DE102017114608A1 - Turbine inlet housing of an axial turbine of a turbocharger - Google Patents

Abstract

Turbine inlet housing (10) of an axial turbine of a turbocharger, having a flow inlet end (11) on which an outer wall (13) of Turbinenzuströmgehäuses defines a circular in cross-section flow channel (15) having a flow outlet end (12) on which the outer wall (13) of the Turbinenzuströmgehäuses and an inner wall (14) thereof define a circular in cross-section flow channel (16), and with ribs (17), via which the outer wall (13) of the Turbinenzuströmgehäuses and the inner wall (14) of the same are. The ribs (17) point between flow-guiding surfaces (18, 19) of the same between an inflow side (21) and an outflow side (20) of the respective rib (17) and between the outer wall (13) and the inner wall (14 ), a mean distance which is at least 1.5 times a thickness (s) of the outer wall (13) of the Turbinenzuströmgehäuses.

Description

The invention relates to a Turbinenzuströmgehäuse an axial turbine of a turbocharger.

A turbocharger has a turbine for relaxing a first medium and a compressor for compressing a second medium. The turbine of the turbocharger has a turbine housing and a turbine rotor. The compressor of the turbocharger has a compressor housing and a compressor rotor. The turbine rotor and the compressor rotor are connected to each other via a shaft which is rotatably mounted in a bearing housing of the turbocharger. The bearing housing of the turbocharger is connected to both the turbine housing and the compressor housing. The turbine of a turbocharger can be designed as an axial turbine or as a radial turbine. Likewise, the compressor of a turbocharger may be designed as an axial compressor or as a centrifugal compressor. The present invention relates to a Turbinenzuströmgehäuse the turbine housing of a designed as an axial turbine turbine of a turbocharger.

From the DE 20 2014 002 981 U1 is the basic structure of an axial turbine of a turbocharger known. Thus, this prior art shows in detail the turbine rotor of the turbine together with the Turbinenzuströmgehäuse the turbine housing. It is in the DE 20 2014 002 981 U1 the flow exit-side end of Turbinenzuströmgehäuses shown, on which the Turbinenzuströmgehäuse, namely a radially inner wall and a radially outer wall thereof, define a circular in cross-section flow channel. About this annular flow channel to be relaxed medium to the turbine rotor of the axial turbine can be fed.

After DE 20 2014 002 981 U1 is a nozzle ring is positioned between the turbine rotor and the flow-exit-side end of Turbinenzuströmgehäuses. The nozzle ring is also referred to as a nozzle or guide grid.

From practice it is known that the radially inner wall of the Turbinenzuströmgehäuses and the radially outer wall thereof are connected to each other via ribs which extend through the annular flow channel at the flow-exit end of Turbinenzuströmgehäuses. These ribs are surrounded by the medium which is to be supplied to the turbine rotor.

Turbine induction housings known from practice are susceptible to cracking due to thermal cycling. As a result, the life of a Turbinenzuströmgehäuses is limited. In addition to the formation of cracks, there is the problem in turbine inlet cases known from practice that a relative movement between the turbine inlet housing and a module mounted on the turbine inlet housing, in particular the nozzle or nozzle ring, can likewise be formed as a result of thermal cycles, whereby gaps then set in operation change between the Turbinenzuströmgehäuse and the nozzle. There is a need for a turbine inlet housing which is less susceptible to cracking due to thermal cycling. Further, there is a need to minimize thermal motion forming relative movements between the turbine inlet housing and an assembly mounted on the turbine inlet housing.

On this basis, the present invention has the object to provide a novel Turbinenzuströmgehäuse.

This object is achieved according to a first aspect of the invention by a Turbinenzuströmgehäuse according to claim 1.

According to the first aspect, the fins between flow-guiding surfaces thereof, located between an upstream side and an outflow side of the respective rib and between the outer wall and the inner wall, an average distance which is at least 1.5 times a thickness of the outer Wall of Turbinenzuströmgehäuses corresponds. This mean distance between the flow-guiding surfaces of the ribs determines the thickness of the ribs. Such ribs can reduce cracking on the turbine inlet housing due to thermal cycling. Furthermore, the risk of relative movement between the turbine inlet housing and an assembly mounted on the turbine inlet housing can be minimized.

This object is achieved according to a second aspect of the invention by a Turbinenzuströmgehäuse according to claim 6.

According to the second aspect, the ribs are axially inclined as viewed in an axial section with respect to the radial direction. This tendency of the ribs also minimizes the risk of cracking and relative movement between the turbine inlet housing and an assembly mounted thereon.

This object is achieved according to a third aspect of the invention by a Turbinenzuströmgehäuse according to claim 9.

According to the third aspect, as viewed in the axial direction, the ribs are tangentially inclined with respect to the radial direction. Also, this inclination of the ribs serves to minimize cracking as well as minimizing relative movement between the turbine inlet housing and a subassembly mounted thereto due to thermal cycling.

This object is achieved according to a fourth aspect of the invention by a Turbinenzuströmgehäuse according to claim 12.

According to the fourth aspect, the ribs pass into the outer wall and into the inner wall with a transition radius, which rotates unevenly around the respective rib in the region of the outer wall and in the region of the inner wall. This can be used to minimize the risk of cracking and relative movement due to thermal cycling.

This object is achieved according to a fifth aspect of the invention by a Turbinenzuströmgehäuse according to claim 15.

According to the fifth aspect, adjacent to a region in which the ribs merge into the inner wall, connecting sections for a guide grid are formed on a side of the inner wall facing away from the ribs. The connection sections for the guide grid or the nozzle or the nozzle ring are particularly advantageous in order to minimize a relative movement between Turbinenzuströmgehäuse and guide grid due to thermal cycles. However, they are also advantageous in minimizing the risk of cracking due to thermal cycling.

The above five aspects of the invention may be used either alone or preferably in combination with each other. Thus, two of the above five aspects, three of the above five aspects, four of the above five aspects, or even all five aspects can be used in combination. Particularly preferred is an embodiment of Turbinenzuströmgehäuses, in which the first aspect, the second aspect, the third aspect and the fourth aspect, so the defined thickness of the ribs with the inclination of the ribs and the non-uniform circumferential radii is combined.

• 1 einen Axialschnitt durch ein erfindungsgemäßes Turbinenzuströmgehäuse einer Axialturbine eines Turboladers,
• 2 eine Ansicht in Blickrichtung II der 1,
• 3 Schnittansicht auf Ebene III-III der 1.

Preferred embodiments of the invention will become apparent from the dependent claims and the description below. Embodiments of the invention will be described, without being limited thereto, with reference to the drawings. Showing:

• 1 an axial section through an inventive Turbinenzuströmgehäuse an axial turbine of a turbocharger,
• 2 a view in the direction of view II of the 1 .
• 3 Section view on level III - III of the 1 ,

1 shows a Turbinenzuströmgehäuse 10 an axial turbine of a turbocharger. Such Turbinenzuströmgehäuse 10 has a flow inlet end 11 as well as via a flow outlet end 12 , At the flow inlet end 11 Medium, which is to be relaxed in the region of the axial turbine, enters the turbine inlet housing 10 one. At the flow exit end 12 this medium exits the Turbinenzuströmgehäuse 10 in the axial direction, to then be fed in the axial direction of a turbine rotor of the axial turbine. An outlet direction of the medium in the region of the flow outlet end 12 runs accordingly in the axial direction of the axial turbine. Therefore, the section of the 1 through the in 1 shown Turbinenzuströmgehäuse 10 also referred to as axial section.

The turbine inlet housing 10 has an outer wall 13 and an inner wall 14 on. The outer wall 13 defined at the flow inlet end 11 the Turbinenzuströmgehäuses 10 a circular cross-sectional flow channel 15 the Turbinenzuströmgehäuses 10 , At the flow exit end 12 defines the outer wall 13 together with the inner wall 14 a circular cross-section flow channel 16 the Turbinenzuströmgehäuses 10 ,

Im in 1 embodiment shown is the Turbinenzuströmgehäuse 10 executed in manifold construction. The inlet direction of the flow in the region of the flow inlet end 11 is opposite to the outlet direction of the flow in the region of the flow outlet end 12 offset by 90 °. Im in 1 In the embodiment shown, therefore, the flow of the medium to be supplied to the turbine rotor is deflected by 90 °.

However, the invention is not limited to manifold-type turbine inlet housings. In a Turbinenzuströmgehäuse, which is not designed in manifold construction, both the flow inlet direction extend in the region of the flow inlet end 11 as well as the flow exit direction in the region of the flow outlet end 12 the Turbinenzuströmgehäuses in the axial direction.

In any case, is in the region of the flow inlet end 11 the circular in cross-section flow channel 15 through the outer wall 13 and in the region of the flow exit end 12 the annular flow channel 16 through the outer wall 13 and the inner wall 14 Are defined.

The inner wall 14 is also called a bell.

In the area of the flow exit end 12 So, where the outer wall 13 and the inner wall 14 the annular flow channel 16 the Turbinenzuströmgehäuses 10 define, ribs extend 17 , where the ribs 17 the outer wall 13 and the inner wall 14 connect with each other and through the annular flow channel 16 extend. Ribs 17 are therefore of the medium which the Turbinenzuströmgehäuse 10 flows through, flows around.

2 shows the Turbinenzuströmgehäuse 10 in the direction of view II of the 1 , The direction of view II of the 1 extends in the axial direction. In 2 is therefore the viewing direction in the annular flow channel 16 in the region of the flow outlet end 12 the Turbinenzuströmgehäuses 10 directed into it.

According to a first aspect of the present invention, the ribs 17 between flow surfaces 18 . 19 the same, located between an upstream side 21 and a downstream side 20 the respective rib 17 as well as between the walls 13 . 14 extend, a mean distance and thus an average thickness, which is at least 1.5 times a thickness s the outer wall 13 equivalent. The average distance between the flow-guiding surfaces preferably corresponds 18 . 19 the ribs 17 and thus the thickness thereof between 1.5 times and 3.0 times the thickness s of the outer wall 13 the Turbinenzuströmgehäuses 10 , Particularly preferred is an expression of the first aspect of the invention, in which the mean distance between the flow-guiding surfaces 18 . 19 the ribs 17 and thus the average thickness thereof is at least 1.6 times the thickness s the wall 13 the Turbinenzuströmgehäuses 10 equivalent. Most preferably, the average distance between the flow-bearing surfaces corresponds 18 . 19 the ribs 17 and thus the average thickness thereof between 1.6 times and 2.6 times the thickness s of the outer wall 13 the Turbinenzuströmgehäuses 10 ,

Like that 3 can be taken, are the ribs 17 adjacent to the upstream side 21 and downstream side 20 rounded, so the distance B _RAn between the flow-guiding surfaces 18 . 19 in the area of the inflow side 21 and the distance B _RAb between the flow-guiding surfaces 18 . 19 in the area of the downstream side 20 each smaller than the distance B _Rm between the flow-guiding surfaces 18 . 19 in the middle of the length L _Rm the rib, being the length L _Rm the rib the distance between the upstream side 21 and downstream side 20 equivalent.

Like that 1 and 2 can be taken, are the ribs 17 preferably designed such that the ribs 17 starting from the outer wall 13 towards the inner wall 14 rejuvenate both in Axialblickrichtung II seen (see 2 ) and in axial section (see 1 ).

Seen in axial section (see 1 ) corresponds adjacent to the outer wall 13 the distance between the upstream side 21 and the downstream side 20 the respective rib 17 and therefore the length L _Rm the rib the measure b and adjacent to the radially inner wall 14 corresponds to this distance between the inflow side 21 and the downstream side 20 the respective rib 17 and therefore the length L _Rm the rib the measure a.

2 can be deduced that the distance B _Rm out 3 between the flow-guiding surfaces 18 . 19 the respective rib 17 adjacent to the outer wall 13 the dimension d and adjacent to the inner wall 14 corresponds to the dimension c. The following applies: b> a and d> c.

It follows that the ribs 17 accordingly, starting from the outer wall 13 towards the inner wall 14 taper, preferably continuously, both in relation to the distance B _Rm between the flow-guiding surfaces 18 . 19 the ribs 17 as well as relative to the distance L _Rm between the upstream side 21 and the downstream side 20 the ribs 17 ,

Therefore, in connection with the first aspect of the invention, the mean distance between the flow-guiding surfaces is also considered 18 and 19 the respective rib 17 Referenced, wherein the average distance and thus the average thickness of the respective rib 17 0.5 * (c + d).

With the average thickness of the respective rib defined above 17 the risk of cracking due to thermal cycling can be reduced. This will increase the life of the turbine inlet housing 10 elevated. Between the inner wall 14 , the outer wall 13 and the ribs 17 a homogeneous distribution of stress and deformation during thermal cycles can be guaranteed. Furthermore, a relative movement between the Turbinenzuströmgehäuse 10 and a mounted on the same assembly, such as a nozzle or a nozzle ring, are minimized, again by thermal cycling indexed relative movement between these assemblies.

According to a second aspect of the invention, preferably in combination with the above-described first aspect of a Turbinenzuströmgehäuse 10 used are the ribs 17 in the axial section of 1 seen opposite to the radial direction 23 axially inclined.

It shows 1 in that in the axial section of the 1 seen between the radial direction 23 and a longitudinal center axis 24 the rib 17 an angle α is formed, which is the axial inclination of the rib 17 in axial section with respect to the radial direction 23 Are defined.

This angle α is preferably between 20 ° and 80 °, preferably between 20 ° and 70 °, more preferably between 20 ° and 60 °, most preferably between 30 ° and 40 °.

At the in 1 and 2 shown Turbinenzuströmgehäuse 10 in manifold construction is in the range of each rib 17 a rib-specific and therefore rib-specific angle α provided with the respective longitudinal central axis 24 the respective rib 17 to the radial direction 23 is inclined, in such a way that the ribs 17 an equal or approximately equal rib heights R _Hm between the outer wall 13 and the inner wall 14 exhibit.

The above details of the second aspect of the invention, as well as the details of the first aspect of the invention, serve to reduce the risk of cracking of the turbine engine housing 10 due to thermal cycles. It can be a uniform, homogeneous stress and deformation distribution between the outer wall 13 , inner wall 14 and the ribs 17 to be provided. Furthermore, the risk is reduced that due to thermal cycles, a relative movement between the Turbinenzuströmgehäuse 10 and one on the turbine inlet housing 10 forms mounted distributor or nozzle ring.

According to a third aspect of the invention, preferably in combination with the first aspect described above and the second aspect of the invention described above on a Turbinenzuströmgehäuse 10 used are the ribs 17 additionally also in axial direction II seen (see 2 ) relative to the radial direction 23 tangentially inclined.

It shows 2 for the in 2 upper rib 17 an angle β , which the longitudinal central axis 24 the rib 17 with the radial direction 23 includes. This angle β is between 5 ° and 30 °, preferably between 5 ° and 20 °, more preferably between 10 ° and 15 °.

Through each of the ribs 17 can be a radial direction 23 extending axis, which is located in the region of the respective rib 17 with the longitudinal central axis 24 the same cuts, in particular in the transition region of the respective rib 17 to the inner wall 14 , The angle β , the respective longitudinal central axis 24 the respective rib 17 with this through the respective rib 17 extending radial direction 23 Therefore, is preferably in the above-mentioned angle ranges for the angle β.

In Axialblickrichtung the 2 Seen the longitudinal central axes intersect 24 of two ribs each 17 at individual intersections. There is no common point of intersection for all longitudinal central axes L all ribs 17 ,

Also, the details of the third aspect of the invention reduce the risk of cracking and relative movement due to thermal cycling. In particular, a homogeneous stress and deformation distribution between the outer wall 13 , inner wall 14 and ribs 17 guaranteed.

Then, as shown in the figures, the turbine inlet housing 10 designed in manifold construction, are the lower ribs 17 namely, the intersections between the respective longitudinal center axes 24 the lower ribs 17 and the outer wall 13 , in about the same height. Transition areas of the lower ribs 17 to the outer wall 13 are therefore seen in the vertical direction, not offset from each other, but seen in the vertical direction positioned approximately at the same vertical position.

According to a fourth aspect of the present invention, preferably in combination with the three aspects of the invention described above, at the turbine inlet housing 10 is used, go the ribs 17 in the outer wall 13 with a transition radius R _a and in the inner wall 14 with a transition radius R _i over, in the area of the outer wall 13 and in the area of the inner wall 14 each unevenly around the respective rib 17 circulates. So that applies in the area of the outer wall 13 the transition radius R _aAn adjacent to the upstream side 21 the respective rib 17 is smaller than the transition radius R _aAb adjacent to a downstream side 20 the same. The following applies: R _aAn <R _aAb . In the area of the inner wall 14 is the transition radius R _iAn adjacent to the upstream side 21 the respective rib 17 is greater than the transition radius R _iAb bennachbart to a downstream side 20 the same. The following applies: R _iAn > R _iAb .

In a fifth aspect of the present invention, preferably in combination with the four aspects of the invention described above, at the turbine inlet housing 10 is used adjacent to the areas where the ribs 17 on the inner wall 14 attack or go into the same, at one of the respective rib 17 opposite side of the inner wall 14 a connection section 22 for fastening a guide grid or nozzle or nozzle ring on Turbinenzuströmgehäuse 10 educated. These connection sections 22 adjacent to the transition region of the ribs 17 to the inner wall 14 in particular, in combination with the other details of the invention described above, reduce the risk of relative movement between the turbine inlet housing 10 and a stator mounted thereon due to thermal cycling. Set games and gaps between Turbinenzuströmgehäuse 10 and nozzle ring remain unchanged and are subject to lesser changes or none due to thermal cycles.

By the aspects of the invention described above, alone or preferably in combination, it can be achieved that a turbine inlet housing is exposed to a significantly reduced risk of cracking due to thermal cycling. As a result, longer service lives can be achieved and maintenance intervals can be increased. It provides an elastic overall structure with fewer jumps in stiffness, whereby a homogeneous stress and deformation distribution between the outer wall 13 , inner wall 14 and ribs 17 ensured by thermal cycles. The inner wall 14 is subject to a similar deformation behavior as the outer wall 13 , In particular, components to be attached to the turbine inlet housing, such as a nozzle, are prevented from relatively shifting due to thermal cycles to the turbine inlet housing, leaving gaps and gaps and undergoing less change due to thermal cycling.

Ribs 17 can be designed as hollow ribs. Then, when the ribs 17 are hollow, weight can be saved, continue to be guided by the same cooling medium.

LIST OF REFERENCE NUMBERS

10

Turbinenzuströmgehäuse

11

flow inlet end

12

flow outlet end

13

outer wall

14

inner wall

15

circular flow channel

16

circular flow channel

17

rib

18

flowing surface

19

flowing surface

20

outflow

21

inflow

22

connecting section

23

radial direction

24

Longitudinal central axis

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202014002981 U1 [0003, 0004]

Claims (16)

Turbine inlet housing (10) of an axial turbine of a turbocharger, having a flow inlet end (11) on which an outer wall (13) of Turbinenzuströmgehäuses defines a circular in cross-section flow channel (15) having a flow outlet end (12) on which the outer wall (13) of the Turbinenzuströmgehäuses and an inner wall (14) thereof define a circular in cross-section flow channel (16), with ribs (17) through which the outer wall (13) of the Turbinenzuströmgehäuses and the inner wall (14) of the same are interconnected characterized in that the ribs (17) are arranged between flow guiding surfaces (18, 19) thereof between an inflow side (21) and an outflow side (20) of the respective rib (17) and between the outer wall (13) and the Inner wall (14), have a mean distance which is at least 1.5 times a thickness of the outer minimum Wall (13) of the Turbinenzuströmgehäuses corresponds. Turbine inlet housing after Claim 1 , characterized in that the mean distance between the flow guiding surfaces (18, 19) of the ribs (17) is between 1.5 and 3.0 times the thickness of the outer wall (13) of the turbine inlet casing. Turbine inlet housing after Claim 1 or 2 , characterized in that the mean distance between the flow-guiding surfaces (18, 19) of the ribs (17) is at least 1.6 times the thickness of the outer wall (13) of the Turbinenzuströmgehäuses. Turbine inlet housing according to one of Claims 1 to 3 , characterized in that the mean distance between the flow-guiding surfaces (18, 19) of the ribs (17) between 1.6 times and 2.6 times the thickness of the outer wall (13). Turbine inlet housing according to one of Claims 1 to 4 , characterized in that the same according to one of Claims 6 to 15 is further developed. Turbine inlet housing (10) of an axial turbine of a turbocharger, having a flow inlet end (11) on which an outer wall (13) of Turbinenzuströmgehäuses defines a circular in cross-section flow channel (15) having a flow outlet end (12) on which the outer wall (13) of the Turbinenzuströmgehäuses and an inner wall (14) thereof define a circular in cross-section flow channel (16), with ribs (17) through which the outer wall (13) of the Turbinenzuströmgehäuses and the inner wall (14) of the same are interconnected , characterized in that the ribs (17) seen in an axial section relative to a radial direction (23) are axially inclined. Turbine inlet housing after Claim 6 characterized in that in the axial section seen a longitudinal central axis (24) of the respective rib (17) with the radial direction (23) an angle (a) between 20 ° and 80 °, preferably between 20 ° and 70 °, more preferably between 20 ° and 60 °. Turbine inlet housing after Claim 6 or 7 , characterized in that seen in the axial section in a Krümmerbauweise Turbinenzuströmgehäuses the longitudinal center axes (24) of the ribs (17) with rib-specific angles (α) relative to the radial direction (23) are axially inclined so that the ribs (17) are equal or approximate have the same rib heights between the outer wall (13) and inner wall (14). Turbine inlet housing (10) of an axial turbine of a turbocharger, having a flow inlet end (11) on which an outer wall (13) of Turbinenzuströmgehäuses defines a circular in cross-section flow channel (15) having a flow outlet end (12) on which the outer wall (13) of the Turbinenzuströmgehäuses and an inner wall (14) thereof define a circular in cross-section flow channel (16), with ribs (17) through which the outer wall (13) of the Turbinenzuströmgehäuses and the inner wall (14) of the same are interconnected , characterized in that the ribs (17) seen in Axialblickrichtung are tangentially inclined relative to a radial direction (23). Turbine inlet housing after Claim 9 , characterized in that viewed in Axialblickrichtung a longitudinal center axis (24) of the respective rib (17) with the radial direction (23) an angle (β) between 5 ° and 30 °, preferably between 5 ° and 20 °, more preferably between 10 ° and 15 °. Turbine inlet housing after Claim 9 or 10 , characterized in that the longitudinal central axes (24) of each two ribs (17) intersect at individual points of intersection. Turbine inlet housing (10) of an axial turbine of a turbocharger, with a flow inlet end (11) on which an outer wall (13) of Turbinenzuströmgehäuses defines a circular in cross-section flow channel (15) having a flow outlet end (12) on which the outer wall (13) of the Turbinenzuströmgehäuses and an inner wall (14) thereof define a circular in cross-section flow channel (16), with ribs (17) through which the outer wall (13) of the Turbinenzuströmgehäuses and the inner wall (14) of the same are interconnected , characterized in that the ribs (17) in the outer wall (13) and in the inner wall (14) with a transition radius, the non-uniform in the region of the outer wall (13) and in the region of the inner wall (14) the respective rib (17) rotates. Turbine inlet housing after Claim 12 , characterized in that in the region of the outer wall (13) of the transition radius adjacent to an inflow side (21) of the respective rib (17) is smaller than the transition radius adjacent to a downstream side (20) thereof. Turbine inlet housing after Claim 12 or 13 , characterized in that in the region of the inner wall (14) of the transition radius adjacent to an inflow side (21) of the respective rib (17) is greater than the transition radius adjacent to a downstream side (20) thereof. Turbine inlet housing (10) of an axial turbine of a turbocharger, with a flow inlet end (11) on which an outer wall (13) of Turbinenzuströmgehäuses defines a circular in cross-section flow channel (15) having a flow outlet end (12) on which the outer wall (13) of the Turbinenzuströmgehäuses and an inner wall (14) thereof define a circular in cross-section flow channel (16), with ribs (17) through which the outer wall (13) of the Turbinenzuströmgehäuses and the inner wall (14) of the same are interconnected , characterized in that adjacent to a region in which the ribs (17) merge into the inner wall (14), formed on a side remote from the ribs (17) side of the inner wall (14) connecting portions (22) for a guide grid are. Turbine inlet housing according to one of Claims 1 to 15 , characterized in that the ribs (17) are hollow.

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