DE102022118713A1 - Compressor arrangement, turbocharger and internal combustion engine - Google Patents

Abstract

The invention relates to a compressor arrangement (1) with a compressor housing (3), which surrounds a compressor wheel (7) arranged therein, and a diffuser (5), wherein the compressor wheel (7) is rotatably arranged in the compressor housing (3), whereby A wall element (9) can be mounted on the compressor housing (3), which - in the assembled state - closes an opening (11) in the compressor housing (3), a flow guide element (15) being arranged in an inflow area (13) of the diffuser (5). , wherein the flow guide element (15) has a flow guide structure (17) which - on a first side (19) of the inflow area (13) - rests with a contact surface (21) on an inner wall (23) of the compressor housing (3), and / or wherein at least one sealing element (25) is arranged between the flow guide element (15) and the wall element (9).

Description

The invention relates to a compressor arrangement, a turbocharger and an internal combustion engine.

Compressor arrangements, turbochargers and internal combustion engines are known. These typically include a compressor housing with a compressor wheel arranged therein, which in the known turbocharger is connected in a rotationally fixed manner via a shaft to a turbine wheel, the turbine wheel being arranged in a turbine housing. Both the turbine housing and the compressor housing each have a flow inlet and a flow outlet, so that an exhaust gas from the internal combustion engine can flow through the turbine housing, the turbine wheel being set in rotation, and a charging gas can flow through the compressor housing, which is flowed through by rotation of the compressor wheel Energy is supplied and the charging gas is thus compressed.

The compressor formed in this way is therefore part of an inflow path of the internal combustion engine, while the correspondingly designed turbine is arranged in an outflow path of the turbine. As a result, a turbocharger, in particular an exhaust gas turbocharger, is designed in a known manner, which serves to increase a pressure of the charging gas and thus enables optimal, in particular efficient combustion in a combustion chamber of the internal combustion engine.

Flow guide rings are also known for optimizing flows.

The disadvantage of these known compressor arrangements, turbochargers and internal combustion engines is that the flow in the area of the compressor, i.e. in the compressor housing, is not optimal. In particular, turbulence, leakage flows and bypass flows occur here, which cause a loss of energy during compression. The charge gas is therefore compressed to a lesser extent than would be theoretically possible. In addition, this means that the degree of compaction can be calculated less precisely in advance and fluctuations in compaction over time can occur.

In addition, the known arrangements, especially if they include a flow guide ring, are difficult to assemble.

The object of the present invention is to create a compressor arrangement, a turbocharger and an internal combustion engine, whereby the disadvantages mentioned are avoided. In particular, it is the object of the invention to create a compressor arrangement, in particular for a turbocharger, and a corresponding internal combustion engine with such a turbocharger, with the flow in the compressor housing being little disturbed and leaks, backflows, bypass flows, turbulence in the flow path and degrees of compression fluctuating over time are avoided. Furthermore, it is a particular object of the invention to enable safe and simple assembly of the compressor arrangement, the turbocharger and the internal combustion engine.

The object is achieved by providing the present technical teaching, in particular the teaching of the independent claims and the embodiments disclosed in the dependent claims and the description.

The object is achieved in particular by creating a compressor arrangement, in particular for an exhaust gas turbocharger of an internal combustion engine, wherein the compressor arrangement has a compressor housing, which surrounds a compressor wheel arranged therein, and a diffuser, the compressor wheel being rotatably arranged, in particular mounted, in the compressor housing, is, wherein a wall element can be mounted, in particular mounted, on the compressor housing, which - in the assembled state - closes an opening in the compressor housing, with a flow guide element being arranged in an inflow area of the diffuser. The flow guide element has a flow guide structure which - on a first side of the inflow area - rests with a contact surface on an inner wall of the compressor housing, and / or at least one sealing element is arranged between the flow guide element on the one hand and the wall element on the other hand. As a result, the flow in the compressor housing is improved in such a way that a more precise and/or higher compression of a charging gas is made possible and - in the operating state - is created. In particular, this avoids turbulence, leakage flows, backflows and bypass flows in the compressor housing. In addition, assembly of the compressor arrangement, in particular insertion of the flow guide element into the compressor housing and/or assembly of the wall element on the compressor housing, is very simple and safe.

The compressor arrangement preferably has a bearing housing in which a shaft is rotatably mounted. The compressor wheel can be connected to the shaft in a rotationally fixed manner, in particular connected. Alternatively, other means are provided to realize the rotatability of the compressor wheel in the bearing housing. As a result, the compressor wheel can be rotated in the bearing housing and a torque is applied to the compressor wheel, in particular by means of the Wave transferable. The torque is preferably provided by a turbine, in particular in the manner of a turbocharger, and/or a motor, in particular an internal combustion engine and/or an electric motor.

A wall element here is understood to mean, in particular, a compressor rear wall, particularly a compressor disk. The wall element is preferably disc-shaped and/or - in the assembled state - arranged directly behind the compressor wheel, with the shaft passing through a particularly central passage in the compressor rear wall. The wall element thus closes the opening and thus an interior of the compressor housing in which the compressor wheel is arranged, so that on the one hand the compressor wheel is held in position in the compressor housing and on the other hand leakage flows are avoided. In particular, the wall element is arranged between the bearing housing and the compressor housing.

Alternatively or additionally, the wall element is formed at least in some areas by the bearing housing. However, the bearing housing is preferably designed separately from the wall element, which simplifies assembly of the compressor arrangement.

The interior is fluidly connected to the diffuser, so that a medium which flows through the interior and the compressor wheel arranged therein then flows through the diffuser.

The wall element is preferably fastened in at least one radial outer fastening region to the compressor housing by means of a fastening means, in particular a screw. Preferably, several such fastening areas are provided and arranged distributed in the circumferential direction around the axis of rotation. As a result, the wall element is held securely and tightly against the compressor housing.

The opening is preferably formed in the compressor housing, in particular on a side of the compressor housing facing the bearing housing, so that - during assembly - the compressor wheel can be moved into the compressor housing, in particular into the interior. The opening therefore has a diameter that is larger than the diameter of the compressor wheel. Furthermore, the opening is preferably designed concentrically to the axis of rotation of the shaft. This prevents imbalance during operation and makes assembly safe and easy.

A diffuser here is understood to mean in particular a flow path in the compressor housing, in particular downstream of the compressor wheel. The diffuser has a diffuser section, which is preferably designed to be spiral-shaped at least in sections, with a flow cross section of the in particular spiral-shaped diffuser section becoming larger - in the flow direction - at least in sections. Part of the compressor housing is particularly preferably designed as a diffuser, with the diffuser section particularly preferably surrounding the interior and the compressor wheel arranged therein - in the circumferential direction around the axis of rotation - at least in sections, preferably completely.

The inflow area preferably forms - especially in the radial direction - a transition between the interior or the compressor wheel arranged therein on the one hand and the particularly spiral-shaped diffuser section on the other hand. The transition is preferably designed at least in sections as an annular channel, which extends essentially in the radial and circumferential directions. In this case, the inner wall and thus - in the assembled state - also the contact surface of the flow guide element are particularly preferably aligned transversely, in particular perpendicular to the axis of rotation. This creates a fluidic connection to the diffuser section, via which a gas flowing through the compressor wheel can be fed to the diffuser. Furthermore, the overall design is compact and assembly errors - and thus bypass flows - are avoided.

The flow guide element is preferably annular, so that flow guidance - starting from the compressor wheel - is created in several, in particular all, radial directions. In particular, the flow guide element is designed as a compressor guide ring. The flow guiding structure preferably comprises a lamellar structure. This means that the flow can be directed efficiently and turbulence and backflow are avoided.

The lamellar structure preferably has a plurality of flow lamellae in the form of webs, which extend from a particularly annular base body of the flow guide element in the axial direction in the direction of the first side and thus in the direction of the inner wall of the compressor housing and on a base body facing away from the base body. in particular the terminal end face has the contact surface. Due to this flat contact of the contact surface on the inner wall, a good seal is created between the flow guide element and the compressor housing, wherein additional sealing elements and thus potential damage and fatigue of such additional sealing elements as well as associated leaks and backflow are avoided. This avoids maintenance work. In addition, the compressor arrangement, in particular the flow guide element, is therefore easy to assemble.

Particularly preferably, at least two end faces of two of the plurality of flow fins are arranged parallel, in particular plane-parallel. This means that the seal is particularly high and installation is particularly simple and error-free.

The individual webs - in the radial direction - are preferably each aligned at least in sections transversely to the radial direction, so that a flow emanating from the compressor wheel radially outwards is directed transversely to the radial direction, in particular deflected in the circumferential direction around the axis of rotation. Furthermore, the webs preferably have a curved, i.e. curved, course in the radial direction, at least in sections. As a result, energy losses during flow control are low and the resulting compression is very high.

Furthermore, the diameter of the opening is preferably larger than a radial extent, in particular a diameter, of the particularly annular flow guide element, so that the flow guide element - before and/or in a step with the closure of the opening by means of the wall element - simply passes through the opening into the inflow area can be used.

Furthermore, the bearing housing has a flow inlet for a medium to be compressed, in particular charging gas, wherein the flow inlet is preferably arranged concentrically to the central axis on a side of the compressor housing facing away from the bearing housing. The medium to be compressed can be fed to the compressor via this flow inlet, whereby it first flows through the compressor wheel, then flows into the diffuser via the inflow area and then flows out of the compressor arrangement via a flow outlet formed in particular in the bearing housing.

The shaft of the compressor arrangement is preferably designed and set up to transmit torque to the compressor wheel via the shaft. A motor, in particular an electric motor, or a turbine, in particular an exhaust gas turbine, can be used as a torque generator.

Preferably, the sealing element surrounds the flow guide element and/or the wall element in the circumferential direction around and/or concentric to the axis of rotation at least partially, preferably completely. At least the sealing element extends in the circumferential direction over the entire extent of the flow guide element and/or the annular channel. The sealing element is particularly preferably designed as an O-ring. This creates a simple, particularly easy-to-install, and reliable seal.

According to a further development of the invention, it is provided that the flow guide element is fitted into a recess on a second side of the inflow area, with a radially outer, first sealing area and a radially inner, second sealing area being formed. As a result, leakage is avoided on the second side between the flow guide element and the delimiting components, in particular the bearing housing and/or the wall element, with the assembly of the compressor arrangement being simple.

The second side here is understood to mean in particular a side of the inflow area, in particular of the annular channel, which is opposite the first side - in the axial direction. The first side is preferably a side of the inflow area facing away from the bearing housing and the second side is a side of the inflow area facing the bearing housing.

The compressor arrangement preferably has a first sealing element of the at least one sealing element and a second sealing element of the at least one sealing element, the first sealing element being in the first sealing region, i.e. between the flow guide element and the compressor housing, and the second sealing element in the second sealing region, i.e. between the flow guide element and the wall element, is arranged such that the flow guide element is sealed relative to the wall element and the compressor housing.

Overall, a seal is thus created on the first side by in particular metallic and/or flat contact of the flow guide element on the bearing housing and on the second side a seal is created by means of the at least one sealing element, in particular the first sealing element and/or the second sealing element.

Preferably, the flow guide element lies on the second side - radially on the outside - on a first shoulder surface of the compressor, which extends in particular annularly in a circumferential direction housing and - radially inside - on a second shoulder surface of the wall element, which extends in particular annularly in a circumferential direction, so that the first sealing area is formed between the first shoulder surface and the compressor housing and the second sealing area is formed between the second shoulder surface and the wall element. Preferably, the first and/or second sealing region extends in the circumferential direction at least in sections, preferably completely, in particular in a ring shape, around the axis of rotation.

The recess is preferably delimited radially on the outside by the compressor housing and radially on the inside by the wall element. The flow guide element, in particular the base body of the flow guide element, are preferably designed in such a way that - when the flow guide element is arranged in the recess - a wall in the transition region of the flow guide element and diffuser is essentially - in the flow direction - gap-free and / or stepless. Particularly preferably, the base body is arranged in the recess, while only the lamellar structure, in particular the flow lamellae, traverse the inflow area transversely, in particular perpendicularly, to the flow direction. This avoids turbulence and leakage flows and the flow is optimally directed into the diffuser so that compression is high.

Furthermore, the recess is preferably delimited in the axial direction by a rear wall of the wall element.

Particularly preferably, the first sealing region and/or the second sealing region extend parallel to the axis of rotation and/or parallel to the fastening direction of the fastening means for fastening the wall element to the bearing housing. This simplifies the assembly of the compressor arrangement.

According to a further development of the invention, it is provided that a first groove is formed in the first sealing area and/or a second groove is formed in the second sealing area, a first sealing element being arranged in the first groove and/or a second sealing element being arranged in the second groove. This creates a reliable and easy-to-install seal.

The groove forms a depression which extends transversely, in particular perpendicular to the axis of rotation and/or the extent of the first and/or second sealing region, i.e. transversely, in particular perpendicular to the first and/or second shoulder surface. As a result, the sealing element can be at least partially inserted into the groove, so that - when assembling the compressor arrangement - an obstruction caused by the sealing element and/or slipping of the sealing element is avoided. In particular, the compressor arrangement can be assembled with little effort and the sealing is high.

According to a further development of the invention, it is provided that the first groove is formed in a first lateral surface of the flow guide element and/or the second groove is formed in a second lateral surface of the wall element. As a result, the compressor arrangement is well sealed and leaks are avoided. Furthermore, the assembly of the compressor arrangement is simple.

The second lateral surface here is understood to mean in particular the second shoulder surface of the wall element. The first lateral surface here is understood to mean in particular a third shoulder surface, which preferably extends at least in sections, preferably completely, parallel to the second lateral surface. The first lateral surface, i.e. the third shoulder surface, lies flat against the first shoulder surface. The first shoulder surface, i.e. a surface normal of the first shoulder surface, is therefore directed radially inwards. A surface normal of the second and/or third shoulder surface is preferably opposite, in particular directed radially outwards. As a result, the two lateral surfaces are designed as outer peripheral surfaces, which extend in the circumferential direction around the axis of rotation.

According to a further development of the invention, it is provided that in a wall adjacent to the recess, in particular in the rear wall of the wall element, at least one bore is formed in the axial direction, which is penetrated by a fastening means, the flow guide element being passed through the fastening means with a particularly axial Pressure can be applied. As a result, the flow guide element is held axially in position and the compressor arrangement is reliably sealed. In particular, the flow guide element is thereby fixed in the axial direction between the wall element, in particular the rear wall of the wall element, and the bearing housing, in particular the inner wall. This also makes assembly very easy.

The fastening means is preferably designed as a screw and the hole as a threaded hole, with the screw particularly preferably being tightened hand-tight. This avoids high forces and the resulting damage.

Alternatively, other fastening means, in particular clamping and/or positive fastening means, are also possible.

The fastening means and the bore are preferably designed and aligned in such a way that the pressure of the fastening means is exerted transversely, in particular perpendicular to the contact surface of the flow guide element on the bearing housing. As a result, the seal between the flow guide element and the bearing housing, especially on the first side, is particularly high.

According to a further development of the invention it is provided that the fastening means is glued in the screwed-in state. As a result, the fastening means, in particular the screw, is additionally secured and in particular in the direction of rotation of the screw, whereby the screw is held securely in the bore, particularly in the case of a hand-tight screw connection.

According to a further development of the invention, it is provided that the fastening means and/or the bore is aligned perpendicular to the first sealing area and/or second sealing area. This avoids pressure on the first and/or second sealing element arranged in the first and/or second sealing region and damage to the first and/or second sealing element.

According to a further development of the invention, it is provided that on a side of the flow guide element facing away from the flow area, at least one positioning aid receptacle is formed in the flow guide element, into which - in the assembled state - a positioning aid engages for positioning the flow guide element relative to the wall element. This makes it possible to position the flow guide element easily during assembly. In addition, the flow guide element is held in position in the circumferential direction.

The positioning aid receptacle is preferably designed as a hole for receiving the positioning aid. The positioning aid is preferably designed as a pin element. This creates an easy-to-install positioning aid and the assembly of the compressor arrangement is easy to carry out.

The object is also achieved in particular by creating a turbocharger, in particular an exhaust gas turbocharger, with a compressor arrangement according to one of the preceding exemplary embodiments and a turbine arrangement, the turbine arrangement having a turbine housing, the turbine housing encompassing a turbine wheel in the circumferential direction, the turbine wheel over the Shaft is rotationally connected to the compressor wheel. This creates a turbocharger that is easy to install, the sealing of the compressor is particularly good and turbulence, leakage flows, backflows and bypass flows are avoided. Furthermore, this results in the advantages already mentioned above in connection with the compressor arrangement.

The turbine arrangement is in particular designed and set up to supply the turbine wheel via a flow inlet of the turbine housing with a medium to be expanded, in particular hot, high-pressure medium, in particular a gas mixture, especially an exhaust gas from an internal combustion engine, whereby energy is transferred to the turbine wheel and thus is rotationally driven. After flowing through the turbine wheel, the high-pressure medium is expelled from the turbine housing via a flow outlet of the turbine housing.

The turbocharger preferably also has a thermal reflector between the bearing housing and the turbine housing. This prevents cooling of the high-pressure medium and excessive heating of the bearing housing, which means that the efficiency of the turbocharger and the compression of the compressor are high.

The object is achieved in particular by creating an internal combustion engine with a compressor arrangement according to a previous exemplary embodiment and/or a turbocharger according to a previous exemplary embodiment. This results in the advantages already mentioned above in connection with the turbocharger and/or the compressor arrangement. In particular, leaks, backflows and bypass flows are avoided and installation is simple. Furthermore, the compression and performance of the internal combustion engine are high. In addition, the internal combustion engine can be operated efficiently because an amount of energy contained in the exhaust gas can be at least partially traced back to the system.

The descriptions of the compressor arrangement, the turbocharger and the internal combustion engine are to be understood as complementary to one another. In particular, features of the turbocharger and the internal combustion engine that have been described explicitly or implicitly in connection with the compressor arrangement are preferably features of the turbocharger and the internal combustion engine individually or combined with one another.

The internal combustion engine mentioned here is preferably designed as a reciprocating piston engine. It is possible for the internal combustion engine to be set up to drive a passenger car, a truck or a commercial vehicle. In a preferred exemplary embodiment, the internal combustion engine is used to drive particularly heavy land or water vehicles, for example mining vehicles, trains, the internal combustion engine being used in a locomotive or a railcar, or ships. It is also possible to use the internal combustion engine to drive a defense vehicle, such as a tank. An exemplary embodiment of the internal combustion engine is preferably also used in a stationary manner, for example for stationary energy supply in emergency power operation, continuous load operation or peak load operation, in which case the internal combustion engine preferably drives a generator. Stationary use of the internal combustion engine to drive auxiliary units, for example fire pumps on drilling rigs, is also possible. Furthermore, it is possible to use the internal combustion engine in the area of producing fossil raw materials and in particular fuels, for example oil and/or gas. It is also possible to use the internal combustion engine in the industrial sector or in the construction sector, for example in a construction or construction machine, for example in a crane or an excavator. The internal combustion engine is preferably designed as a diesel engine, as a gasoline engine, as a gas engine for operation with natural gas, biogas, special gas or another suitable gas. In particular, if the internal combustion engine is designed as a gas engine, it is suitable for use in a combined heat and power plant for stationary energy generation.

• 1 einen ersten Längsschnitt einer Verdichteranordnung gemäß einem ersten Ausführungsbeispiel,
• 2 einen Ausschnitt aus dem in 1 dargestellten Längsschnitt der Verdichteranordnung in einer vergrößerten Darstellung,
• 3 eine Draufsicht auf eine Verdichteranordnung gemäß des ersten Ausführungsbeispiels,
• 4 eine vergrößerte Darstellung der Verdichteranordnung gemäß dem ersten Ausführungsbeispiel entlang einer zweiten Längsschnittebene, und
• 5 eine Draufsicht auf eine Verdichteranordnung gemäß einem zweiten Ausführungsbeispiel insbesondere in einem Montagezustand.

The invention is explained in more detail below with reference to the drawings. Show:

• 1 a first longitudinal section of a compressor arrangement according to a first exemplary embodiment,
• 2 an excerpt from the in 1 shown longitudinal section of the compressor arrangement in an enlarged view,
• 3 a top view of a compressor arrangement according to the first exemplary embodiment,
• 4 an enlarged view of the compressor arrangement according to the first exemplary embodiment along a second longitudinal sectional plane, and
• 5 a top view of a compressor arrangement according to a second exemplary embodiment, in particular in an assembled state.

1 shows a longitudinal section along a rotation axis A through a compressor arrangement 1 according to a first exemplary embodiment. The compressor arrangement 1 has a compressor housing 3 and a diffuser 5. The compressor housing 3 surrounds a compressor wheel 7 in the circumferential direction around the axis of rotation A. The compressor wheel 7 is rotatably arranged in the compressor housing 3. A wall element 9 can be mounted on the compressor housing 3, in particular mounted, which - in the assembled state - closes an opening 11 in the compressor housing 3. Furthermore, a flow guide element 15 is arranged in an inflow area 13 of the diffuser 5. The flow guide element 15 has a flow guide structure 17, which - on a first side 19 of the inflow area 13 - rests with a contact surface 21 on an inner wall 23 of the compressor housing 3. Alternatively or additionally, at least one sealing element 25 is arranged between the flow guide element 15 and the wall element 9. This creates an easy-to-assemble compressor arrangement 1 overall. In addition, the compressor arrangement 1 is very efficient in operation and the compression of a supplied medium generated by the compressor arrangement 1 is very high. In particular, leakage flows, backflows and bypass flows are avoided in the compressor arrangement 1.

About one - in 1 The flow inlet 27 shown on the left can be fed to an interior 29 in which the compressor wheel 7 is arranged, a medium to be compressed, in particular a gas, especially a charging gas for an internal combustion engine. The medium flows through - during operation of the compressor arrangement 1 - the rotating compressor wheel 7 and thus reaches the inflow area 13 in a radially outer area of the compressor wheel 1 and then into the diffuser 5, which here in particular spirals around the interior 29 and the inflow area 13 in the circumferential direction encompasses the axis of rotation A. The medium to be compressed then comes out of the compressor arrangement 1 via a flow outlet 31 and can therefore then be fed to a combustion chamber of the internal combustion engine 33 in particular. The flow outlet 31 is in 1 facing away from the viewer, so that the viewer is in the in 1 shown first longitudinal section can see through the diffuser 5 shown in the upper half in the flow direction up to the flow outlet 31.

In the 1 The compressor arrangement 1 shown also has a bearing housing 35 to which the wall element 9 is attached. The wall element 9 is designed here in particular as a compressor disk and has a central passage 37, which is passed through by a shaft 39 mounted in the bearing housing 35. The compressor wheel 7 is attached to the shaft 39 in a rotationally fixed manner. Furthermore, the wall element 9 is here in particular arranged directly behind the compressor wheel 7, so that leaks are avoided.

1 also shows a turbocharger 41, which has the compressor arrangement 1 and a turbine arrangement 43 operatively connected to it. In particular, in order to transmit torque, a turbine wheel 45 is connected in a rotationally fixed manner to the compressor wheel 7 via the shaft 39. The turbine wheel 45 is arranged in a turbine housing 47, the turbine housing 47 encompassing the turbine wheel 45 in the circumferential direction about the axis of rotation A.

Furthermore shows 1 in particular also the internal combustion engine 33, which has the turbocharger 41 and thus also the compressor arrangement 1 and is operatively connected to these in such a way that a charge gas flowing through the compressor arrangement 1 can be fed to a combustion chamber of the internal combustion engine 33 and an exhaust gas from the internal combustion engine 33 can be fed to the turbine arrangement 43, in order to flow through this and thereby drive the turbine wheel 45.

2 shows an enlarged view of the compressor arrangement 1 according to in 1 illustrated embodiment. It can be clearly seen how the contact surface 21, which is located in 2 extends essentially perpendicular to the image plane, rests flatly on the inner wall 23 of the compressor housing 3. This creates a reliable seal on the first side 19 of the inflow area 13 and bypass flows that bypass the flow guide structure 17 of the flow guide element 15 are avoided.

Furthermore, in 2 It can be seen that the flow guide element 15 has a base body 49, which is arranged in a recess 51 between the wall element 9 and the compressor housing 3. This recess 51 and thus also the base body 49 extend here preferably in a circle around the axis of rotation A. Starting from the base body 49 of the flow guide element 15 extend - in 2 to the left - several web-shaped flow lamellae 53, which form the flow guide structure 17 and have the contact surfaces 21 at their ends facing away from the base body. The flow fins 53 are preferably aligned at an angle relative to the flow direction, so that the medium, in particular gas, flowing through the inflow area 13 is deflected by the flow fins 53. This allows the medium to be introduced into the diffuser in a controlled manner, with the efficiency and compression of the compressor arrangement 1 being very high.

Due to the arrangement of the flow guide element 15 in the recess 51, a radially outer, first sealing area 57 and a radially inner, second sealing area 59 are formed on a second side 55 of the inflow area 13. A first groove 61 is formed in the first sealing area 57, in which a first sealing element 63 is arranged as a sealing element 25. Furthermore, a second groove 65 is formed in the second sealing region 59, in which a second sealing element 67 is arranged as a sealing element 25. The first sealing element 63 and the second sealing element 67 are preferably designed as an O-ring. This creates a simple and cost-effective seal in the first viewing area 57 and in the second sealing area 59, which can be installed with little effort.

Both sealing elements 25, i.e. the first sealing element 63 and the second sealing element 67, preferably extend in the circumferential direction around the rotation axis A, in particular circularly.

As in 2 can also be seen, the first groove 61 is formed in a first lateral surface 69 of the flow guide element 15. The second groove 65 is correspondingly formed in a second lateral surface 71 of the wall element 9. Both lateral surfaces are aligned radially outwards, with a respective surface normal of the respective lateral surface pointing radially outwards. As a result, the sealing elements 25 can be easily inserted into the grooves from the outside and assembly is simplified.

Furthermore, in a wall of the wall element 9 adjacent to the recess 51 in the axial direction, a bore 73, here in particular a threaded bore, is formed, which is penetrated by a fastening means 75, here in particular a screw. In the assembled state of the compressor arrangement 1, the flow guide element 15 is subjected to a pressure from the fastening means 75, so that the contact surface 21 of the flow guide element 15 is pressed firmly against the inner wall 23. As a result, bypass flows in the area of the contact surface 21 are avoided. In addition, this means that mechanical loads in the first sealing area 57 and in the second sealing area 59 are low, since the pressure of the fastening means acts essentially perpendicular to the sealing surfaces in the first sealing area 57 and second sealing area 59.

The fastening means 75 is preferably glued in the bore 73, so that in particular rotation of the fastening means 75 is prevented. As a result, hand-tightening of the screw is sufficient to hold the fastening means 75 in its position, with the axial forces being low.

The fastening means and the bore 73 are aligned here in particular perpendicular to the first sealing area 57 and the second sealing area 59. As a result, as already mentioned above, the mechanical loads in the first sealing area 57 and in the second sealing area 59 are low.

3 shows the compressor arrangement 1 according to the first exemplary embodiment in a top view. One side of the compressor arrangement 1, which is in 1 the turbine housing 47 faces, here facing the viewer. Thus, in 3 the compressor wheel 7 is largely covered by the wall element 9, so that the compressor wheel 7 is essentially not visible here.

The wall element 9 is fastened to the compressor housing 3 by means of a plurality of fastening elements 77, which are arranged distributed in the circumferential direction around the axis of rotation A. In addition, the fastening means 75 can be seen here, which are also arranged distributed around the axis of rotation A in the circumferential direction.

4 shows - similar to 2 - an enlarged view of the compressor arrangement 1, with the longitudinal section in 4 from the in 2 shown longitudinal section differs. The in 4 The longitudinal section shown is in the circumferential direction to that in 2 shown longitudinal section twisted. Therefore, in 4 the hole 73, through which the fastening means 75 passes, is not shown.

A positioning aid receptacle 79 is formed in the flow guide element 15 and/or in the wall element 9. This positioning aid receptacle 79 is thus arranged on a side of the flow guide element 15 facing away from the inflow area 13. In the exemplary embodiment shown here, the positioning aid receptacle is formed both in the wall element 9 and in the flow guide element 15, with a positioning aid 81, here in particular a positioning pin, engaging in both of the positioning aid receptacles 79. Alternatively, the positioning aid can be firmly connected, in particular integrally formed with the wall element 9 or the flow guide element 15. This makes positioning the flow guide element 15 very easy and precise when assembling the compressor arrangement on the wall element 9. In particular, this prevents slipping and/or rotation of the flow guide element 15 relative to the wall element 9.

5 shows a top view of the compressor arrangement 1 according to that in the 1 until 4 illustrated embodiment. In the illustration chosen here, the wall element 9 is not shown, so that the flow guide element 15 and the compressor wheel 7, in particular a rear side of the compressor wheel 7, are visible. As a result, it can be seen in particular that in the flow guide element 15 on a side facing away from the flow guide structure 17 and the inflow area 13, which in 5 facing the viewer, the positioning aid receptacle 79 is arranged. In particular, it can also be seen that the positioning aid receptacle 79 is arranged offset in the circumferential direction relative to the bore 73, in particular relative to all bores 73. Alternatively or additionally, it is possible for several such positioning aid receptacles 79 to be formed. This makes assembly, in particular positioning, the wall element 9 on the flow guide element 15 easy.

Claims (10)

Compressor arrangement (1) with a compressor housing (3), which surrounds a compressor wheel (7) arranged therein, and a diffuser (5), the compressor wheel (7) being rotatably arranged in the compressor housing (3), wherein on the compressor housing (3 ) a wall element (9) can be mounted, which - in the assembled state - closes an opening (11) of the compressor housing (3), a flow guide element (15) being arranged in an inflow area (13) of the diffuser (5), whereby a) the flow guide element (15) has a flow guide structure (17) which - on a first side (19) of the inflow area (13) - rests with a contact surface (21) on an inner wall (23) of the compressor housing (3), and / or where b) at least one sealing element (25) is arranged between the flow guide element (15) and the wall element (9). Compressor arrangement (1) according to one of the preceding claims, characterized in that on a second side (55) of the inflow area (13), the flow guide element (15) is fitted into a recess (51), with a radially outer, first sealing area (57) and a radially inner, second sealing region (59) are formed. Compressor arrangement (1) according to one of the preceding claims, characterized in that in the first sealing area (57) there is a first groove (61) and/or in the second seal A second groove (65) is formed in the area (59), a first sealing element (63) being arranged in the first groove (61) and/or a second sealing element (67) being arranged in the second groove (65). Compressor arrangement (1) according to one of the preceding claims, characterized in that the first groove (61) in a first lateral surface (69) of the flow guide element (15) and / or the second groove (65) in a second lateral surface (71) of the wall element (9) is formed. Compressor arrangement (1) according to one of the preceding claims, characterized in that in a wall adjacent to the recess (51) in the axial direction at least one bore (73) is formed, which is penetrated by a fastening means (75), the flow guide element ( 15) can be pressurized by the fastening means (75). Compressor arrangement (1) according to one of the preceding claims, characterized in that the fastening means (75) is glued in the screwed-in state. Compressor arrangement (1) according to one of the preceding claims, characterized in that the fastening means (75) and/or the bore (73) is aligned perpendicular to the first sealing region (57) and/or second sealing region (59). Compressor arrangement (1) according to one of the preceding claims, characterized in that on a side of the flow guide element (15) facing away from the inflow area (13), at least one positioning aid receptacle (79) is formed in the flow guide element (15), in which - in the mounted Condition - a positioning aid (81) engages for positioning the flow guide element (15) relative to the wall element (9). Turbocharger (41) with a compressor arrangement (1) according to one of the preceding claims and a turbine arrangement (43), which has a turbine housing (47), the turbine housing (47) encompassing a turbine wheel (45) in the circumferential direction, the turbine wheel (45 ) is connected in a rotationally fixed manner to the compressor wheel (7) via a shaft (39). Internal combustion engine (33) with a compressor arrangement (1) according to one of Claims 1 until 8th and/or a turbocharger (41). Claim 9 .

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