WO2021233685A1 - Heating device for a stack of electrochemical cells, fuel cell stack, and heating method - Google Patents

Abstract

The invention relates to a heating device (12) for a stack of electrochemical cells, wherein the heating device (12) comprises a heating layer (54) having a first side (56) and an opposite second side (58), a first thermal insulation layer (60) and a second thermal insulation layer (62), the first thermal insulation layer (6) being arranged on the first side (56) of the heating layer (54) and the second thermal insulation layer (62) being arranged on the second side (58) of the heating layer (54), and wherein the heating layer (54) has a central region (64) and an edge region (66) and the first thermal insulation layer (60) has a first cut-out (68) at the edge region (66) of the heating layer (54) and the second thermal insulation layer (62) has a second cut-out (70) at the central region (64) of the heating layer (54). The invention further relates to a fuel cell stack (4) comprising the heating device (12) and to a method for heating parts of the fuel cell stack (4).

Description

Heater for a stack of electrochemical cells, fuel cell stacks and methods of heating

The invention relates to a heating device for a stack of electrochemical cells, the heating device comprising a heating layer and a first thermal insulating layer. The invention also relates to a fuel cell stack comprising the heating device and a method for heating parts of the fuel cell stack.

State of the art

A fuel cell is an electrochemical cell that converts the chemical reaction energy of a continuously supplied fuel and an oxidizing agent into electrical energy. A fuel cell is therefore an electrochemical energy converter. In known fuel cells, hydrogen (H ₂ ) and oxygen (O ₂ ) in particular are converted into water (H ₂ O), electrical energy and heat.

Among other things, proton exchange membrane (PEM) fuel cells are known. Proton exchange membrane fuel cells have a centrally arranged membrane that is permeable to protons, i.e. hydrogen ions. The oxidizing agent, in particular atmospheric oxygen, is thereby spatially separated from the fuel, in particular hydrogen.

Solid oxide fuel cells, which are also referred to as solid oxide fuel cells (SOFC), are also known. SO FC fuel cells have a higher operating temperature and exhaust gas temperature than PEM fuel cells and are used in particular in stationary operation. Fuel cells have an anode and a cathode. The fuel is fed to the anode of the fuel cell and is catalytically oxidized by releasing electrons to protons, which reach the cathode. The electrons released are diverted from the fuel cell and flow to the cathode via an external circuit.

The oxidizing agent, in particular atmospheric oxygen, is fed to the cathode of the fuel cell and reacts by absorbing electrons from the external circuit and protons to form water. The resulting water is drained from the fuel cell. The gross response is:

0 + 4H ⁺ + 4e - 2H ₂ 0

A voltage is applied between the anode and the cathode of the fuel cell. To increase the voltage, several fuel cells can be arranged mechanically one behind the other to form a fuel cell stack, which is also referred to as a stack, and electrically connected in series.

A fuel cell stack usually has end plates which press the individual fuel cells together and give the fuel cell stack stability. The end plates can also be used as a positive pole or negative pole of the fuel cell stack to divert the current if no separate current collectors are arranged between the respective outer fuel cells and the end plates.

The electrodes, that is to say the anode and the cathode, and the membrane can be structurally combined to form a membrane electrode assembly (MEA), which is also referred to as a membrane electrode assembly.

Fuel cell stacks also have bipolar plates, which are also referred to as gas distributor plates. Bipolar plates are used to evenly distribute the fuel to the anode and to distribute the oxidizing agent evenly to the cathode. Bipolar plates usually have a surface structure, for example channel-like structures, for distributing the fuel and the oxidizing agent to the electrodes. The channel-like Structures also serve to drain off the water produced during the reaction.

In addition, the bipolar plates can have structures for conducting a cooling medium through the fuel cell in order to dissipate heat.

In addition to the media supply with regard to oxygen, hydrogen and water, the bipolar plates ensure a flat electrical contact with the membrane.

The fuel cells in the fuel cell stack are often supplied with media, in particular hydrogen and oxygen, via supply channels or discharge channels arranged perpendicular to the membrane of the fuel cell. Media are also discharged via these supply channels or discharge channels. The supply channels or discharge channels are connected to the fuel cell, in particular to the bipolar plates, by ports, which can also be referred to as fluid connections.

Each fuel cell in the fuel cell stack is usually connected to the other fuel cells via the ports. The media are led from the ports through port feedthroughs into the actual so-called flow field, the active surface of the bipolar plate.

A fuel cell stack typically consists of up to a few hundred individual fuel cells that are stacked in layers as so-called sandwiches. The individual fuel cells have a membrane-electrode arrangement as well as a bipolar plate half on the anode side and on the cathode side.

The supply channels or discharge channels, which can also be referred to as media channels, are usually located at the edge of the fuel cell stack for the distribution of the media supplied from outside the fuel cell stack and discharged again to the outside. The supply channels or discharge channels usually run vertically through the individual bipolar plates and are produced by recesses which are arranged congruently one above the other and which form the ports. The fuel cell stack is usually terminated by two end plates. A current collector is usually arranged in each case adjacent to the end plates. The end plates usually have port structures into which the ports open from within the fuel cell stack.

If fuel cell stacks are put into operation at a temperature below the freezing point of water, frozen water can occur in particular at the port structures. This can also occur if the fuel cell stack can be heated electrically by means of a heating layer, since the port structures can be thermally insulated by an insulating intermediate layer and thus separated from the heating.

Areas of the end plates in a fuel cell stack can be so cold, especially when starting at temperatures below 0 ° C., that water in the fuel cell stack must be prevented from freezing. This is described, inter alia, in Maruo et al. “Development of Fuel Cell System Control for Sub-Zero Ambient Conditions”, SAE Technical Paper, 2017, doi: 10.4171 / 2017-01-1189.

When a cold fuel cell stack is started, the fuel cells comprised by the fuel cell stack heat up rapidly and with these the area of the ports or the supply channels and discharge channels in the stacking direction through the fuel cell stack also heats up. However, due to their heat capacity, the end plates prevent rapid heating of the edge areas, in particular the outer fuel cells, that is to say the first and last fuel cells in the fuel cell stack, and the port structures on the end plates.

In the area of the end plates, as described in US Pat. No. 9,525,185, heating elements such as heating foils can be provided, which can be arranged between the current collector and the end plate. In order to prevent the heating foil from primarily heating the end plate, a thermal barrier is provided between the heating foil and the end plate according to US Pat Heat flow from the heating foil in the direction of the end plate is prevented. Thus there is still the risk that water will get into the during a cold start Port structures of the end plate can freeze, so that the supply or disposal of the fuel cell stack with media can be impaired, as a result of which the efficiency and / or the service life of the fuel cell stack decrease.

Disclosure of the invention

A heating device for a stack of electrochemical cells, in particular a fuel cell stack, is proposed, the heating device comprising a heating layer with a first side and an opposite second side, a first thermal insulation layer and a second thermal insulation layer, the first thermal insulation layer on the first side the heating layer is arranged and the second thermal insulating layer is arranged on the second side of the heating layer and wherein the heating layer has a central region and an edge region and the first thermal insulating layer has a first recess at the edge region of the heating layer and the second thermal insulating layer has a second recess at the central area of the heating layer.

Furthermore, a fuel cell stack is proposed, comprising at least the following layers in the specified order: an end plate with port structures, a heating device according to the invention, a current collector, a membrane-electrode arrangement and a bipolar plate, the heating device being arranged between the current collector and the end plate in such a way that the first side of the heating layer faces the end plate and the second side of the heating layer faces the current collector.

The fuel cell stack preferably comprises two end plates, two heating devices and two current collectors, one of the heating devices preferably being arranged in each case between an end plate and a current collector.

In the fuel cell stack, the first thermal insulation layer and / or the second thermal insulation layer can be arranged on the heating layer and connected to it, for example by means of an adhesive. The first thermal insulation layer can additionally or alternatively be arranged on the end plate and possibly be connected to the end plate. The second thermal insulation layer can additionally or alternatively be arranged on the current collector and optionally connected to the current collector. The current collector is preferably a flat component.

The heating device is preferably a one-piece or multi-piece, flat component. Furthermore, the heating layer is preferably designed as a film. Furthermore, the heating layer is preferably constructed from a flexible material that can in particular adapt to unevenness of a surface of the end plate or of the current collector and can contact them. The heating layer can be constructed from electrically conductive polymers, in particular polypropylene (PP) containing a filler such as graphite, or comprise these, which heat up due to electrical resistance.

The heating layer is in particular a surface heating element. The heating layer can be designed as a resistance heater, preferably as separate wires or printed circuit board. In particular, the resistance heater has heating wires between two electrically insulating foils, that is to say the first thermal insulating layer and the second thermal insulating layer, it being possible for the foils to have different thicknesses on different sides in order to control the heat flow.

Alternatively, the heating layer can be implemented by means of electrically conductive polymers, which are also referred to as heat-inducing thermoplastics, which preferably have a power of 2 watt / cm ² to 3 watt / cm ² . The electrically conductive polymers are preferably processed into the heating layer by means of injection molding and / or film drawing. Preferred matrix materials of the electrically conductive polymers, which are also referred to as composites, are, for example, hard polyethylene or high density polyethylene (HDPE), polyphenylene sulfide (PPS), polypropylene (PP), polyvinylidene fluoride (PVDF) and mixtures thereof. The lower the electrical conductivity, the higher the resistance and the greater the heat generation. The electrically conductive polymers furthermore preferably contain an electrically conductive filler such as carbon black, graphite and / or metal powder, in particular in the form of particles.

The edge area and the central area of the heating layer can be connected to one, in particular a common, heating circuit. Alternatively, the the central area and the edge area of the heating system must be connected to different heating circuits.

The central area of the heating layer is preferably enclosed by the edge area of the heating layer. The central area further preferably has a rectangular shape if the active area of the membrane-electrode arrangement is rectangular, or it essentially simulates the geometry of the active area, that is to say of the electrochemically active area, of the membrane-electrode arrangement. The edge area has in particular the shape of a rectangular frame.

The first thermal insulation layer and / or the second thermal insulation layer are preferably designed as a coating on the heating layer or the end plate or the current collector. The first thermal insulation layer and / or the second thermal insulation layer preferably comprise ceramics and / or polymers such as PVDF, polytetrafluoroethylene (PTFE), PP, polyethylene (PE), polyetheretherketone (PEEK), acrylates and / or polystyrenes. The first thermal insulation layer and / or the second thermal insulation layer preferably consist of ceramics and / or polymers such as PVDF, polytetrafluoroethylene (PTFE), PP, polyethylene (PE), polyetheretherketone (PEEK), acrylates and / or polystyrenes. The polymers are particularly preferred. Mylar® foils can also be used as a first thermal insulation layer and / or as a second thermal insulation layer. In particular, the first thermal insulation layer and the second thermal insulation layer consist of the same material.

The first thermal insulation layer preferably has a first thickness and the second thermal insulation layer has a second thickness. The first thickness and / or the second thickness are preferably in a range from 19 μm to 500 μm.

In one embodiment, the second thickness does not differ by more than 30% from the first thickness, based on the first thickness.

Alternatively, the first thickness and the second thickness can be adapted as a function of a position on the heating layer. Thus, in the first recess and in the second recess, material of the first thermal insulation layer and the second thermal insulation layer, respectively, can be included of reduced or smaller thickness. The first thickness of the first thermal insulation layer in the edge area is preferably smaller than in the central area, more preferably by at least 30%, in particular by at least 60%, and preferably not more than 95%, smaller based on the larger first thickness in the central area Area. The second thickness of the second thermal insulating layer is preferably smaller in the central area than in the edge area, more preferably by at least 30%, in particular by at least 60%, and preferably not more than 95%, smaller in relation to the larger second thickness in the edge area. The thermal resistance of the first thermal insulation layer or the second thermal insulation layer depends preferably linearly on the first thickness or on the second thickness. For example, a smaller first thickness and / or a smaller second thickness can be 19 μm and a larger first thickness and / or a larger second thickness can be 60 μm.

The heating layer has a thermal insulating layer on both sides, the first thermal insulating layer and the second thermal insulating layer preferably overlapping by less than 30%, more preferably less than 10%, particularly preferably less than 5% and particularly preferably not, based on a total area of the heating location. In particular, there is a gap between the first thermal insulation layer and the second thermal insulation layer or between the edge area and the central area. The total area of the heating layer is to be understood in particular as the area of the first side or the area of the second side of the heating layer.

The heating layer is preferably in thermal contact with the end plate at the first recess and in thermal contact with the current collector at the second recess and optionally with a fuel cell of the fuel cell stack adjacent to the current collector, in particular with the membrane-electrode arrangement adjacent to the current collector. The membrane-electrode arrangement preferably comprises a polymer electrolyte membrane.

The first thermal insulation layer and / or the second thermal insulation layer can also be referred to as partial thermal barriers. The edge area preferably occupies 5% to 30% and the central area 70% to 95% of the heating layer, in each case based on the total area of the heating layer.

The first recess of the first thermal insulating layer is preferably essentially congruent with the edge region of the heating layer and / or the second recess of the second thermal insulating layer is essentially congruent with the central region of the heating layer.

Essentially congruent is to be understood to the effect that the first recess covers an area of the edge region to at least 90%, preferably at least 95% and in particular 99% and not more than 10%, preferably not more than 5% and particularly preferably not more than 1 % protrudes beyond the area of the edge area, in each case based on the total area of the edge area. The same applies to the second thermal insulation layer and the central area of the heating layer.

Furthermore, the central area of the heating layer is preferably congruent with an active surface of the membrane-electrode arrangement. The active surface is understood to mean, in particular, an area of the membrane-electrode arrangement in which an electrochemical reaction can actually take place on at least one side of the membrane due to the present construction or geometry and the present process parameters. These parameters relate in particular to the membrane, the catalytic converter on both sides, the supply of media, the electronic contacting of the catalytic converter layers, the temperature and the humidification.

The edge region of the heating layer preferably comprises ports. The edge region of the heating layer further preferably comprises all ports of the fuel cell stack which in particular open into the port structure of the end plate.

The edge region of the heating layer is preferably essentially congruent with the port structure of the end plate or larger. More preferably, the edge area of the heating layer is at least 10%, more preferably at least 30% and particularly preferably at least 50% larger than an area of the end plate that is occupied by the port structure, based on the area of the end plate that is occupied by the port structure. The end plate is preferably constructed from a polymer-metal composite material, in particular in order to keep the heat capacity of the end plate low. If the end plate is constructed from a polymer-metal composite material, part of the end plate can constitute the first thermal insulation layer.

The invention also relates to a method for heating parts of the fuel cell stack according to the invention, the port structures of the end plate being heated by means of the edge region of the heating layer and the active surface of the membrane-electrode arrangement being heated by means of the central region of the heating layer. This is to be understood to the effect that there is a heat flow between the port structures and the edge area which is greater than a heat flow between the port structures and the central area and vice versa. In particular, the port structures and the active surface are heated with the same heating layer. The membrane-electrode arrangement is in particular a membrane-electrode arrangement arranged adjacent to the current collector.

The heating device can also be used in heat exchangers and / or plate filters.

Advantages of the invention

The heating device according to the invention or the fuel cell stack according to the invention and the method according to the invention optimize a heat flow of a heater, in particular an auxiliary heater for cold starts, of the fuel cell stack. The port structures of the end plates and the active area, in particular the outer fuel cells, can be optimally defrosted or heated with just one heating layer. Accordingly, only one component is required for heating.

The energy requirement up to a point in time at which both the active surface of an outer fuel cell in the fuel cell stack and the port structure of the end plate are sufficiently heated is minimized, since one is superfluous Heating of the core of the end plate and the edge area of the fuel cell by the heating layer can be avoided.

Freezing of water in the fuel cells and the end plates of the fuel cell stack and thus an impaired supply or disposal of the fuel cell stack with media is reduced or prevented. This leads to a higher degree of efficiency and an increased service life of the fuel cell stack.

In the case of an end plate made of polymer-metal composite material that can be used for weight reduction, the heating device according to the invention is particularly advantageous since the heat flow from the heated ports or the heated port structure is reduced.

Brief description of the drawings

Embodiments of the invention are explained in more detail with reference to the drawings and the following description.

Show it:

Figure 1 is a schematic view of a fuel cell stack,

Figure 2 is a side view of a fuel cell stack according to the invention,

FIG. 3 shows a plan view of a first end plate of the fuel cell stack according to FIG. 2,

FIG. 4 shows a plan view of a membrane-electrode arrangement of the fuel cell stack according to FIG. 2,

FIG. 5 shows a plan view of a first side of a first heating device of the fuel cell stack according to FIG. 2,

FIG. 6 shows a plan view of a second side of the first heating device, FIG. 7 shows a plan view of a second end plate of the fuel cell stack according to FIG. 2,

FIG. 8 shows a plan view of a first side of a second heating device of the fuel cell stack according to FIG. 2 and FIG

FIG. 9 is a plan view of a second side of the second heating device.

Embodiments of the invention

In the following description of the embodiments of the invention, the same or similar elements are denoted by the same reference numerals, a repeated description of these elements being dispensed with in individual cases. The figures represent the subject matter of the invention only schematically.

FIG. 1 shows a schematic illustration of a fuel cell stack 4 with a plurality of fuel cells 3. Each fuel cell 3 has a membrane 23, two gas diffusion layers 1, an anode side 31 and a cathode side 32. The individual fuel cells 3 are delimited from one another by bipolar plates 50, which can include a cooling plate 45.

The fuel cell stack 4, to which hydrogen 40 and oxygen 42 and a coolant 44 are supplied, is closed off by two end plates 48 and has current collectors 52. The various inlets are separated from one another by seals 46. A heating device 12 is arranged between each end plate 48 and a current collector 52.

FIG. 2 shows a side view of a fuel cell stack 4 which has a first end plate 47 and a second end plate 49.

The fuel cell stack 4 also has two heating devices 12. A first heating device 11 is arranged between the first end plate 47 and a current collector 52. A second heating device 13 is arranged between the second end plate 49 and a further current collector 52. the Heating devices 12 each have a heating layer 54 with a first side 56 and a second side 58 which lies opposite the first side 56.

Furthermore, the heating devices 12 each include a first thermal insulation layer 60 and a second thermal insulation layer 62. The first thermal insulation layer 60 is arranged on the first side 56 of the heating layer 54 and the second thermal insulation layer 62 is in each case on the second side 58 of the heating layer 54 arranged.

The heating layers 54 each have a central region 64 and an edge region 66. The first thermal insulating layer 60 has a first recess 68 on the edge region 66 of the respective heating layer 54 and the second thermal insulating layer 62 has a first recess 68 on the central region 64 of the respective heating layer 54 second recess 70. The first recess 68 is in each case congruent with the edge region 66 and the second recess 70 is in each case congruent with the central region 64.

The first thermal insulation layers 60 each have a first thickness 74 and the second thermal insulation layers 62 each have a second thickness 76, the first thickness 74 being equal to the second thickness 76 in the embodiment shown.

In the fuel cell stack 4, bipolar plates 50 and membrane electrode assemblies 80 are stacked between the current collectors 52. The bipolar plates 50, the membrane electrode arrangements 80 and one of the heating layers 54 have ports 72 which lead through the fuel cell stack 4 and open into port structures 78 of the first end plate 47.

The heating devices 12 are each arranged between the current collector 52 and the respective end plate 48 in such a way that the first side 56 points towards the end plate 48 and the second side 58 towards the current collector 52.

The membrane-electrode arrangements 80 also each have an active surface 82, the central areas 64 of the heating layers 54 each being congruent with the active surfaces 82 of the membrane-electrode arrangements 80. The port structures 78 of the first end plate 47 can be heated by means of the edge region 66 of the heating layer 54 of the first heating device 11 and the active surface 82 of an adjacent membrane-electrode arrangement 80 can be heated by means of the central region 64 of the heating layer 54 of the first heating device 11. The first cutout 68 of the first thermal insulation layer 60 is located on the edge area 66 of the heating layer 54 and the second cutout 70 of the second thermal insulation layer 62 is located on the central area 64 of the heating layer 54.

FIG. 3 shows a plan view of the first end plate 47 according to FIG. 2, which has the port structures 78.

FIG. 4 shows a plan view of a membrane-electrode arrangement 80 of the fuel cell stack 4 according to FIG. 2, which comprises ports 72 and an active surface 82.

FIG. 5 shows a top view of the first side 56 of the first heating device 11 according to FIG the first end plate 47 can be heated.

FIG. 6 shows a top view of the second side 58 of the first heating device 11 of the fuel cell stack 4 according to FIG. 2. Ports 72 are located in the edge region 66 of the heating layer 54, which is covered with the second thermal insulation layer 62.

The second recess 70 is located in the central region 64 of the heating layer 54, so that the heating layer 54 can emit a heat flow in the central region 64, with which the active surface 82 of an adjacent membrane-electrode arrangement 80 can be heated.

FIG. 7 shows a plan view of the second end plate 49.

FIG. 8 shows a top view of the first side 56 of the second heating device 13 according to FIG. 2, which is arranged on the second end plate 49, and FIG. 9 shows a top view of the second side 58 of the second heating device 13 according to FIG. 2. FIG. 8 essentially corresponds to FIG. 5 and FIG. 9 essentially corresponds to FIG. 6, with the difference that the second heating device 13, in contrast to the first heating device 11, does not have any ports 72. The invention is not restricted to the exemplary embodiments described here and the aspects emphasized therein. Rather, a large number of modifications are possible within the range specified by the claims, which are within the scope of expert knowledge.

Claims

Expectations

1. Heating device (12) for a stack of electrochemical cells, the heating device (12) having a heating layer (54) with a first side (56) and an opposite second side (58), a first thermal insulating layer (60) and a second thermal Comprises insulating layer (62), the first thermal insulating layer (60) is arranged on the first side (56) of the heating layer (54) and the second thermal insulating layer (62) is arranged on the second side (58) of the heating layer (54) and wherein the heating layer (54) has a central region (64) and an edge region (66) and the first thermal insulating layer (60) has a first recess (68) in the edge region (66) of the heating layer (54) and the second thermal insulating layer (62) has a second recess (70) in the central region (64) of the heating layer (54).

2. Heating device (12) according to claim 1, characterized in that the first recess (68) of the first thermal insulating layer (60) is essentially congruent with the edge region (66) of the heating layer (54) and / or the second recess (70 ) the second thermal insulation layer (62) is essentially congruent with the central region (64) of the heating layer (54).

3. Heating device (12) according to claim 1 or 2, characterized in that the edge region (66) of the heating layer (54) comprises ports (72).

4. Heating device (12) according to one of the preceding claims, characterized in that the edge area (66) of the heating layer (54) occupy 10% to 30% and the central areas (64) of the heating layer (54) occupy 70% to 90%, each based on a total area of the heating layer (54).

5. Heating device (12) according to one of the preceding claims, characterized in that the heating layer (54) is constructed from a flexible material.

6. Heating device (12) according to one of the preceding claims, characterized in that the heating layer (54) comprises electrically conductive polymers.

7. Fuel cell stack (4) comprising at least the following layers in the specified order: an end plate (48) with port structures (78), a heating device (12) according to one of claims 1 to 6, a current collector (52), a membrane-electrode arrangement (80) and a bipolar plate (50), the heating device (12) being arranged between the current collector (52) and the end plate (48) in such a way that the first side (56) of the heating layer (54) faces the end plate (48) and shows the second side (58) of the heating layer (54) to the current collector (52).

8. The fuel cell stack (4) according to claim 7, characterized in that the central region (64) of the heating layer (54) is essentially congruent with an active surface (82) of the membrane-electrode arrangement (80).

9. fuel cell stack (4) according to claim 7 or 8, characterized in that the end plate (48) is constructed from a polymer-metal composite material.

10. The method for heating parts of a fuel cell stack (4) according to any one of claims 7 to 9, wherein the port structures (78) of the end plate (48) by means of the edge region (66) of the heating layer (54) and the active surface (82) of the Membrane-electrode arrangement (80) are heated by means of the central region (64) of the heating layer (54).