DE102021200005A1 - Method and device for recirculating anode gas in an anode circuit of a fuel cell system, fuel cell system - Google Patents

Abstract

The invention relates to a method for recirculating anode gas in an anode circuit of a fuel cell system, in which at least two jet pumps (1, 2) connected in parallel are used, which are operated individually or jointly depending on the load. The invention also relates to a device (10) for recirculation of anode gas in an anode circuit of a fuel cell system and a fuel cell system with a device (10) according to the invention.

Description

The invention relates to a method for recirculating anode gas in an anode circuit of a fuel cell system. A device for recirculating anode gas in an anode circuit of a fuel cell system is also proposed. The device enables the method according to the invention to be carried out. In addition, the invention relates to a fuel cell system with a device according to the invention.

State of the art

A fuel cell system includes at least one fuel cell, which can be used to convert a fuel, for example hydrogen, and an oxidizing agent, for example oxygen, into electrical energy, heat and water. For this purpose, the fuel cell has an anode and a cathode. During operation of the fuel cell system, the anode is supplied with the fuel and the cathode with the oxidizing agent. The fuel is therefore the anode gas.

Systemically, when supplying the anode with fuel or anode gas, the approach has become established of recirculating the anode gas exiting the fuel cell, which is still rich in fuel, and feeding it back to the anode together with fresh fuel. Here, a jet pump - alone or in combination with a recirculation fan - is often used as the gas delivery unit. The problem here is a decreasing recirculation performance of the jet pump in the partial load range or in the low load range.

The present invention is concerned with solving this problem. The method with the features of claim 1 and the device with the features of claim 5 are proposed for the solution. Advantageous developments of the invention can be found in the respective dependent claims. Furthermore, a fuel cell system with a device according to the invention is specified.

Disclosure of Invention

In the proposed method for recirculating anode gas in an anode circuit of a fuel cell system, at least two jet pumps connected in parallel are used, which are operated individually or jointly depending on the load.

By providing at least one additional jet pump, which is preferably designed for a different load range than the first jet pump, one or the other jet pump can be activated depending on the load. In principle, both jet pumps can also be used for the recirculation of anode gas. In this way, a consistently high recirculation performance can be achieved, both at high and at low loads.

At low load, only one jet pump and/or one jet pump designed for low load is preferably operated. This leads to a load-adapted recirculation performance. A high-load jet pump can be provided for high loads, which is then operated instead of or together with the low-load jet pump.

Furthermore, it is proposed that a valve is used to control at least one jet pump, via which fresh anode gas is supplied to the jet pump. The jet pump can thus be controlled separately from the at least one other jet pump; in particular, the jet pump can be switched on or off.

The valve for controlling the jet pump or supplying fresh anode gas is preferably arranged upstream of a driving nozzle of the jet pump. With the aid of the motive nozzle, a fluid jet is generated from fresh anode gas, which generates the pumping effect required for recirculation. The fresh anode gas therefore serves as the motive medium. If the supply of fresh anode gas is prevented, the jet pump remains deactivated, which means that no depleted anode gas is drawn in from a recirculation line connected to the jet pump.

In a development of the invention, it is proposed that a metering valve, preferably a metering valve with an integrated propulsion nozzle, be used to control the at least one jet pump. A separate driving nozzle can thus be omitted. The dosing valve can then be integrated into the jet pump instead of the driving nozzle. In this way a compact arrangement is created. By integrating the driving nozzle into the metering valve, the pressure loss can also be reduced and the efficiency of the jet pump increased.

If only one jet pump is operated, there is a risk that anode gas will be sucked back via an inactive jet pump. In a further development of the invention, it is therefore proposed that, when only one jet pump is in operation, a backflow of anode gas through an inactive jet pump is prevented with the aid of at least one blocking element, for example a flap or a valve. The use of a flap as a blocking element is particularly easy to implement, in particular when it opens and closes under pressure control. An additional actuator is not necessary in this case. If a valve, in particular a non-return valve, is used as the blocking element, this can also be a passive or pressure-controlled valve, so that implementation is comparatively simple here as well.

The at least one blocking element is preferably arranged on the outlet side. If each jet pump has its own outlet, a blocking element is preferably arranged in the area of each outlet. However, if the flow paths of the jet pumps are combined on the outlet side, only one blocking element is preferably arranged in the area of a common outlet in order to prevent anode gas from flowing back. This one blocking element can preferably not only be opened and closed, but also assume an intermediate position in order to operate several jet pumps at the same time. This means that all flow paths are open in the intermediate position of the blocking element. The flow paths are then combined downstream of the one blocking element.

The additionally proposed device for the recirculation of anode gas in an anode circuit of a fuel cell system comprises at least two jet pumps connected in parallel, which can be operated individually or together depending on the load. The proposed device is therefore particularly suitable for carrying out the method according to the invention described above. The same advantages can thus be achieved with the aid of the device as with the aid of the method according to the invention described above. In particular, a consistently high recirculation capacity can be provided since the jet pumps can be controlled separately from one another.

According to a preferred embodiment of the device, the two jet pumps connected in parallel are structurally coupled. They preferably form a structural unit. A particularly compact device can be created in this way. In addition - as described below - the number of connections can be reduced.

For example, the jet pumps connected in parallel can have a common inlet for fresh anode gas and/or a common inlet for recirculated anode gas. In this case, the common inlet and/or the common inlet are/is preferably arranged on the side. If both a common inlet and a common inflow are present, they can be arranged on the same side or on different sides of the device.

Alternatively or additionally, it is proposed that the jet pumps connected in parallel have a common outlet. The advantages of a common outlet have already been described above; in particular, only one blocking element is required to prevent anode gas from undesirably flowing back through an inactive jet pump.

At least one jet pump preferably has a valve on the inlet side. The valve can in particular be a metering valve that enables fresh anode gas to be metered in precisely. The valve is preferably arranged upstream of a propulsion nozzle integrated into the jet pump, with the aid of which the desired pumping effect can be achieved. Alternatively, a metering valve with an integrated motive nozzle can be used in the inlet area, so that a separate motive nozzle is not required. In this way, the device can be made even more compact. The integrated propulsion nozzle is controlled with the help of the dosing valve.

Furthermore, at least one jet pump preferably has a blocking element on the outlet side, for example a flap or a valve, in particular a check valve. If the jet pumps are not brought together on the outlet side, each jet pump has its own blocking element to prevent undesired backflow. If the jet pumps are brought together on the outlet side, they can have a common blocking element. In this way, the number of blocking elements can be reduced. The at least one blocking element is preferably actuated in a pressure-controlled manner, so that no additional actuators are required.

According to a preferred embodiment of the invention, the jet pumps are brought together on the outlet side and upstream of the meeting point a single blocking element in the form of a flap is arranged, by means of which a flow path through the first or the second jet pump can be shut off, so that backflow through the respective inactive jet pump is prevented . In addition, the flap can preferably assume an intermediate position in which the flow paths of both jet pumps are released. In the intermediate position of the blocking element or the flap, all jet pumps can thus be operated simultaneously.

Since the preferred area of application of the device according to the invention is a fuel cell system, a fuel cell system with a device according to the invention is also proposed. The device is arranged in an anode circuit of the fuel cell system. Of the The anode circuit preferably comprises an inflow path, via which a fuel cell stack of the fuel cell system can be supplied with anode gas, and a recirculation path, via which depleted anode gas exiting the fuel cell stack is recirculated. The device according to the invention connects the recirculation path to the inflow path of the anode circuit. This means that the device is connected both to the inflow path and to the recirculation path. In addition, at least one connection of the device to a storage facility for fresh anode gas is provided. The fresh anode gas is introduced into a jet pump upstream of a driving nozzle with the aid of a valve, preferably a metering valve, so that a fluid jet is generated which achieves the desired pumping effect. Instead of a separate motive nozzle, a dosing valve with an integrated motive nozzle can be used.

• 1 einen schematischen Längsschnitt durch eine erfindungsgemäße Vorrichtung gemäß einer ersten bevorzugten Ausführungsform mit einem Sperrelement in einer ersten Schließstellung,
• 2 die Vorrichtung der 1 mit dem Sperrelement in einer zweiten Schließstellung,
• 3 die Vorrichtung der 1 mit dem sperre Element in einer Zwischenstellung,
• 4 einen schematischen Längsschnitt durch eine erfindungsgemäße Vorrichtung gemäß einer zweiten bevorzugten Ausführungsform, und
• 5 einen schematischen Längsschnitt durch eine erfindungsgemäße Vorrichtung gemäß einer dritten bevorzugten Ausführungsform.

Preferred embodiments of the invention are explained in more detail below with reference to the accompanying drawings. These show:

• 1 a schematic longitudinal section through a device according to the invention according to a first preferred embodiment with a blocking element in a first closed position,
• 2 the device of 1 with the blocking element in a second closed position,
• 3 the device of 1 with the locking element in an intermediate position,
• 4 a schematic longitudinal section through a device according to the invention according to a second preferred embodiment, and
• 5 a schematic longitudinal section through a device according to the invention according to a third preferred embodiment.

Detailed description of the drawings

The one in the 1 The device 10 shown can be used for the recirculation of anode gas in an anode circuit of a fuel cell system (not shown). To avoid a decreasing recirculation performance, the device 10 has a first jet pump 1 and a second jet pump 2 . The two jet pumps 1, 2 are connected in parallel and combined to form a structural unit. Both jet pumps 1 , 2 can be controlled separately via valves 3 , 4 . The valves 3, 4 are each integrated into the jet pumps 1, 2 in the area of an inlet 8, so that the jet pumps 1, 2 can be supplied with fresh anode gas via the valves 3, 4. Downstream of the valves 3, 4 a propulsion nozzle 7 is arranged in an intake chamber 11, 12 of the respective jet pump 1, 2. The pumping effect required for recirculation is generated with the aid of the propulsion nozzles 7 . The fresh anode gas supplied via the valves 3, 4 acts as a driving medium.

At the level of the driving nozzles 7 there is a common inlet 6 through which the recirculated anode gas is drawn in. Both jet pumps 1 , 2 each have a mixing tube 13 , 14 adjoining the intake chamber 11 , 12 and a diffuser 15 , 16 following thereon, via which the recirculated anode gas enriched with fresh anode gas is fed to a common outlet 9 . This is because the flow paths of the two jet pumps 1, 2 are brought together on the outlet side. The device 10 can be connected to a fuel cell stack (not shown) via the common outlet 9 .

In order to prevent anode gas from flowing back via the respective inactive jet pump 1, 2 when only one of the two jet pumps 1, 2 is in operation, a blocking element 5 in the form of a flap is provided in the area of the common outlet 9. In the 1 the flap is shown in a first closed position. In this position, the flap prevents anode gas from flowing back via jet pump 1, which is inactive while jet pump 2 is active. If the situation is reversed, so that the jet pump 1 is active and the jet pump 2 is inactive, a backflow of anode gas via the jet pump 2 can be prevented by moving the flap into a second closed position. This is an example in the 2 shown. The flap is actuated under pressure control, so that when both jet pumps 1, 2 are in operation, the flap assumes an intermediate position in which the flow paths of both jet pumps are at least partially released. The volume flows are brought together by both jet pumps 1, 2 downstream of the flap. This position of the flap is an example in the 3 shown.

Of the 4 a second embodiment of a device 10 according to the invention can be seen. The valves 3, 4 are designed here as metering valves with integrated driving nozzles 7, so that separate driving nozzles 7 are not required. In addition, the device 10 of 4 only a common inlet 8 for fresh anode gas, which is arranged laterally. The inlet 8 is arranged in the vicinity of a common inlet 6 for recirculated anode gas, so that the connection situation is simplified.

Of the 5 A third embodiment can be seen, which is a modification of that in FIG 4 device 10 shown is. The two jet pumps 1, 2 are on the outlet side here not brought together, but each have their own outlet 9 with an integrated blocking element 5, the blocking elements 5 being designed as check valves. Only downstream of the two check valves are the volume flows brought together by the two jet pumps 1, 2. The inlet 8 for fresh anode gas is also arranged on the side of the device 10 facing away from the inlet 6 for the recirculated anode gas. Incidentally, the in the 5 shown device 10 of the 4 .

Claims (11)

Process for the recirculation of anode gas in an anode circuit of a fuel cell system, in which at least two jet pumps (1, 2) connected in parallel are used, which are operated individually or jointly depending on the load. procedure after claim 1 , characterized in that at low load only one and/or one jet pump (1) designed for low load is operated. procedure after claim 1 or 2 , characterized in that to control at least one jet pump (1, 2) a valve (3, 4), preferably a metering valve, further preferably a metering valve with an integrated driving nozzle (7), is used, via which the jet pump (1, 2) fresh anode gas is supplied. Method according to one of the preceding claims, characterized in that when only one jet pump (1, 2) is in operation, anode gas is prevented from flowing back through the respective other jet pump (2, 1) with the aid of at least one blocking element (5), for example a flap or a valve , In particular a check valve is prevented. Device (10) for recirculating anode gas in an anode circuit of a fuel cell system, comprising at least two jet pumps (1, 2) connected in parallel, which can be operated individually or together depending on the load. Device (10) after claim 5 , characterized in that the jet pumps (1, 2) connected in parallel are structurally coupled, preferably forming a structural unit. Device (10) after claim 5 or 6 , characterized in that the jet pumps (1, 2) connected in parallel have a common inlet (8) for fresh anode gas and/or a common inlet (6) for recirculated anode gas and/or a common outlet (9). Device (10) according to one of Claims 5 until 7 , characterized in that at least one jet pump (1, 2) has a valve (3, 4) on the inlet side, preferably a metering valve, further preferably a metering valve with an integrated jet nozzle (7). Device (10) according to one of Claims 5 until 8th , characterized in that at least one jet pump (1, 2) has a blocking element (5), for example a flap or a valve, in particular a check valve, on the outlet side. Device (10) after claim 9 , characterized in that the jet pumps (1, 2) are brought together on the outlet side and a single blocking element (5) in the form of a flap is arranged upstream of the joint, by means of which a flow path through the first or the second jet pump (1, 2) can be shut off or the flow paths of both jet pumps (1, 2) can be released. Fuel cell system with a device (10) according to one of the preceding ones Claims 5 until 10 , wherein the device (10) is arranged in an anode circuit of the fuel cell system.

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