DE102020213082A1 - Fuel cell system, vehicle with fuel cell system and method for operating a fuel cell system - Google Patents

Abstract

The invention relates to a fuel cell system (1) comprising a fuel cell stack (2) with an anode which can be supplied with hydrogen via an anode path (3) and a cathode which can be supplied with oxygen via a cathode path (4). According to the invention, a cooling device (5) integrated into the anode path (3) and a cooling device (6) integrated into the cathode path (4) form a structural unit. The invention also relates to a vehicle with a fuel cell system (1) according to the invention and a method for operating it a fuel cell system (1).

Description

The invention relates to a fuel cell system, comprising a fuel cell stack according to the preamble of claim 1. The invention also relates to a vehicle with a fuel cell system according to the invention and a method for operating a fuel cell system.

State of the art

Fuel cells convert hydrogen into electrical energy with the help of oxygen. By-products are heat and water. The hydrogen required for this is stored in a suitable tank and fed to an anode of the fuel cell via an anode path. The oxygen that is also required is taken from the ambient air. The ambient air serving as an oxygen supplier is supplied to a cathode of the fuel cell via a cathode path. A multiplicity of fuel cells in a stacked arrangement form a fuel cell stack.

Fuel cell systems with hydrogen-based fuel cells are considered to be the mobility concept of the future, since they essentially only emit water as exhaust gas and enable fast refueling times.

The ambient air supplied to the cathode is compressed beforehand. For this purpose, an air compressor driven by an electric motor is arranged in the cathode path. During compression, the air heats up, so it has to be cooled down before entering the fuel cell stack. A cooling device, for example in the form of a heat exchanger, is therefore generally integrated into the cathode path downstream of the air compressor.

In addition, a device for the thermal conditioning of hydrogen can be arranged in the anode path. With the help of the device, the hydrogen can be cooled or heated, depending on the current conditions, in particular ambient temperatures.

The present invention is concerned with the task of simplifying the structure of fuel cell systems, in particular reducing the number of parts and/or saving installation space.

To solve the problem, the fuel cell system with the features of claim 1 is proposed. Advantageous developments of the invention can be found in the dependent claims. Furthermore, a vehicle with a fuel cell system according to the invention and a method for operating a fuel cell system are specified.

Disclosure of Invention

The proposed fuel cell system comprises a fuel cell stack with an anode, which can be supplied with hydrogen via an anode path, and a cathode, which can be supplied with oxygen via a cathode path. According to the invention, a cooling device integrated into the anode path and a cooling device integrated into the cathode path form a structural unit.

The design of the cooling devices as a structural unit enables a more compact design and at the same time a higher power density of the fuel cell system. The more compact design helps to save space.

The design of the cooling devices as a structural unit requires the spatial proximity of the cooling devices. For this purpose, the position of at least one cooling device must be changed accordingly. Due to the spatial proximity of the cooling devices to one another, line lengths can be reduced, which are used, for example, to connect the cooling devices to a coolant circuit.

The cooling devices preferably each form a sub-unit and the sub-units are firmly connected to one another. This means that conventional cooling devices can be used, each of which is composed of a number of components connected to one another. The multiple components connected to one another can, for example, be plates that are soldered to one another. After assembling the two sub-units, they can be combined into one unit.

The cooling devices connected to form a unit can each have a housing or a common housing. If each cooling device has its own housing, these are firmly connected to one another, in particular screwed, glued and/or welded. If the cooling devices have a common housing, the number of parts is further reduced since there is only one housing. As the number of parts decreases, so does the assembly work. With only one housing, the number of coolant connections can also be reduced. This reduces the risk of leaks occurring. As a result, the robustness of the fuel cell system increases.

Furthermore, the cooling devices are preferred as heat connected in series or in parallel executed exchanger and connected to a coolant circuit via a common coolant inlet and a common coolant outlet. The number of coolant connections can thus be reduced to two. If each cooling device forms its own sub-unit and/or has its own housing, these can be connected via coolant interfaces. The tightness of the coolant interfaces can be ensured with the aid of intermediate sealing elements, in particular in the form of sealing rings. Alternatively, the coolant can be routed from sub-unit to sub-unit or from housing to housing via a connecting hose.

The cooling devices designed as heat exchangers can be plate heat exchangers, for example. These can be combined to form a particularly compact structural unit.

The cooling device integrated into the cathode path is preferably arranged downstream of an air compressor. The previously compressed hot air can thus be cooled with the aid of the cooling device integrated into the cathode path.

The cooling device integrated in the anode path is preferably arranged upstream of an ejector pump. Anode off-gas that is leaving the fuel cell stack and still contains a residual amount of hydrogen is sucked back into the anode path via the ejector pump via a recirculation path. The hydrogen contained in the anode exhaust gas can therefore still be converted into electricity. Upstream of the ejector pump there is only fresh hydrogen, which was taken from a tank. Since - depending on the current conditions, in particular the ambient temperatures - hydrogen can heat up very strongly, cooling can be achieved with the help of the cooling device arranged upstream of the ejector pump, which protects the ejector pump and all subsequent components in the anode path from excessive thermal stress . If necessary, for example during a cold start, the cooling device can also be used to preheat hydrogen and/or air. The cooling device integrated into the anode path is advantageously arranged upstream of a hydrogen metering valve, with the aid of which the fresh hydrogen taken from the tank is metered into the anode path upstream of the ejector pump. In this way, the thermal load on the hydrogen metering valve can be reduced at the same time.

According to an advantageous embodiment of the invention, the cooling devices are connected via at least one common carrier. The structural unit can be realized particularly easily in this way. The at least one carrier can, for example, be designed in the form of a profile or plate and/or be part of a frame accommodating the fuel cell stack. This means that existing parts can be used as carriers in order to continue to keep the number of parts and space requirements low.

A compact design and a small installation space requirement prove to be an advantage, especially in mobile applications. Therefore, a vehicle with a fuel cell system according to the invention is also proposed.

In addition, a method for operating a fuel cell system is proposed, which includes a fuel cell stack with an anode and a cathode. In the method, the anode is supplied with hydrogen via an anode path and the cathode is supplied with oxygen via a cathode path. According to the invention, the gases conducted via the anode path and the cathode path are cooled with the aid of cooling devices which form a structural unit and are designed as heat exchangers connected in series or in parallel.

With the aid of the proposed method, a common coolant circuit can be used to cool the air serving as the oxygen supplier and the hydrogen. Because the heat exchangers are connected in series or in parallel, only one coolant inlet and one coolant outlet have to be provided in each case. Furthermore, due to the physical proximity of the heat exchangers, line lengths can be saved.

A mixture of glycol and deionized water, for example, can be used as the coolant.

• 1 eine schematische Darstellung eines ersten erfindungsgemäßen Brennstoffzellensystems,
• 2 eine schematische Darstellung eines zweiten erfindungsgemäßen Brennstoffzellensystems,
• 3 eine schematische Darstellung eines dritten erfindungsgemäßen Brennstoffzellensystems,
• 4 eine schematische Darstellung eines vierten erfindungsgemäßen Brennstoffzellensystems und
• 5 eine schematische Darstellung eines fünften erfindungsgemäßen Brennstoffzellensystems.

The invention and its advantages are explained in more detail below with reference to the accompanying drawings. These show:

• 1 a schematic representation of a first fuel cell system according to the invention,
• 2 a schematic representation of a second fuel cell system according to the invention,
• 3 a schematic representation of a third fuel cell system according to the invention,
• 4 a schematic representation of a fourth fuel cell system according to the invention and
• 5 a schematic representation of a fifth fuel cell system according to the invention.

Detailed description of the drawings

That in the 1 The fuel cell system 1 shown comprises a fuel cell stack 2 which can be supplied with air on the cathode side via a cathode path 4 and with hydrogen on the anode side via an anode path 3 . The air is taken from the environment and compressed with the aid of an air compressor 12 arranged in the cathode path 4 . In the present case, the air compressor 12 can be driven by an electric motor, supported by a turbine 16 which is arranged in a cathode exhaust gas path 17 . With the help of the turbine 16, part of the energy used can be recovered and used as drive energy. The hydrogen is stored in a tank (not shown) and mixed with anode off-gas that exits the fuel cell stack 2 and is routed back into the anode path 3 via a recirculation path 18 . In the present case, the passive recirculation is supported by an ejector pump 13 arranged in the anode path 3 . Since the anode waste gas also contains water, a water separator 19 is arranged in the recirculation path 18, which removes the water from the anode waste gas. The water collecting in the water separator 19 can be discharged via a drain valve 20 . A purge valve 21 is also provided in order to flush the anode area with fresh hydrogen. For this purpose, a hydrogen metering valve 14 arranged upstream of the ejector pump 13 in the anode path 3 must also be opened.

That in the 1 The fuel cell system 1 shown also includes two cooling devices 5, 6, each of which is housed in its own housing 7, 8. These are connected to form a compact structural unit. The cooling devices 5, 6 are designed as heat exchangers connected in parallel and are connected to a common coolant circuit. For this purpose, the housing 7 has a coolant inlet 10 and a coolant outlet 11 . The coolant flows from the housing 7 into the housing 8 and back again via interfaces 22 on the housing side with sealing rings 23 in between.

That in the 2 Fuel cell system 1 shown represents a modification of the system 1 Instead of the housings 7 and 8, both cooling devices 5, 6 are accommodated in a common housing 9. This eliminates a housing and the housing-side interfaces 22 with the sealing rings 23. The number of parts can thus be further reduced, and at the same time the risk of leakage is reduced.

Of the 3 A fuel cell system 1 according to the invention can be seen in which the cooling devices 5, 6 are connected in series. Each cooling device 5, 6 in turn has its own housing 7, 8. The coolant inlet 10 is formed in the housing 7, the coolant outlet 11 in the housing 8. In order to fluidly connect the two housings 7, 8, a short connecting hose 24 is provided. The housings 7, 8 of the series-connected cooling devices 5, 6 are arranged on a common carrier 15, which in the present case is plate-shaped. The carrier 15 can be dispensed with if the housings 7, 8 are connected directly to one another, for example screwed. This embodiment is in the 4 shown as an example.

As an alternative to the embodiments of 3 and the 4 the series-connected cooling devices 5, 6 can also be arranged in a common housing 9 (not shown).

Of the 5 a fuel cell system 1 according to the invention with cooling devices 5, 6 connected in series can be seen, which are connected via common supports 15 and attached to a support structure 25, in particular a frame, of a fuel cell stack 2.

Claims (9)

Fuel cell system (1) comprising a fuel cell stack (2) with an anode which can be supplied with hydrogen via an anode path (3) and a cathode which can be supplied with oxygen via a cathode path (4), characterized in that a Anode path (3) integrated cooling device (5) and in the cathode path (4) integrated cooling device (6) form a structural unit. Fuel cell system (1) after claim 1 , characterized in that the cooling devices (5, 6) each form a sub-unit and the sub-units are firmly connected to one another. Fuel cell system (1) after claim 1 , characterized in that the cooling devices (5, 6) each have a housing (7, 8) or a common housing (9). Fuel cell system (1) according to one of the preceding claims, characterized in that the cooling devices (5, 6) are designed as heat exchangers connected in series or in parallel and are connected to a coolant circuit via a common coolant inlet (10) and a common coolant outlet (11). . Fuel cell system (1) according to one of the preceding claims, characterized in that the cooling device (6) integrated into the cathode path (4) is arranged downstream of an air compressor (12). Fuel cell system (1) according to one of the preceding claims, characterized in that the cooling device (5) integrated in the anode path (3) is arranged upstream of a suction jet pump (13), preferably upstream of a hydrogen metering valve (14). Fuel cell system (1) according to one of the preceding claims, characterized in that the cooling devices (5, 6) are connected via at least one common support (15), which is designed, for example, in the form of a profile or plate and/or is part of a support that accommodates the fuel cell stack (2). frame is. Vehicle with a fuel cell system (1) according to one of the preceding claims. Method for operating a fuel cell system (1), comprising a fuel cell stack (2) with an anode and a cathode, in which the anode is supplied with hydrogen via an anode path (3) and the cathode is supplied with oxygen via a cathode path (4), characterized that the gases guided via the anode path (3) and the cathode path (4) are cooled with the aid of cooling devices (5, 6), which form a structural unit and are designed as heat exchangers connected in series or in parallel.

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