EP2821596A1 - Air intake a compressor of an exhaust gas turbocharger - Google Patents

Abstract

The inlet cone on the air inlet housing of a compressor is locally targeted weakened in the potential contact area to the insert wall of the compressor by external, axially guided notches. The notches are introduced outside to a residual depth of 1 to 3 mm in the inlet cone, so that the flow channel to the outside limiting wall of the inlet cone remains intact from the inside. In the region of the notches, predetermined breaking points are thus formed, which give way under load. In the local impact area of the wall, there is a concentration of stress during the impact. The compressive stresses caused by the impact lead to breakage of at least one of the predetermined breaking points, whereby the continuous annular cross section is canceled in the exit plane of the air inlet housing. As a result, the compressive stresses can no longer be distributed over the annular cross-section of the inlet cone interrupted by the at least one breakage point. It comes to the failure and breaking out of individual segments of the inlet cone. By breaking off individual, limited by predetermined breaking points segments from the inlet cone of the transmitted to the entire air inlet housing axial pulse is reduced by energy is dissipated by deformation and sufficient path for the deformation of the wall insert is provided.

Description

Technical area

The invention relates to the field of supercharged internal combustion engines. It relates to an air inlet housing, in particular a filter silencer or an air intake, a compressor of an exhaust gas turbocharger and a compressor with such an air inlet housing.

Turbochargers have an air inlet housing. This is usually either a filter silencer or an air suction. Which variant is used differs depending on the cable routing on the motor and is determined by the motor manufacturer. From the manufacturers of the turbocharger usually both air intake variants are offered for the same type of turbocharger.

The flow channel limiting inner contour of the air inlet housing in the area directly upstream of the compressor is performed as identical as possible in both variants of air inlet housings. The quality of the flow of the compressor wheel influences the thermodynamic behavior and thus the efficiency and the compressor stability of the turbocharger and the mechanical behavior, such as blade vibrations of the compressor wheel. Thus, from a fluid mechanical point of view, it is necessary that the flow of the compressor wheel is as homogeneous as possible and that only the lowest possible pressure losses occur. For modern turbochargers an inlet cone is used, which is the same for filter silencer and air intake. Thus, one obtains a similar flow state before the compressor for both air inlet variants.

In the event of a burst - bursting of the compressor wheel at high speed - it must be ensured due to safety regulations that no parts leave the turbocharger. When bursting the compressor wheel, the leading edge of the insert wall is displaced axially in the direction of air inlet due to plastic deformation. As a result, the gap between the exit plane of the inlet cone in the air inlet housing and the entrance level of the flow channel in the wall insert and it can come to the contact between the wall insert and the air inlet housing in the region of the inlet cone. In this case, the insert wall transmits an axial impulse to the air inlet housing when impacting on the inlet cone. This can lead to breaking of the mounting flange on the air inlet housing or failure of the screw on this flange

An embodiment is required for the air inlet channel, which minimizes the axial pulse occurring in the containment case on the air inlet housing, without which the flow of the compressor is disturbed appreciably.

One option would be to increase the gap between the exit plane of the inlet cone in the air inlet housing and the inlet plane of the flow channel in the wall insert. Due to an increased gap between the exit plane of the inlet cone in the air inlet housing and the inlet level of the flow channel in the wall insert occurs only with large plastic deformation of the wall insert to the contact wall between inlet wall and inlet cone. The disadvantage is potentially higher flow losses and thus a lower compressor efficiency.

• Versagen des Flansches des Lufteintrittsgehäuses
• Bruch von Schrauben in der Flanschverbindung
• Absprengen der Lufteintrittsgehäuses-Struktur vom Turbolader

Another option would be to locally weaken the inlet cone in the potential contact area by axial slots. The continuous annular cross-section in the exit plane of the air inlet housing is canceled by the axial slots. In the local impact area of the insert wall, a stress concentration occurs during the impact. The compressive stresses caused by the impact can no longer be distributed over the annular cross-section of the inlet cone (interrupted by the slots). It comes to the failure and breaking out of individual segments of the inlet cone. This is a wanted effect. By breaking individual segments out of the inlet cone (one segment running from slot to slot), the axial momentum transmitted to the entire air inlet housing is reduced by dissipating energy through deformation and providing sufficient travel for deformation of the insert wall. The following risks relevant to containment are thus reduced:

• Failure of the flange of the air inlet housing
• Breakage of screws in the flange connection
• Blowing off the air intake housing structure from the turbocharger

However, since the flow of the compressor wheel is disturbed by the slots and pressure losses are generated by the slots, this measure has a negative impact on the compressor efficiency. In addition, through the slots, the mechanical load of the compressor blades can be increased, since it can come to an additional flow-induced vibration excitation of the compressor blades.

Brief description of the invention

The object of the present invention is to optimize the inflow region of the compressor of an exhaust gas turbocharger to the effect that the structural load can be minimized in case of bursting while maintaining a high quality of the flow.

According to the invention, this is achieved by local weakening of the inlet cone on the air inlet housing in the potential contact area to the insert wall of the compressor by external, axially guided notches. The notches are introduced from the outside into the inlet cone to a residual depth, so that the wall of the inlet cone, which delimits the flow channel to the outside, remains intact from the inside. In the region of the notches, predetermined breaking points are thus formed, which give way under load. In the local impact area of the wall, there is a concentration of stress during the impact. The compressive stresses caused by the impact lead to breakage of at least one of the predetermined breaking points, whereby the continuous annular cross section is canceled in the exit plane of the air inlet housing. As a result, the compressive stresses can no longer be distributed over the annular cross-section of the inlet cone interrupted by the at least one breakage point. It comes to the failure and breaking out of individual segments of the inlet cone. By breaking off individual, limited by predetermined breaking points segments from the inlet cone of the transmitted to the entire air inlet housing axial pulse is reduced by energy is dissipated by deformation and sufficient path for the deformation of the wall insert is provided.

Thus, the advantages of the known design are used with slots, but without having to accept its disadvantages.

Further advantages emerge from the dependent claims.

Brief description of the drawings

Fig. 1

eine Gesamtansicht eines Abgasturboladers gemäss dem Stand der Technik mit einem Verdichter, umfassend, schematisch angedeutet, zwei unterschiedliche Lufteintrittsgehäuse, einen Filterschalldämpfer und einen Luftansaugstutzen

Fig. 2

den Grundkörper eines Filterschalldämpfers mit einem erfindungsgemäss ausgebildeten Einlaufkonus,

Fig. 3

einen Luftansaugstutzen mit einem erfindungsgemäss ausgebildeten Einlaufkonus, und

Fig.4

einen im Bereich IV geführten axialen Schnitt durch den Lufteintritt eines Verdichters nach Fig. 1 mit erfindungsgemäss ausgebildetem Einlaufkonus.

The invention will be explained in detail with reference to figures. This shows

Fig. 1

an overall view of an exhaust gas turbocharger according to the prior art with a compressor, comprising, schematically indicated, two different air inlet housing, a filter muffler and an air intake

Fig. 2

the main body of a filter muffler with an inventively designed inlet cone,

Fig. 3

an air intake with an inventively designed inlet cone, and

Figure 4

a guided in the area IV axial section through the air inlet of a compressor after Fig. 1 with inventively designed inlet cone.

Way to carry out the invention

Fig. 1 shows a side view of a conventional exhaust gas turbocharger with compressor 1 and exhaust gas turbine 3. The compressor comprises a compressor disposed in the compressor housing 10 compressor wheel, the turbine disposed in the turbine housing 30 turbine wheel. Between the turbine and the compressor, the bearing housing 40 is arranged. The housing of the exhaust gas turbine 3 comprises a gas inlet 31, through which the hot exhaust gas flows onto the turbine wheel and drives it, before the exhaust gas is supplied through the gas outlet 32 of the exhaust system.

The turbine wheel is arranged at one end of a rotatable about the axis A turbocharger shaft, which is rotatably mounted in the bearing housing 40. At the other end of the turbocharger shaft is the compressor wheel, which compresses air drawn in through the air inlet 11, which is subsequently collected in a spiral or collector housing and fed via the air outlet 12 to the combustion chambers of the internal combustion engine. The air can be supplied to the intake area of the compressor via a tubular air intake 22 (in the Fig. 1 indicated in the left half above the axis A) or via a silencer 21 (in the Fig. 1 in the left half below the axis A indicated) are supplied. The muffler may additionally comprise filter elements which prevent the entry of larger particles in prevent the compressor. In this case, we talk about a filter silencer.

Fig. 2 shows the cylindrical base body 210 of a filter muffler without inserted damping elements and without attached filter element. The main body is either a monobloc (casting) or a component composed of several individual parts. In the present case, the base body has a closed end-side front wall 211 and a rear wall 212 with a central air outlet opening 213. To the lateral surface of the cylindrical body is usually a filter element through which the air flows into the interior of the filter muffler and there approximately in the radial direction along the grooves provided in 214 arranged damping elements in a central cavity. After a deflection in the axial direction, the air flows through the central air outlet opening 213 in the rear wall 212 along the inlet cone 24 from the filter silencer into the inlet region of the compressor. In the inlet cone 24 according to the invention outboard notches 25 are embedded.

Fig. 3 shows an air intake which causes in the illustrated form, a deflection of the compressor supplied air flow from the radial direction in the axial direction. The air intake 22 has two mounting flanges, an inlet-side mounting flange 221 with holes for receiving fasteners and the exit-side mounting flange with holes for receiving fasteners. On the inlet side, a supply line is connected to the flange, on the outlet side, the air intake is attached to the compressor housing. In the outlet region, the air intake 22 has an inlet cone 24, which directs the flow in the inlet region of the compressor. In the inlet cone 24 according to the invention outboard notches 25 are embedded.

The recessed into the inlet cone 24 of the filter muffler or the air intake notches 25 are based Fig. 4 explained in detail.

The inlet cone 24 on the air inlet housing 2 (filter muffler or air intake) is weakened locally targeted in the potential contact area to the wall of the compressor by external, axially guided notches 25. The notches are introduced up to a residual wall thickness b from the outside into the inlet cone 24 with the wall thickness a, so that the flow channel S outwardly bounding wall of the inlet cone from the inside remains intact. In the region of the notches, predetermined breaking points are thus formed, which give way under load.

When bursting the compressor wheel, the leading edge 151 of the insert wall 15 is displaced axially in the direction of air inlet due to plastic deformation (in the figure to the left). As a result, the gap dimension c between the outlet plane F _{A of} the flow channel in the inlet cone 24 in the air inlet housing 2 and the inlet plane F _{E of} the flow channel in the insert wall 15 is used up and it can come to contact between the insert wall 15 and the air inlet housing 2 in the region of the inlet cone 24. In the local impact area of the wall, there is a concentration of stress during the impact. The compressive stresses caused by the impact lead to breakage of at least one of the predetermined breaking points, whereby the continuous annular cross section is canceled in the exit plane of the air inlet housing. As a result, the compressive stresses can no longer be distributed over the annular cross-section of the inlet cone interrupted by the at least one breakage point. It comes to the failure and breaking out of individual segments of the inlet cone. By breaking off individual, limited by predetermined breaking points segments from the inlet cone of the transmitted to the entire air inlet housing axial pulse is reduced by energy is dissipated by deformation and sufficient path for the deformation of the insert wall is provided.

The inlet cone is part of the air inlet housing 2 and usually integrated in the casting. In an advantageous embodiment, the inlet cone is designed with 8 axial notches. When bursting the compressor wheel is expected from experience with up to 4 larger fragments. A number of 8 notches is sufficient to achieve the desired effect of dividing the ring cross-section into segments which are then locally loaded. The notches are evenly distributed over the circumference. Optionally, the notches may be unevenly distributed around the circumference.

The depth of the notch is as large as manufacturing technology makes sense. The thinner the residual wall thickness b, the higher the manufacturing effort and the reject rate in the manufacture of the air inlet housing. As a rule, an optimum notch depth is likely to be around 70-90% of the mean wall thickness of the inlet cone along the notch, with the edges of the notch, which terminate obliquely in terms of production, not being taken into account for this purpose. With a starting wall thickness a of 11 mm would correspond to the mentioned value of 70-90% notch depth (depending on casting tolerances and used machining method) about a residual wall thickness of 1 to 3 mm. This is sufficient in order to obtain the desired failure pattern (breaking out of individual segments from the inlet cone) in the case of contact. In contrast to through slots, there is no negative effect on the flow since the flow-guiding geometry is not changed.

LIST OF REFERENCE NUMBERS

1

compressor

10

compressor housing

11

Air inlet into the air inlet housing (filter silencer or air intake)

12

Air outlet from the compressor

13

compressor

15

insert wall

151

leading edge

2

Air intake housing

21

(Filter) silencer

210

Main body of the filter silencer

211

Front wall of the filter silencer

212

rear wall

213

Central air outlet

214

Grooves for guiding / fastening damping elements

22

air intake

23

Mounting flange with holes for mounting fasteners

24

intake cone

25

notch

3

exhaust turbine

30

turbine housing

31

Gas entry into the turbine

32

Gas outlet from the turbine

40

bearing housing

A

Axis of the rotor (compressor wheel, turbine wheel, turbocharger shaft)

S

flow channel

F _A

Exit plane of the flow channel of the inlet cone

F _E

Entry level of the flow channel in the wall insert

a

Wall thickness of the inlet cone

b

Remaining wall thickness at the bottom of the score

c

Gap between the exit plane of the inlet cone and the entry level of the Flow channel in the wall insert

Claims (7)

Air inlet housing (2) of a compressor of an exhaust turbocharger, comprising an inlet cone formed by a housing wall of the air inlet casing (24) for supplying air in an intake region of the compressor, wherein the inlet cone encloses a flow passage which extends in the flow direction up to an exit plane of the inlet cone characterized characterized in that leaving a residual wall thickness (b) from radially outside notches (25) in the inlet cone (24) forming housing wall are embedded, which notches extending along the axial extent of the inlet cone. The air intake case of claim 1, wherein a plurality of notches are provided and the notches are distributed along the circumference. Air inlet housing according to claim 2, wherein the notches are arranged distributed uniformly along the circumference. Air inlet housing according to one of claims 1 to 3, wherein the notches has a depth of 70-90% of the average wall thickness (a) of the housing wall forming the inlet cone (24), wherein the mean wall thickness (a) is the average wall thickness along the notch. Air inlet housing according to one of claims 1 to 4, wherein the air inlet housing is a silencer (21). Air inlet housing according to one of claims 1 to 4, wherein it is the air inlet housing to an air intake (22). Compressor of an exhaust gas turbocharger, comprising an air inlet housing according to one of claims 5 or 6.

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