DE102009043565A1 - Device for supplying media into fuel cell system in e.g. motor vehicle, has compressor, sound absorbers, drive motor, valve device, recirculation conveying device and drain and/or purge valve, which are supported by sound-absorbing housing - Google Patents

Abstract

The device has an air supply device (12) i.e. volumetric compressor, sound absorbers (13, 14), a drive motor i.e. electric motor, a valve device (16), a recirculation conveying device (18) and a drain and/or purge valve (19), which are supported by a sound-absorbing housing. The sound-absorbing housing comprises an inner shell and an outer shell. The compressor, the absorbers, the motor, the valve device, the conveying device and the valve are firmly connected with the inner shell. The sound-absorbing housing is made of metal, plastic or fiber-reinforced plastic or composite material.

Description

The invention relates to a device for media supply in a fuel cell system according to the closer defined in the preamble of claim 1.

Fuel cell systems, and especially those equipped with PEM fuel cells, are well known in the art. Such fuel cell systems are fed media. These media can typically be air and hydrogen. The oxygen contained in the air serves as an oxidizing agent in a cathode compartment of the fuel cell. The hydrogen supplied to the fuel cell system is usually stored in a pressure accumulator under high pressure of for example 350 or 750 bar. It is reacted through a valve means an anode chamber of the fuel cell together with the oxygen in the air through a proton-conducting membrane. This creates water and the desired electrical power. Now, the hydrogen is typically offered with an excess in volume, by itself, to evenly supply all areas of the anode compartment with hydrogen. The anode chamber thus leaves an exhaust gas, which still has a high proportion of hydrogen. In addition, with the exhaust gas, a portion of the product water and through the membranes into the area of the anode space penetrating inert gases, in particular nitrogen, discharged. The exhaust gas from the anode compartment 3 is now promoted via a recirculation device and a recirculation line back into the inlet region of the anode compartment, so that the hydrogen contained therein can be completely consumed. Over time, more and more inert gas accumulates in the recirculated gas stream and an ever-increasing amount of water accumulates. From time to time, therefore, the water and the inert gas are discharged from the system.

The air supply of such fuel cell systems is now typically via air conveyors, which are very often in the form of screw or Roots compressors. Alternatively, however, other types of air handling equipment are conceivable, for example blowers, membrane compressors or the like. All air conveyors now have the disadvantage that they generate pressure pulsations in the air conveyor itself and / or in the funded volume flow of air. Especially with volumetric compressors, such as screw or Roots compressors, these pressure pulsations are relatively high. They lead to a corresponding noise level through the device for air supply.

In stationary systems, such noise pollution may possibly still be tolerated. However, if the fuel cell system is to be used in means of transport, in particular in motor vehicles, in which it provides at least some of the energy required for the drive, then such noise emissions are highly undesirable because they affect both the operator of the means of transport and the environment in which moves the means of transport, load accordingly.

From the German patent application DE 10 2006 07 176 A1 It is therefore known to couple a compressor in an air module of a fuel cell with one or more dampers, which are arranged in the conveyed gas flow before and after the air conveyor to achieve a noise reduction.

Although this construction is comparatively small and compact, achieved by the arranged in the supported air flow muffler only a limited reduction of noise emissions, and in particular sound, which is not transmitted by the funded air flow itself, but which is emitted as structure-borne noise or radiated sound , steam.

In the area of the hydrogen supply, the valves, which are typically operated in a clocked manner, can produce an undesired noise emission. The recirculation conveyor for the anode exhaust gas, which is generally designed as a flow compressor or recirculation blower, emits sound. However, since higher pressure losses are problematic in this area, it is only possible to work with silencers in this area to a limited extent.

It is therefore an object of the present invention to provide a device for media supply in a fuel cell system, which largely prevents the propagation of sound generated in the device and thereby builds lightweight and compact.

According to the invention this object is achieved by the features mentioned in the characterizing part of claim 1. Advantageous developments and refinements of the invention emerge from the dependent claims.

The inventive device summarizes the components for media supply in a sound-absorbing housing. This largely prevents the emission of sound from these components, which in any case comprise a media conveyor and optionally clocked valves and / or an electromotive drive of the media conveyor. The Problems that support frame and the like penetrate the sound-absorbing housing, and thus form sound bridges, can be avoided with the structure of the invention. This is in fact such that the sound-absorbing housing is designed self-supporting, and that the components are supported by the sound-absorbing housing. The housing thus takes over both the functionality of the sound-absorbing housing and the functionality of a support frame for the components of the media supply, which are to be sound-insulated.

This creates a very quiet, lightweight and very compact design for a corresponding device for media supply.

According to a very favorable development of the device according to the invention, it is provided that the components are decoupled attached to the sound-absorbing housing. This construction with media components decoupled relative to the sound-absorbing housing makes it possible for these to be correspondingly movable in the interior of the sound-absorbing housing and to be decoupled against the transmission of structure-borne sound. The sound-absorbing housing itself can then be installed in a stationary packaging such as the fuel cell system without corresponding space must be provided for movement of the housing, since all due to the decoupled attachment movably arranged components are located inside the housing.

In an alternative very favorable development of the device according to the invention, however, it can also be provided that the sound-absorbing housing is divided into an inner shell and an outer shell, wherein the components are fixedly connected to the inner shell, and wherein the inner shell is decoupled fixed in the outer shell. This results in a similar structure, in which the outer shell can be installed firmly and in particular stationary in the system. Any space that would ensure a movement of the shell, must not be kept here. In the construction, the components of the device for media supply are also fixedly arranged in the inner shell of the sound-absorbing housing, so that here too a relatively tight packaging can take place. The two shells are then decoupled from each other, so that no transmission of sound, in particular no transmission of structure-borne noise from the inner shell to the outer shell and thus for example to a support frame of the system or the like can take place.

In a very advantageous embodiment of the device according to the invention, it is provided that the sound-absorbing housing has a grid-shaped support structure and an outer shell. This structure with a grid-shaped support structure brings with comparatively little material a comparatively high rigidity in the sound-absorbing housing and can be used in particular for receiving the components or fixed analogous to the two alternative developments described above. This grid-shaped support structure is then surrounded by an outer shell, which assumes a seal for the sound insulation. This shell only has to form a closure of the sound-absorbing housing, so that it can be made correspondingly light, since it only has to form its self-supporting properties in combination with the latticed support structure. This creates a very light construction for the sound-absorbing housing.

In a very favorable embodiment of this it can be provided that this structure is formed as a development of the construction described above with inner shell and outer shell and that the lattice-shaped support structure acts as the inner shell, which is uncoupled from the outer shell suspended. This construction is also correspondingly light and guarantees very good sound insulation with a low construction volume and the best mechanical properties.

In an advantageous development of the device according to the invention, it is provided that the media supply is designed as an air supply module, which comprises as components at least one air conveying device and at least one silencer. The device according to the invention with the sound-insulating housing can thus be used preferably for an air supply module or cathode module, which comprises the air conveying device as a primary noise source, which can be designed in particular as a volumetric compressor, for example screw or Roots compressor. In principle, the training as a flow compressor is conceivable, the sound emissions are correspondingly higher by a volumetric compressor and therefore the very good sound insulation according to the structure of the invention then come to bear very well.

In a further very favorable embodiment thereof, it is further provided that the at least one muffler is coupled directly to the air conveyor. This means that the silencer is connected fluidically either directly to the suction side and / or the pressure side of the air conveying device without piping arranged therebetween. This will be surfaces of the components avoided connecting pipes, which in turn could radiate sound to the environment.

In a very favorable and advantageous development of the device according to the invention, the media supply can also be designed as a hydrogen supply module, which comprises as components at least one recirculation conveyor and at least one cyclically operated valve device. The media supply is thus designed here as a hydrogen supply module or so-called anode module. The sound-absorbing housing insulates the sound, which is produced by the recirculation conveyor, which is typically designed as a fan. In addition, valve devices, such as those needed for example to supply hydrogen to the fuel cell system, or for the discharge of inert gas and water from the recirculation circuit are operated very frequently clocked. Such cyclically operated valve devices are therefore a source of corresponding noise emissions. In the structure according to the invention, therefore, these can also be sound-proofed and supported by the sound-absorbing housing.

In a very favorable and advantageous embodiment of the device according to the invention, it is also provided that the sound-absorbing housing has metal, plastic, fiber-reinforced plastic or a composite material thereof as one of its materials. The sound-absorbing housing can thus be relatively flexible and easy to set up, for example by using different very stable materials such as fiber-reinforced plastic and / or metals or combined with each other.

According to a very favorable development thereof, it is also provided that the sound-absorbing housing is lined with a sound-absorbing material. This sound-absorbing material may for example be a foam or the like, which at least the outer shell correspondingly lines the sound-absorbing housing or in the construction with a plurality of shells or lattice structures, and thus swells in the sound-absorbing housing resulting sound waves.

The device according to the invention thus makes possible a compact, light and very quiet device for media supply in a fuel cell system. The preferred, but not the only application of the device according to the invention is therefore in the use for media supply of a fuel cell system in a means of transport. Such a means of transport may in particular be a motor vehicle, but also a rail-bound or trackless land vehicle in the field of logistics, goods promotion or the like. Even ships or aircraft are conceivable as appropriate means of transport.

Further advantageous embodiments of the device according to the invention also result from the exemplary embodiment, which is illustrated and explained in more detail below with reference to FIGS.

Showing:

1 a schematic representation of a means of transport with a fuel cell system;

2 a schematic diagram of an apparatus for supplying media of a fuel cell system according to the invention; and

3 a schematic diagram of an inventive device for supplying hydrogen to a fuel cell system.

In the presentation of the 1 is a very roughly indicated vehicle 1 to recognize which with a fuel cell system 2 is provided, of which only the most necessary components are shown. The fuel cell system 2 consists in the embodiment shown here of a fuel cell 3 , which should be constructed as a stack of PEM fuel cells. For operation of the fuel cell system 2 becomes a cathode compartment 4 the fuel cell 3 Air over a device 5 for supplying air to the fuel cell system 2 fed. In the fuel cell 3 The oxygen contained in this air reacts with hydrogen, which is an anode space 6 the fuel cell 3 about a device 7 for hydrogen supply from a pressure accumulator 8th is supplied. In the fuel cell 3 Then electrical power is generated, which via an electronic unit indicated here in principle 9 , at least one traction motor 10 of the vehicle 1 is supplied, which the here indicated in principle wheels 11 of the vehicle 1 at least indirectly. The device 5 for the supply of air to the fuel cell system is intended in the embodiment shown here, a volumetric compressor 12 as well as two before and after the volumetric compressor 12 arranged muffler 13 . 14 include. The compressor 12 , which in principle could also be designed as a flow compressor, is thereby an electric motor of a motor 15 driven, which in the representation of 2 can be seen.

The device 7 for hydrogen supply is often referred to as an anode module. It comprises a valve device 16 , those who Supply of hydrogen from the accumulator 8th takes over. In addition, the anode module is a recirculation line 17 with a recirculation conveyor 18 comprise, by means of which unused exhaust gas from the anode compartment 6 again the anode room 6 is supplied. In this so-called anode circuit accumulates over time inert gas, in particular nitrogen, which, through the membranes of the fuel cell 3 through from the cathode compartment 4 in the anode compartment 6 diffused. In addition, a small amount of product water also accumulates in the anode compartment 6 and is discharged from its exhaust. Due to the circulation of these media, these accumulate in the anode recirculation and must be drained from time to time. For this purpose, at least one valve device 19 , a so-called drain / purge valve 19 , intended. This can be arranged in particular in a water separator and so first drain the water and then the inert gas, as is known in the prior art. In principle, however, would also be several such valve devices 19 conceivable, for example, to separate water and gas separated from each other.

As the valve devices 16 . 19 Typically operated clocked, you assume a certain noise emission, as well as from the recirculation conveyor 18 , For the device 7 for hydrogen supply is thus essentially the same as for the device 5 for supplying air to the fuel cell system 2 in that they cause corresponding noise emissions by the components used in them.

This construction shown and described here corresponds to the structure according to the prior art, so that the simplified representation will not be discussed in more detail. The device 5 for supplying air to the fuel cell system 2 is in the representation of 2 again in a still schematic, but more detailed representation to recognize. The device 5 consists essentially of the compressor 12 as well as its drive motor 15 For example, an electric motor. In the embodiment of the device shown here 5 this also has the two silencers 13 . 14 on. These are with the compressor 12 over indicated connecting pipes 20 coupled. These connecting pipes 20 can be very short in particular, or in the muffler 13 . 14 be integrated so that the muffler 13 . 14 preferably directly to the compressor 12 are coupled. This eliminates any sound emissions, which in the field of connecting pipes 20 occur and could be radiated to the environment.

The one of the silencers 13 is in the embodiment shown here with a suction line 21 connected, through which air, for example from the environment, via an air filter or the like can be sucked. The way through the muffler 13 sucked air is then through the compressor 12 in the muffler 14 promoted and passes from this via a pressure line 22 in the area of the fuel cell system 2 , and in particular in the area of the cathode compartment 4 the fuel cell 3 , Of course, the air delivery would be via the pressure line 22 parallel to the cathode compartment 4 or serially before or after the cathode compartment 4 in other components, such as a humidifier, a burner or the like, conceivable.

The problem with this structure is now that of the compressor 12 , Especially if it is designed as a volumetric compressor, causes a comparatively high noise emission by pressure fluctuations in the conveyed air flow. Through the two silencers 13 . 14 a part of these pressure fluctuations in the conveyed air flow itself can already be significantly reduced. Nevertheless, there is a radiation of sound from the area of the surfaces of the muffler 13 . 14 of the compressor 12 and also the drive motor 15 , In order to avoid such noise emissions, is in the device 5 according to the invention, this structure of a sound-absorbing housing 23 surround. This sound-absorbing housing 23 Closes the structure tightly and is about flexible elements not shown here, such as foams or other flexible compensators, in the area of the sound-absorbing housing 23 penetrating elements, ie in particular in the region of the suction line 21 and the pressure line 22 , sealed accordingly.

The sound-absorbing housing 23 is constructed as a self-supporting housing and can be constructed for example of a metal or a correspondingly stable plastic. In addition to solid plastics, fiber-reinforced plastics would also be conceivable here, for example plastics reinforced with glass fibers or carbon fibers, fiberglass-reinforced plastics being preferred with regard to the production costs. Depending on the design and material may also be a composite material for the sound-absorbing housing 23 , For example, plastic and metal, are used. If necessary, the sound-insulating housing points 23 In this case, corresponding reinforcing ribs in order to perform this stable accordingly, so that this is sufficiently stable in each case. The illustration of such reinforcing ribs or the like has been omitted here for reasons of clarity. In addition, the components of the device for media supply, So in the presentation of 2 , the device 5 for supplying air to the fuel cell system 2 from the sound-absorbing housing 23 worn and attached to this. In the embodiment of 2 This attachment of the components, here the unit of compressor 12 and drive motor 15 as well as the silencer 13 . 14 on the sound-absorbing housing 23 via decoupling elements 24 For example, rubber buffer or the like. This ensures that the components no structure-borne noise on the sound-absorbing housing 23 transfer. The sound-absorbing housing 23 is also with a sound-absorbing material 25 , For example, a foam layer, one in the sound-absorbing housing 23 Injected porous foam or the like lined to prevent noise emissions of the components 12 . 13 . 14 . 15 in the sound-absorbing housing 23 get outside.

The sound-absorbing housing 23 Thus, it takes over the sound insulation of the components of the device enclosed in it 5 for supplying air to the fuel cell system 2 , In addition, it carries these components, so that on a complex, expensive and especially heavy support frame, which also soundproofed and decoupled by the sound-absorbing housing 23 should be conducted, can be waived. The construction becomes simpler, easier and cheaper. In addition, the decisive advantage arises that the sound-absorbing housing 23 As a whole, it does not have to be hung up decoupled and typically does not perform any movements caused by the sound. Therefore, the sound-absorbing housing 23 in its environment in the fuel cell system 2 be relatively tightly surrounded with other modules and elements, since no mobility due to the decoupled attachment must be provided. This is in the presentation of 2 through a support frame 26 indicated in principle, which via rigid fasteners 27 with the sound-absorbing housing 23 is connected and laterally very close to or next to the housing 23 can be arranged.

In addition to the structure of the sound-absorbing housing mentioned here 23 From a housing part, which optionally has reinforcing ribs, would also be a structure of the sound-absorbing housing 23 from an inner support structure, which is in particular formed grid-shaped, conceivable. At this support structure could then the components 12 . 13 . 14 . 15 according to the decoupling elements 24 be attached. This inherently stable but open structure would then be surrounded by a shell, which in turn takes over the sealing of the sound-absorbing housing to the outside and at least in the area between the latticed struts of the support structure with a sound-absorbing material, such as foam or porous foam could be foamed.

In the presentation of the 3 is now an alternative construction of the sound-absorbing housing 23 to recognize which in this case exemplifies the device 7 for the hydrogen supply of the fuel cell system 2 receives. The sound-absorbing housing 23 consists in this embodiment of an outer shell 28 as well as an inner shell 29 , In the inner shell 29 are the valve devices 19 . 16 and the recirculation conveyor 17 with its electric drive motor 30 arranged and over the rigid fasteners 27 stuck with this inner shell 29 the sound-absorbing housing 23 connected. The inner shell can in turn be formed as a continuous shell of a metal, a fiber-reinforced plastic or the like. In principle, it would also be conceivable, the inner shell 29 analogous to the embodiment described above, only as a lattice-shaped support structure, for example of metal rods form. At this inner shell 29 are now the components 16 . 17 . 19 . 30 Tightly tied and used by this inner shell 29 carried. The inner shell 29 is then via decoupling elements 24 of which four are exemplified here, with the outer shell 28 the sound-absorbing housing 23 connected. Depending on the structure of the inner shell 29 So, depending on whether this is dense or designed as a lattice-shaped structure, the foamed material for sound insulation now inside the inner shell 29 and / or inside the outer shell 28 be arranged. In the in 3 chosen representation was the sound-absorbing material 25 as an example in the outer shell 28 shown. Also in this embodiment, a corresponding structure, in which due to sound emissions and on the inner shell 29 Structure-borne sound transmitted only the inner shell 29 opposite the outer shell 28 emotional. The sound-absorbing housing 23 as such, in turn, as well as the sound-absorbing housing 23 in the embodiment according to 2 , fixed and integrated into the overall system without any leeway.

The two embodiments described here, which on a device 5 for supplying air to the fuel cell system 2 on the one hand and a device 7 for the hydrogen supply of the fuel cell system 2 On the other hand, are of course interchangeable, so that in the context of 2 also described structure for a water supply module and in 3 described structure could be used for an air supply module. Also, the ideas that have been described in the context of the two embodiments, Of course, can be combined with each other, with such embodiments are also within the scope of the invention.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10200607176 A1 [0005]

Claims (13)

Device for media supply in a fuel cell system, with components of the media supply, which comprise at least one media conveyor, and with a sound-absorbing housing, characterized in that the sound-absorbing housing ( 23 ) is self-supporting, wherein the components ( 12 . 13 . 14 . 15 . 16 . 18 . 19 ) of the sound-absorbing housing ( 23 ) are worn. Device according to claim 1, characterized in that the components ( 12 . 13 . 14 . 15 . 16 . 18 . 19 ) decoupled at the sound-absorbing housing ( 23 ) are attached. Apparatus according to claim 1, characterized in that the sound-absorbing housing ( 23 ) an inner shell ( 29 ) and an outer shell ( 28 ), wherein the components ( 12 . 13 . 14 . 15 . 16 . 18 . 19 ) firmly with the inner shell ( 29 ), and wherein the inner shell ( 29 ) decoupled in the outer shell ( 28 ) is attached. Apparatus according to claim 1, 2 or 3, characterized in that the sound-absorbing housing ( 23 ) a grid-shaped support structure and an outer shell ( 28 ) having. Apparatus according to claim 3 or 4, characterized in that the grid-shaped support structure as the inner shell ( 28 ) is trained. Device according to one of claims 1 to 5, characterized in that the media supply as air supply module ( 5 ) is formed, which as components at least one air conveying device ( 12 ) and at least one silencer ( 13 . 14 ). Apparatus according to claim 6, characterized in that the at least one silencer ( 13 . 14 ) directly to the air conveyor ( 12 ) is coupled. Apparatus according to claim 6 or 7, characterized in that the air conveying device ( 12 ) is designed as a volumetric compressor. Device according to one of claims 1 to 8, characterized in that the media supply as hydrogen supply module ( 7 ) is formed, which as components at least one recirculation conveyor ( 18 ) and at least one cyclically operated valve device ( 16 . 19 ). Device according to one of claims 1 to 9, characterized in that the sound-absorbing housing ( 23 ) Metal, plastic, fiber reinforced plastic or a composite material thereof as one of its materials. Device according to one of claims 1 to 10, characterized in that the sound-absorbing housing ( 23 ) Has reinforcing ribs. Device according to one of claims 1 to 11, characterized in that the sound-absorbing housing ( 23 ) at least partially with a sound absorbing material ( 25 ) is lined. Use of the device according to one of claims 1 to 12, for media supply in a fuel cell system ( 2 ) in a means of transport ( 1 ).

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