DE102019214279A1 - Side channel compressor for a fuel cell system for conveying and / or compressing a gaseous medium - Google Patents

Abstract

Side channel compressor (1) for a fuel cell system (37) for conveying and / or compressing a gaseous medium, in particular hydrogen, with a housing (3), with a compression chamber (30) located in the housing (3), which has at least one circumferential side channel ( 19, 21), with a compressor wheel (2) located in the housing (3), which is arranged rotatably about an axis of rotation (4), the compressor wheel (2) being arranged on its circumference in the area of the compressor chamber (30). 5), and each with a gas inlet opening (14) formed on the housing (3) and a gas outlet opening (16), which are fluidically connected to one another via the compressor chamber (30), in particular the at least one side channel (19, 21) are connected, the housing (3) each having a first and second end face (32, 34) radially to the axis of rotation (4), each facing the compressor wheel (2) and a first and second f According to the invention, the compressor wheel (2) is constructed in several parts and has a guide vane wheel (10) and a first delimiting plate (22) and / or a second delimiting plate (24), these being in particular at least partially axial are arranged side by side with respect to the axis of rotation (4) and the guide vane wheel (10) is at least almost completely made of plastic.

Description

State of the art

The present invention relates to a side channel compressor for a fuel cell system for conveying and / or compressing a gaseous medium, in particular hydrogen, which is provided in particular for use in vehicles with a fuel cell drive.

In the vehicle sector, in addition to liquid fuels, gaseous fuels will also play an increasing role in the future. Hydrogen gas flows must be controlled, especially in vehicles with fuel cell drives. The gas flows are no longer controlled discontinuously as in the case of the injection of liquid fuel, but the gaseous medium is taken from at least one high-pressure tank and fed to an ejector unit via an inflow line of a medium-pressure line system. This ejector unit leads the gaseous medium via a connecting line of a low-pressure line system to a fuel cell. After the gaseous medium has flowed through the fuel cell, it is returned to the ejector unit via a return line. The side channel compressor can be interposed, which supports the gas recirculation in terms of flow and efficiency. In addition, side channel compressors are used to support the flow build-up in the fuel cell drive, in particular when the vehicle is (cold) started after a certain idle time. These side channel blowers are usually driven by electric motors, which are supplied with voltage from the vehicle battery when they are operated in vehicles.

From the DE 10 2007 053 016 A1 a side channel compressor for a fuel cell system is known in which a gaseous medium, in particular hydrogen, is conveyed and / or compressed. The side channel compressor has a compressor wheel which revolves in a housing, which is fastened on a drive shaft and is set in rotation by a drive and is thus arranged to be rotatable about an axis of rotation. Furthermore, the side channel compressor has a compression chamber located in the housing, which has at least one circumferential side channel. The compressor wheel has delivery cells arranged on its circumference in the area of the compressor chamber. A gas inlet opening and a gas outlet opening, which are fluidically connected to one another via the at least one side channel, are also arranged in the housing. The housing has a first and a second end face facing the compressor wheel, each of which runs radially to the axis of rotation. In these areas, an inner and an outer axial gap are formed between the housing and the compressor wheel.

The one from the DE 10 2007 053 016 A1 known side channel blowers can have certain disadvantages. When using the side channel compressor, in particular as a recirculation fan, with which the compressor wheel is formed from a one-piece cast part, in particular a metallic cast part, the manufacturing costs of the compressor wheel can be correspondingly high. The high manufacturing costs are made up as follows: high raw material costs of the casting material and / or high energy costs in the production, in particular in a casting process, of the compressor wheel as a cast part and / or high processing costs in the post-processing of the compressor wheel, such as machining and / or grinding post-processing. This applies in particular to the complex and thus complex and expensive to manufacture geometry of the guide vanes and / or a guide vane wheel.

Another disadvantage of the DE10 2007 053 016 A1 known side channel compressor is the large size of the compressor wheel made from the cast material. In particular when the side channel compressor is started up and braked frequently, the compressor wheel must be continuously accelerated and / or braked in such a way that it builds up and / or decreases a corresponding speed. When using the compressor wheel made of cast material, due to the mass of the cast material, a correspondingly high energy expenditure of the drive is necessary for this, in particular in the form of electrical energy, which in turn leads to increased operating costs of the side channel compressor.

Disclosure of the invention

Advantages of the invention

Referring to claim 1, a side channel compressor is designed in such a way that a compressor wheel is constructed in several parts and has a guide vane wheel and a first delimitation plate and / or a second delimitation plate. In this case, these components are in particular arranged at least partially axially next to one another in relation to an axis of rotation and the guide vane wheel is at least almost completely made of plastic. In this way, the manufacturing costs of the compressor wheel can be reduced, the reduced costs during the phases of the manufacturing process being explained below. The material costs, in particular the raw material costs, for the guide vane wheel, which is at least almost completely made of plastic, are lower than the material costs, in particular the raw material costs of the Compressor wheel made of a cast material, in particular a metal cast material. Furthermore, when the guide vane wheel is formed from plastic, for example by means of an injection molding process, less energy, in particular electrical energy, has to be expended than when it is formed, in particular by means of a metallic casting process. Furthermore, the costs for the reworking of the compressor wheel and / or the impeller shells, in which plastic is used as the material, are lower compared to the compressor wheel and / or the impeller shells made of cast material, in particular due to the material hardness and the resulting tool wear and one for the Compressor wheel disadvantageous temperature development during post-processing. Furthermore, when using plastic for the guide vane wheel, complex geometries of the guide vanes can be implemented, which can improve the conveying effect of the side channel compressor and increase the efficiency. In this way, by using plastic instead of, for example, a cast material, on the one hand the manufacturing costs and also the total weight and / or the total mass of the compressor wheel can be reduced. Consequently, the compressor wheel thus has a lower mass moment of inertia, in particular during a rotational movement. On the one hand, this results in the advantage that the compressor wheel has improved rotational dynamics and a faster response behavior when accelerating and / or braking into and / or out of the rotational movement, with the desired speed change thus being able to be achieved more quickly. A desired operating state of the anode circuit and thus of the entire fuel cell can thus be brought about more quickly. On the other hand, the advantage can be achieved that the energy required, in particular the electrical energy, for driving the side channel compressor can be reduced, since less energy is required to accelerate and / or decelerate the compressor wheel and / or the guide vane wheel due to the lower mass moment of inertia. in particular electrical energy must be used. In this way, the overall operating costs and / or the production costs of a fuel cell system can be reduced. By arranging the components guide vane wheel and first delimitation plate and / or second delimitation plate next to one another at least partially axially to the axis of rotation, a stable connection of the multi-part compressor wheel can be achieved, since the interfaces between the components run circumferentially around the axis of rotation and are therefore not exposed to increased centrifugal forces. In this way, the reliability of the compressor wheel and thus of the side channel compressor can be increased.

The measures listed in the subclaims allow advantageous developments of the side channel compressor specified in claim 1. The subclaims relate to preferred developments of the invention.

According to a particularly advantageous embodiment, the guide vane wheel is at least almost completely enclosed and / or surrounded by the first delimitation plate and / or the second delimitation plate. In this way, the area of the compressor wheel, in particular the guide vane wheel, which is at least almost completely made of plastic, can be protected by the respective delimitation plate. This prevents this area from coming into mechanical contact with a first end face and / or a second end face of a housing, in particular in the area of a first functionally relevant gap dimension and / or a second functionally relevant gap dimension. In addition, if the side channel compressor and / or the vehicle is not used for a long time, especially at low temperatures, ice bridges can form in the area of the functionally relevant gap dimensions between the compressor wheel and the housing. When the side channel compressor is started, these ice bridges can lead to damage to the guide vane wheel if this is at least almost completely made of plastic, as in the embodiment according to the invention. However, this is prevented in such a way that the guide vane wheel is at least almost completely enclosed by the first and / or second delimitation plate. In this way, damage to the at least relatively soft components of the compressor wheel, which are made in particular of plastic, can be prevented by ice bridges. This leads to a longer service life and a lower probability of failure of the entire side channel blower.

According to an advantageous embodiment of the side channel compressor, the compressor wheel has, in addition to the limiting plates, at least one first intermediate element and / or a second intermediate element, the first intermediate element in particular being located axially to the axis of rotation between the first limiting plate and the guide vane wheel and / or in particular the second intermediate element located axially to the axis of rotation between the second delimitation plate and the guide vane wheel. In this way, the advantage can be achieved that a compact arrangement of the components of the compressor wheel, in particular the first delimiting plate, the first intermediate element, the guide vane wheel, the second intermediate element and the second delimiting plate can be achieved. A compact design of the compressor wheel and thus of the side channel compressor can thus be achieved, whereby in particular less installation space is required in the fuel cell system and / or in the overall vehicle.

According to an advantageous development, the compressor wheel is connected to a drive shaft by means of a driver ring rotating around the axis of rotation, the driver ring being connected to the drive shaft with its inner diameter radially to the axis of rotation in a non-positive manner, in particular by means of a press fit, and / or the Driver ring in the area of a connection point, in particular cohesively, is connected to the first and / or second delimitation plate. In this way, a cost-effective connection of the compressor wheel to the drive shaft can be realized, in addition, high torques and high speeds can be transmitted from the drive by means of the drive shaft via the driver ring to the compressor wheel. In addition, the assembly and disassembly of the compressor wheel on the shaft is simplified by using the driving flanges, and the assembly and maintenance costs can thus be reduced.

According to a particularly advantageous development, the delimitation plates are fixed on the driver ring in such a way that they each exert a pretensioning force running axially to the axis of rotation on the guide vane wheel and / or the respective intermediate element. In this way it can be ensured that there is a reliable connection between the drive shaft and / or the driving ring and the compressor wheel. Furthermore, it is ensured that the components of the compressor wheel, in particular the first delimitation plate, the first intermediate element, the guide vane wheel, the second intermediate element and the second delimitation plate do not move at least almost axially away from one another in the event of a temperature change, which leads to the disconnection of the compressor wheel assembly could, whereby the functionality of the side channel blower would be restricted. Thus, the reliability of the side channel compressor can be improved in this way. Furthermore, such a configuration of the side channel compressor according to the invention offers the advantage that the function-relevant gap dimensions can be compensated for with at least one floating and / or floating bearing of the drive shaft. Reliable encapsulation of at least one side channel or the respective side channels can thus be achieved, as a result of which the efficiency of the side channel compressor can be improved.

According to an advantageous embodiment, the first delimitation plate and / or the second delimitation plate and / or the first intermediate element and / or the second intermediate element each have at least one fixing hole running at least approximately axially to the axis of rotation into which at least one fixing pin of the guide vane wheel running axially to the axis of rotation protrudes . In this way, the advantage can be achieved that the respective delimitation plate and / or the respective intermediate element is fixed in a form-fitting manner by means of the respective driver flange. When the drive shaft and / or the driver ring rotates around the axis of rotation, a torque is transmitted to the respective delimitation plate and / or the respective intermediate element, with the form fit between the locating pin in the locating bore ensuring that a high motor-side drive torque is applied to the Compressor wheel, can be transferred. This leads to a lower probability of failure of the entire side channel compressor, even with strongly fluctuating torques and / or excessive torque from the drive.

According to an advantageous development, the first intermediate element is designed as a first compensating disk and / or the second intermediate element is designed as a second compensating disk, the respective compensating disk being made at least partially from an elastic material. In this way, the advantage can be achieved that a total width of the compressor wheel which runs in particular at least almost parallel to the axis of rotation, and / or a respective first or second function-relevant gap dimension, even when passing through a wide temperature range, for example from -60 ° C to 120 ° C, hardly changes or at least changes only slightly. This advantage can be achieved insofar as the intermediate element is designed to be elastic in such a way that when the width of the guide vane wheel and / or the respective first or second delimitation plate increases, for example due to a temperature increase in the side channel compressor and the resulting thermal expansion of the respective component, in Is compressed in the direction of the axis of rotation and thus the total width of the compressor wheel does not change or at least only slightly increased. Therefore, the overall width of the compressor wheel changes almost not at all or at least only slightly, since the increase in width of the guide vane wheel components and / or the respective delimitation plate when the temperature increases is compensated for by reducing the elastic intermediate element, in particular at least almost axially to the axis of rotation. In this way, the advantage can be achieved that the at least one functionally relevant gap dimension between the compressor wheel and the housing does not change or at least changes only slightly, so that a disadvantageous effect is prevented. On the one hand, a negative effect can be such an enlargement of the respective functionally relevant gap that a pneumatic encapsulation and / or separation of the at least one side channel is abolished, whereby the conveying effect of the side channel compressor is reduced or completely inhibited becomes. On the other hand, a further negative effect can be such a reduction in the respective function-relevant gap size that the rotating compressor wheel comes into contact with the housing, which can damage the components of the compressor wheel and / or housing and / or the compressor wheel completely in the housing blocked and / or the medium to be conveyed ignites due to sparking due to contact with the components. This can lead to a total failure of the side channel blower. The reliability and / or the efficiency of the side channel compressor can thus be increased or at least maintained, even when passing through a wide temperature range.

According to a particularly advantageous embodiment, the respective compensating disk has at least two openings which run at least approximately axially to the axis of rotation, the respective opening creating a fluidic connection of the side channels axially to the axis of rotation through a respective delivery cell in the compressor wheel. In this way, the gaseous medium can flow at least partially in the direction of the axis of rotation from the first side channel through the delivery cell into the second side channel, but in particular only when the compressor wheel is at a standstill or when the compressor wheel rotates slowly. In this way, the gaseous medium flowing from the respective side channel axially to the axis of rotation through the at least one opening into the delivery cell can be better shifted in the desired direction and in the desired state of a circulation flow, whereby the conveying effect of the side channel compressor can be improved. This increases the delivery pressure in the compressor chamber and the efficiency of the side channel compressor can be improved. Furthermore, the double conveying effect due to two existing side channels can be used even if only one gas inlet opening and one gas outlet opening are provided, for example, only in a housing lower part and thus in an interrupter area of the first side channel. In the transition from the second side channel to the interrupter area, the gaseous medium can flow through the respective delivery cell and the respective openings of the compensating disk to the gas outlet opening when the compressor wheel rotates in the direction of the axis of rotation. The delivery volume and / or the efficiency of the side channel compressor can thus be increased.

According to an advantageous development, the housing has an upper housing part and a lower housing part, the upper housing part having a cylindrical collar encircling the axis of rotation and the lower housing part having a cylindrical projection encircling the axis of rotation and the collar surrounding the projection . In addition, there is a compensation gap running radially to the axis of rotation axially to the axis of rotation between the extension of the lower housing part and the upper housing part and / or there is a first adjusting disk extending radially to the axis of rotation axially to the axis of rotation between a contact surface of the collar of the upper housing part and the lower part of the housing. In this case, at least one gap dimension can be set between the compressor wheel and the housing, in particular by means of the first adjusting disk. In this way, on the one hand, the advantage can be achieved that the lower housing part can be centered in the upper housing part, since the extension with its outer diameter is guided on the inner diameter of the upper housing part, whereby assembly costs can be reduced. In addition, assembly errors can be reduced, for example due to housing parts that are not optimally aligned with one another, whereby the probability of failure of the side channel compressor can be reduced. Furthermore, by using the first adjusting washer, it is possible to compensate for manufacturing tolerances of the upper housing part and / or the lower housing part in such a way that an optimal, functionally relevant first and / or second gap dimension can be set. In this case, first setting disks with different thicknesses running in the direction of the axis of rotation can either be used during assembly or the first setting disk can be machined shortly before or during the assembly process. It is no longer necessary to rework the upper part of the housing and / or the lower part of the housing. In this way, the monthly time and / or the assembly costs can be reduced.

According to an advantageous development, the upper housing part and / or the lower housing part and / or the limiting plates and / or the drive shaft and / or the driver ring are at least partially made of a metallic material, the components having at least approximately the same coefficient of thermal expansion exhibit. In addition, the metallic material can be aluminum and / or steel and / or a metallic alloy. In this way, a constant pressing force running at least approximately parallel to the axis of rotation can be exerted on the respective compensating disks and / or the guide vane wheel. The boundary plates are pressed against the respective intermediate element and / or the guide vane wheel by means of the change in length of the driver ring and / or the drive shaft in the direction of the axis of rotation in such a way that the total width of the compressor wheel extends over a wide temperature range, for example from -60 ° C to 120 ° C, hardly changes or at least changes only slightly. A change in the overall width, in particular in the direction of the axis of rotation, the respective delimitation plate and / or the guide vane wheel due to the expansion of the material in the event of a temperature change due to the variable width of a respective gap between the respective delimitation plate and the guide vane wheel, with the respective compressible intermediate element in particular being located in the respective gap is located. As soon as the respective delimitation plate and / or the guide vane wheel increases in width in the direction of the axis of rotation, the gap becomes smaller, with the prestress of the assembly compound and / or the prestress being at least indirectly between the housing, in particular a first bearing, and the compressor wheel The spring element ensures constant pressing of the delimitation plate against the respective intermediate element and / or the guide vane wheel. In this way, the advantage can be achieved that the at least one functionally relevant gap dimension does not change or at least changes only slightly, so that in particular there is no such expansion of the at least one functionally relevant gap dimension that pneumatic encapsulation and / or separation of the Side channels is canceled. The reliability and / or the efficiency of the side channel compressor can thus be increased or at least maintained, even when passing through a wide temperature range.

According to a particularly advantageous development, there is a stiffening ring between the guide vane wheel, in particular the inner diameter of the guide vane wheel, and the driver ring, in particular the outer diameter of the driver ring, the stiffening ring in the direction of the axis of rotation with a respective fifth and sixth end face of the first and second delimitation plate is in contact and wherein the stiffening ring extends annularly around the axis of rotation. In this way, the overall rigidity and service life of the compressor wheel can be increased, as a result of which the probability of failure of the side channel compressor is reduced.

The invention is not restricted to the exemplary embodiments described here and the aspects emphasized therein. Rather, a large number of modifications are possible within the range specified by the claims, which are within the scope of expert action.

Figure list

The invention is described in more detail below with reference to the drawing.

• 1 eine schematische Schnittansicht eines erfindungsgemäßen Seitenkanalverdichters und eines erfindungsgemäßen Verdichterrads gemäß einem ersten Ausführungsbeispiel,
• 2 einen in 1 mit II bezeichneten Ausschnitt Verdichterrads in vergrößerter Darstellung
• 3 einen in 1 mit A-A bezeichneten Schnitt des Verdichterrads mit Schaufelblättern,
• 4 eine in 3 mit C-C bezeichnete Seitenansicht des ersten Begrenzungsblechs mit Öffnungen,
• 5 eine in 3 mit D-D bezeichnete Seitenansicht des zweiten Zwischenelements mit Öffnungen,
• 6 eine schematische Schnittansicht des erfindungsgemäßen Seitenkanalverdichters und des erfindungsgemäßen Verdichterrads gemäß mit einem Versteifungsring gemäß einem zweiten Ausführungsbeispiel,

It shows:

• 1 a schematic sectional view of a side channel compressor according to the invention and a compressor wheel according to the invention according to a first embodiment,
• 2 one in 1 with II designated section of the compressor wheel in an enlarged view
• 3rd one in 1 Section of the compressor wheel with blades marked AA,
• 4th one in 3rd side view, marked with CC, of the first delimitation plate with openings,
• 5 one in 3rd side view of the second intermediate element with openings, denoted by DD,
• 6th a schematic sectional view of the side channel compressor according to the invention and the compressor wheel according to the invention according to the invention with a stiffening ring according to a second embodiment,

Description of the embodiment

According to the representation 1 is a schematic sectional view of a side channel blower according to the invention 1 and a compressor wheel according to the invention 2 according to a first embodiment.

The side channel blower 1 shows the compressor wheel 2 on, around a horizontal axis of rotation 4th rotatable in a housing 3rd is stored. A drive is used for this 6th , especially an electric drive 6th , as a rotary drive 6th of the compressor wheel 2 and a transmission of the torque and / or the rotary movement takes place from the drive 6th via a drive shaft 9 at least indirectly on the compressor wheel 2 instead of. Here is the compressor wheel 2 designed in several parts and has a guide vane wheel 10 and a first delimitation plate 22nd and / or a second delimitation plate 24 on, this in particular at least partially axially to the axis of rotation 4th are arranged side by side and wherein the guide vane 10 is at least almost entirely made of plastic. Furthermore, there is the guide vane wheel 10 at least almost completely from the first delimitation plate 22nd and / or the second delimitation plate 24 enclosed and / or surrounded. For example, the first delimitation plate 22nd be designed in such a pot-shaped manner that it is disc-shaped circumferentially around the axis of rotation 4th runs, but at its outer diameter runs at least approximately parallel to the axis of rotation, in particular around the axis of rotation 4th , circumferential partial web 57 having the guide vane 10 on its the axis of rotation 4th facing away from the outer diameter surface encloses. The circumferential part of the web can 57 of the first delimitation plate 22nd with orthogonal to the axis of rotation 4th running sixth end face 46 of the second delimitation plate 24 stand in plant. The second delimitation plate 24 runs disc-shaped around the axis of rotation 4th .

In addition, the compressor wheel 2 in addition to the boundary plates 22nd , 24 a first intermediate element 13th and / or a second intermediate element 25th have, in particular the first intermediate element 13th axial to the axis of rotation 4th between the first delimitation plate 22nd and the guide vane 10 is and / or in particular the second intermediate element 25th axial to the axis of rotation 4th between the second delimitation plate 24 and the guide vane 10 is located. The respective intermediate elements 13th , 25th run around the axis of rotation in the form of a disk 4th . The compressor wheel 2 has a total width 45 at least approximately parallel to the axis of rotation 4th runs.

Furthermore, the housing 3rd in the area of a compressor room 30th a first circumferential side channel 19th and / or a second circumferential side channel 21 on. A large number of conveyor cells run here 5 (not shown, see 3rd ) around the axis of rotation 4th in which almost completely around the axis of rotation 4th circumferential compressor room 30th of the housing 3rd in the compressor wheel 2 . The side channels run 19th , 21 such in the case 3rd in the direction of the axis of rotation 4th that this is axially to the delivery cell 5 run on both sides. The side channels 19th , 21 can at least in a partial area of the housing 3rd all around the axis of rotation 4th run, in the sub-area in which the side channels 19th , 21 in the housing 3rd is not formed, a breaker area 15th in the housing 3rd is trained.

The drive shaft 9 one end is axial to the axis of rotation 4th at least gimbal with the drive 6th connected. There is a first warehouse 27 on the outside diameter of the drive shaft 9 axially in the area between the drive 6th and the compressor wheel 2 and a second warehouse 47 on the the drive 6th remote side of the compressor wheel 2 . At the camps 27 , 47 it can be roller bearings 27 , 47 act, especially ball bearings 27 , 47 . Furthermore, the housing forms 3rd a gas inlet port 14th and a gas outlet port 16 out. Here are the gas inlet opening 14th and the gas outlet port 16 , in particular via the at least one side channel 19th , 21 fluidically connected to each other.

As soon as from the drive 6th the torque on the compressor wheel 2 is transmitted, the compressor wheel 2 set in rotation and the at least one conveyor cell 5 moves in a rotational movement around the axis of rotation 4th through the compressor room 30th in the housing 3rd . One is already in the compressor room 30th gaseous medium present through the pumping cell 5 moved along and promoted and / or compressed. In addition, there is a movement of the gaseous medium, in particular an exchange of flow, between the delivery cell 5 and the at least one side channel 19th , 21 instead of. It is crucial for the conveying effect that there is a circulation flow during operation 50 within the respective side channel 19th , 21 can train. The case 3rd points radially to the axis of rotation 4th a first and a second end face each 32 , 34 on each of the compressor wheel 2 are facing. This forms in the area of the gap surfaces, in particular between the respective end surfaces 32 , 34 are located, a first and a second functionally relevant gap each 36 , 38 between the housing 3rd and the compressor wheel 2 out.

By means of the functionally relevant gap dimensions 36 , 38 is achieved that the side channels 19th , 21 are encapsulated and thus pneumatically separated from each other. This forms the compressor wheel 2 and the case 3rd , in particular an upper part of the housing 7th and / or a lower housing part 8th , a respective functionally relevant gap 36 , 38 from, which is so small that the gaseous medium the respective gap size 36 , 38 cannot pass and / or cannot flow past. The surface pairings mentioned have 32 , 34 usually as little play to one another as possible. Furthermore, the gaseous medium flows, which is in particular an unused recirculation medium from a fuel cell system 37 , acts, through the gas inlet port 14th in the compressor room 30th of the side channel blower 1 one and / or the side channel blower 1 is supplied and / or is from the area that the gas inlet opening 14th is upstream, sucked. The gaseous medium is released through the gas outlet opening after it has passed through 16 of the side channel blower 1 diverted and flows back into the fuel cell system 37 . There is also an axis of symmetry 48 shown, the orthogonal to the axis of rotation 4th and symmetrically centered through the cutting geometry of the compressor wheel 2 runs.

In 1 it is also shown that the compressor wheel 2 by means of a around the axis of rotation 4th circumferential driver ring 12th with the drive shaft 9 is connected, the driver ring 12th with its inner diameter radial to the axis of rotation 4th non-positively, in particular by means of a press fit, with the drive shaft 9 is connected and / or wherein the driver ring 12th in the area of a connection point 28 a, b, in particular cohesively, with the first and / or second delimitation plate 22nd , 24 connected is. In addition, the boundary plates are 22nd , 24 in each case on Driver ring 12th fixed that this each one axially to the axis of rotation 4th running preload force on the guide vane wheel 10 and / or the respective intermediate element 13th , 25th exercise. Here is the first intermediate element 13th as a first shim 13th and / or the second intermediate element 25th as a second shim 25th is executed, the respective shim 13th is at least partially made of an elastic material.

Furthermore, in 1 shown that the case 3rd the upper part of the housing 7th and the lower part of the housing 8th having, wherein the housing upper part 7th one around the axis of rotation 4th circumferential cylindrical collar 23 and the lower part of the housing 8th one around the axis of rotation 4th circumferential cylindrical approach 26th has and that the collar 23 the approach 26th surrounds. There is a radial to the axis of rotation 4th running compensation gap 43 axial to the axis of rotation 4th between the approach 26th of the lower part of the housing 8th and the upper part of the housing 7th , one being radial to the axis of rotation 4th running first shim 29 axial to the axis of rotation 4th between a contact surface 33 of the collar 23 of the upper part of the housing 7th and a front surface of the lower part of the housing 8th is located, in particular by means of the first adjusting disk 29 at least the gap size in each case 36 , 38 between the compressor wheel 2 and the case 3rd can be adjusted. Here are the upper part of the housing 7th and / or the lower part of the housing 8th and / or the delimitation plates 22nd , 24 and / or the drive shaft 9 and / or the driving ring 12th at least partially made of a metallic material, the components having at least approximately the same coefficient of thermal expansion. In addition, the metallic material is aluminum and / or steel and / or a metallic alloy.

In 1 it is also shown that the upper part of the housing 7th one around the axis of rotation 4th circumferential cylindrical collar 23 and the lower part of the housing 8th one around the axis of rotation 4th circumferential cylindrical approach 26th having, the cylindrical extension 26th with its the axis of rotation 4th remote surface of the axis of rotation 4th facing inner surface of the cylindrical collar 23 is facing. The radial to the axis of rotation 4th running compensation gap 43 is located axially to the axis of rotation 4th between a front surface of the approach 26th of the lower part of the housing 8th and a front surface of the upper part of the housing 7th . Furthermore, the is located radially to the axis of rotation 4th running first shim 29 axial to the axis of rotation 4th between the contact surface 33 of the collar 23 of the upper part of the housing 7th and a front surface of the lower part of the housing 8th . In particular, by means of the adjusting disk 29 at least one gap each 36 , 38 between the compressor wheel 2 and the case 3rd can be set. Here are the upper part of the housing 7th and / or the lower part of the housing 8th and / or the delimitation plates 22nd , 24 and / or the drive shaft 9 and / or the driver ring 12th at least partially made of a metallic material, the components having at least approximately the same coefficient of thermal expansion. The metallic material can be aluminum and / or steel and / or a metallic alloy.

Due to the design of the components, the upper part of the housing 7th and / or lower part of the housing 8th and / or the delimitation plates 22nd , 24 and / or the drive shaft 9 and / or driver ring 12th These components are made from a, in particular metallic, material with at least approximately the same coefficient of thermal expansion in the direction of the axis of rotation 4th expand at least almost the same amount when the temperature increases and contract at least almost as much when the temperature decreases. As the guide vane 10 is made at least partially from a plastic, this has a different coefficient of thermal expansion. Thus the width changes 65 of the guide vane 10 different in the case of a temperature change compared to the components of the upper part of the housing 7th and / or lower part of the housing 8th and / or respective delimitation plate 22nd , 24 and / or drive shaft 9 and / or driver ring 12th . This in turn could lead to such a widening of the respective function-relevant gap size 36 , 38 lead, whereby the encapsulation and thus fluidic and / or pneumatic separation of the side channels 19th , 21 would no longer be guaranteed from each other. On the other hand, there could be a reduction in the respective gap size 36 , 38 due to temperature changes and different coefficients of thermal expansion of the components of the side channel blower 1 the respective functionally relevant gap size 36 , 38 become so small that the compressor wheel 2 and the case 3rd come into contact with each other, the components are damaged as a result and / or the compressor wheel 2 in the housing 3rd blocked and thus the side channel blower 1 would no longer be functional. Due to the use of the respective shim 13th , 25th can change the width of the components of the guide vane wheel 10 compared to the components of the upper part of the housing 7th and / or lower part of the housing 8th and / or boundary plates 22nd , 24 and / or drive shaft 9 and / or driver ring 12th are compensated in such a way that the respective shim 13th , 25th at least almost in the direction of the axis of rotation 4th is compressed and / or pulled apart. The first shim 13th and / or the second shim 25th can choose either a larger or a smaller change in width 65 to width 45 Compensate, for example, by a temperature change and an associated material expansion of the components of the Side channel blower 1 accompanied. This is due to the elastic deformability of the respective shim 13th , 26th justified.

In 1 is also shown that the drive 6th one axially to the axis of rotation 4th trending rotor 17th having, the rotor 17th frictionally and / or positively with the drive shaft 9 is connected, in particular by means of a press fit. Encapsulation of the rotor 17th ensures that at least almost no hydrogen from the side channel compressor 1 can get into the environment, which can lead, for example, to a reaction with oxygen and an oxyhydrogen gas effect, which in turn affects the side channel blower 1 and / or could damage other components of the entire vehicle. In addition, the drive 6th one around the axis of rotation 4th rotating stator 11 on, with the stator 11 outside revolving around the rotor 17th and / or the rotor is 17th within the inner diameter of the stator 11 is located. By energizing the stator 11 can the rotor 17th are driven and, in particular, are set in a rotational movement. An encapsulation of the stator 11 against environmental influences and / or against moisture and pollution from the outside through the use of a stator housing 39 achieved. A rotor housing 41 and / or a stator housing 39 can do this on the housing 3rd of the side channel blower 1 be fixed, in particular to the housing 3rd be screwed on.

Furthermore, in 1 shown that in an exemplary embodiment of the side channel blower 1 the second camp 47 , in particular on its outer bearing shell, by means of a second adjusting disk 63 that is to one end face of the housing 3rd at least almost in the direction of the axis of rotation 4th is in contact, whereby by means of the machining of the second adjusting disk 63 during the assembly of the respective bearing 27 , 47 or before assembly, the respective bearing preload and / or the play of the compressor wheel in the area of the first and second functionally relevant gap dimension 36 , 38 can be adjusted. Furthermore, an acts axially to the axis of rotation 4th between the housing 3rd and the first camp 27 arranged spring element 35 for a bearing preload. In an exemplary embodiment of the side channel compressor 1 the bearing outer ring of the first bearing 27 with the case 3rd in the direction of the axis of rotation 4th stand in plant while the first camp 27 with its inner bearing ring with the spring element 35 in the direction of the axis of rotation 4th is attached. In addition, the spring element is standing 35 in the direction of the axis of rotation 4th on the first camp 27 remote side with the compressor wheel 2 in Appendix.

In 2 is an in 1 with II marked section of the compressor wheel 2 shown in an enlarged view. It is shown that there is always a gap 52 between the first delimitation plate 22nd and the guide vane 10 as well as the second delimitation plate 24 and the guide vane 10 . In this respective gap 52 is the first or second shim 13th , 25th . In addition, have the first delimitation plate 22nd and / or the second delimitation plate 24 and / or the first intermediate element 13th and / or the first intermediate element 13th and / or the second intermediate element 25th in each case at least one at least approximately axially to the axis of rotation 4th running fixing hole 20th on, in which at least one is axially to the axis of rotation 4th running fixing pin 18th of the guide vane 10 protrudes.

Furthermore, in 2 shown that the guide vane 10 , especially the first delimitation plate 22nd , a third face 40 having the housing 3rd , especially the first face 32 of the upper part of the housing 7th , (shown in 1 ) is facing. In addition, the guide vane 10 , especially the second delimitation plate 24 , a fourth face 42 on that the case 3rd , in particular the second end face 34 of the lower part of the housing 8th , (shown in 1 ) is facing. The first delimitation plate is also in place 22nd with a fifth face 44 a seventh face 54 the first shim 13th in the system and / or the second delimitation plate 24 stands with the sixth face 46 an eighth face 56 the second shim 25th in Appendix. The guide vane 10 again stands with an eleventh face 64 with the ninth face 58 the first shim 13th in plant and / or the guide vane 10 stands with a twelfth face 66 with the tenth face 60 the second shim 25th in Appendix. The respective end faces 32 , 34 , 40 , 42 , 44 , 46 , 54 , 56 , 58 , 60 , 64 , 66 run at least almost orthogonally to the axis of rotation 4th . It acts axially to the axis of rotation 4th acting pretensioning force over the surfaces 40 , 42 , 44 , 46 , 54 , 56 , 58 , 60 , 64 , 66 on the respective components 10 , 13th , 22nd , 24 , 25th and ensures a stable assembly of the compressor wheel 2 , whereby there are also high torques on the part of the drive 6th on the compressor wheel 2 let transfer. The overall width 45 of the compressor wheel 2 can at least almost be maintained in the event of a temperature change in this way by removing the shims 13th , 25th changing the width 65 of the guide vane 10 and / or compensate for the metallic components by elastically deforming them. The first delimitation plate 22nd stands with its partial bridge 57 with the second delimitation plate 24 either at least in attachment or it is via a joint 59 between an end face of the partial web 57 with the sixth face 46 firmly connected.

3rd shows an in 1 Section of blade blades marked AA 55 of the compressor wheel 2 and the conveyor cells 5 with the shims 13th , 25th and the first and second delimitation plates 22nd , 24 . In addition, in 3rd the axis of symmetry 48 shown, the orthogonal to the axis of rotation 4th and by the symmetry of the impeller 2 runs. Here are the components of the compressor wheel 2 in sandwich construction in the following order in the direction of the axis of rotation 4th assembled or joined: first delimitation plate 22nd , first shim 13th , Guide vane 10 , second shim 25th , second delimitation plate 24 . Each between two blades 55 becomes the delivery cell 5 formed to a respective side channel 19th , 21 is open. This at least one opening 53a , b in the compressor wheel 2 that are at least approximately axially to the axis of rotation 4th runs, thereby connecting the side channels 19th , 21 and / or runs through the compressor wheel 2 . Furthermore, the gaseous medium from the compressor wheel 2 in the respective side channel 19th , 21 flow in and / or from the respective side channel 19th , 21 in the respective delivery cell 5 of the compressor wheel 2 can flow back. The components have the first delimitation plate 22nd , first shim 13th , second shim 25th , second delimitation plate 24 at least one such opening 53 on. In this way, by means of the respective conveyor cells 5 in the guide vane 10 and the openings 53a , b in the respective shim 13th , 25th and the respective delimitation plate 22nd , 24 a fluidic connection of the side channels 19th , 21 axial to the axis of rotation 4th through the compressor wheel 2 getting produced.

The shovel blades 55 are at least almost symmetrical and V-shaped to the axis of symmetry 48 shaped. As soon as the compressor wheel 2 by means of the drive 6th is set in rotation from a standstill position, presses a respective end face of the blades 55 that is in the delivery cell 5 located gaseous medium, in particular hydrogen, in a direction of rotation from the area of the gas inlet opening 14th to the area of the gas outlet opening 16 , whereby an acceleration and / or compression of the gaseous medium takes place. The gaseous medium is removed from the pumping cell in the direction of rotation 5 from the axis of symmetry 48 away into the respective side channel 19th , 21 pressed, the gaseous medium in the circulating flow 50 is displaced and with one speed out of the conveyor cell 5 outflowing gaseous medium in the respective side channel 19th , 21 encounters a slower flowing gaseous medium. This side channel flow of the medium flows more slowly than the delivery cell flow of the medium, with a force from the medium in the delivery cell being generated due to the resulting centrifugal force difference 5 on the medium in the side channel 19th , 21 results. An exchange of momentum takes place between the two media and it is circulated through it 50 shifted gaseous medium energy through an exchange of impulses on a conveying flow, which is in particular in the respective side channel 19th , 21 is still gaseous medium located, transferred. Here the conversion of speed energy into pressure energy takes place. The energy transfer takes place over the entire length of the respective circumferential side channel 19th , 21 takes place several times and depends on the number of blades 55 and funding cells 5 dependent. Thus there is a large transfer of energy between the one in the pumping cell 5 located gaseous medium and in the respective side channel 19th , 21 possible and a pressure build-up takes place linearly over the circumference through the exchange of impulses.

On the embodiment of the side channel compressor according to the invention 1 with the at least one side channel 19th , 21 It is also advantageous that if the side channel blower fails 1 furthermore the gaseous medium through the at least one side channel 19th , 21 can flow, even if the compressor wheel 2 stands still and there is therefore no risk of the fuel cell system being fed 37 due to the failed side channel blower 1 leads to a complete standstill. This is particularly the case when there is a high pressure and a high delivery rate of the medium to be delivered in the fuel cell system 37 is retained, in particular by a further component of the fuel cell system 37 .

4th shows an in 3rd with CC designated side view of the first delimitation plate 22nd with at least two openings 53a , the second delimitation plate 24 is shaped geometrically at least approximately coincident. It is shown that the first delimitation plate 22nd at least one fixing hole 20a having such fixing bores 20a in particular in a ring around the axis of rotation 4th in the respective delimitation plate 22nd , 24 are arranged. Furthermore, the respective delimitation plate 22nd , 24 an outer contour 51a on, the annular around the axis of rotation 4th runs. This is the inner part of the respective delimitation plate 22nd , 24 by means of at least two connecting ribs 62a with the outer contour 51 connected, the connecting ribs 62a at least almost radially to the axis of rotation 4th run away. The arrangement of the connecting ribs 62a is all around the axis of rotation 4th , where the respective delimitation plate 22nd , 24 between two connecting ribs 62a always an opening 53a forms, with the respective delimitation plate 22nd , 24 multiple openings 53a may have.

5 shows an in 3rd side view of the second shim, labeled DD 25th , being the first shim 13th is shaped geometrically at least approximately coincident. The respective shim 13th , 25th know an outer contour 51b and an inner contour 49b each ring around the axis of rotation 4th run away. The outer contour has 51b a larger diameter than the inner contour 49b and surrounds them. Furthermore, the respective compensating washer 13th , 25th at least two openings 53b on, which is at least approximately axially to the axis of rotation 4th run, by means of the respective opening 53b a fluidic connection of the side channels 19th , 21 axial to the axis of rotation 4th through the respective delivery cell 5 in the compressor wheel 2 will be produced. The respective openings 53b be outward, especially on your axis of rotation 4th remote side, through the outer contour 51b limited, and inward, especially on your axis of rotation 4th facing side, through the inner contour 49b limited. It is also located in the area of the inner contour 49b the respective axially to the axis of rotation 4th running fixing holes 20b that is in the area of the inner contour 49b all around the axis of rotation 4th are arranged.

According to the representation 6th is a schematic sectional view of the side channel blower according to the invention 1 and the compressor wheel according to the invention 2 according to a second embodiment. The compressor wheel 2 a stiffening ring 31 on. This stiffening ring 31 is located between the guide vane 10 , especially the inner diameter of the guide vane 10 , and the driver ring 12th , especially the outer diameter of the driver ring 12th , the stiffening ring 31 in the direction of the axis of rotation 4th with a respective end face of the first and second delimitation plates 22nd , 24 is in contact with the stiffening ring 31 in a ring around the axis of rotation 4th runs. By means of different diameters 61 of the stiffening ring 31 can achieve optimal rigidity of the compressor wheel 2 are brought about, depending on the component dimensions of the other components of the compressor wheel 2 , like first delimitation plate 22nd , second delimitation plate 24 , Guide vane 10 , the respective shim 13th , 25th and / or the driver ring 12th . In an exemplary embodiment, the stiffening ring 31 during assembly between the two boundary plates 22nd , 24 are inserted and / or are connected to these non-positively and / or positively and / or cohesively.

There is also the stiffening ring 13th made of a metallic material and / or has at least approximately the same coefficient of thermal expansion as the components of the upper housing part 7th and / or the lower part of the housing 8th and / or the delimitation plates 22nd , 24 and / or the drive shaft 9 and / or the driver ring 12th on.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• DE 102007053016 A1 [0003, 0004, 0005]

Claims (13)

Side channel compressor (1) for a fuel cell system (37) for conveying and / or compressing a gaseous medium, in particular hydrogen, with a housing (3), with a compression chamber (30) located in the housing (3), which has at least one circumferential side channel ( 19, 21), with a compressor wheel (2) located in the housing (3), which is arranged rotatably about an axis of rotation (4), the compressor wheel (2) on its circumference in the area of the compressor chamber (30) arranged delivery cells ( 5), and each with a gas inlet opening (14) formed on the housing (3) and a gas outlet opening (16), which are fluidically connected to one another via the compressor chamber (30), in particular the at least one side channel (19, 21) are connected, the housing (3) having a first and a second end face (32, 34) radially to the axis of rotation (4), each facing the compressor wheel (2) and a first and a second f Forms unction-relevant gap dimension (36, 38), characterized in that the compressor wheel (2) is constructed in several parts and has a guide vane wheel (10) and a first delimitation plate (22) and / or a second delimitation plate (24), these in particular at least partially axially to the axis of rotation (4) are arranged next to one another and wherein the guide vane wheel (10) is at least almost completely made of plastic. Side channel compressor (1) according to Claim 1 , characterized in that the guide vane wheel (10) is at least almost completely enclosed and / or surrounded by the first delimitation plate (22) and / or the second delimitation plate (24). Side channel compressor (1) according to Claim 1 , characterized in that the compressor wheel (2) in addition to the delimitation plates (22, 24) has a first intermediate element (13) and / or a second intermediate element (25), wherein in particular the first intermediate element (13) is axially to the axis of rotation (4 ) is located between the first delimitation plate (22) and the guide vane wheel (10) and / or in particular the second intermediate element (25) is located axially to the axis of rotation (4) between the second delimitation plate (24) and the guide vane wheel (10). Side channel compressor (1) according to one of the preceding claims, characterized in that the compressor wheel (2) is connected to a drive shaft (9) by means of a driver ring (12) rotating around the axis of rotation (4), the driver ring (12) ) is connected to the drive shaft (9) with its inner diameter radially to the axis of rotation (4), in particular by means of a press fit, and / or the driver ring (12) in the region of a connection point (28), in particular with a material connection, to the first and / or second delimitation plate (22, 24) is connected. Side channel compressor (1) according to Claim 4 , characterized in that the limiting plates (22, 24) are fixed on the driver ring (12) in such a way that they each apply a pretensioning force axially to the axis of rotation (4) to the guide vane wheel (10) and / or the respective intermediate element (13, 25) exercise. Side channel compressor (1) according to Claim 3 , characterized in that the first delimitation plate (22) and / or the second delimitation plate (24) and / or the first intermediate element (13) and / or the second intermediate element (25) each run at least one at least approximately axially to the axis of rotation (4) Have fixing bore (20) into which at least one fixing pin (18) of the guide vane wheel (10, 12) extends axially to the axis of rotation (4). Side channel compressor (1) according to one of the Claims 1 to 6th , characterized in that the first intermediate element (13) is designed as a first compensating disk (13) and / or the second intermediate element (25) is designed as a second compensating disk (25), the respective compensating disk (13) at least partially made of an elastic material is made. Side channel compressor (1) according to Claim 3 or 6th , characterized in that the respective compensating disc (13, 25) and / or the respective delimitation plate have at least two openings (53a, b) which run at least approximately axially to the axis of rotation (4), whereby by means of the respective opening (53a, b) a fluidic connection of the side channels (19, 21) axially to the axis of rotation (4) through the respective delivery cell (5) in the compressor wheel (2) is established. Side channel compressor (1) according to one of the preceding claims, characterized in that the housing (3) has an upper housing part (7) and a lower housing part (8), the upper housing part (7) having an axis around the axis of rotation (4 ) has circumferential cylindrical collar (23) and the lower housing part (8) has a cylindrical extension (26) surrounding the axis of rotation (4) and that the collar (23) surrounds the extension (26). Side channel compressor (1) according to Claim 9 , characterized in that a compensation gap (43) extending radially to the axis of rotation (4) extends axially to the axis of rotation (4) between the extension (26) of the lower housing part (8) and the upper housing part (7) and / or that a radial to the axis of rotation (4) extending first adjusting washer (29) axially to the axis of rotation (4) between a contact surface (33) of the collar (23) of the upper housing part (7) and a front surface of the Housing lower part (8) is located, wherein in particular by means of the first adjusting washer (29) at least in each case the gap (36, 38) between the compressor wheel (2) and the housing (3) can be set. Side channel compressor (1) according to one of the preceding claims, characterized in that the upper housing part (7) and / or the lower housing part (8) and / or the limiting plates (22, 24) and / or the drive shaft (9) and / or the driver ring (12) are made at least partially from a metallic material, the components having at least approximately the same coefficient of thermal expansion. Side channel compressor (1) according to Claim 11 , characterized in that the metallic material is aluminum and / or steel and / or a metallic alloy. Side channel compressor (1) according to Claim 4 , characterized in that there is a stiffening ring (31) between the guide vane wheel (10), in particular the inside diameter of the guide vane wheel (10), and the driver ring (12), in particular the outside diameter of the driver ring (12), wherein the stiffening ring (31) in the direction of the axis of rotation (4) is in contact with a respective end face (44, 46) of the first and second delimitation plates (22, 24), the stiffening ring (31) running in a ring around the axis of rotation (4) .

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