also included for an ion exchange membrane fuel cell comprising an alternate stacking of electrode membrane and bipolar plate.

Description

The present invention relates to a bipolar plate for battery

  proton exchange membrane type fuel.

  Proton exchange membrane-type fuel cells are known consisting of an alternating stack of electrode membranes and bipolar plates, the bipolar plates being intended to convey active gases and cooling fluids, and to distribute them on the surface. electrode membrane assemblies, so as to generate electrochemical reactions through the electrode membrane to generate electrical currents.

  In these stacks, the bipolar plates are generally rigid plates made of rigid conductive materials such as graphite machined to form channels for the circulation of gases, or formed of metal plates shaped by stamping so as to form also channels for the circulation of gases.

  These bipolar plates have the particular disadvantage of being rigid, which can cause problems to ensure a good seal of the various contacts that may be between the bipolar plates of a large stack. These bipolar plates also have the disadvantage of having corrosion problems, which lead to the poisoning of catalytic sites. Bipolar plates made of metallic material have the further disadvantage of causing problems of differential expansion. These bipolar plates lead to significant ohmic losses from relatively large contact resistances resulting from the fact that the contacts between the rigid plates are sometimes irregular. In addition, the assemblies made with these plates are relatively heavy insofar as the metal bipolar plates or machined solid carbon have a significant weight. Finally, the manufacture of these bipolar plates is complex since it is necessary, in particular, to accurately machine networks of gas circulation channels often complex.

  The object of the present invention is to remedy these drawbacks by proposing a bipolar plate for fuel cell type proton exchange membrane which is light, which can be easily manufactured, which does not pose a problem of corrosion or problem of dilation or problem of contact and which facilitates the realization of seals.

  For this purpose, the subject of the invention is a bipolar plate for fuel cell of the ion exchange membrane type, consisting of two layers of electrically conductive porous material separated by a sealed membrane, the two layers of porous material being electrically connected.

  Preferably, the waterproof membrane is a polymer membrane.

  The porous material layers may be shaped to form fluid circulation channels.

  The porous material is made of, for example, carbon fibers or a metal foam.

  Preferably, the electrical connection of the two layers of porous material is provided by current-conducting fibers passing through the sealed membrane.

  The invention also relates to a fuel cell comprising an alternating stack of membrane / electrode assembly and plates according to the invention.

  The invention will now be described in a more precise but nonlimiting manner with regard to the single appended figure which schematically represents a stack of bipolar plates and electrode membrane assemblies of a membrane exchange fuel cell. protons.

  To achieve an alternating stack of bipolar plates and membrane electrode assemblies, as shown in the single figure, and which consists of three bipolar plates 1, 1 ', 1 "separated by two electrode membrane assemblies 2, 2'. three bipolar plates 1, 1 ', 1 "which are identical consist of two layers 10 and 11 or 10' and 11 'or 10" and 11 ", respectively, of porous material such as for example a material made of carbon fibers forming a felt or cotton, or a very porous metal foam, separated by fluid-tight membranes 12 or 12 'or 12 ", respectively, the two porous layers 10 and 11 or 10' and 11 'or 10" and 11 "being electrically connected to each other via conductive fibers 13 or 13 'or 13", respectively, passing through the sealed membrane 12 or 12' or 12 ".

  When the fuel cell is in use, each of the porous layers is fed with an active gas and for example the layer 11 of the bipolar plate 1 is supplied with fuel gas which passes through the porous layer II and comes into contact with the membrane electrode 2. The porous layer 10 'of the bipolar plate 1' is supplied with oxidizing gas which diffuses through the porous layer and licks the other side of the electrode membrane 2. The fuel gas which passes through the porous layer 11 reacts through the electrode membrane with the oxidant gas that passes through the porous layer 10 ', this reaction produces water which is also discharged through the porous layer 10', and simultaneously generates an electrical voltage. In the same way, the layer 11 'is supplied with fuel gas, for example hydrogen, which reacts through the membrane electrode 2' with oxidizing gas, for example oxygen, which passes through the porous layer Due to the presence of the impervious membrane 12 ', the oxidant gas which passes through the porous layer 10' is not in contact with the fuel gas which passes through the layer 11 ', it follows that the the only electrochemical reactions that take place are the electrochemical reactions that take place through the electrode membranes.

  Thus, the stack consisting of a porous layer 11 fed with fuel gas, the electrode 2 and the porous layer 10 'traversed by oxidizing gases constitutes an electricity generator. Similarly, the stack constituted by the porous layer 11 'traversed by fuel gas, the membrane electrode 2' and the porous layer 10 "traversed by oxidizing gas constitutes a second electricity generator.

  Due to the presence of the electrically conductive fibers 13, which surround the sealed membrane 12 ', the first current generator which has just been described is connected in series with the second current generator which has just been described, and thus immediately in the entire stack that constitutes the fuel cell generating electricity.

  Such a bipolar plate design has many advantages.

  Indeed, such a bipolar plate is flexible and therefore all the problems of adaptation of the stack to ensure good contact of successive plates or to ensure sealing between two successive plates are simplified.

  In addition, the plates are of materials that do not pose the differential expansion problems that are encountered with rigid bipolar plates.

  The flexibility of these bipolar plates also makes it possible to obtain a homogeneity of the pressure of the reactive gases in the reaction chambers, in particular minimizing the risk of pressure difference between the anode and the cathode, due to self-compression to the rigidity of the membranes.

  Finally, these flexible plates avoid the irregularities of local contact pressures. In particular, they avoid high local contact pressures, especially on the peripheral part of the ion exchange membranes.

  To ensure the operation of such a fuel cell, it is necessary to provide inserts for example of polymer material for creating active fluid inflows. It is also possible to provide cooling fluid circulation channels embedded in the porous materials.

Claims (6)

  Bipolar plate for ion exchange membrane type fuel cell, characterized in that it consists of two layers (10, 11) of porous electrically conductive material separated by a sealed membrane (12), the two layers of porous material being electrically connected.   2. Bipolar plate according to claim 1, characterized in that the waterproof membrane (12) is a polymer membrane.   Bipolar plate according to claim 1 or claim 2, characterized in that the layers of porous material (10, 11) are shaped to form fluid circulation channels.   4. Bipolar plate according to one of claims 1 to 3, characterized in that the porous material is made of carbon fibers or a metal foam.   5. Bipolar plate according to claim 4, characterized in that the electrical connection of the two layers (10, 11) of porous material is provided by current-conducting fibers (13) passing through the sealed membrane.   6. The ion exchange membrane type fuel cell, characterized in that it comprises an alternating stack of membrane / electrode assemblies and bipolar plates according to any one of claims 1 to 5.