CH720052A2 - Compressor of a turbocharger and turbocharger - Google Patents

Abstract

Compressor of a turbocharger, with a compressor housing (10), with a compressor rotor accommodated in the compressor housing (10), wherein the compressor housing (10) has an insert piece (13) which delimits a flow channel (16) for a medium radially on the outside in the region of the compressor rotor, wherein the compressor housing (10) has a spiral housing section (14) which delimits a flow channel for the compressed medium downstream of the insert piece (13), and wherein the insert piece (13) is connected to the spiral housing section (14) via a plurality of struts (15) which are inclined with respect to an axial direction and a radial direction of the compressor housing (10).

Description

[0001] The invention relates to a compressor of a turbocharger and a turbocharger.

[0002] A turbocharger has a turbine for expanding a first medium, in particular for expanding exhaust gas, and a compressor for compressing a second medium, in particular charge air, using the energy gained during the expansion of the first medium in the turbine. The turbine has a turbine housing and a turbine rotor. The compressor has a compressor housing and a compressor rotor. The turbine rotor and compressor rotor are coupled via a shaft which is mounted in a bearing housing, the bearing housing being connected on the one hand to the turbine housing and on the other hand to the compressor housing.

[0003] DE 10 2017 106 360 A1 discloses the basic structure of a turbocharger. In particular, it is disclosed there that the compressor housing of the compressor of the turbocharger has an insert piece and a spiral housing section. The insert piece delimits a flow channel for the medium in the area of the compressor wheel radially on the outside, adjacent to the compressor rotor, wherein, viewed in the flow direction of the medium, the spiral housing section adjoins downstream of the insert piece, which delimits a flow channel for the medium to be compressed.

[0004] According to DE 10 2017 106 360 A1, both the insert piece and the spiral housing section have a collar or flange running around the circumference, via which the insert piece and the spiral housing section are connected to one another via a screw connection.

[0005] During operation, the compressor rotor may burst as a result of high loads on the compressor rotor. In this case, fragments or pieces of the compressor rotor can penetrate the compressor housing. This represents a significant risk potential for operating personnel. Furthermore, fragments or pieces that penetrate the compressor housing can damage technical equipment located in the vicinity of the turbocharger. There is therefore a need for a compressor of a turbocharger in which the risk of fragments or pieces of the compressor rotor penetrating the compressor housing in the event of a bursting of the compressor rotor is reduced.

[0006] Based on this, the present invention is based on the object of creating a novel compressor of a turbocharger and a turbocharger with such a compressor.

[0007] This object is achieved by a compressor of a turbocharger according to claim 1 and by a turbocharger according to claim 9.

[0008] According to the invention, the insert piece of the compressor housing is connected to the spiral housing section of the compressor housing via a plurality of struts which are inclined relative to an axial direction of the compressor housing and a radial direction of the compressor housing. The struts which are inclined in the axial direction of the compressor housing and in the radial direction of the compressor housing and via which the insert piece is connected to the spiral housing section can provide a defined energy absorption in the event of a bursting of the compressor rotor and when, in the event of a bursting of the compressor rotor, fragments of the compressor rotor strike the insert piece. The risk of fragments of the compressor rotor penetrating the compressor housing can thus be significantly reduced. Fragments of the compressor rotor can be safely captured by the compressor housing.

[0009] Preferably, the insert piece is connected to the spiral casing section via at least three struts, preferably via five, six or seven struts, wherein the struts form an angle of between 40° and 80°, preferably between 60° and 70°, with the axial direction of the compressor casing, and wherein the struts form an angle of between 35° and 75°, preferably between 55° and 65°, with the radial direction of the compressor casing. Such a combination of the number of struts and their orientation allows particularly advantageous energy absorption in the event of the compressor rotor bursting. Fragments of the compressor rotor can be safely captured. The risk of fragments of the compressor rotor penetrating the compressor casing can be reduced.

[0010] Preferably, the struts are all inclined in the same orientation and in particular at the same angle to the radial direction, such that, viewed in the direction of flow through the spiral casing section, radially inner ends of the struts are arranged in front of or upstream of radially outer ends of the struts. Furthermore, preferably, the struts are all inclined in the same orientation and in particular at the same angle to the axial direction, such that, viewed in the direction of flow through the insert piece, radially outer ends of the struts are arranged in front of or upstream of radially inner ends of the struts. This also allows particularly advantageous energy absorption in the event of the compressor rotor bursting. The risk of the fragments or pieces of the compressor rotor penetrating the compressor casing can be reduced.

[0011] Preferably, the struts have a circular or oval or elliptical cross-section, with the cross-section of the struts widening from the radially inside to the radially outside. This shape of the struts is preferred in order to ensure optimal energy absorption for fragments of the compressor rotor that strike the insert piece in the event of a bursting of the compressor rotor.

[0012] Preferred developments of the invention emerge from the dependent claims and the following description. Exemplary embodiments of the invention are explained in more detail with reference to the drawing, without being limited thereto. In the drawing: Fig. 1: a cross section in the radial direction through a compressor housing of a compressor according to the invention of a turbocharger; and Fig. 2 a cross section in the axial direction through a compressor housing of a compressor according to the invention of a turbocharger.

[0013] A turbocharger has a turbine for expanding a first medium, in particular for expanding exhaust gas from an internal combustion engine. A turbocharger also has a compressor for compressing a second medium, in particular charge air, using energy gained in the turbine when expanding the first medium. The turbine has a turbine housing and a turbine rotor. The compressor has a compressor housing and a compressor rotor. The compressor rotor is coupled to the turbine rotor via a shaft that is mounted in a bearing housing, the bearing housing being positioned between the turbine housing and the compressor housing and being connected to both the turbine housing and the compressor housing. This basic structure of a turbocharger is familiar to the person skilled in the art addressed here.

[0014] The present invention relates to details of the compressor of the turbocharger, namely details of the compressor housing of the compressor. Fig. 1 and 2 show different cross sections through a compressor housing 10 of a compressor of a turbocharger, namely Fig. 1 a cross section in the radial direction R and Fig. 2 a cross section in the axial direction A. Fig. 2 uses arrows 11, 12 to illustrate the flow direction of a medium to be compressed in the compressor.

[0015] The compressor housing 10 has an insert piece 13 which radially outwardly encloses the compressor rotor (not shown in Fig. 1 and 2) of the compressor at least in sections and radially outwardly adjacent to the compressor rotor (not shown) delimits a flow channel 16 for the medium in the area of the compressor rotor. The compressor rotor (not shown) is flowed against in the axial direction A by the medium to be compressed according to the arrow 11 in Fig. 2.

[0016] The compressor housing 10 also has a spiral housing section 14. The spiral housing section 14 delimits a flow channel 17 for the medium compressed in the compressor downstream of the insert piece 13, wherein according to the arrows 12 in Fig. 2, medium which was compressed in the area of the compressor wheel (not shown) flows away from the compressor wheel in the radial direction and enters the spiral housing section 14. The spiral housing section 14 or the flow channel 17 thereof is flowed through in the circumferential direction according to the arrows 18 in Fig. 1.

[0017] In the embodiment shown, the insert piece 13 and the spiral housing section 14 are integral and therefore designed as a monolithic assembly. It is also possible for the insert piece 13 and the spiral housing 14 to be designed as separate assemblies.

[0018] In order to prevent the compressor housing 10 from being penetrated by the fragments or pieces of the compressor rotor (not shown) if the compressor rotor should break due to high loads and fragments or pieces of the same should strike the insert piece 13, the insert piece 13 is connected to the spiral housing 14 via a plurality of struts 15, the struts 15 being inclined relative to the axial direction A and the radial direction R of the compressor housing 10. According to Fig. 1, the struts 15 form an angle β with the radial direction R of the compressor housing 10 and an angle α with the axial direction A.

[0019] Such struts 15, which are inclined in the axial direction A and in the radial direction R, can be used to optimally absorb the kinetic energy of fragments of a compressor rotor which, in the event of the rotor bursting, strike the insert piece 13. The fragments of the compressor wheel are then caught and it is prevented that they penetrate the compressor housing 10 and enter the environment.

[0020] Preferably, the insert piece 13 is connected to the spiral housing section 14 of the compressor housing 10 via at least three struts 15, in particular via five, six or seven struts 15. In the embodiment shown, the insert piece 13 and the spiral housing section 14 of the compressor housing 10 are connected to one another via five struts 15, which are each inclined in the same orientation and at the same angle with respect to the axial direction A and the radial direction R of the compressor housing 10.

[0021] The orientation of the struts 15 inclined with respect to the axial direction A and radial direction R is in each case such that the struts 15 are all inclined in the same orientation to the radial direction R, such that, as seen in the flow direction of the spiral housing section 14, radially inner ends of the struts 15 are arranged in front of or upstream of the radially outer ends of the struts 15, and/or that the struts 15 are all inclined in the same orientation to the axial direction A, such that, as seen in the flow direction of the insert piece 13, radially outer ends of the struts 15 are arranged in front of or upstream of the radially inner ends of the struts 15.

[0022] The struts 15 enclose the angle α between 40° and 80°, preferably between 60° and 70°, with the axial direction A of the compressor housing 10. The struts 15 enclose the angle β between 35° and 75°, preferably between 55° and 65°, with the radial direction R of the compressor housing 10.

[0023] The struts 15 are preferably circular or oval or elliptical in cross-section and are solid, i.e. made of solid material. It is preferably provided that the cross-section of the struts 15 widens from radially inside to radially outside, i.e. starting from the insert piece 13 in the direction of the spiral housing section 14.

[0024] The number of struts 15 described above and/or the arrangement or orientation of the struts 15 and/or the shape of the struts 15 can prevent both a displacement of the insert piece 13 in the axial direction and a rotation of the same in the circumferential direction in response to a bursting of the compressor rotor and the impact of fragments or pieces of the same on the insert piece 13. The above design of the struts 15 allows the kinetic energy of fragments or pieces of the compressor rotor to be optimally absorbed in the event of a bursting of the same. There is no risk of fragments or pieces of a bursting compressor rotor penetrating the compressor housing 10.

[0025] If, as in the embodiment shown, the insert piece 13 and the spiral housing section 14 are designed as one piece and therefore as a monolithic assembly, the struts 15 are also part of this monolithic assembly. If the insert piece 13 and the spiral housing section 14 are designed as separate assemblies, the struts 15 are an integral part of the insert piece 13 and are connected or clamped to the spiral housing section 14.

List of reference symbols

[0026] 10 Compressor housing 11 Arrow / flow direction 12 Arrow / flow direction 13 Insert 14 Spiral casing section 15 Strut 16 Flow channel 17 Flow channel 18 Arrow / flow direction A Axial direction R Radial direction α angle β angle

Claims (9)

1. Compressor of a turbocharger, with a compressor housing (10), with a compressor rotor accommodated in the compressor housing (10), wherein the compressor housing (10) has an insert piece (13) which delimits a flow channel (16) for a medium radially on the outside in the area of the compressor rotor, wherein the compressor housing (10) has a spiral housing section (14) which delimits a flow channel (17) for the compressed medium downstream of the insert piece (13), characterized in that the insert piece (13) is connected to the spiral housing section (14) via a plurality of struts (15) which are inclined with respect to an axial direction (A) and a radial direction (R) of the compressor housing (10). 2. Compressor according to claim 1, characterized in that the insert piece (13) is connected to the spiral casing section (14) via at least three struts (15), preferably via five, six or seven struts (15). 3. Compressor according to claim 1 or 2, characterized in that the struts (15) enclose an angle (a) between 40° and 80°, preferably between 60° and 70°, with the axial direction (A) of the compressor housing (10). 4. Compressor according to one of claims 1 to 3, characterized in that the struts (15) enclose an angle (β) between 35° and 75°, preferably between 55° and 65°, with the radial direction (R) of the compressor housing (10). 5. Compressor according to one of claims 1 to 4, characterized in that the struts (15) are all inclined in the same orientation to the radial direction, such that, viewed in the flow direction of the spiral casing section (14), radially inner ends of the struts (15) are arranged in front of or upstream of radially outer ends of the struts (15). 6. Compressor according to one of claims 1 to 5, characterized in that the struts (15) are all inclined in the same orientation to the axial direction, such that, viewed in the flow direction of the insert piece (13), radially outer ends of the struts (15) are arranged in front of or upstream of radially inner ends of the struts (15). 7. Compressor according to one of claims 1 to 6, characterized in that the struts (15) have a circular or oval or elliptical contour in cross section. 8. Compressor according to claim 7, characterized in that the cross section of the struts (15) widens from radially inside to radially outside. 9. Turbocharger, with a turbine for expanding a first medium, with a compressor for compressing a second medium using energy gained in the turbine during the expansion of the first medium, characterized in that the compressor is designed according to one of claims 1 to 8.