Patent Application
20170271690
The invention relates to electrochemical reactors that include a stack of individual electrochemical cells, and more particularly a stack that includes bipolar plates and proton exchange membranes. Such electrochemical reactors constitute, for example, fuel cells or electrolysers.
Fuel cells are in particular envisaged as a source of energy for mass-produced automotive vehicles in the future or as sources of auxiliary energy in aeronautics. A fuel cell is an electrochemical device that converts chemical energy directly into electrical energy. A fuel cell comprises a stack, in series, of several individual cells. Each individual cell typically generates a voltage of the order of 1 volt, and the stack thereof makes it possible to generate a higher level supply voltage, for example of the order of about a hundred volts.
Among the known types of fuel cells, mention may in particular be made of the proton exchange membrane (PEM) fuel cell that operates at low temperature. Such fuel cells have particularly advantageous compactness properties. Each individual cell comprises an electrolytic membrane that allows only protons to pass through and not electrons. The membrane comprises an anode on a first face and a cathode on a second face in order to form a membrane electrode assembly (MEA).
At the anode, molecular hydrogen used as fuel is ionized in order to produce protons that pass through the membrane. The membrane thus forms an ion conductor. Electrons produced by this reaction migrate toward a flow plate, then pass through an electrical circuit external to the individual cell in order to form an electric current. At the cathode, oxygen is reduced and reacts with the protons to form water.
The fuel cell may comprise several plates, referred to as bipolar plates, for example made of metal, stacked on top of one another. The membrane is positioned between two bipolar plates. The bipolar plates may comprise flow channels and orifices in order to continuously guide the reactants and the products to/from the membrane. The bipolar plates also comprise flow channels in order to guide coolant that discharges the heat produced. The reaction products and the non-reactive species are discharged by entrainment by the flow to the outlet of the networks of flow channels. The flow channels of the various flows are separated by means of bipolar plates in particular.
The bipolar plates are also electrically conductive in order to collect electrons generated at the anode. The bipolar plates also have a mechanical role of transmitting the stack clamping forces, necessary for the quality of the electrical contact. Gas diffusion layers are inserted between the electrodes and the bipolar plates and are in contact with the bipolar plates.
Electron conduction is carried out through the bipolar plates, ion conduction being obtained through the membrane.
Three methods of circulation of the reactants in the flow channels are mainly distinguished:
In order to favor the compactness and the performance, the design involves reducing the dimensions of the flow channels. The method of circulation by parallel channels is then favored, in order to limit the pressure drops in such flow channels of reduced dimensions, and to avoid coolant flow problems that may lead to hot spots.
With parallel flow channels, the distribution of the reactants at the electrodes should be as homogeneous as possible over the entire surface, to avoid impairing the operation of the electrochemical reactor. For this purpose, the bipolar plates comprising parallel flow channels frequently use homogenizing zones in order to couple inlet and outlet manifolds to the various flow channels of the bipolar plates. The reactants are brought into contact with the electrodes using inlet manifolds and the products are discharged using outlet manifolds connected to the various flow channels. The inlet manifolds and the outlet manifolds generally pass right through the thickness of the stack. The inlet and outlet manifolds are usually obtained by:
Various technical solutions are known for placing the inlet and outlet manifolds in communication with the various flow channels. It is in particular known to produce passages between two metal sheets of a bipolar plate. These passages open on the one hand into orifices of respective manifolds, and on the other hand into injection orifices. A homogenizing zone comprises channels that place injection orifices in communication with flow channels.
The homogenizing zone comprises: a coolant transfer zone, an oxidant circuit homogenizing zone and a fuel circuit homogenizing zone that are superposed and that open respectively toward a coolant manifold, an oxidant circuit manifold and a fuel circuit manifold.
In practice, with molecular hydrogen as fuel circulating at the anode and molecular oxygen as oxidant in air circulating at the cathode, a very great pressure drop disparity appears between the two flows for the same flow circuits in the homogenizing zones and in the flow channels of the reactive zone. The ratio of pressure drops between the flow of molecular hydrogen and of air is then generally between 2 to 10. On the one hand, molecular hydrogen is generally less viscous than air including molecular oxygen, and on the other hand its flow rate is lower. The pressure drops in the air flow may thus be very detrimental for the reactor performance.
Furthermore, in the presence of homogenizing zones, it is observed that they generate a sizeable portion of the pressure drops in the flows, in particular in designs that aim to reduce the bulkiness of these homogenizing zones which do not participate or participate only partially in the electrochemical reaction.
The invention aims to solve one or more of these drawbacks. The invention thus relates to an electrochemical reactor as defined in the appended claims.
Document US 2010/0129694 and document US 2010/0129265 describe a fuel cell equipped with a membrane electrode assembly between bipolar plates. These documents propose to reduce the pressure drops in a fluid inlet zone relative to a fluid outlet zone. A first embodiment relates to a homogenizing zone without homogenizing channels. A second embodiment relates to a homogenizing zone with flow channels. In the second embodiment, the pressure drop reduction is achieved by increasing the width of the inlet flow channels relative to the outlet flow channels. The membrane electrode assembly described lacks reinforcement in all the embodiments. The membrane covers the flow channels and the homogenizing zones of the anode and cathode plates in all the embodiments.
Other features and advantages of the invention will become clearly apparent from the description that is given thereof below, by way of nonlimiting illustration, and with reference to the appended figures, in which:
The fuel cell 4 comprises a source of fuel 40. The source of fuel 40 here supplies an inlet of each individual cell 1 with molecular hydrogen. The fuel cell 4 also comprises a source of oxidant 42. The source of oxidant 42 here supplies an inlet of each individual cell 1 with air, oxygen from the air being used as oxidant. Each individual cell 1 also comprises exhaust channels. One or more individual cells 1 also have a cooling circuit.
Each individual cell 1 comprises a membrane electrode assembly 110 or MEA 110. A membrane electrode assembly 110 comprises an electrolyte 113, a cathode 112 and an anode (not illustrated) which are placed on either side of the electrolyte and fastened to this electrolyte 113. The layer of electrolyte 113 forms a semi-permeable membrane that allows protons to be conducted while being impermeable to the gases present in the individual cell. The layer of electrolyte also prevents passage of electrons between the anode and the cathode 112.
Between each pair of adjacent MEAs, a bipolar plate 5 is positioned. Each bipolar plate 5 defines anodic flow channels and cathodic flow channels. Bipolar plates 5 also define coolant flow channels between two successive membrane electrode assemblies.
In a manner known per se, during the operation of the fuel cell 4, air flows between an MEA and a bipolar plate 5, and molecular hydrogen flows between this MEA and another bipolar plate 5. At the anode, the molecular hydrogen is ionized in order to produce protons that pass through the MEA. The electrons produced by this reaction are collected by a bipolar plate 5. The electrons produced are then applied to an electrical load connected to the fuel cell 1 in order to form an electric current. At the cathode, oxygen is reduced and reacts with the protons to form water. The reactions at the anode and the cathode are governed as follows:
H2→2H++2e− at the anode;
4H++4e−+O2→2H2O at the cathode.
During its operation, one individual cell of the fuel cell usually generates a DC voltage between the anode and the cathode of the order of 1 V.
The orifices of the bipolar plates 5 and of the membrane electrode assemblies 110 are positioned opposite in order to form the various flow manifolds. Orifices 12, 14 and 16 are for example made in the membrane electrode assemblies 110 and are positioned opposite respectively the orifices 592, 594 and 596. For the sake of simplification, the orifice 594 will be likened to an oxidant supply manifold.
Each of the bipolar plates 5, 51 and 52 illustrated includes two attached conductive metal sheets 61 and 62. The conductive metal sheets 61 and 62 are advantageously (but nonlimitingly) made of stainless steel, a very common material suitable for many widespread industrial transformation processes, for example drawing, stamping and/or punching. The conductive metal sheets 61 and 62 are here attached by means of welds 513.
In a manner known per se, the various manifolds passing through the stack communicate with respective injection zones. In the example illustrated in
Injection orifices 512 are made in the metal sheet 62 in the injection zone 586. Injection orifices 514 are made in the metal sheet 61 in the injection zone 584. As illustrated in
Fluid communications, which are not described and not illustrated, are also made on the one hand between the manifold 596 and the injection zone 586, and on the other hand between the manifold 592 and injection zone 582.
The conductive metal sheets 61 and 62 are in relief, so as to make fluid flow channels at the outer faces of each bipolar plate, and advantageously between the conductive metal sheets 61 and 62 within each of these bipolar plates. The conductive metal sheet 61 comprises a reactive zone 615 and a homogenizing zone 611 on its outer face. The reactive zone 615 comprises flow channels 616. The homogenizing zone 611 comprises homogenizing channels 612 placing the injection zone 584 in communication with the reactive zone 615, as illustrated by the dotted-line arrow.
The conductive metal sheet 62 comprises a reactive zone 625 and a homogenizing zone 621 on its outer face. The reactive zone 625 comprises flow channels 626. The homogenizing zone 621 comprises homogenizing channels 622 placing the injection zone 586 in communication with the flow channels 626.
A homogenizing zone is generally differentiated from a reactive zone by the absence of electrode overhanging this homogenizing zone in the membrane electrode assembly 110, and/or by the presence of homogenizing channels having a lateral deviation relative to the flow channels of the reactive zone, so as to make the homogenizing zone more compact. The role of a homogenizing zone is in particular to limit the difference in flow rates between the various flow channels of its respective reactive zone and to homogenise the pressure drops for the various possible flow paths.
The membrane electrode assembly 110 here comprises a reinforcement 116 surrounding the cathode 112 and fastened to the membrane 113. The reinforcement 116 comprises a median opening giving access to the cathode 112. A gas diffusion layer 114 is positioned here in contact with the cathode 112 across this median opening. In this example, the membrane electrode assembly 110 also comprises a reinforcement 117 surrounding the anode 111 and fastened to the membrane 113. The reinforcement 117 comprises a median opening giving access to the anode 111. A gas diffusion layer 115 is positioned here in contact with the anode 111 across this median opening.
The dotted line illustrates the boundary between the reactive zones 615, 625 and the homogenizing zones 611, 621. According to the invention, at least one reinforcement or the membrane 113 does not extend as far as the homogenizing zones 611, 621 and does not therefore cover the homogenizing channels 612, 622.
Thus, the thickness of the membrane electrode assembly 110 covering the homogenizing zones 611 and 621 is less than the thickness of this membrane electrode assembly 110 at a superposition between the membrane 113 and the reinforcements 116 and 117.
In the example illustrated, two elements from among the membrane 110 and the reinforcements 116 and 117 do not extend as far as the homogenizing zones 611, 621. In particular, the membrane 113 and the reinforcement 116 do not extend as far as the homogenizing zones 611, 621.
Thus, the thickness of the membrane electrode assembly 110 covering the homogenizing zones 611 and 621 is reduced even more relative to the superposition between the membrane 113 and reinforcements 116 and 117.
Consequently, the depth of the homogenizing channels 612 may be increased, so as to reduce the pressure drops of the flow passing through the homogenizing zone 611. As illustrated in
The difference in depth between the homogenizing channels 612 and the flow channels 616 is at least equal to the thickness of the membrane 113 (thickness em) or of the reinforcement 116 (thickness er116) not extending as far as the homogenizing zone 611: Δh≧em or Δh≧er116.
The depth em is typically between 15 and 60 μm.
If at least two elements from among the membrane 113 and the reinforcements 116 and 117 (thickness er117) do not extend as far as the homogenizing zone 611, the difference in depth between the homogenizing channels 612 and the flow channels 616 is at least equal to the sum of the thickness of these two elements: Δh≧em+er116 or Δh≧em+er117 or Δh≧er116+er117.
Furthermore, in the presence of a gas diffusion layer 114 in contact with the cathode 112, the differences in depth mentioned above are further increased by the thickness of the gas diffusion layer 114.
Namely Δhca=hh−hha.
Depending on the elements that do not cover the homogenizing zone 611, provision may be made for Δhca≧em or Δhca≧er116 or Δhca≧er117 or Δhca≧em+er116 or Δhca≧em+er117 or Δhca≧er116+er117.
The depth hha of the homogenizing channels 622 is typically between 200 and 500 μm. The width of the homogenizing channels 622 and 612 (defined by their average width) is typically between 1 and 3 mm. The thickness em is typically between 15 and 60 μm. The thicknesses er116 and er117 are typically between 30 and 200 μm.
It is possible to envisage, depending on the scenario, a depth difference Δhca between 15 and 400 μm.
For example, with em=25 μm, er116=50 μm and er117=50 μm, according to the example illustrated in
In
The membrane electrode assembly 110 covers the homogenizing zone 611 of the plate 52 and the homogenizing zone 622 of the plate 51 in order to separate a cathodic flow from an anodic flow. The membrane electrode assembly 110 extends here up to gaskets 2, covering injection orifices 514. In this example, only the anodic reinforcement 117 of the membrane electrode assembly 110 covers the homogenizing zones.
The flow channels 616 and the flow channels 626 are here of parallel type and extend along the same direction. These various flow channels are not necessarily rectilinear (these channels may have a wave), their direction being defined by a straight line connecting their inlet to their outlet.
The invention has been described with reference to an injection of a molecular hydrogen type fuel into a fuel cell. The invention of course also applies to the injection of other types of fuels, for example methanol.
The invention has been described with reference to an electrochemical reactor of proton exchange membrane fuel cell type. The invention may of course also apply to other types of electrochemical reactors, for example an electrolyser also comprising a stack of bipolar plates and of proton exchange membranes.
| Number | Date | Country | Kind |
|---|---|---|---|
| FR1457327 | Jul 2014 | FR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/FR2015/051893 | 7/8/2015 | WO | 00 |
