EP3767081A1 - Turbine housing with a reduced stress connecting flange and exhaust gas turbine comprising such a turbine housing - Google Patents

Abstract

The invention relates to a turbine housing for an exhaust gas turbine, which has a connection flange for connection on the bearing housing side to a bearing housing, in which housing connection bores spaced apart in the circumferential direction are provided, with material recesses in the connection flange open radially inwardly towards a longitudinal center axis of the turbine housing between adjacent housing connection bores are provided. The invention also relates to an exhaust gas turbine which is equipped with such a turbine housing.

Description

Technical field of the invention

The invention relates to a turbine housing with a low-stress connecting flange and an exhaust gas turbine with such a turbine housing. Depending on the embodiment, the exhaust gas turbine can be, for example, a turbocharger turbine for a turbocharger or a utility turbine.

State of the art

A typical turbocharger has a turbine housing, a bearing housing and a compressor housing, the turbine housing being connected to the bearing housing and the bearing housing also being connected to the compressor housing.

The connection between the turbine housing and the bearing housing must meet several requirements. These requirements include ensuring gas tightness, preventing twisting between the two housings due to external forces and ensuring that the two housings are held together even in the event of a burst. In order to be able to meet these requirements, the connection between the turbine housing and the bearing housing must in particular be designed in such a way that it can cope with large temperature differences between the turbine housing and the bearing housing and high forces in the event of a burst. A reliable safety enclosure - called "containment" in English - is a very important and therefore structurally very demanding requirement for an exhaust gas turbine in such a case of bursting.

It is already known to connect a turbine housing to a bearing housing using a clamping ring which has an end portion of a flange of the turbine housing with an end portion of the flange of the Turbine housing adjacent end portion of a flange of the bearing housing connects. Such a clamping ring connection is used in particular in turbochargers with comparatively low outputs. A disadvantage of such a clamping ring connection is that it cannot guarantee the cohesion of the housing in the event of a bursting event in which high forces become effective.

In the case of turbochargers with greater power, for example with more than 500 KW engine power per turbocharger, a connection of the turbine housing to the bearing housing using a flange of the turbine housing equipped with clamping lugs has become established in practice. Screws, for example, which are screwed into threaded bores in the turbine housing and press said clamping lugs against the turbine housing and the bearing housing adjoining it, for example, thereby pressing the bearing housing against the turbine housing, are passed through these clamping lugs. When using such a clamping bracket flange, a comparatively large penetration depth of the screws into the turbine housing is required due to the strong forces when a burst occurs. In order to be able to provide this great penetration depth of the screws, it is necessary to dimension the thickness of the connecting flange of the turbine housing to be correspondingly large. This great thickness of the connecting flange on the one hand increases the rigidity of the connecting flange, but on the other hand causes a comparatively slow and also uneven heating of the connecting flange of the turbine housing. This increases the thermal transient stresses in the turbine housing, in particular in the area of the connecting flange, but also in the area of the tongue of the turbine housing. The higher thermal transient stresses in turn lead to a reduced service life of the turbine housing and thus also of the entire turbocharger.

The Figure 1 shows a first sectional view to illustrate a turbine housing according to the prior art. This turbine housing has a connecting flange 2, via which the turbine housing 1 is connected to the bearing housing 14 of a turbocharger. This connection is made using in housing connection bores of the connection flange Realized screwed connecting elements which press clamping lugs 16 onto the connecting flange 2 of the turbine housing 1 and onto the bearing housing 14 by means of nuts 17, whereby the bearing housing 14 is also pressed against the turbine housing. The said housing connection bores are spaced from one another (that is to say spatially apart from one another) and are arranged in the circumferential direction along a circle. The clamping lugs are also arranged along a circle in the circumferential direction of the turbine housing. Since - as stated above - the requirements for the connection between the turbine housing and the bearing housing are high, the depth of penetration of the connecting elements into the connecting flange must be great. This in turn requires a comparatively large flange thickness 19 of the connecting flange 2 in the area of the connection between the turbine housing and the bearing housing.

The Figure 2 shows a second sectional view to illustrate a turbine housing according to the prior art. This second sectional illustration illustrates the turbine housing at an interface at which a connecting element 15 is screwed into a housing connecting bore 3 of the connecting flange 2 of the turbine housing. Also from the Figure 2 It can be seen that a clamping lug 16 is pressed both onto the turbine housing 2 and onto the bearing housing 14, which is implemented using a nut 17 and a washer 18.

Object of the invention

The object of the invention is to provide a turbine housing and an exhaust gas turbine in which the disadvantages mentioned above with reference to a turbocharger are reduced.

Summary of the invention

This object is achieved by a turbine housing with the features specified in claim 1 or an exhaust gas turbine with the features specified in claim 11.

A turbine housing of this type has a connecting flange for connection on the bearing housing side to a bearing housing, in which housing connecting bores spaced apart from one another in the circumferential direction are provided, with material recesses in the connecting flange being provided between adjacent housing connecting bores radially inwardly towards a longitudinal center axis of the turbine housing. Depending on the embodiment and requirements, the turbine housing can also be in several parts. Depending on the requirements, a heat shield or a nozzle ring can be arranged between the turbine housing and the bearing housing.

In any case, in this entire description, the term "drilling" is to be interpreted functionally and not, due to the manufacturing process, to mechanical processing using a drilling machine or milling machine.

According to one embodiment of the invention, the spaced apart housing connecting bores in the connecting flange are arranged along at least one circle.

According to one embodiment of the invention, the turbine housing has a clamping edge which is arranged adjacent to the housing connecting bores in the radial direction.

According to one embodiment of the invention, an annular recess is provided in the clamping edge, which has a recess base, the adjacent housing connection bores being made in the recess base and the material recesses provided between two adjacent housing connection bores being provided in the recess base.

According to one embodiment of the invention, the clamping edge in the area between two adjacent housing connecting bores each has a clamping edge recess that widens the annular recess.

According to one embodiment of the invention, the depth of the clamping edge recess corresponds to the sum of the depth of the annular recess and the depth of the material recesses provided in the annular recess.

According to one embodiment of the invention, the turbine housing is constructed in several pieces.

According to one embodiment of the invention, the clamping edge forms a separate part of the turbine housing.

According to one embodiment of the invention, a heat shield or a nozzle ring forms a separate part of the turbine housing.

According to one embodiment of the invention, the clamping edge is part of the heat shield or the nozzle ring.

According to one embodiment of the invention, an exhaust gas turbine has a turbine housing with the features according to the invention.

According to one embodiment of the invention, an exhaust gas turbine has a bearing housing connected to the turbine housing, the turbine housing being connected to the bearing housing by means of connecting elements.

According to one embodiment of the invention, an exhaust gas turbine has clamping elements which are each pressed by a connecting element or a plurality of connecting elements onto the connecting flange of the turbine housing and onto the bearing housing.

According to one embodiment of the invention, the clamping elements of the exhaust gas turbine are pressed against the clamping edge.

In an embodiment that is simple in terms of both construction and assembly, the connecting elements are screws or threaded pins.

The advantages of the invention are in particular that the material recesses provided between the housing connecting bores enable the connecting flange area to be heated more quickly and more evenly during operation of the respective exhaust gas turbine. Due to these material cutouts, there is also a reduced rigidity of the turbine housing in the area of the connecting flange. As a result, lower thermal transient stresses occur when the exhaust gas turbine is in operation. This in turn leads to an extension the service life of the turbine housing and thus also to an extension of the service life of the entire exhaust gas turbine.

Brief description of the drawings

Figur 1

eine erste Schnittdarstellung zur Veranschaulichung eines Turbinengehäuses nach dem Stand der Technik,

Figur 2

eine zweite Schnittdarstellung zur Veranschaulichung eines Turbinengehäuses nach dem Stand der Technik,

Figur 3

eine Skizze zur Veranschaulichung eines erfindungsgemäßen Turbinengehäuses,

Figur 4

eine Schnittdarstellung in Radialrichtung zur Veranschaulichung einer Ausführungsform der Erfindung,

Figur 5

eine Schnittdarstellung gemäß der in der Figur 4 gezeigten Schnittlinie C-C,

Figur 6

eine Skizze zur Veranschaulichung einer anderen Ausführungsform der Erfindung,

Figur 7

eine Schnittdarstellung in Richtung der in der Figur 6 gezeigten Schnittlinie A-A,

Figur 8

eine Skizze zur Veranschaulichung einer weiteren Ausführungsform der Erfindung und

Figur 9

eine Schnittdarstellung in Richtung der in der Figur 8 gezeigten Schnittlinie B - B.

It shows:

Figure 1

a first sectional view to illustrate a turbine housing according to the prior art,

Figure 2

a second sectional view to illustrate a turbine housing according to the prior art,

Figure 3

a sketch to illustrate a turbine housing according to the invention,

Figure 4

a sectional view in the radial direction to illustrate an embodiment of the invention,

Figure 5

a sectional view according to the in Figure 4 shown section line CC,

Figure 6

a sketch to illustrate another embodiment of the invention,

Figure 7

a sectional view in the direction of in the Figure 6 shown section line AA,

Figure 8

a sketch to illustrate a further embodiment of the invention and

Figure 9

a sectional view in the direction of in the Figure 8 shown section line B - B.

Detailed description of exemplary embodiments

The Figure 3 shows a sketch to illustrate a turbine housing according to the invention, wherein in FIG Figure 3 only part of this turbine housing is shown. The turbine housing has a connecting flange 2 which is arranged coaxially to a longitudinal center axis of the turbine housing and which is equipped with a clamping edge 7. In this clamping edge 7, connecting webs 19 extending inward in the radial direction 8 are provided, in FIG which housing connection bores 3 are introduced. Said connecting webs 19 and thus also the housing connecting bores 3 introduced into them are spaced apart from one another in the circumferential direction 9 of the turbine housing. They are arranged in the connection flange in the circumferential direction 9 along one or more circles. Between two housing connection bores 3 spaced apart from one another in the circumferential direction 9, material recesses 4 which are open radially inward are provided in the clamping edge 7 of the connecting flange 2. These material recesses 4 can be introduced into the clamping edge of the connecting flange by material removal or, if a shaping manufacturing process is used, they can be modeled directly. The geometry of the material recesses can be selected differently. For example, the material recesses can be made semicircular, elliptical, bell-shaped or rectangular.

A connection of the turbine housing with one in the Figure 3 bearing housing, not shown, of a turbocharger is carried out as above in connection with Figure 2 has been explained using connecting elements that are each introduced into a housing connecting bore 3 of the connecting flange 2, furthermore clamping elements arranged along a circle in the circumferential direction of the turbine housing, which in one embodiment are clamping lugs, both on the turbine housing and on the bearing housing can be pressed, which is realized using a nut and a washer.

The material recesses 4 provided in contrast to the prior art bring about faster and more uniform heating of the connecting flange 2 of the turbine housing when the turbocharger is in operation. Furthermore, due to the material cutouts 4 made in the connecting flange 2, there is a reduced rigidity of the turbine housing in the area of the connecting flange 2. This in turn has the consequence that in the area of the connecting flange 2, reduced thermal transient stresses occur in comparison with the prior art. By reducing the thermal transient stresses in the area of the connecting flange, the The service life of the turbine housing and thus the service life of the entire turbocharger are extended.

The Figure 4 shows a sectional view in the radial direction to illustrate an embodiment of the invention. The connection flange 2 of the turbine housing and the bearing housing 14 connected to the connection flange 2 and thus to the turbine housing are shown Figure 4 It can be seen that in the sectional plane shown, the connection of the turbine housing to the bearing housing is implemented using a clamping lug 16. This clamping lug 16 is pressed onto the connecting flange 2 of the turbine housing and onto the bearing housing 14. This pressing is implemented using a nut 17 and a washer 18 arranged between the nut 17 and the clamping bracket 16. Furthermore, from the Figure 4 shows that the bearing housing is pressed against the connecting flange 2 of the turbine housing by this pressing, since the bearing housing 14 is radially outward, ie in the Figure 4 has upwardly directed clamping edge, the rear side of which on a radially inward, ie in the Figure 4 downward, directed extension of the connecting flange 2 is pressed. Finally from the Figure 4 also one of the in the Figure 3 illustrated recesses 4 which are provided in the interconnected state of the turbine housing with the bearing housing in the sectional plane shown in the axial direction between the clamping lug 16 and the connecting flange 2.

The Figure 5 FIG. 13 shows a sectional view according to FIG Figure 4 shown section line CC. From this illustration it can be seen in particular that between each two housing connection bores 3 spaced apart from one another in the circumferential direction 9, in which connection elements 15 are introduced, material recesses 4 are provided in the clamping edge 7 of the connection flange 2 of the turbine housing, which in the sectional plane shown are outside the radial direction 8 Bearing housing 14 are located and are open radially inward.

The Figure 6 shows a sketch to illustrate another embodiment of the invention. In this other embodiment is in the radially inner edge area of the clamping edge 7 of the connecting flange 2 of the turbine housing, an annular recess 5 is provided which extends in the circumferential direction 9 over the entire circumference of the turbine housing. This annular recess 5 has a recess bottom 6.

In this embodiment of the invention, the housing connecting bores 3, which are spaced apart from one another in the circumferential direction 9, are introduced into the recess bottom 6 of the annular recess 5.

Furthermore, in this embodiment, the material recesses 4 provided between each two adjacent housing connection bores 3 are also made in the recess bottom 6 of the annular recess 5. These material recesses 4 extend in the radial direction 8 over the entire recess base 6.

By making the housing connection bores 3 and the material recesses 4 in the recess bottom 6 of the annular recess 5, the thickness of the connecting flange 2 of the turbine housing in the connecting area of the turbine housing with the bearing housing and thus the thermal-transient stresses that occur in the connecting flange 2 during operation of the turbocharger are further reduced .

The Figure 7 FIG. 11 shows a sectional view in the direction of FIG Figure 6 shown section line A - A. In this Figure 7 the depth of the housing connecting bores 3 made in the recess bottom 6 is denoted by the reference number 12. Furthermore, it can be seen that, in this embodiment, the depth of the material recesses 4 corresponds to the depth 12 of the housing connecting bores 3 made in the recess base 6. According to other embodiments, the depth of the material recesses 4 can also differ from the depth of the housing connecting bores 3. The depth of the annular recess 5 is denoted by the reference number 11. The sum of the depth 11 of the annular recess and the depth 12 of the housing connecting bores made in the recess base is denoted by the reference number 20.

The Figure 8 shows a sketch to illustrate a further embodiment of the invention. In this further embodiment, an annular recess 5 is again provided in the radially inner edge region of the clamping edge 7 of the connecting flange 2 of the turbine housing, which extends in the circumferential direction 9 over the entire circumference of the turbine housing. Housing connection bores 3 spaced apart from one another in the circumferential direction 9, between which the material recesses 4 are located, are again made in the recess bottom 6 of the annular recess 5. These recesses 4 are open inward in the radial direction 8 and extend into the area of the clamping edge 7. Consequently, in this development, the clamping edge 7 has clamping edge recesses 10, which are each provided between two adjacent housing connection bores 3. In the exemplary embodiment shown, these clamping edge recesses 10 extend in the radial direction 8 through the entire clamping edge 7.

The Figure 9 FIG. 11 shows a sectional view in the direction of FIG Figure 8 shown section line B - B. According to this Figure 9 the clamping edge recess 10 provided in the clamping edge 7 has a first depth 20. The annular recess 5 has a second depth 11. The housing connection bores 3 made in the recess bottom 6 have a third depth 12. In the exemplary embodiment shown, the first depth 20 of the clamping edge recess 10 corresponds to the sum of the second depth 11 of the annular recess 5 and the third depth 12 of the housing connecting bore 3 provided in the annular recess 5. The depths 20, 11 and 12 each extend in the axial direction 13 of the turbine housing.

Preferred general aspects of the invention are described below, the reference symbols referring to all of the aforementioned embodiments, but what has been said is not limited to any single embodiment, but rather can be combined with any desired embodiments and aspects.

According to one aspect, the flange thickness 19 of the connecting flange 2 is reduced due to the recesses 4 or 10 made in the connecting flange 2 in addition to the housing connecting bores 3, so that in comparison to the PRIOR ART The thermal transient stresses occurring in the connecting flange 2 are reduced, which leads to an extended service life of the turbine housing and thus of the entire turbocharger. This turbocharger has a turbine housing, as has been explained above.

According to a further aspect, this turbocharger has a bearing housing connected to the turbine housing, the turbine housing being connected to the bearing housing by means of connecting elements 15 introduced into the housing connection bores 3 of the turbine housing, which are for example screws or threaded pins.

According to a further aspect, the turbocharger has clamping elements implemented as clamping lugs 16, which are each pressed by one or more connecting elements onto the connecting flange 2 of the turbine housing and onto the bearing housing 14. The clamping elements are pressed against a clamping edge of the connecting flange. Instead of clamping tabs, clamping disks or clamping rings can also be used, for example. The clamping elements are preferably designed to be at least slightly elastic in order to be able to yield at least slightly when the nuts are tightened.

According to a further aspect, the spaced apart housing connection bores 3 in the connection flange 2 are arranged in the circumferential direction along at least one circle, preferably at most three or at most two (concentric to one another and / or to the turbine axis) and extend along the entire at least one circle, preferably over the entire circumference distributed at regular intervals. The number of housing connection holes required depends on the strength requirements in the event of damage (containment) and the tightness requirements.

According to a further aspect, the spaced apart housing connection bores 3 in the connection flange 2 can also be arranged in the circumferential direction along two or more circles, for example every second housing connection bore 3 being arranged along a first circle and each intervening housing connecting bore 3 is arranged along a second circle.

According to one aspect, the flange has at least five housing connection bores 3 and / or at least two, preferably at least four, particularly preferably at least five of the material recesses 4 between adjacent housing connection bores 3.

According to a further aspect, 3 material recesses 4 are provided between all housing connecting bores. The material recesses 4 are open radially inward. The material recesses 4 are preferably closed in the axial direction by a (e.g., ring-shaped) rear side of the connecting flange, so they are not continuous in the axial direction.

As an alternative to this, material recesses 4 cannot be provided between all the housing connecting bores 3, but only where the influence on the service life is relevant, for example in the area of the entry into the spiral.

According to one aspect, the flange is arranged coaxially to the longitudinal center axis of the turbine housing.

According to a further aspect, the flange is oriented towards a bearing housing of the exhaust gas turbine or is arranged for the connection of the turbine housing to the bearing housing (optionally with part of a heat shield and / or a diffuser ring between the flange and the corresponding part of the bearing housing).

According to one aspect, the recess 4 has an arc length in the circumferential direction of more than half the distance between the centers of the two housing connection bores 3.

According to one aspect, the connecting flange 2 has connecting webs 19 which, at least in sections, directly connect the housing connecting bores 3 and which are arranged in the circumferential direction between the adjacent housing connecting bores 3 and the material recess 4 lying therebetween.

According to one aspect, the connection flange 2 has a clamping edge 7 which is arranged adjacent to the housing connection bores 3 in the radial direction 8.

According to one aspect, the connecting webs 19 run radially inward, starting from the clamping edge 7. The clamping edge can be provided as a separate part of the turbine housing or be provided in one piece with the rest of the turbine housing or connecting flange.

According to one aspect, the turbine housing can be designed in several pieces. In this case, a heat shield or a nozzle ring can form a separate part of the turbine housing. In this case, the clamping edge of the turbine housing can be part of the heat shield or the nozzle ring, i.e. it can be integrated into the heat shield or the nozzle ring.

According to one aspect, the connecting webs are arranged recessed in the axial direction with respect to the clamping edge 7. In other words, the clamping edge protrudes (for example by less than 1 mm or even by at most 0.5 mm and / or by more than 0.1 mm) in the axial direction beyond the connecting webs (for example in the direction away from the turbine housing or towards to the bearing housing of the exhaust gas turbine). Accordingly, the connecting webs form part of a recess bottom. According to one aspect, the material recesses 4 provided between each two adjacent housing connection bores are arranged so as to be deeper than the connection webs in the axial direction.

According to one aspect, the clamping edge can run continuously (without interruption) in the circumferential direction or have recesses.

According to one aspect, the connecting flange 2 has an annular recess 5 which has a recess bottom 6.

According to one aspect, the adjacent housing connecting bores 3 are made in the recess bottom.

According to one aspect, the material recesses 4 provided between each two adjacent housing connecting bores are provided in the recess bottom.

List of reference symbols

1

Turbine housing

2

Connecting flange

3

Housing connecting hole

4th

Material recess

5

annular recess in the connecting flange

6th

Recess bottom

7th

Clamping edge of the connection flange

8th

Radial direction

9

Circumferential direction

10

Clamping edge recess

11

Depth of the annular recess 5

12

Depth of the housing connection holes 3

13

Axial direction; Direction of the longitudinal center axis of the turbine housing

14th

Bearing housing

15th

Connecting element

16

Clamping element

17th

mother

18th

Washer

19th

Connecting bridge

20th

Sum of the depth of the annular recess 5 and the depth of the housing connecting bores 3

21st

Longitudinal central axis of the turbine housing

Claims (15)

Turbine housing (1) for an exhaust gas turbine, which has a connecting flange (2) for connection on the bearing housing side to a bearing housing, in which housing connection bores (3) spaced apart in the circumferential direction (9) are provided, with housing connection bores adjacent to one another radially inwards towards Material recesses (4) open to a longitudinal center axis of the turbine housing are provided in the connecting flange. Turbine casing according to Claim 1, in which the casing connecting bores (3) which are spaced apart from one another are arranged in the connecting flange (2) in the circumferential direction (9) along at least one circle. Turbine casing according to Claim 2, which has a clamping edge (7) which is arranged adjacent to the casing connecting bores (3) in the radial direction (8). Turbine housing according to Claim 3, in which the adjacent housing connecting bores (3) are at least partially surrounded by connecting webs (19) which are arranged recessed in the axial direction (13) of the turbine housing opposite the clamping edge (7), the material recesses provided between each two adjacent housing connecting bores (4) are arranged recessed opposite the connecting webs (19) in the axial direction (13) of the turbine housing. Turbine housing according to Claim 4, in which the clamping edge (7) in the area between two adjacent housing connecting bores (3) each has a clamping edge recess (10) which widens the annular recess (5). Turbine housing according to Claim 5, in which a first depth (20) of the clamping edge recess (10) with the sum of a second depth (11) of the annular recess (5) and a third depth (12) of the housing connecting bores (3) provided in the annular recess matches, these depths extending in the axial direction (13) of the turbine housing. Turbine housing according to one of the preceding claims, wherein the turbine housing is constructed in several pieces. Tubine housing according to Claim 7, in which the clamping edge (7) forms a separate component of the turbine housing. Turbine casing according to Claim 7, in which a heat shield or a nozzle ring forms a separate component of the turbine casing. Turbine casing according to Claim 9, in which the clamping edge (7) is part of the heat shield or the nozzle ring. Exhaust gas turbine (15) which has a turbine housing (1) according to one of Claims 1 to 10. The exhaust gas turbine according to claim 11, which has a bearing housing (14) connected to the turbine housing (1), the turbine housing being connected to the bearing housing by means of connecting elements (15). Exhaust gas turbine according to Claim 12, which has clamping elements (16) which are each pressed by one or more connecting elements (15) onto the connecting flange (2) of the turbine housing (1) and onto the bearing housing (14). Exhaust gas turbine according to Claim 11, in which the clamping elements (16) are pressed against the clamping edge (7). Exhaust gas turbine according to one of Claims 11-14, in which the connecting elements (15) are screws or threaded pins.

Images