DE102016213836A1 - Method for heating a water separator and water separator for a fuel cell system of a motor vehicle - Google Patents

Abstract

The technology disclosed herein relates to a method for heating a water separator and a water separator of a fuel cell system for a motor vehicle. The method comprises the step of irradiating the water separator with electromagnetic radiation so that water collected in the water separator heats up.

Description

The technology disclosed herein relates to a method for heating a water separator of a fuel cell system of a motor vehicle and such a water separator.

Fuel cell systems as such are known. When operating a fuel cell system, nitrogen and water accumulate in the anode subsystem. For separating water from the anode subsystem, a water separator is used at the anode outlet of the fuel cell stack. Furthermore, it is known to separate water from the cathode exhaust gas by means of a water separator. Water to be separated and nitrogen are discharged in previously known solutions through a so-called anode purge valve or purge valve.

If a motor vehicle with a fuel cell is parked in the winter at low ambient temperatures, then it may happen that water contained in the fuel cell system freezes. Before the regular operation of the motor vehicle, the fuel cell system is conditioned for operation. For this, the frozen water should be removed from the fuel cell system. In particular, it may happen that a frozen anode rinse valve can not be operated properly.

It is a preferred object of the technology disclosed herein to reduce or eliminate at least one disadvantage of the previously known solutions. It is in particular an object of the technology disclosed here to provide a fuel cell system which can be put into operation comparatively quickly and safely, wherein preferably the costs and / or the space required for the components of the fuel cell system do not increase. Other preferred objects may result from the beneficial effects of the technology disclosed herein. The object (s) is / are solved by the subject matter of the independent claims. The dependent claims are preferred embodiments.

The technology disclosed herein relates to a fuel cell system having at least one fuel cell. The fuel cell system is intended, for example, for mobile applications such as motor vehicles, in particular for providing the energy for at least one drive machine for locomotion of the motor vehicle. In its simplest form, a fuel cell is an electrochemical energy converter that converts fuel (e.g., hydrogen) and oxidants (e.g., air, oxygen, and peroxides) into reaction products, thereby producing electricity and heat.

A fuel cell system comprises, in addition to the at least one fuel cell, peripheral system components (BOP components) which can be used during operation of the at least one fuel cell. As a rule, several fuel cells are combined to form a fuel cell stack or stack.

The fuel cell system includes an anode subsystem formed by the fuel-bearing components of the fuel cell system. An anode subsystem may include at least one pressure vessel, at least one pressure reducer, at least one anode inlet leading to the anode inlet, an anode space in the fuel cell stack, at least one anode exhaust line leading away from the anode outlet, at least one water purge (= AWS), at least one anode purge valve (= APV), at least one active or passive fuel recirculation conveyor (= ARE or ARB) and / or at least one recirculation line and further elements. The main task of the Anodensubsystems is the introduction and distribution of fuel to the electrochemically active surfaces of the anode compartment and the removal of anode exhaust gas.

The fuel cell system includes a cathode subsystem. The cathode subsystem is formed from the oxidant-carrying components. A cathode subsystem may comprise at least one oxidant promoter, at least one cathode feed line leading to the cathode inlet, at least one cathode waste gas line leading away from the cathode outlet, a cathode space in the fuel cell stack, and further elements. The main task of the cathode subsystem is the introduction and distribution of oxidant to the electrochemically active surfaces of the cathode compartment and the removal of oxidant.

The fuel cell system disclosed herein includes, in particular, a water separator. The water separator comprises at least one radiator. The radiator is designed to heat water contained in the water separator by means of electromagnetic radiation. In particular, the radiator can be designed and arranged such that it can defrost the water and / or heat, preferably evaporate.

Preferably, the radiator emits an electromagnetic radiation having a wavelength of 3000 mm to 0.1 mm, more preferably from 300 mm to 1 mm. Preferably, therefore, a microwave radiator is used.

The at least one radiator can be arranged laterally from the water separator. Preferably, the radiator on the outer wall of the Water separator attached. But that does not have to be this way. Particularly preferably, the radiator is arranged such that it can heat water immediately adjacent to the Wasserabscheiderauslass. The emitter is therefore preferably arranged adjacent to the water separator outlet.

The water separator may be arranged in the exhaust path of the fuel cell system. The exhaust path of the fuel cell system may be an exhaust path of the anode subsystem and / or the cathode subsystem. The exhaust path is the path which is arranged downstream of the anode outlet or from the cathode outlet of the fuel cell stack. The exhaust path may directly or indirectly open into the environment and / or be a recirculating path.

The disclosed technology further relates to a method of heating the water trap disclosed herein, particularly during cold start of a fuel cell system. The method comprises the step:
Irradiating the water separator with electromagnetic radiation, so that heats up in the water collected water. In particular, the water is irradiated so that molecules contained in the water separator are excited to dipole and multipole oscillations.

Further, the method disclosed herein may include the step of having the electromagnetic radiation at a wavelength of 3000 mm to 0.1 mm, more preferably from 300 mm to 1 mm. The method disclosed herein may include the step of generating the electromagnetic radiation by at least one radiator. The method disclosed herein may further comprise the step of arranging the at least one radiator laterally of the water separator and / or adjacent to the water separator outlet.

In other words, the technology disclosed here is based on the idea that the water or ice accumulated in a water separator is heated or melted by the electrical radiation.

By the technology disclosed here, it is possible that the water or ice is not heated by externally introduced heat by means of heat conduction, but that in the water or ice, the heat arises directly where it is needed. Compared to previously known methods, the water or ice can thus be heated or melted faster and with better efficiency.

The technology disclosed herein will now be explained with reference to the figures. Show it:

1 a schematic structure of the fuel cell system; and

2 a schematic cross-sectional view of a water separator.

The 1 schematically shows a fuel cell system with an anode subsystem and a cathode subsystem. For simplicity, many system components have been omitted here. In the pressure vessel 100 Fuel is stored via the tank shut-off valve 210 as well as the pressure reducers 211 . 212 an anode space A of the fuel cell stack 300 provided. The fuel reacts in the fuel cell stack 300 with the oxidizing agent. The resulting anode exhaust gas flows out of the fuel cell stack through the anode outlet. The anode exhaust gas line opens here in the water 240 , In the water separator 240 Water is condensed out of the anode exhaust gas. The water separator 240 is fluidly connected to an anode purge valve 238 , By opening the anode rinse valve 238 Both water and nitrogen can escape. The water separator 240 is also via a recirculation line 235 with the anode lead 215 connected. In the recirculation line 235 may further include an anode recirculation pump 236 and / or a hydrogen injector 234 be provided (shown in phantom). Through the oxidizer conveyor 410 Air is sucked in and in the intercooler 420 cooled. The air enters the cathode space K and reacts there with the fuel of the anode space A. After the electrochemical reaction in the fuel cell stack 300 the exhaust gas leaves the cathode space K. In the cathode exhaust can also be a water 240 and optionally a purge valve 238 be provided.

Alternatively, gas discharged from the anode subsystem may be merged with the cathode exhaust gas in a mixing chamber (often called "diluter"). In such a case it can be provided that the water separator 240 is arranged in this mixing chamber with integrated or downstream of this mixing chamber.

The control unit 500 is set up, the fuel cell system shown here, in particular the water trap disclosed here 240 or its radiator 242 (see. 2 ), to control or regulate.

The 2 schematically shows the water trap disclosed here 240 , Through an exhaust inlet 246 exhaust gas flows into the water separator 240 one. The exhaust outlet is not shown here. On the wall 241 of the water separator 240 here is a spotlight 242 intended. The spotlight 242 is formed, an electromagnetic radiation (shown here as dashed arrows) in the interior of the water separator 242 contribute. The electromagnetic radiation can be located in particular in the wave range of microwaves. The microwaves generate heat in the water itself, so that the water is heated quickly and efficiently. The spotlight 242 is here on the side of the water separator 240 and adjacent to the water separator outlet 244 arranged. Adjacent means in this context that the radiator closer to the Wasserabscheiderauslass 244 is arranged as the upper edge of the water separator 240 , preferably in the installation position in the lower third of the water separator 240 , The spotlight 242 does not extend over the complete side wall of the water separator 240 , But that does not have to be this way. It is also conceivable that the spotlight 242 along the entire side wall 241 extends and / or that multiple emitters 242 along the side wall 241 are arranged. For example, a radiator in the proximal region could be adjacent to the water separator outlet 244 be arranged and another radiator in the distal region spaced from the Wasserabscheiderauslass 244 , With the technology disclosed herein, frozen water can typically be heated and / or vaporized faster and / or more efficiently.

For the sake of legibility, the term "at least one" has been omitted for simplicity. If a feature of the technology disclosed herein is singularized (eg, the / an exhaust path, the / a water trap, the / a radiator, the / a water drain port, the / a proximal or distal region, etc.) so At the same time, the majority of them should also be disclosed (eg the at least one exhaust path, the at least one water separator, the at least one radiator, the at least one water drainage opening, the at least one proximal or distal region, etc.). The technology disclosed herein is not limited to tempering during shutdown and startup of fuel cell operation. Likewise, the at least one radiator can be used during the rest phase and / or during normal operation of the fuel cell to temper the water separator.

The foregoing description of the present invention is for illustrative purposes only, and not for the purpose of limiting the invention. Various changes and modifications are possible within the scope of the invention without departing from the scope of the invention and its equivalents.

Claims (10)

Method for heating a water separator ( 240 ) of a fuel cell system, comprising the step: irradiating the water separator with electromagnetic radiation, so that in the water separator ( 240 ) heats accumulated water.  The method of claim 1, wherein the electromagnetic radiation has a wavelength of 1 mm to 300 mm. Method according to claim 1 or 2, wherein the electromagnetic radiation is transmitted through at least one radiator ( 242 ) is produced. Method according to one of the preceding claims, wherein the at least one radiator ( 242 ) laterally from the water separator ( 240 ) and / or adjacent to a water separator outlet ( 244 ) is arranged. Method according to one of the preceding claims, wherein the water separator ( 240 ) is arranged in the exhaust path of the fuel cell system, and / or wherein the water separator ( 240 ) is arranged in a cathode feed air. Water separator ( 240 ) for a fuel cell system of a motor vehicle, comprising at least one radiator ( 242 ), whereby the radiator ( 242 ) is formed by means of electromagnetic radiation in the water separator ( 240 ) to heat the water contained. Water separator according to claim 6, wherein the radiator ( 242 ) is adapted to emit electromagnetic radiation having a wavelength of 1 mm to 300 mm. Water separator according to claim 6 or 7, wherein the at least one radiator ( 242 ) laterally from the water separator ( 240 ) and / or adjacent to a water separator outlet ( 244 ) is arranged. Water separator according to one of claims 6 to 8, wherein the water separator ( 240 ) is arranged in the exhaust path of the fuel cell system, and / or wherein the water separator is arranged in a cathode feed air. Fuel cell system for a motor vehicle, comprising at least one water separator ( 240 ) according to one of claims 6 to 9.

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