DE102007031647A1 - Exhaust gas turbocharger for internal combustion engine, has gas turbine and fresh air compressor, where one face of each vane forms labyrinth seal with opposite limiting surface - Google Patents

Abstract

The exhaust gas turbocharger has a gas turbine (1) and a fresh air compressor (2). The exhaust gas turbine and the fresh air compressor remain in drive connection with one another. Turbine rotor (1.1) of the exhaust gas turbine is surrounded by a collar of adjusting guide vanes (4). The guide vane collar is located in an exhaust gas flow channel between a carrier plate (5) and a turbine casing (6). One face of each vane forms a labyrinth seal with the opposite limiting surfaces.

Description

The invention relates to the field of exhaust gas turbochargers. See for example WO 00/73630 A1 ,

turbocharger are indispensable in modern motor vehicles. They include as important components a turbine and a compressor. These two Components are generally seated on one and the same shaft or are at least in drive connection with each other. The turbine will the exhaust gas fed to an internal combustion engine. The exhaust gas drives the Turbine on. The turbine in turn drives the compressor. This sucks air from the environment and compresses it. The condensed Air is then used for combustion in the internal combustion engine. Exhaust gas turbochargers have the purpose of reducing exhaust emissions as well as to increase the efficiency of the engine and its torque. They also have an important function regarding the effect of the catalyst.

The Turbine includes a ring of vanes. The vanes are upstream of the turbine and in a flow channel arranged, which is traversed by exhaust gas. The vanes are adjustable. Its axis of rotation runs parallel to the said shaft of the exhaust gas turbocharger, or at least approximately parallel to this.

Of the Exhaust gas channel is limited by two surfaces. For one thing is This is a wall surface of a support ring, the Carrying shovels. On the other hand, this is the wall surface a so-called turbine housing. The two wall surfaces run substantially perpendicular to the shaft of the supercharger. The shovels range from wall surface to wall surface of the carrier ring or the turbine housing. Each face a blade is thus facing one of the two wall surfaces.

Between the faces of each blade and the wall surfaces there must be a certain amount of play left. The game must be enough be great to the mobility of the blade, that is their Twisting to allow their adjustment axis. It may However, do not be so big that between a face and the associated wall surface significant amounts Flow through the exhaust gas.

The Exhaust is very hot; the temperatures are between 650 ° C and 1100 ° C, occasionally over it. this leads to to a thermal expansion of the components involved. The Expansion can be different, both from component to component, as well as over the duration of the operation. This can cause the said game to zero disappears, and that it comes to clamping the blades. This in turn leads to significant dysfunctions, or even the failure of the loader.

Of the Invention is based on the object, an exhaust gas turbocharger according to the The preamble of claim 1 to be designed such that it neither to an inadmissibly large game between the faces the blades and the boundary walls, yet to one Jamming of the blades comes.

These The object is achieved with the features of claim 1.

Consequently become the facing surfaces - the End faces of the blades and the limiting wall surfaces of carrier ring and / or turbine housing - such designed to form a labyrinth seal with each other.

For this There are several options. So one of the two facing surfaces - for example the Boundary surface of the carrier ring and this facing end face of the individual blade - with Recesses be provided, and the other of the two mentioned Surfaces with projections. The projections grip into the recesses. A leakage current of the exhaust gas flow is therefore diverted. The deflection generates a flow resistance in a known manner and thus represents a barrier against leakage currents. Also two facing surfaces can be toothed mesh. In extreme cases, it can be enough one of the two surfaces with a certain roughness too Mistake.

Also can be a labyrinth seal on the two end faces each blade are formed, thus not just one-sided.

Becomes a labyrinth seal on a single side of the bucket provided, it may be advantageous to the bucket constantly or temporarily suspend an axial thrust, the Blade against the other, labyrinth seal-free boundary surface presses. In this way, the gap is in the range of Labyrinth seal enlarged but what According to the sealing effect of the labyrinth is irrelevant. however if the gap on the opposite side is reduced, if necessary, down to zero, so that there is no more leakage can occur.

The The invention is explained in more detail with reference to the drawing. The following is shown in detail:

1 shows an exhaust gas turbocharger in an axial section.

2 shows a blade with a view on one of their faces.

3 shows a blade in the installed state overlooking one of the two vanes of the blade, with a first labyrinth design.

4 shows a blade in the installed state with a view of one of the two guide surfaces of the blade, according to a second embodiment of the labyrinth design.

5 is a view of the support plate with a view in the axial direction on the boundary surface.

6 shows in perspective a turbine housing with a ring of vanes and associated adjusting.

7 shows a section of the object of 6 in an enlarged view.

The in 1 shown exhaust gas turbocharger has a turbine 1 and a compressor 2 on. The turbine rotor 1.1 and the compressor rotor 2.1 are on a wave 3 wedged and thus rotatably connected.

The turbine further includes a housing 1.2 , The housing comprises a helical inlet and an outlet 1.3 , The rotor 1.1 is a wreath of adjustable vanes 4 upstream. The vanes 4 are located in a flow channel. This is limited by a carrier plate 5 and a turbine housing 6 ,

Of the Sense of the labyrinth seal according to the invention exists among other things, that if possible no more trumpet must use. The trumpet becomes part of the turbine housing. The Limitation of the exhaust duct on the one hand is then the corresponding one Surface of the turbine housing.

During operation, the helical inlet of the housing 1.2 supplied an exhaust gas mass flow. This exhaust gas flow passes through the spaces between the vanes 4 through and reaches the rotor 1.1 , He leaves the case 1.2 through the outlet 1.3 ,

The compressor 2 draws in fresh air through an inlet port. This passes under increased pressure in a collecting space 2.3 , and from there to an internal combustion engine.

The vane 4 extends in the flow channel in the axial direction of the support plate 5 to the turbine housing 6 , The exhaust gas mass flow is intended solely through the spaces between the vanes 4 but not between the end faces of the vanes and the delimiting surfaces of the carrier plate 5 and turbine housing 6 , For this purpose is a touching concern between the two end faces of each vane 4 on the one hand and the carrier plate 5 or the turbine housing 6 desirable. Since it is due to the high operating temperatures to a thermal expansion of the vanes 4 - Also in the axial direction - comes, a labyrinth seal is provided according to the invention, in the region of at least one end face of each blade.

For this purpose, a recess in the respective boundary surface of the support plate 5 and / or the turbine housing 6 be provided. This is from the 2 and 3 seen. The shovel shown there 4 is located between a boundary surface 5.1 the support plate and a boundary surface 6.1 of the turbine housing. The boundary surface 5.1 the carrier plate is made of a pot-shaped recess 5.2 educated. In this recess engages the relevant end region of the vane 4 one. This is a labyrinth seal between said end face of the vane 4 and the boundary surface 5.1 the carrier plate 5 educated.

The vane 4 is dimensioned in the axial direction such that between the boundary surface 6.1 of the turbine housing 6 and there located end face of the vane 4 a minimal gap prevails. The gap located on the opposite side - thus between the local face and the boundary surface 5.1 - However, can be sized slightly larger, since there is the labyrinth seal.

The vane 4 has a drive shaft 4.1 on, with which they can be adjusted.

An interesting embodiment is in 4 shown. You can see there again a vane 4 , a support plate 5 and a turbine housing 6 , The boundary surface 5.1 However, the support plate is here - in this representation - designed meandering. The boundary surface 5.1 the carrier plate 5 is formed of concentric grooves and concentric ribs. The face of the vane 4 in the area of the carrier plate 5 is designed in a similar manner, thus also provided with grooves and ribs. The ribs of one of the two elements engages in corresponding grooves of the other of the two elements.

In this case, a device may be provided to bias the individual vanes in the axial direction. In the versions of the 3 and 4 could accordingly a Thrust on the vane in a minimization of the gap on the turbine housing 6 be made.

5 schematically illustrates a carrier plate 5 - Formed as a ring -, in plan view of the boundary surface 5.1 , It can be seen a plurality of cup-shaped recesses, analogous to that recess according to the 2 and 3 , The number of recesses corresponds to the number of vanes 4 ,

In 6 you recognize a turbine housing 6 , This is again with pot-like recesses 6.2 provided, according to the number of vanes 4 , Each vane has a shaft 4.1 on. An adjusting ring 7 is rotatable about its own axis. He reaches over handlebars 7.1 on the waves 4.1 the vanes 4 at.

7 again shows a partial view of a turbine housing 6 , some vanes 4 as well as the adjusting ring 7 and a handlebar 7.1 ,

The special feature of this embodiment consists in the following:
The turbine housing 6 is provided with a plurality of cup-shaped recesses - analogous to the embodiment according to the 2 and 3 , The associated end of each vane carries a plate 4.2 , Plate 4.2 and vane 4 are connected in one piece or non-rotatably. Every plate 4.2 is circular and the shape of the cup-shaped recess 6.2 adapted, thus the same size as this.

Also here could be plates 4.2 and cup-shaped recess 6.2 again analogous to 4 be designed so have concentric grooves and concentric ribs.

In the embodiment according to 7 forms the said plate, the end face of the individual blades, as defined in claim 1.

1

turbine

1.1

turbine rotor

1.2

turbine housing

1.3

outlet

2

compressor

2.1

compressor rotor

2.2

inlet port

2.3

plenum

3

wave the exhaust gas turbocharger

4

vanes

4.1

waves the vanes

4.2

Plate

5

support plate

5.1

boundary surface the carrier plate

5.2

cup-shaped recess

6

turbine housing

6.1

boundary surface of the turbine housing

6.2

cup-shaped recess

7

adjusting

7.1

handlebars

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• WO 00/73630 A1 [0001]

Claims (6)

Exhaust gas turbocharger for an internal combustion engine 1.1 with an exhaust gas turbine ( 1 ); 1.2 with a fresh air compressor ( 2 ); 1.3 Exhaust gas turbine ( 1 ) and fresh air compressor ( 2 ) are in driving connection with each other; 1.4 the rotor ( 1.1 ) of the exhaust gas turbine ( 1 ) is surrounded by a ring of adjustable vanes ( 4 ) surround; 1.5 the vane ring is located in an exhaust gas flow channel between a support plate ( 5 ) and a turbine housing ( 6 ), each having a limiting the flow channel boundary surface ( 5.1 . 6.1 ) exhibit; 1.6 each face of each vane ( 4 ) is one of the two boundary surfaces ( 5.1 . 6.1 facing); characterized by the following features: 1.7 at least one of the end faces of each blade ( 4 ) forms with the facing boundary surface ( 5.1 . 6.1 ) a labyrinth seal. Exhaust gas turbocharger according to claim 1, characterized in that that one of the two facing surfaces projections, and the other surface has recesses into which protrude the projections. Exhaust gas turbocharger according to one of the claims 1 or 2, characterized in that the labyrinth seal tooth-like has interlocking surfaces. Exhaust gas turbocharger according to one of claims 1 to 3, characterized in that a device for applying an axial thrust on the guide vanes ( 4 ) is provided. Exhaust gas turbocharger according to one of claims 1 to 4, characterized in that the end face of the individual blades of a circular body ( 4.2 ) is formed. Exhaust gas turbocharger according to claim 5, characterized in that the circular body is a circular plate ( 4.2 ).