FR2930681A1 - Cathode humidifier bypass system for proton exchange membrane fuel cell in e.g. public transport field, has pipe placed between pipe exhausting gas from stack and water rejecting pipe to form outlet bypass - Google Patents

Abstract

The system has pipe (9) provided with a valve (10) and placed between a pipe (3) supplying comburant gas to a humidifier (4) and a pipe (5) supplying the comburant gas to a stack (6) for forming an inlet bypass. A pipe (11) is provided with a valve (12) and placed between a pipe (7) exhausting the gas from the stack and a water rejecting pipe (8) for forming an outlet bypass. The humidifier is placed in fluid communication with the pipes (3, 5, 7, 8). An independent claim is also included for a method for eliminating water droplets formed in a stack of a proton exchange membrane fuel cell.

Description

The present invention relates to a PEM type fuel cell, and more particularly to a PEM type fuel cell with short-circuit or bypass systems of the humidifier.

The Fuel Cell works by the opposite process of electrolysis. It restores water from hydrogen and oxygen from the air, producing electricity and heat. This non-polluting reaction (the battery produces only water) is obtained in each of the base cells which are associated to constitute a module of energy of the desired power: the stack. Fuel cells have many advantages, and in particular: - high energy efficiency net electric efficiency of a battery varies between 30 and 70%, in comparison, that of a combustion engine is on average 20%; - low sound levels: only certain components such as the compressor and the ventilation system produce a slight noise. The noise emissions are very low of the order of 40 to 50 dB at 1m; - Modularity The stack consists of elementary cells placed in series and in parallel to obtain the desired voltage-intensity torque.

Despite recent development progress and the emergence of new materials that have made it possible to consider different applications of fuel cells in the fields of public transport, stationary, small portable and energy distribution, industrialists are still working to improve the performance of these batteries.

One of the elements known and likely to reduce these performances comes from the control of the moisture content in the stack. Furthermore, it is necessary to make the ignition of such batteries possible in all atmospheric conditions. Thus, it has been found that at high current density, water accumulates in the channels and blocks reagent supply, thereby reducing the active surface of the electrode-membrane-electrode assembly (EME or Membrane). Assembly Electrode MEA). It is then necessary to increase the feed rate of reagents and stoichiometry to remove liquid water. However, this leads to increased consumption of the compressor and therefore a loss of performance of the battery. In addition, irreversible mechanical damage to the gas diffusion membranes can be caused by a build-up of water in the channels. Even though microchannel design, plate design, material selection, feed gas properties, current density, operating temperature, assembly pressure, etc. are set to optimize the operation of the microchannels. heterogeneities in the control of these parameters lead to unpredictable operating conditions that make the formation of water droplets inevitable. It is therefore necessary to provide the systems with effective means of eliminating these droplets. A proposal for a solution to the loss of performance by water accumulation has been described in patent application US2006 / 0029837. However this solution does not prove completely satisfactory. Surprisingly and surprisingly, the present inventors have found that it is possible to overcome the operating difficulties of a fuel cell whose cathode system is connected to a humidifier by providing a humidifier bypass system. in the incoming direction and a bypass system of the humidifier in the outgoing direction. This system is particularly suitable for fuel cells whose cathode system is equipped with its own humidifier, that is to say the fuel cells whose humidification of the cathode system and humidification of the anode system are independent. Such cells are for example described in FR 2 843 236.

Thus, the invention relates to a bypass system of a fuel cell cathode humidifier comprising: a humidifier; - a stack; a conduit for supplying the oxidizing gas, such as air, into the humidifier; a conduit for supplying the stack with oxidant gas; an outlet pipe for the comburant gas of the stack; and - a water discharge duct; said humidifier being in fluid communication with: - the supply duct of the oxidizing gas, in order to allow the humidification of the incoming oxidizing gas, - the supply duct of the comburant gas of the stack, - the outlet duct of the oxidizing gas the stack, and - the water discharge pipe; A first conduit having a valve being disposed between the combustion gas supply duct in the humidifier and the combustion gas supply duct of the stack, thus forming a first bypass of the humidifier (which is called in the following incoming bypass); A second conduit having a valve being disposed between the stack oxidant gas outlet conduit and the oxidizer gas rejection conduit, thereby forming a second bypass of the humidifier (hereinafter referred to as outgoing bypass) . Through the water rejection pipe, the evacuated water is mixed with the depleted oxygen gas leaving the stack.

According to a first embodiment of the system of the invention, said valves are operable simultaneously. Thus, the two bypass systems, i.e., the inbound bypass and the outgoing bypass are activated together, so most of the fluid no longer flows through the humidifier.

In the present invention, the major part is understood to mean at least 75%, preferably at least 90% and even more preferably at least 95%. According to a second embodiment, said valves are independently operable. It is then possible to actuate the valve of the incoming bypass and thus the flow of incoming oxidant gas no longer passes through the humidifier or, it is possible to actuate the outgoing bypass valve and thus the flow out of the stack is directly extracted of the system.

In an advantageous embodiment, the valves are all or nothing valves. The valves are actuated automatically according to a pre-established opening and closing scheme or the closing and opening of the valves can be caused by the triggering of a predefined event. According to another embodiment, the valves are variable opening valves that modulate the flow and thus achieve partial bypass of the humidifier on both the incoming flow and the outgoing flow.

Thus, it is possible to pass only a portion of the flow into the humidifier, so as to regulate the moisture content of the air while reducing the pressure drop due to the passage of the humidifier.

The invention also relates to a fuel cell of the PEM type comprising a bypass system of the humidifier as described above. The battery according to the invention is a battery of the PEM type in which only the cathode stream is humidified in the humidifier, the flow of hydrogen at the anode is not wetted by the same humidifier. The cathodic flow or oxidizing gas is either oxygen or, and less expensively, ambient air. The subject of the invention is also a method for eliminating water droplets formed in the stack of a PEM fuel cell, according to which the water accumulated in the stack is forced towards the outlet duct of the stack by decreasing the pressure loss due to the presence of the humidifier. The pressure drop is reduced by shunting the incoming oxidant gas flow that no longer crosses the humidifier (incoming bypass) and / or by shunting the combustion gas flow out of the stack that no longer crosses the humidifier (outgoing bypass). The method is advantageously implemented using the bypass system according to the invention described above. According to an advantageous embodiment of the method of the invention, the incoming bypass and the outgoing bypass are performed simultaneously, thus a minimal pressure drop is imposed on the flow. It crosses the stack at a significant flow and pressure, thus facilitating the elimination of water droplets that are mechanically forced by the flow through the stack to the outlet. The method of the invention can thus reduce the pressure drop by at most about twice the pressure drop due to the presence of the humidifier.

According to another embodiment, the incoming bypass and the outgoing bypass are made separately. This method is particularly suitable in the case of average current density, or in the case where only a few channels are blocked by the presence of water droplets and less mechanical effort is required to unlock them. According to an advantageous embodiment, the incoming bypass is carried out regularly for a time t and at intervals AT, t being between 0.01s and 2s, preferably between 0.2s and 1s and still more preferably between 0.3s and 0.5s and AT being between 2s and 10min, preferably between 5s and 30s and more preferably between 10s and 15s. Of course, those skilled in the art are able to adapt the values t and AT depending on the operating conditions of the battery. Advantageously, the outgoing bypass is realized simultaneously. It is thus possible to purge the system systematically at regular intervals of time. According to a particular embodiment, it is possible to purge the system when the performance decreases. The method then includes a parameterization of the opening and closing of the valves as a function of a threshold value of a parameter measured during the entire process time which makes it possible to detect the presence of excess liquid water. The process is easy to implement and allows a regular removal of any droplet of unwanted water. The method also makes it possible to start when the temperatures are negative. In this case, the water solidified in the humidifier prevents any supply of the stack in airflow, so we open the valve of the incoming bypass, the combustion gas feeds the stack, the outgoing heated oxidant gas is sent into the humidifier causing the gradual thawing of the water of it. As soon as the humidifier regains a positive operating temperature, the incoming bypass valve can be operated again according to normal battery operation. Similarly, at negative temperatures, if the stack is supplied with humidified combustion air, the water thus introduced into the membranes can solidify and obstruct the flow circulation. The bypass valve can then be opened in such a way that dry air is brought into the stack which will gradually regain a positive operating temperature, the water will become liquid again and can be eliminated. It is also possible to temporarily stop the operation of the battery and force dry air into the stack by opening the incoming bypass while leaving the compressor running, the incoming dry air is then forced to the outlet duct. The method according to the invention also allows the restart of the system when the humidifier is too wet or completely dried. In the case where it is too wet, at start-up, the inlet bypass valve is kept open and the outgoing bypass valve is opened. The incoming oxidant gas is not humidified and dries the humidifier, and the flow out of the stack, humidified, is directly eliminated without passing through the humidifier. In the case of a dry humidifier, at start-up the valve of the incoming bypass valve is opened by keeping the outgoing bypass valve closed, the oxidizing gas is introduced into the stack, the outgoing stream enriched with water is then introduced into the humidifier for recharge it with moisture. The invention will be described with the aid of the following drawing which is given solely for illustrative and non-limiting purposes. In this drawing, Figure 1 shows schematically a cathode system of a fuel cell according to the invention.

Air, as a combustion gas, is fed through line 1 into a compressor or booster 2, then through a duct 3 into the humidifier 4. The humidified air leaves the humidifier 4 by a conduit 5 which supplies the stack 6. The air leaving the stack 6 is returned via the conduit 7 to the humidifier 4 where it is rejected by the conduit 8. A bypass 9, with a valve of regulation 10, is placed between the pipes 3 and 5, this bypass is called inbound bypass. A second bypass 11, equipped with a regulating valve 12, is placed between the pipes 7 and 8, this bypass is called outgoing bypass. Thus, in conventional operation, the valves 10 and 12 are closed and regularly purge the system by simultaneously opening the valves 10 and 12.

When the valves 10 and 12 are closed, the total pressure imposed by the compressor between the outlet of the compressor and the water discharge duct is Ptotale-Patm = 2xAP4 + AP6, AP4 being the pressure drop due to the humidifier and AP6 being the pressure drop due to the stack. For example, in a battery delivering a current of 40A, the pressure drop due to the humidifier AP4 is about 40mbar and the pressure drop due to the AP6 stack is about 100mbar. If we consider the case where the pressure drop between the ducts 3 and 5 and between the ducts 7 and 8 is of the order of 40mbars, then, when the valves 10 and 12 are opened, the pressure difference between the ducts 5 and 7 is of the order of 80mbars greater than that encountered when the valves 10 and 12 are closed. This additional pressure difference will cause a greater force on the water droplets present in the stack channels and cause their mechanical drainage. This is achieved without increasing the power of the compressor, that is to say without additional energy consumption.

Of course, by operating one of the two valves, the additional pressure difference will be reduced by half. It may nevertheless be sufficient in cases where lesser amounts of water have to be removed.5

Claims (11)

REVENDICATIONS1. A fuel cell cathode humidifier bypass system comprising: - a humidifier (4); - a stack (6); a conduit for supplying the combustion gas into the humidifier (3); a pipe for supplying oxidant gas to the stack (5); an outlet pipe for the oxidant gas of the stack (7); and - a water discharge duct (8); said humidifier (4) being in fluid communication with: the combustion gas supply duct (3), in order to allow humidification of the incoming combustion gas, the combustion gas supply duct of the stack (5), the the combustion gas outlet pipe of the stack (7), and the water discharge duct (8); the system further comprising a first conduit (9) having a valve (10), which is disposed between the oxidizer gas supply duct (3) in the humidifier and the combustion gas supply duct of the stack (5), thus forming a first bypass of the humidifier (4); and a second conduit (11) having a valve (12), which is disposed between the oxidizer gas outlet pipe of the stack (7) and the water rejection conduit (8), thereby forming a second bypass of the humidifier (4). 2. System according to claim 1, characterized in that said valves (10,12) are operable simultaneously. 3. System according to claim 1, characterized in that said valves (10, 12) are all-ourien valves. 4. PEM fuel cell comprising a humidifier bypass system as described in any one of claims 1 to 3. 5. Battery according to claim 4, characterized in that only the cathode system is provided with its own humidifier. 6. A method of removing water droplets formed in the stack of a PEM fuel cell as defined in claim 4 or 5, wherein the water accumulated in the stack is forced to the feed pipe. output of the stack by reducing the pressure drop due to the presence of the humidifier. 20 7. A method according to claim 6, characterized in that the decrease in the pressure drop due to the presence of the humidifier is obtained by bypassing the flow of incoming oxidant gas which no longer passes through the humidifier (bypass entering) and or by bypassing the flow of oxidant gas leaving the stack which no longer passes through the humidifier (outgoing bypass). 8. Method according to claim 6 or 7, characterized in that the incoming bypass and the outgoing bypass are made simultaneously. 9. Method according to claim 6 or 7, characterized in that the incoming bypass and the outgoing bypass are made separately. 10. Method according to any one of claims 6 to 8, characterized in that the incoming bypass is carried out regularly for a time t and AT intervals, t being between 0.01s and 2s, preferably between 0, 2s and 1s and even more preferably between 0.3s and 0.5s and AT being between 2s and 10min, preferably between 5s and 30s and more preferably between 10s and 15s. 11. The method of claim 10, characterized in that the outgoing bypass is performed simultaneously.