CH720036A2 - Turbine of a turbocharger and turbocharger - Google Patents

Abstract

Turbine (10) of a turbocharger, with a turbine housing (11), with a turbine rotor (12) arranged in the turbine housing (11), wherein the turbine housing (11) has an inflow housing (15) which can be connected to a bearing housing (14) of the turbocharger and via which a medium to be relaxed can be fed to the turbine rotor (12), wherein the turbine housing (11) has an outflow housing (17) via which relaxed medium can be discharged from the turbine rotor (12), wherein the turbine housing (11) has a cover (18) which can be clamped radially on the outside between the inflow housing (15) and the bearing housing (14), wherein the turbine housing (11) has an insert piece (20) which delimits a flow channel for the medium radially on the outside in the region of the turbine rotor (12) upstream of the outflow housing (17), and wherein the turbine housing (11) has a bladed Nozzle ring (19) which, upstream of the insert piece (20), on a side opposite the cover (18), delimits a flow channel for the medium to be expanded, wherein guide vanes (22) of the nozzle ring (19) are pressed against the cover (18).

Description

[0001] The invention relates to a turbine 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 from expanding 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 that is mounted in a bearing housing, the bearing housing being connected to the turbine housing on the one hand and to the compressor housing on the other. This basic structure of a turbocharger is known from DE 10 2017 106 360 A1. Medium to be expanded in the turbine can be guided towards the turbine rotor via an inflow housing of the turbine housing. Medium expanded in the turbine can be discharged from the turbine rotor via the outflow housing of the turbine housing.

[0003] During operation, the turbine rotor may burst as a result of high loads on the turbine rotor. In this case, fragments or pieces of the turbine rotor can penetrate the turbine housing. This represents a significant risk potential for operating personnel. Furthermore, fragments or pieces that penetrate the turbine housing can damage equipment located in the vicinity of the turbocharger. There is therefore a need for a turbine of a turbocharger in which the risk of fragments or pieces of the turbine rotor penetrating the turbine housing in the event of a bursting of the turbine rotor is reduced.

[0004] Based on this, the present invention is based on the object of creating a novel turbine of a turbocharger and a turbocharger with such a turbine.

[0005] This object is achieved by a turbine of a turbocharger according to claim 1. According to the invention, the turbine housing has a cover, an insert and a bladed nozzle ring, wherein the cover can be clamped radially on the outside between the inflow housing and the bearing housing, wherein the insert delimits a flow channel for the medium radially on the outside in the area of the turbine rotor upstream of the outflow housing, and wherein the bladed nozzle ring delimits a flow channel for the medium to be expanded upstream of the insert on a side opposite the cover, wherein guide vanes of the nozzle ring are pressed against the cover. The interaction of the cover, insert and bladed nozzle ring can increase the so-called containment safety of a turbine of a turbocharger. The risk that in the event of a bursting of the turbine rotor, fragments or pieces of the same will penetrate the turbine housing can be reduced with the invention. It is particularly important that the bladed nozzle ring is arranged opposite the cover and is pressed against the cover with its guide vanes. If the turbine rotor bursts, pieces or fragments can be caught between the cover and the nozzle ring.

[0006] Preferably, a base of the nozzle ring has an axial width or thickness that corresponds to 0.2 to 0.7 times a maximum outer radius of the turbine rotor and/or a radial width or thickness that corresponds to 0.3 to 0.8 times the maximum outer radius of the turbine rotor. These dimensions of the base of the nozzle ring are particularly advantageous for increasing the containment safety of the turbine.

[0007] Preferably, the axial height of the nozzle ring guide vanes corresponds to 0.1 to 0.2 times the maximum outer radius of the turbine rotor. This dimension of the nozzle ring guide vanes is also particularly advantageous for increasing the containment safety of the turbine, preferably in combination with the above dimensions of the nozzle ring base.

[0008] Preferably, a minimum axial width or thickness of the cover corresponds to 0.15 times to 0.4 times the maximum outer radius of the turbine rotor. This can also increase the containment safety of the turbine, preferably in combination with the above dimensions of the base of the nozzle ring and the height of the nozzle ring guide vanes.

[0009] Preferably, the insert piece has a minimum width or thickness over its entire contour, which corresponds to 0.07 times to 0.6 times a maximum outer radius of the turbine rotor. This can also further increase the containment safety of the turbine, in particular in combination with the above dimensions of the base and the guide vanes of the nozzle ring and the axial width or thickness of the cover.

[0010] Preferably, a radially inner section of the cover is convexly curved on a side facing the turbine rotor in such a way that if the turbine rotor bursts, pieces or fragments thereof hit the insert piece in the radial direction and axial direction. This ensures that if the turbine rotor bursts, pieces or fragments do not reach the area between the cover and the nozzle ring directly, but first hit the insert piece and kinetic energy can be dissipated here. This can also increase the containment safety of the turbine.

[0011] The turbocharger according to the invention is defined in claim 10.

[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. Therein: Fig. 1: a cross section through a turbine of a turbocharger according to the invention; and Fig. 2 is a perspective view of Fig. 1.

[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 a turbine of a turbocharger. Fig. 1 and 2 each show cross sections through a turbine 10 of a turbocharger in the region of a turbine housing 11 and a turbine rotor 12 which is arranged or accommodated in the turbine housing 11. Fig. 1 also shows a shaft 13 via which the turbine rotor 12 of the turbine 10 is coupled to a compressor rotor (not shown) of a compressor of the turbocharger. The shaft 13 is mounted in a bearing housing 14.

[0015] The turbine housing 11 has an inflow housing 15, which is connected to the bearing housing 14 via a screw connection 16, wherein medium to be expanded in the turbine can be fed to the turbine rotor 12 via the inflow housing 15. The turbine housing 11 also has an outflow housing 17, via which medium expanded in the turbine 10 can be discharged from the turbine rotor 12.

[0016] In addition to the inflow housing 15 and the outflow housing 17, the turbine housing 11 also has a cover 18, a nozzle ring 19 and an insert piece 20.

[0017] The cover 18 closes the turbine housing 11 adjacent to the bearing housing 14, wherein in the assembled state a radially outer portion 18c of the cover 18 is clamped between the inflow housing 15 and the bearing housing 14.

[0018] The cover 18, together with the nozzle ring 19, which is opposite the cover 18, delimits a flow channel 21 for the medium to be expanded in the region of the turbine rotor 12, wherein this flow channel 21 extends in the radial direction R of the turbine rotor 12 and guides the medium to be expanded, starting from the inflow housing 15, in the direction of the turbine rotor 12.

[0019] The nozzle ring 19 is a nozzle ring 19 provided with guide vanes 22, wherein the guide vanes 22 of the nozzle ring 19 are pressed against the cover 18. The guide vanes 22 extend in the axial direction A of the turbine rotor 12. A base 23 of the nozzle ring 19, on which the guide vanes 22 of the nozzle ring 19 are formed in one piece, together with the cover 18, on a side opposite the cover 18, delimits the flow channel 21 for the medium to be expanded, via which the medium to be expanded can be fed to the turbine rotor 12 from the inflow housing 15.

[0020] The insert piece 20 is arranged downstream of the nozzle ring 19 as seen in the flow direction S of the medium, the insert piece 20 radially outwardly in the flow direction S of the medium upstream of the outflow housing 17 and downstream of the nozzle ring 19 delimiting a flow channel for the medium in the region of the turbine rotor 12, which at its downstream end merges into the outflow housing 17 and at its upstream end into the flow channel 21. The insert piece 20 is connected at its downstream end to the outflow housing 17 via a screw connection 24.

[0021] It is therefore within the meaning of the invention that the radially outer section 18c of the cover 18 is clamped between the bearing housing 14 and the inflow housing 15, and that the nozzle ring 19 is arranged opposite the cover 18 and is pressed against the cover 18 with its guide vanes 22. This structural design of the turbine 10, namely the turbine housing 11 of the turbine 10, can increase the containment safety of the turbine 10. The risk that, in the event of the turbine rotor 12 bursting, pieces or fragments of the turbine rotor will enter the environment can be reduced.

[0022] Preferably, the nozzle ring 19, namely its base 23, is designed such that the base 23 of the nozzle ring 19 has an axial width X1 which corresponds to 0.2 times to 0.7 times a maximum outer radius r of the turbine rotor 12. Preferably, the base 23 of the nozzle ring 19 is further designed such that a radial width X2 of the base 23 of the nozzle ring 19 corresponds to 0.3 times to 0.8 times the maximum outer radius r of the turbine rotor 12. An axial height X3 of the guide vanes 22 of the nozzle ring 19 and thus the axial dimension of the flow channel 21 formed between the cover 18 and the base 23 of the nozzle ring 19 preferably corresponds to 0.1 to 0.2 times the maximum outer radius r of the turbine rotor 12.

[0023] The above dimensions of the nozzle ring 19, namely the dimensions X1 and X2 of the base 23 and the dimension X3 of the guide vanes 22 thereof, are particularly preferred for increasing the containment safety.

[0024] The containment safety of the turbine 10 can be further increased if the cover 18 has a minimum width X4 which corresponds to 0.15 times to 0.4 times the maximum outer radius r of the turbine rotor 12.

[0025] The minimum thickness X5 of the insert piece 20, viewed over its entire contour, is preferably 0.07 times to 0.6 times the maximum outer radius r of the turbine rotor 12. This can also increase the containment safety.

[0026] In the embodiment shown, the cover 18 is formed in two parts, namely from a radially inner cover part 18a and a radially outer cover part 18b. The section 18c, with which the cover 18 is clamped radially outward between the bearing housing 14 and the inflow housing 15, is formed on the radially outer cover part 18b of the cover 18.

[0027] It is also possible that the cover 18 is formed in one piece.

[0028] A radially inner section of the cover 18, in the embodiment shown the radially inner cover part 18a, is convexly contoured on a side facing the turbine rotor 12 and curved outwards in the direction of the turbine rotor 12 in such a way that in the event of a bursting of the turbine rotor 12, fragments or pieces thereof strike the insert piece 20 in the radial direction and in the axial direction in order to dissipate kinetic energy in the region of the insert piece 20 before the fragments can enter the flow channel 21.

[0029] The turbine 10 according to the invention has a high level of containment safety. The risk that fragments of the turbine rotor 12 will enter the environment if it bursts is reduced.

List of reference symbols

[0030] 10 Turbine 11 Turbine housing 12 Turbine rotor 13 Shaft 14 Bearing housing 15 Inflow housing 16 Screw connection 17 Outflow housing 18 Cover 18a Cover part 18b Cover part 18c Section 19 Nozzle ring 20 Insert piece 21 Flow channel 22 Guide vane 23 Base 24 Screw connection A Axial direction R Radial direction S Flow direction X1 Width/thickness X2 Width/thickness X3 Height X4 Width/thickness X5 Width/thickness r Outer radius

Claims (10)

1. Turbine (10) of a turbocharger, with a turbine housing (11), with a turbine rotor (12) arranged in the turbine housing (11), wherein the turbine housing (11) has an inflow housing (15) that can be connected to a bearing housing (14) of the turbocharger, via which a medium to be relaxed can be fed to the turbine rotor (12), wherein the turbine housing (11) has an outflow housing (17) via which relaxed medium can be discharged from the turbine rotor (12), characterized in that the turbine housing (11) has a cover (18) that can be clamped radially on the outside between the inflow housing (15) and the bearing housing (14), the turbine housing (11) has an insert (20) that forms a flow channel for the medium radially on the outside in the area of the turbine rotor (12) upstream of the outflow housing (17). limited, the turbine housing (11) has a bladed nozzle ring (19) which, upstream of the insert piece (20), on a side opposite the cover (18), delimits a flow channel for the medium to be expanded, wherein guide vanes (22) of the nozzle ring (19) are pressed against the cover (18). 2. Turbine according to claim 1, characterized in that a base (23) of the nozzle ring (19) has an axial width or thickness (X1) which corresponds to 0.2 times to 0.7 times a maximum outer radius (r) of the turbine rotor (12). 3. Turbine according to claim 1 or 2, characterized in that a base (23) of the nozzle ring (19) has a radial width or thickness (X2) which corresponds to 0.3 times to 0.8 times a maximum outer radius (r) of the turbine rotor (12). 4. Turbine according to one of claims 1 to 3, characterized in that the axial height (X3) of the guide vanes (22) of the nozzle ring (19) corresponds to 0.1 times to 0.2 times a maximum outer radius (r) of the turbine rotor (12) 5. Turbine according to one of claims 1 to 4, characterized in that the cover (18) has a minimum axial width or thickness (X4) which corresponds to 0.15 times to 0.4 times a maximum outer radius (r) of the turbine rotor (12) 6. Turbine according to one of claims 1 to 4, characterized in that the cover (18) is formed in one piece. 7. Turbine according to one of claims 1 to 4, characterized in that the cover (18) is designed in several parts. 8. Turbine according to one of claims 1 to 7, characterized in that a radially inner section (18b) of the cover (18) is convexly curved on a side facing the turbine rotor (12) in such a way that in the event of a bursting of the turbine rotor (12), fragments or pieces thereof strike the insert piece (20) in the radial direction and axial direction. 9. Turbine according to one of claims 1 to 8, characterized in that the insert piece (20) has, over its entire contour, a minimum width or thickness (X5) which corresponds to 0.07 times to 0.6 times a maximum outer radius (r) of the turbine rotor (12). 10. Turbocharger, with a turbine (10) for expanding a first medium, with a compressor for compressing a second medium using energy gained in the turbine (10) during the expansion of the first medium, with a bearing housing (14) which is arranged between the turbine (10) and the compressor, characterized in that the turbine (10) is designed according to one of claims 1 to 9.