CH713634B1 - Compressor for a turbocharger. - Google Patents

Abstract

The invention relates to a compressor for a turbocharger, comprising at least the following: a compressor housing (10) with an air inlet for receiving air to be compressed in the compressor and with an air outlet for discharging air compressed in the compressor, a drive shaft extending in the axial direction which is rotatably mounted in the compressor housing (10) and can be driven in rotation via a drive acting on it, a compressor impeller (40) which is arranged in the compressor housing (10) in relation to an air flow path between the air inlet and the air outlet and on the drive shaft, a radially extending diffuser passage (14) in the compressor housing (10), which has a first radial wall (22) and a second radial wall (24), a compressor spiral (15) which is as an air passage in the air flow path over the diffuser passage (14) connects to the compressor impeller (40) and opens into the air outlet, a separate one vane-less guide device, which is arranged in the radial diffuser passage (14) and attached to the first radial wall (22) of the diffuser passage (14), with between the separate vane-less guide device and a second radial wall (24) of the diffuser passage (14) axially opposite it ) there is an axial clearance (a). The separate vane-less guide device is designed as an annular disk (60) which, in the area of its radially inner diameter, comprises a first pipe section (32) which is coaxial with the drive shaft and points away from the second radial wall (24) of the diffuser passage (14) and which has a specific axial extension (b), a radially inner circumferential surface of the first pipe section (32) lies radially opposite a section (13) of the compressor housing (10) and the axial clearance (a) is smaller than the axial extension (b) of the first pipe section (32).

Description

State of the art

The invention is based on a compressor for a turbocharger according to claim 1.

Radial compressors as described, for example, in WO 2014/012725 A1, usually have an inlet channel through which the fluid flows in, an impeller which is used to drive or compress the fluid, and an outlet channel through which the compressed fluid flows Centrifugal compressor leaves again. In radial compressors, a so-called guide device is located in the outlet channel, i.e. behind the compressor impeller in the direction of flow, which is formed by a diffuser passage, often by means of a simple parallel-walled flow channel. It is used to delay the flow behind the impeller and thus to build up pressure by converting kinetic energy into potential energy before it is further decelerated and rectified in an annular channel (compressor spiral). In some cases fixed, usually profiled guide vanes are built into this diffuser passage, which serve to change the characteristic curve of the compressor. In these cases, one often speaks of a bladed diffuser or guide device. These guide vanes are usually a component together with a diffuser wall and press with their blunt end against the opposite housing wall. The fluidically disadvantageous gaps, which lead to so-called gap losses, between the guide vane and the housing can be reduced in this way. Radial compressors are also known in the prior art in which these guide vanes are rotatably adjustable or rotatable for the purpose of controlling or regulating the compressor.

In addition, compressors with so-called vane-less guide vanes are also known from the prior art, i.e. with guide apparatuses without guide vanes, in which the guide apparatus is inserted as a separate body into the diffuser passage behind the compressor impeller. Vane-less guide vanes have the disadvantage that they cannot be jammed in the housing using guide vanes, and therefore connecting elements such as screws are used to fasten such a vane-less guide vane to the housing. If the connecting elements fail, however, it is possible that the vane-less guide device comes into contact with the compressor impeller and thus causes serious damage to the compressor.

[0004] The present invention is therefore based on the object of developing a compressor with a vane-less guide device in such a way that it has a higher level of functional reliability. Furthermore, a turbocharger with such a compressor should also be made available.

According to the invention, this object is achieved by the features of claim 1 and claim 9. Advantageous further developments of the invention are the subject matter of the attached dependent claims.

Disclosure of the invention

The invention relates to a compressor for a turbocharger, including at least the following: A compressor housing with an air inlet for receiving air to be compressed in the compressor and with an air outlet for discharging air compressed in the compressor, a drive shaft extending in the axial direction which is rotatably mounted in the compressor housing and is rotatably drivable via a drive acting on it, a compressor impeller which is arranged in the compressor housing in relation to an air flow path between the air inlet and the air outlet and on the drive shaft, a radially extending diffuser passage in the compressor housing, which has a first radial wall and a second radial wall, a compressor spiral which connects to the compressor impeller as an air passage in the air flow path via the diffuser passage and opens into the air outlet, a separate vane-less guide device, which in d he radial diffuser passage is arranged and attached to the first radial wall of the diffuser passage, an axial clearance being present between the separate vane-less guide device and a second radial wall of the diffuser passage axially opposite it.

According to the invention it is provided that the separate vane-less Nachleitapparat is designed as an annular disk, which in the region of its radially inner diameter comprises a coaxial with the drive shaft and pointing away from the second radial wall of the diffuser passage first pipe section which has a certain axial extent comprises, wherein a radially inner circumferential surface of the first pipe section lies radially opposite a section of the compressor housing and wherein the axial clear width is smaller than the axial extent of the first pipe section. The first pipe section encloses in particular the drive shaft and the compressor impeller.

Because a radially inner circumferential surface of the first pipe section lies radially opposite a section of the compressor housing and also the axial clearance between the separate vane-less Nachleitapparat and this axially opposite second radial wall of the diffuser passage is smaller than the axial extent of the first pipe section, is ensured that in the event of an unintentional detachment of the separate vane-less guide apparatus from the first radial wall of the diffuser passage, the separate vane-less guide apparatus cannot come into contact with the compressor wheel. Because then the first pipe section of the separate vane-less guide device strikes against the radially opposite section of the compressor housing or against the second radial wall of the diffuser passage, but the remaining axial clearance in the diffuser passage is too narrow for axial and / or radial movement of the separate vane-less guide device which could bring it into contact with in the direction of the compressor wheel.

Therefore, according to the invention, a geometry of the separate vane-less Nachleitapparats is created by the axial extension of the first pipe section, which viewed in the axial direction in relation to the clear width of the diffuser passage is too large to allow an axial and / or radial movement of the separate To allow vane-less Nachleitapparats, which is sufficient to contact the compressor wheel if its connection to the compressor housing has accidentally loosened. The invention thus solves the problem described at the outset that failure of the connection between the separate vane-less guide device and the compressor housing can damage the compressor. Overall, this increases the functional reliability of the compressor.

The measures listed in the dependent claims allow advantageous developments and improvements of the invention specified in the independent claims.

The first radial wall of the diffuser passage particularly preferably forms part of the compressor spiral.

According to a development, the annular disc has a second, deviating from the first pipe section, second pipe section which is coaxial with the drive shaft, faces away from the second radial wall of the diffuser passage and which centers the annular disc on a step of the compressor spiral. In particular, the second pipe section can be centered on a radially inner step of the second radial wall of the diffuser passage. In particular, the second pipe section can have a larger inside diameter than the first pipe section.

At least the first pipe section can be formed in one piece with the annular disc, the second pipe section also being formed, for example, in one piece with the pipe disc.

According to a particularly preferred embodiment, a radially inner diameter of the first pipe section lies radially opposite an insert piece which is inserted into the compressor housing on the air inlet side and radially surrounds the compressor impeller. This insert then forms part of the compressor housing, for example.

In particular, connecting elements such as screws can be provided, by means of which the vane-less guide device or the annular disk is releasably attached to the first radial wall of the diffuser passage.

According to a preferred development, the axial clear width between the separate vane-less guide device or the annular disc and the axially opposite second radial wall of the diffuser passage can be at least largely constant with respect to the radial extent.

The invention also relates to a turbocharger, in particular an exhaust gas turbocharger with a compressor as described above.

The turbocharger is preferably characterized by a turbine which has a turbine housing and a turbine impeller which forms the drive for the drive shaft and which is arranged in the turbine housing on the drive shaft. The turbine housing is preferably connected to the compressor housing.

drawing

The invention is described in more detail below using an exemplary embodiment with reference to the accompanying drawings. 1 shows a sectional view of a turbocharger with a compressor according to a preferred embodiment of the invention; FIG. 2 shows an enlarged section from the compressor from FIG. 1.

Description of the embodiment

As shown inFig.1, a turbocharger has a turbine 2 driven here, for example, by exhaust gas from an internal combustion engine, and a compressor 1 driven by the turbine 2. In other words, the turbocharger shown in FIG. 1 is an exhaust gas turbocharger.

The compressor 1 has a compressor housing 10 with an air inlet 11 for receiving air to be compressed in the compressor 1 and an air outlet 12 for discharging air compressed in the compressor 1, a drive shaft 30 which is rotatably mounted in the compressor housing 10 , so that the drive shaft 30 can be driven in rotation via a drive of the turbine 2 acting on it, and a compressor impeller 40 with a blading 41, the compressor impeller 40 in the compressor housing 10 in relation to an air flow path between the air inlet 11 and air outlet 12 and on the drive shaft 30 is arranged.

The turbine 2 is designed in the usual way and has a turbine housing 20 and a turbine impeller 21 which forms the drive for the drive shaft 30 and is arranged in the turbine housing 20 and on the drive shaft 30.

In the compressor housing 10 of the compressor 1, a diffuser passage or intermediate passage 14 and a compressor spiral 15 are formed in the form of a spiral housing. The compressor spiral 15 adjoins the compressor impeller 40 as an air passage in the air flow path via the radially extending intermediate passage 14 and opens into the air outlet 12.

As can be seen from Fig.1undFig.2, the compressor housing 10 also has an insert 13 which is inserted into the compressor housing 10 on the air inlet side, so that the insert 13 radially surrounds the compressor impeller 40. The compressor 1 also has a guide device 60 which is arranged in the diffuser passage 14 of the compressor housing 10.

In the preferred embodiment of the compressor 1, the radially extending diffuser passage 14 in the compressor housing 10 has a first radial wall 22 and a second radial wall 24. The first radial wall 22 of the diffuser passage 14 preferably forms part of the compressor spiral 15.

The guide apparatus 60 is a separate vane-less guide apparatus which is arranged in the radial diffuser passage 14 and attached to the first radial wall 15 of the diffuser passage 14. In particular, connecting elements (not shown in the figures), such as screws, are provided, by means of which the separate vane-less guide device 60 is releasably attached to the first radial wall 22 of the diffuser passage 14.

As in particularFig.2 shows, between the separate vane-less guide device 60 and the axially opposite second radial wall 24 of the diffuser passage 14 there is an axial clear width a. The axial clear width a between the separate vane-less guide device 60 and the axially opposite second radial wall 24 of the diffuser passage 14 is preferably largely constant in relation to the radial extent of the diffuser passage 14. Only in the area of the radially inner diameter of the separate vane-less guide device 60 does it diverge somewhat from the axially opposite second radial wall 24 of the diffuser passage 14, essentially conically.

The separate vane-less guide apparatus 60 is designed as an annular disk which, in the region of its radially inner diameter, comprises a first pipe section 32 which is coaxial with the drive shaft 30 and points away from the second radial wall 24 of the diffuser passage 14 and which has a certain axial extent b .

Furthermore, a radially inner circumferential surface of the first pipe section 32 lies radially opposite a section of the compressor housing 10, this section being formed in particular by a section of the insert 13 and in particular a narrow radial gap, not visible in FIG. 2, between the radially inner circumferential surface of the first pipe section 32 and this section of the insert piece 13 is present, but which is so narrow that it does not affect the air flow through the diffuser passage 14.

Preferably, the annular disc 60 has a second, deviating from the first pipe section 32 second pipe section 34, which is coaxial with the drive shaft 30, facing away from the second radial wall 24 of the diffuser passage 14 and which the annular disc 60 on a radially inner one Stage 36 of the compressor spiral 15 centered. In particular, the second pipe section 34 has a larger inside diameter than the first pipe section 32. The first pipe section 32 and the second pipe section 34 are, for example, formed in one piece with the annular disk 60. Furthermore, the first pipe section 32 and the second pipe section 34 enclose, in particular, the drive shaft 30 and the compressor impeller 40.

Furthermore, the axial clear width a between the separate vane-less Nachleitapparat in the form of the annular disk 60 and this axially opposite second radial wall 24 of the diffuser passage 14 is smaller than the axial extent b of the first pipe section 34. This prevents a Unintentional loosening of the separate vane-less guide device in the form of the annular disk 60 from the first radial wall 32, for example as a result of a break in the screw (s), this can come into contact with the compressor impeller 40 and the compressor 1 is severely damaged as a result.

The invention can be implemented in any type of compressor 1 without a combination of the compressor 1 with a turbine 2 being necessary for this.

List of reference symbols

1 compressor 2 turbine 10 compressor housing 11 air inlet 12 air outlet 13 insert 14 diffuser passage 15 compressor spiral 20 turbine housing 21 turbine impeller 22 first radial wall 24 second radial wall 30 drive shaft 32 first pipe section 34 second pipe section 36 radially inner stage 40 compressor impeller 41 blading 60 guide device a axial clear width b axial extent

Claims (11)

1. Compressor (1) for a turbocharger, including at least the following: a) a compressor housing (10) with an air inlet (11) for receiving air to be compressed in the compressor (1) and with an air outlet (12) for discharging air compressed in the compressor (1), b) a drive shaft (30) extending in the axial direction, which is rotatably mounted in the compressor housing (10) and can be driven in rotation via a drive acting on it, c) a compressor impeller (40) which is arranged in the compressor housing (10) with respect to an air flow path between the air inlet (11) and the air outlet (12) and on the drive shaft (30), d) a radially extending diffuser passage (14) in the compressor housing (10) which has a first radial wall (22) and a second radial wall (24), e) a compressor spiral (15) which connects to the compressor impeller (40) as an air passage in the air flow path via the diffuser passage (14) and opens into the air outlet (12), f) a separate vane-less guide device which is arranged in the radial diffuser passage (14) and attached to the first radial wall (22) of the diffuser passage (14), wherein g) there is an axial clear width (a) between the separate vane-less guide device and the second radial wall (24) of the diffuser passage (14) axially opposite it, wherein h) the separate vane-less guide device is designed as an annular disk (60) which, in the area of its radially inner diameter, has a first pipe section (32) which is coaxial with the drive shaft (30) and points away from the second radial wall (24) of the diffuser passage (14) comprises, which has a certain axial extension (b), i) a radially inner circumferential surface of the first pipe section (32) lies radially opposite a section (13) of the compressor housing (10), wherein j) the axial inside width (a) is smaller than the axial extension (b) of the first pipe section (32). 2. Compressor according to claim 1, characterized in that the first radial wall (22) of the diffuser passage (14) forms part of the compressor spiral (15). 3. Compressor according to claim 2, characterized in that the annular disc (60) has a second, from the first pipe section (32) deviating second pipe section (34) which is arranged coaxially with the drive shaft (30) from the second radial wall (24) faces away from the diffuser passage (14) and which centers the annular disk (60) on a step (36) of the compressor spiral (15). 4. Compressor according to claim 3, characterized in that the second pipe section (34) has a larger inner diameter than the first pipe section (32). 5. Compressor according to one of the preceding claims, characterized in that at least the first pipe section (32) is formed in one piece with the annular disc (60). 6. Compressor according to one of the preceding claims, characterized in that a radially inner circumferential surface of the first pipe section (32) lies radially opposite an insert (13) which is inserted on the air inlet side as said section (13) of the compressor housing (10) and the compressor impeller ( 40) at least partially encloses radially. 7. Compressor according to one of the preceding claims, characterized in that connecting elements are arranged through which the annular disc (60) is releasably attached to the first radial wall (22) of the diffuser passage (14). 8. Compressor according to one of the preceding claims, characterized in that the axial clearance (a) between the annular disk (60) and the axially opposite second radial wall (24) of the diffuser passage (14) relative to its radial extension is at least largely constant is. 9. Turbocharger with a compressor (1) according to one of claims 1 to 8. 10. Turbocharger according to claim 9, characterized by a turbine (2) which has a turbine housing (20) and a turbine impeller (21) which forms the drive for the drive shaft (30) of the compressor and which is in the turbine housing (20) on the drive shaft ( 30) is arranged. 11. Turbocharger according to claim 10, characterized in that the turbine housing (20) is connected to the compressor housing (10).