EP2379864A1

EP2379864A1 - Connection assembly of a turbine housing to a bearing housing and exhaust gas turbocharger

Info

Publication number: EP2379864A1
Application number: EP10701316A
Authority: EP
Inventors: Joachim Siegfried Delitz
Original assignee: IHI Charging Systems International GmbH
Current assignee: IHI Charging Systems International GmbH
Priority date: 2009-01-17
Filing date: 2010-01-14
Publication date: 2011-10-26
Also published as: JP2012515295A; JP5340416B2; CN102282349A; WO2010081697A1; DE102009005013A1; DE102009005013B4; US8827638B2; RU2486352C2; CN102282349B; US20110299983A1; RU2011133951A

Abstract

The invention relates to a connection assembly (30) of a turbine housing (14') to a bearing housing (12') of an exhaust gas turbocharger, wherein said turbine housing (14') and said bearing housing (12') are centered relative to one another and connected to one another in the region of a connection joint (19') by way of a sealing assembly (20') and wherein a heat shield (18') is provided between said turbine housing (14') and said bearing housing (12"), wherein at least one recess (42) is provided for a centering means (32) in said heat shield (18') by means of which the turbine housing (14') and the bearing housing (12') are directly centered relative to one another, and to an exhaust gas turbocharger.

Description

Connecting arrangement of a turbine housing with a bearing housing and

turbocharger

The invention relates to a connection arrangement of a turbine housing with a bearing housing of an exhaust gas turbocharger according to the preamble of patent claim 1 and an exhaust gas turbocharger according to the preamble of patent claim 10.

Such a connection arrangement is already known and shown in Fig. 1.

1 shows a connection arrangement 10 of a turbine housing 14 with a bearing housing 12 of an exhaust gas turbocharger. In this case, the turbine housing 14 is centered on the bearing housing 12 by means of a centering collar 21.

When connecting the two housings by means of a V-band clamp 16 naturally results in a connecting joint 19, which requires a seal.

The sealing of the joint 19 is realized such that the turbine housing 14 and the bearing housing 12 with a heat shield 18 form a seal assembly 20, whereby leakage of a turbine, not shown in the turbine housing 14 driving exhaust gas is prevented from the exhaust gas turbocharger out into the environment.

In Fig. 1, this seal assembly between the turbine housing 14, bearing housing 12 and heat shield 18 is denoted by the reference numeral 20. The illustrated sealing arrangement 20 also realizes positioning of the heat shield 18 by axial and radial contact with the turbine housing 14. In addition, the heat shield 18 has the purpose of avoiding or at least reducing excessive heat input from the hot exhaust gas flowing through the turbine housing 14 into the bearing housing 12.

Due to the fact that the bearing housing 12 made of the material gray cast iron and the turbine housing 14 are made of the material cast steel, the turbine housing has a higher thermal expansion coefficient. This results in the disadvantage of the prior art shown in Fig. 1, which takes place due to the different thermal expansion coefficients, a different thermal expansion of the two housings.

Due to the positioning of the heat shield 18 more in the axial direction toward the turbine housing 14, whereby the seal assembly 20 is not centered to the V band clamp 16, at extreme temperature differences due to the different thermal expansions of the housing, a gap, the V band clamp insufficient or even can not compensate. The result may be a gas leak, and exhaust gases may leak from the exhaust gas turbocharger into the environment.

Furthermore, the different thermal expansions of the housing are reinforced by the fact that due to the unfavorable positioning of the heat shield 18, the turbine housing 14 heats up more than the bearing housing 12.

Furthermore, due to this higher heat input, a curvature of the surfaces of the heat shield 18 that are in contact in the sealing arrangement 20 can occur, which results in gas leakage.

It is therefore an object of the present invention, a connection arrangement of the type mentioned in such a way that a gas leakage avoided and at the same time a centering of the two housings is possible with each other.

This object is achieved by a connection arrangement with the features of patent claim 1 and by an exhaust gas turbocharger with the features of claim 10. Advantageous embodiments with expedient and non-trivial developments of the invention are specified in the dependent claims.

Such a connection arrangement according to the invention of a turbine housing with a bearing housing of an exhaust gas turbocharger, in which the turbine housing and the Bearing housing centered with each other and are connected to each other in the region of a joint via a seal assembly, and in which a heat shield is provided between the turbine housing and the bearing housing, provides that in the heat shield at least one recess for a centering means is provided, through which the turbine housing and the bearing housing are centered directly with each other.

Such an arrangement allows advantageous positioning of the heat shield and the seal assembly, thereby preventing gas leakage. Thus, no exhaust gas flowing through the turbine housing and driving a turbine of the exhaust gas turbocharger can flow out of the exhaust gas turbocharger into the environment through an exhaust gas aftertreatment system without being cleaned. The exhaust gas remains in the exhaust gas turbocharger and is passed through a corresponding exhaust gas piping to the exhaust gas aftertreatment system, where it is cleaned and only then flows through an exhaust into the environment.

In a connection arrangement according to the invention, it is also possible to center the turbine housing and the bearing housing together. As a result, a better radial alignment of the housing is ensured to each other, whereby a risk of tarnishing of the turbine wheel of the exhaust gas turbocharger is reduced.

Preferably, a plurality of recesses for a centering means are provided in the heat shield. However, it is also conceivable that only one recess is provided, which, however, would then have to extend over a relatively large portion of the circumference of the heat shield in order to allow sufficient centering by the centering means.

The centering means is preferably a centering collar, wherein according to the invention the bearing housing and the turbine housing are centered with each other by means of an outer circumferential surface of the bearing housing and a corresponding inner lateral surface of the turbine housing. Nonetheless, alternative centering means and / or a reversal of the described inner circumferential surface to outer circumferential surface reference are conceivable.

For a very good centering, it is accordingly desirable to ensure that the largest possible parts of the outer lateral surface and the inner lateral surface are in contact with each other. In an advantageous embodiment of the connection arrangement, therefore, the at least one recess of the heat shield is formed as an at least partially circumferential gap in the radial outer surface of the heat shield. As already mentioned, this gap should run around the largest possible portion of the circumference of the heat shield in order to achieve a very good centering.

In a further advantageous embodiment, the heat shield has a plurality of recesses in the form of a respective partially circumferential gap in its radial lateral surface. This is advantageous insofar as on the one hand a very good centering of the housing is made possible by these recesses, on the other hand, the heat shield has a further good stability.

The mentioned stability of the heat shield with at the same time very good design of a sealing arrangement with a very good sealing effect to prevent gas leakage is realized in the connection arrangement according to the invention such that the heat shield has at least one, but in an advantageous embodiment, a plurality of connecting webs, a body of the heat shield, which represents a cylinder-like part of the heat shield, connects with a brim-shaped part of the heat shield, wherein the brim-shaped part with corresponding surfaces of the turbine housing and the bearing housing forms the seal assembly.

By this embodiment, on the one hand, a very good shielding of the heat from the bearing housing through the heat shield is achieved, on the other hand, a very good sealing effect is achieved.

In order to further positively influence these effects of the seal and the shielding, a defined positioning and / or centering of the heat shield in the turbine housing or in the bearing housing is necessary. This is inventively realized by a paragraph of the respective housing, by means of which the heat shield is centered.

The described positioning and Zentriermöglichkeiten the individual components in addition to the mentioned advantageous radial and extremely advantageous axial alignment of the components, and in particular of the turbine housing and the bearing housing realized, whereby the risk of tarnishing of the turbine wheel is further reduced. In a further advantageous embodiment of the invention, the sealing arrangement of the described brim-shaped part of the heat shield and from corresponding surfaces of the turbine housing and bearing housing within, in particular centrally, of a region arranged by an axial extension of a connecting device between the bearing housing and the turbine housing in the direction of Bearing housing is defined on the one hand and in the direction of the turbine housing on the other.

This connecting device is designed, for example, as a clamp and in particular as a V band clamp. If the described sealing arrangement is positioned as described, this results in the advantage that a gas leakage and thus leakage of unpurified exhaust gas into the environment is avoided.

The reason of such gas leakage is that the bearing housing is made of a different material than the turbine housing. If the bearing housing, for example, gray cast iron, and the turbine housing consists of cast steel, so the turbine housing has a higher coefficient of thermal expansion. This has the consequence that both housings expand to different extents, whereby a connecting joint between the two connected housings, which actually by the connecting device, d. H. the V-band clamp, to be kept low, gets bigger. This is reinforced by a different degree of heating of the housing.

Due to the described, preferably central positioning of the seal assembly with respect to the connecting device different thermal expansions of the housing are avoided, whereby gas leakage and thereby undesirable pollution of the environment is prevented. At the same time, however, as described, a centering of the bearing housing and the turbine housing is made possible by recesses in the heat shield.

In addition, a heat shield of the heat shield from the bearing housing over the turbine housing through which the hot exhaust turbine housing is significantly improved by the positioning of the seal assembly according to the invention, whereby it does not come to large different thermal expansion of the housing, as is the case for example in conventional connection arrangements.

Nevertheless, a risk of buckling of the corresponding sealing surfaces in the seal assembly, which would result in gas leakage, is significantly reduced. The connection arrangement according to the invention is not restricted to single-flow turbine housings, but can also be used with multi-flow turbine housings. Furthermore, the use is also possible with housing parts made of materials other than those mentioned.

In an advantageous embodiment of the invention, the bearing housing on Freimachungen that provide space for the at least one connecting web of the heat shield. As a result, the positioning of the heat shield is further positively influenced.

Another advantageous aspect of the invention is that the costs compared to a conventional connection arrangement are little to no negative impact, because so all the advantageous embodiments without costly and / or additional manufacturing steps can be realized. It should be mentioned at this point that the connection arrangement according to the invention can also be used, for example, in multi-part housings, in particular bearing housings.

The use of the connection arrangement according to the invention in an exhaust gas turbocharger of an internal combustion engine proves to be extremely advantageous because unwanted emissions of unpurified exhaust gas and thus additional pollution of the environment, for example due to increased NO _x emissions, can be avoided.

Further advantages, features and details of the invention will become apparent from the following description of a preferred embodiment and from the drawings. The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or in the figures alone can be used not only in the respectively specified combination but also in other combinations or in isolation, without the scope of To leave invention. The figures show in:

Fig. 1 is a perspective view and a longitudinal sectional view of a

Connecting arrangement according to the prior art, Fig. 2 is a perspective view and a longitudinal sectional view of a

Connecting arrangement of a turbine housing with a bearing housing and

Fig. 3 is a perspective view and another longitudinal sectional view of

Connecting arrangement of FIG. 2.

While Fig. 1 shows a connection arrangement of a turbine housing with a bearing housing of an exhaust gas turbocharger according to the prior art, in which a heat shield and thus a seal assembly from the bearing housing, the turbine housing and the heat shield in the axial direction to the turbine housing is positioned and thus outside a connecting device 2 shows a connection arrangement of a turbine housing with a bearing housing of an exhaust gas turbocharger, in which said seal arrangement is positioned centrally to a connecting element and thus to the housings. Fig. 3 shows the connection arrangement of Fig. 2, wherein the longitudinal section lies in another plane of the connection arrangement, whereby further aspects of the connection arrangement of Fig. 2 are shown.

Fig. 2 shows a connection arrangement 30, in which a bearing housing 12 'with a turbine housing 14' by means of a connecting device in the form of a V-band clamp 16 'are interconnected.

Between the bearing housing 12 'and the turbine housing 14', a heat shield 18 'is arranged, which on the one hand serves the purpose of shielding a large heat due to a hot, the turbine housing 14' flowing through and an unillustrated turbine exhaust gas from the bearing housing 12 ^* ,

This task is largely realized by a cylindrical main part 36 of the heat shield 18 '.

On the other hand, the heat shield 18 'forms a sealing arrangement 20 "via a brim-shaped part 38 with the bearing housing 12" and the turbine housing 14', which seals a connecting joint 19 'as a result of connecting the bearing housing 12' to the turbine housing 14 ' that the turbine housing 14 'flowing unpurified exhaust gas does not escape into the environment, but via a corresponding Exhaust piping is guided to an exhaust aftertreatment system in an exhaust system and cleaned there.

Due to the embodiment of the heat shield 18 'shown in FIG. 2, a positioning of the seal arrangement 20' is possible such that the seal arrangement 20 'is arranged centrally in an area which is defined by an axial extent of the V band clamp 16' in the direction of the bearing housing 14 On the one hand and in the direction of the turbine housing 12 'on the other hand defined. This described range is illustrated by the lines 40 and 41.

By such positioning of the seal assembly 20 ', a sealing effect of this seal assembly 20' from corresponding sealing surfaces of the heat shield 18 ', the bearing housing 12' and the turbine housing 14 "significantly increased because different thermal expansion of the bearing housing 12 'and the turbine housing 14' due to different materials can not occur.

In addition, the heat shield of the heat shield 18 is improved by an enlargement of the cylindrical portion 36 of the heat shield 18 '.

In addition, the radial alignment of the housing is optimized by the connection arrangement 30 shown in FIG. 2.

A centering of the bearing housing 12 'with the turbine housing 14' takes place in the connection arrangement 30 of FIG. 2 via a centering surface 32 of the bearing housing 12 'with a corresponding not shown in this illustration, centering surface of the turbine housing. As can be seen, the heat shield 18 "openings 42 in the form of each of a partially circumferential gap in its radial lateral surface, ie the cylindrical part 36, on.

To connect the brim-shaped part 38 with the cylindrical part 36 of the heat shield 18 ", the heat shield has connecting webs 34, which each lead through a corresponding franking of the bearing housing.

A centering of the heat shield 18 'is realized by means of a shoulder 37 of the turbine housing 14'. Thus, the said components are not only optimally set axially, but also radially. Alternatively, the radial attachment of the heat shield 18 'may also be otherwise, for example, by a corresponding shoulder or collar not in the turbine housing 14 ', but in the bearing housing 12' done.

The centering of the housing is not shown in Fig. 2, since the section shown by a connecting web 34 leads.

The centering of the bearing housing 12 'with the turbine housing 14' is shown in Fig. 3, in which the longitudinal section through a centering surface 32 leads.

FIG. 3 shows the connection arrangement 30 from FIG. 2, likewise in a perspective and in a longitudinal sectional view, wherein in FIG. 3 further aspects of the connection arrangement 30 are illustrated by the different guidance of the section described with reference to FIG.

The centering of the bearing housing 12 'with the turbine housing 14' via the centering surface 32 of the bearing housing, which is designed as an outer lateral surface and which is in contact with a corresponding inner lateral surface of the turbine housing 14 ', can now be seen in the longitudinal sectional view in FIG. The centering of the two housings thus takes place via a centering collar.

The longitudinal sectional view in Fig. 3 first contemplates the impression that the heat shield 18 'is formed in two parts, wherein a part through the cylindrical part 36 of the heat shield 18' and the second part through the brim-shaped part 38 of the heat shield 18 'is shown. This bipartite nature of the heat shield 18 'could be a tribute to the intended described centering of the housings while positioning the seal assembly 20' in the middle of the region of the V-band clip 16 'delimited by the lines 40 and 41.

However, only in combination with the longitudinal sectional view of Fig. 2 is clear that a bipartite of the heat shield 18 'is not necessary and still the described positioning can be maintained together with the described centering.

This is in the manner described by the openings 42 of the heat shield 18 ', by the connecting webs 34 and by the corresponding clearances on the bearing housing 12' allows.

Claims

claims

1. connection arrangement (30) of a turbine housing (14 ') with a bearing housing (12') of an exhaust gas turbocharger, in which the turbine housing (14 ') and the bearing housing (12') centered together and in the region of a connecting joint (19 ') via a Sealing arrangement (20 ') are interconnected, and in which between the turbine housing (14') and the bearing housing (12 ') a heat shield (18') is provided, characterized in that in the heat shield (18 ') at least one recess ( 42) is provided for a centering means (32) through which the turbine housing (14 ') and the bearing housing (12') are directly centered with each other.

2. Connecting arrangement (30) according to claim 1, characterized in that the at least one recess (42) as at least partially circumferential gap (42) in the radial outer surface (36) of the heat shield (18 ') is formed.

3. Connection arrangement (30) according to any one of claims 1 or 2, characterized in that the heat shield (18 ") by means of a shoulder (37) of the turbine housing (14 ¹ ) or the bearing housing (12 ') is centered.

4. Connecting arrangement (30) according to one of the preceding claims, characterized in that the bearing housing (12 ') and the turbine housing (14') by means of a Outer shell surface of the bearing housing (12 ') and a corresponding inner circumferential surface of the turbine housing (14') are centered with each other.

5. Connecting arrangement (30) according to any one of the preceding claims, characterized in that the sealing arrangement (20 ') within, in particular centrally, a region is arranged, which by an axial extension of a connecting device (16') between the bearing housing (12 ') and the turbine housing (14 ') in the direction of the bearing housing (12') on the one hand (40) and in the direction of the turbine housing (14 ') on the other hand (41) is defined.

6. Connecting arrangement (30) according to claim 5, characterized in that the connecting device (16 ") comprises a clamp (16 '), in particular a V-band clamp (16').

7. Connecting arrangement (30) according to any one of the preceding claims, characterized in that the heat shield (18 ') has at least one connecting web (34).

8. Connecting arrangement (30) according to one of the preceding claims, characterized in that on the bearing housing (12 ¹ ) clearances for the at least one connecting web (34) of the heat shield (18 ') are provided.

9. Connecting arrangement (30) according to any one of the preceding claims, characterized in that the turbine housing (14 ') is formed mehrflutig.

10. Exhaust gas turbocharger with a connection arrangement (30) according to one of the preceding claims.