WO2022268448A1 - Humidification device for a fuel cell system - Google Patents

Abstract

The invention relates to a delivery unit for a fuel cell system, comprising a jet pump that has a first bore with a first sensor and a second bore with a second sensor.

Description

description

Title:

Humidification device for a fuel cell system

The invention relates to a humidifier for a fuel cell system. In addition, the invention relates to a fuel cell system with a humidification device according to the invention.

State of the art

Fuel cells, e.g Cathode of the fuel cell stack is supplied. Air, which is taken from the environment, is usually used as the oxygen supplier. Since the energy conversion process requires a certain air mass flow and a certain pressure level, the air supplied on the cathode side is first compressed with the aid of an air compressor arranged in the cathode supply air path. The air heats up during compression, so that a cooling device for cooling the compressed air is usually arranged downstream of the air compressor in the cathode supply air path. In addition, a humidification device is generally provided for humidifying the previously compressed air. Humidification is intended to prevent the membranes of the fuel cells in the fuel cell stack from drying out.

An example humidifier is e.g. B. from the document US2017077531A be known.

During the energy conversion process in the fuel cells of the fuel cell stack, water is a by-product. This will come along with the cathode exhaust air out of the fuel cell stack and discharged via a cathode exhaust air path. Since water contained in the cathode exhaust air can damage an exhaust gas turbine for energy recovery that is arranged in the cathode exhaust air path and serves for energy recovery, for example through droplet erosion or droplet impact, a water separator is usually arranged in the cathode exhaust air path upstream of the exhaust gas turbine.

The object of the present invention is to simplify the structure of a fuel cell system. In particular, the number of parts and thus the assembly effort should be reduced. Furthermore, space is to be saved.

To solve the problem, the humidifying device for a fuel cell system according to claim 1 is proposed. Advantageous developments of the invention can be found in the dependent claims. In addition, a fuel cell system with a humidification device according to the invention is specified.

Disclosure of Invention

The humidification device proposed for a fuel cell system comprises an inlet and an outlet for a first medium to be humidified, preferably cathode supply air, and an inlet and an outlet for an aqueous second medium, preferably cathode exhaust air. According to the invention, a water separator is integrated into a flow path that connects the inlet to the outlet for the water-containing medium.

Through the proposed integration of the water separator in the humidification device, two independent components of a fuel cell system are combined into one structural unit. This means that interfaces and the connecting parts required for this, such as flanges, hose connectors and/or quick-release couplings, are eliminated. The number of parts in a fuel cell system that has the humidifier is reduced accordingly. With the omission of the interfaces, the assembly effort is reduced at the same time, while the robustness of the fuel cell system increases. The reduced number of parts also reduces the space requirement of a fuel cell system having the humidification device. The reduction in installation space requirements, in turn, is accompanied by an increased power density of the fuel cell system.

The flow path accommodating the water separator is preferably routed through a humidifier functional group. Within the humidifier functional group, the water-containing medium can be brought into contact with the medium to be humidified. The humidifier functional group thus represents the core of the humidifying device. In order to bring the water-containing medium into contact with the medium to be humidified, another flow path for the medium to be humidified is also led through the humidifier functional group.

The proposed humidification device preferably has a modular structure and the humidifier functional group forms an independent modular element of the humidification device. The modular structure enables individual module elements to be exchanged so that the humidification device can be adapted to different installation situations. The module elements are preassembled and then built into a fuel cell system as a unit. During installation, the humidification device can, for example, be used as a unit in a frame of the fuel cell system and attached to it.

According to a first preferred embodiment of the invention, the water separator is integrated into the flow path for the water-containing medium upstream of the humidifier functional group. In this area, the water load of the water-containing medium is very high, so that a lot of water can be separated, which increases the efficiency of the water separator.

According to an alternative embodiment of the invention, the water separator is integrated into the flow path for the water-containing medium downstream of the humidifier functional group. In this case, the water load of the water-containing medium is significantly lower, since part of the water contained within the humidifier functional group is already attached to the medium to be humidified was delivered. In this way, the efficiency of the humidifier can be increased.

In a further development of the invention, it is proposed that the flow path for the water-containing medium is guided through a further module element of the humidification device. In this case, the humidifier functional group or the module element having the humidifier functional group can be designed to be particularly compact, since no additional installation space has to be reserved for the water separator. The integration of the water separator in another modular element also increases the degree of freedom when adapting the humidification device to the respective installation situation. In particular, the inlet and/or outlet for the water-containing medium can also be integrated into the respective module element with the water separator. The further module element can in particular be an end cap of the humidification device, which at the same time forms the inlet or the outlet for the medium to be humidified.

The inlet and the outlet for the medium to be humidified are advantageously arranged on different sides of the humidifying device. For example, end caps arranged on both sides of the central humidifier functional group can form the inlet on the one hand and the outlet on the other hand. This arrangement enables the medium to be moistened to be guided easily through the moistening device.

The inlet and the outlet for the water-containing medium are preferably arranged on the same side of the humidifying device. This arrangement enables a particularly compact design of the humidifying device. The flow path for the water-containing medium can also be kept short.

Furthermore, it is proposed that the water separator is a sediment separator, a cyclone separator and/or a water separator using baffle plates. It is also possible for several separation techniques to be combined in the water separator in order to achieve effective water separation. To solve the problem mentioned above, a fuel cell system is also proposed, which includes a humidification device according to the invention. The humidification device is integrated into a cathode supply air path of the fuel cell system via the inlet and the outlet for the medium to be humidified. The humidification device is integrated into a cathode exhaust air path of the fuel cell system via the inlet and the outlet for the aqueous medium. The use of a humidifier according to the invention reduces the number of parts in the fuel cell system, since a separate water separator and the corresponding interfaces are eliminated. The space requirement of the fuel cell system also decreases accordingly. This in turn is accompanied by an increased power density.

The invention is explained in more detail below with reference to the accompanying drawings. These show:

1 shows a schematic representation of a fuel cell system with a humidification device according to the invention according to a first preferred embodiment,

FIG. 2 shows an enlarged representation of the humidifying device of FIG. 1,

3 shows a schematic representation of a humidifying device according to the invention according to a second preferred embodiment,

4 shows a schematic representation of a humidifying device according to the invention according to a third preferred embodiment,

5 shows a schematic representation of a humidifying device according to the invention according to a fourth preferred embodiment,

Fig. 6 is a schematic representation of a humidifying device according to the invention according to a fifth preferred embodiment and

7 shows a schematic representation of a humidifying device according to the invention according to a sixth preferred embodiment. Detailed description of the drawings

1 shows an example of a fuel cell system 2 with a fuel cell stack 14 to which air is supplied on the cathode side via a cathode supply air path 12 . The air serves as an oxygen supplier and is converted in the fuel cell stack 14 together with hydrogen into electrical energy, heat and water.

Before entering the fuel cell stack 14 , the air is compressed with the aid of an air compressor 15 arranged in the cathode supply air path 12 . Since the air heats up to a great extent during compression, a cooling device 20 is integrated into the cathode supply air path 12 downstream of the air compressor 15 . Further downstream a humidifying device 1 is arranged, by means of which the air is additionally humidified.

After leaving the fuel cell stack 14, the water-enriched cathode exhaust air is fed via a cathode exhaust air path 13 to an exhaust gas turbine for energy recovery. For this purpose, the exhaust gas turbine has a turbine wheel 18 which is arranged in the exhaust air path 13 and which is arranged on a shaft 17 with a compressor wheel 16 of the air compressor 15 . This relieves an electric motor drive 19 of the air compressor 15.

In order to avoid damage to the turbine wheel 18 caused by droplet erosion or droplet impact, the fuel cell system 2 shown has a water separator 7 . With the help of the water separator 7 of the Katho denabluft water should be removed. In the illustrated humidification device 1 according to the invention, the water separator 7 is integrated into a flow path 8, which is guided through a humidification function group 9 of the humidification device 1, within which the water-containing cathode air comes into contact with the compressed air to be humidified.

As can be seen in particular from FIG. 2, the humidification device 1 has three module elements 10, 11, 21. The module elements 10 and 11 form end caps, of which the right end cap forms an inlet 3 and the left end cap forms an outlet 4 for the air to be humidified. that between The third module element 21 arranged on the two end caps has the humidification function group 9 and an inlet 5 and an outlet 6 for the water-containing cathode exhaust air. The water separator 7 is integrated into the third module element 21, namely downstream of the humidifier functional group 9. This means that the water separator 7 is supplied with water-containing cathode exhaust air, which has already given a large part of its water load to the compressed air.

In order to increase the efficiency of the water separator 7, this can - be integrated into the flow path 8 also upstream of the humidifier function group 9 - as shown in FIG. 3 by way of example. The water load of the cathode exhaust air is significantly greater in this area, since no exchange with the compressed air has taken place.

As shown by way of example in FIGS. 4 and 5, the water separator 7 can also be integrated into a modular element 10, 11, which forms an end cap of the humidifying device 1. For this purpose, the flow path 8 is guided through the respective module element 10 , 11 . This arrangement enables a changed position of the inlet 5 (see FIG. 4) or the outlet 6 (see FIG. 5) for the cathode exhaust air, so that the humidification device 1 can be optimally adapted to the respective installation situation. Thanks to the modular design of the humidifying device 1, an adjustment can be made simply by replacing the modular element 11. The modular elements 10 and 21 remain the same.

However, a modular design of the moistening device 1 is not absolutely necessary, as the exemplary embodiments in FIGS. 6 and 7 show. In the fig

6, the water separator 7 is integrated into the flow path 8 downstream of the humidifier functional group 9. In FIG. 7 the water separator 7 is arranged upstream of the humidifier functional group 9 .

Claims

Expectations

1. humidification device (1) for a fuel cell system (2), comprising an inlet (3) and an outlet (4) for a first medium to be humidified, preferably cathode supply air, and an inlet (5) and an outlet (6) for an aqueous medium second medium, preferably cathode exhaust air, characterized in that a water separator (7) is integrated in a flow path (8) which connects the inlet (5) to the outlet (6) for the water-containing medium.

2. Humidification device (1) according to claim 1, characterized in that the flow path (8) is guided through a humidifier function group (9), which preferably forms an independent module element (21) of the humidification device (1).

3. humidification device (1) according to claim 2, characterized in that the water separator (7) upstream of the humidifier functional group (9) is integrated into the flow path (8) for the water-containing medium.

4. Humidification device (1) according to claim 2, characterized in that the water separator (7) is integrated downstream of the humidifier functional group (9) in the flow path (8) for the water-containing medium.

5. Humidification device (1) according to one of the preceding claims, characterized in that the flow path (8) for the water-containing medium is guided through a further module element (10, 11) of the humidification device (9), which is preferably a den Inlet (3) or the outlet (4) for the medium to be humidified is forming end cap.

6. humidification device (1) according to one of the preceding claims, characterized in that the inlet (3) and the outlet (4) for the medium to be humidified are arranged on different sides of the humidification device.

7. Humidifying device (1) according to one of the preceding claims, characterized in that the inlet (5) and the outlet (6) for the medium containing water are arranged on the same side of the humidifying device (1).

8. Humidifying device (1) according to one of claims 5 to 7, characterized in that the water separator (7) is a sediment separator, a cyclone separator and/or a water separator using baffle plates.

9. Fuel cell system (2) comprising a humidifier (1) according to one of the preceding claims, wherein the humidifier (1) via the inlet (3) and the outlet (4) for the medium to be humidified in a cathode supply air path (12 ) and via the inlet (5) and the outlet (6) for the water-containing medium in a cathode exhaust path (13) of the fuel cell system (2).