DE102015007758A1 - Compressor, in particular for an exhaust gas turbocharger of an internal combustion engine - Google Patents

Abstract

The invention relates to a compressor (26), in particular for an exhaust gas turbocharger (24) of an internal combustion engine (10), having a compressor wheel (28) for compressing the air, which has at least one compressor blade, arranged in an air flowable flow channel of the compressor (26) an outlet edge over which the air flows during an operation of the compressor (26) from the compressor blade, wherein an actuating element (50) is provided, by means of which arranged at least at one upstream of the trailing edge point (A) pulsations of at least one property of the air flow a frequency of at least five hertz are effected.

Description

The invention relates to a compressor, in particular for an exhaust gas turbocharger of an internal combustion engine, according to the preamble of patent claim 1.

Such a compressor, in particular for an exhaust gas turbocharger of an internal combustion engine, for example, is already the DE 603 10 142 T2 to be known as known. The compressor has a flow channel through which air can pass and a compressor wheel arranged in the flow channel for compressing the air. The compressor wheel has at least one compressor blade with an outlet edge, via which the air flows out of the compressor blade during operation of the compressor.

In modern internal combustion engines for driving motor vehicles, especially passenger cars, usually exhaust gas turbochargers are used, which each comprise at least one compressor for compressing air. By means of the compressor air can be compressed, which is the respective internal combustion engine, in particular at least one combustion chamber such as a cylinder of the internal combustion engine, supplied. The compressor is also referred to as a flow compressor and may be formed for example as a radial compressor. Usually, the compressor has a so-called surge limit. This describes the smallest mass flow that the compressor is still able to promote against an applied higher pressure. If the mass flow falls below this limit, no stable operation of the compressor is possible. It then comes to unwanted compressor pumps. The compressor pumping is a periodically fluctuating between forward and reverse flow conditions in which the compressor blade, which is also commonly referred to as a bucket or impeller vane, may be damaged by excited vibrations. Furthermore, the internal combustion engine process is impaired, so that the internal combustion engine process can break down sharply. In addition, noise problems can occur, which are also referred to as NVH problems (NVH - Noise Vibration Harshness).

Object of the present invention is therefore to develop a compressor of the type mentioned in such a way that an improved position of the surge limit can be realized.

This object is achieved by a compressor having the features of patent claim 1. Advantageous embodiments with expedient developments of the invention are specified in the remaining claims.

In order to develop a compressor specified in the preamble of claim 1 type such that an improved surge limit, that is, an improved position of the surge limit can be realized according to the invention an actuator provided by means of which at least at one upstream of the trailing edge arranged location, in particular of the flow channel , Pulsations of at least one property of the air flow with a frequency of at least five hertz, preferably at least 20 hertz and advantageously in a range of 20 hertz to 500 hertz, are effected. Investigations have shown that, for example, in an engine operation of an internal combustion engine which comprises at least one exhaust gas turbocharger and a compressor, a different compressor pumping behavior occurs than in stationary operation of the internal combustion engine on a combustor test bench, at which a pulsation of a pressure of the air flow due to suction of Combustion chambers, in particular cylinders, the internal combustion engine is missing. Under the aforementioned engine operation is an operation of the internal combustion engine in its fully manufactured state, especially during the driving of a motor vehicle to understand. In such a real operation thus occurs a different compressor pumping behavior than during steady-state operation of a test stand for examining the internal combustion engine.

Theoretical considerations suggest that the pulsations can have a positive as well as a negative influence on the use of compressor pumps. The invention thus provides for positively influencing the air flow, in particular its inflow to the compressor wheel, by means of the actuating element of the compressor designed, for example, as a centrifugal compressor or axial compressor. The compressor can have exactly one compressor stage or a plurality of compressor stages, the compressor wheel being a compressor wheel of one of the compressor stages. By effecting the pulsations, the air flow is selectively and actively influenced, whereby the compressor pumps can be actively counteracted. This makes it possible, for example, to actively avoid the compressor pumps. As a result, an improved pumping limit or position of the pumping limit can be realized, so that higher torques of the internal combustion engine can be displayed, especially at low engine speeds. In addition, an improved exchange relationship, a so-called trade-off in the so-called matching of the exhaust gas turbocharger with the internal combustion engine can be realized, thereby optionally a higher performance, lower fuel consumption and improved response of the internal combustion engine can be realized.

By suitable expression of the actuating element, a defined fluctuation of at least one property of the air flow, that is to say at least one flow variable with the frequency, can be effected. The frequency corresponds, for example, to a frequency of pulsations at the outlet edge or in an outlet region of the compressor comprising the outlet edge or an integral multiple thereof. Alternatively, it is conceivable that in general a suitable frequency is chosen to counteract the compressor pumps.

The control element is, for example, an actuator which generates, for example, either a periodic throttling of the compressor inlet flow or a periodic pressure increase upstream of the compressor or in front of the compressor wheel. The pulsation of at least one property is in particular a rhythmically fluctuating, in particular periodic, process to understand, in the context of which the at least one property changes, for example recurrently or periodically, this change is actively effected by means of the control element.

As the property, for example, a mass flow and / or a pressure of the air flow by means of the control element with the frequency can be influenced.

It has proved to be advantageous if the compressor has a guide channel which is different from the flow channel and can be flowed through by a medium, via which the medium can be supplied to the flow channel at the location, wherein a pulsating inflow of the medium from the guide channel into the flow channel by means of the adjusting element at the point with the frequency is effected. Preferably, the medium is a gas, in particular air.

The named point is upstream, that is arranged in front of the trailing edge and can be arranged in particular upstream or in front of the compressor wheel. For example, the compressor blade has an inlet edge, via which the compressor blade is flown during the operation of the compressor of the air to be compressed. In this case, the location is arranged, for example, upstream of the leading edge. Alternatively, it is conceivable that the point upstream of the trailing edge and downstream of the leading edge and thus in the region of an outer contour of the compressor is arranged so that, for example, the outer contour of the compressor wheel is covered in the radial direction to the outside through the body. In this case, the guide channel, for example, at least one outlet opening, via which the guide channel opens at the point in the flow channel, so that the medium flowing through the guide channel medium can flow through the outlet opening at the point in the flow channel. If the point and thus the outlet opening are arranged between the outlet edge and the inlet edge, ie upstream of the outlet edge and downstream of the inlet edge, the outer contour of the compressor wheel is covered in the radial direction outwards by the outlet opening. To realize the pulsations can be provided that the guide channel by means of the adjusting element with the frequency is alternately openable and fluidic lockable.

For example, the guide channel at a downstream of the point, in particular downstream of the trailing edge, arranged second point with a flow-through air flow path, in particular the flow channel, fluidly connected, so that the guide channel at the second location, the air is supplied as the medium. In this case, the guide channel is designed as a return flow, so that, for example, the pressure increase described above comes about through at least one flow connection between a pressure and suction side of the compressor. This flow connection is clocked at the frequency mentioned periodically opened and closed, whereby the pulsations are effected. The flow connection is effected by the guide channel formed as a return flow channel. Downstream of the outlet edge, that is to say on the pressure side, a higher pressure prevails with respect to the suction side, so that the air flowing through the guide channel has a higher pressure than the air at the first location. As a result, the pressure increases or the pulsations can be realized. As already mentioned, the introduction of the air or of the medium takes place in a compressor housing along the wheel contour, that is to say between the inlet edge and the outlet edge, or from upstream of the inlet edge and thus upstream of the compressor wheel.

Preferably, the pulsations and the resulting fluctuations of at least one property with frequencies in the range of the ignition frequency of the combustion chambers of the internal combustion engine are effected so that the frequency is preferably in a range of from 5 Hertz up to and including 500 Hertz.

As an alternative or in addition to the embodiment of the guide channel as a return flow channel, it is conceivable that the guide channel is connected to a different source from the compressor which supplies different medium from the compressed air by means of the compressor, from which the medium can be fed to the feed channel. This source is for example one of the compressor different pressure accumulator of the motor vehicle. Furthermore, it is possible, especially at stationary applications to take in the periphery of the internal combustion engine air or air mass and introduce at the said first location with the appropriate frequency in the flow channel.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawing. 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 shown alone in the figures 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 drawing shows in:

1 a schematic representation of an internal combustion engine for a motor vehicle, with an exhaust gas turbocharger with a compressor which comprises an actuating element, by means of which arranged at least at one upstream of a trailing edge of a compressor wheel of the compressor pulsations at least one property of air flow with a frequency of at least five Hertz be effected , in which 1 shows a first embodiment of the internal combustion engine;

2 a schematic representation of the internal combustion engine according to a second embodiment; and

3 a schematic representation of the internal combustion engine according to a third embodiment.

In the figures, identical or functionally identical elements are provided with the same reference numerals.

1 shows in a schematic representation of a whole 10 designated internal combustion engine according to a first embodiment, wherein the internal combustion engine 10 is designed as a reciprocating internal combustion engine. The internal combustion engine 10 is for example part of a motor vehicle, in particular a passenger car, which by means of the internal combustion engine 10 is drivable. The internal combustion engine 10 includes a cylinder housing 12 , which has a plurality of combustion chambers in the form of cylinders 14 having. The internal combustion engine 10 Air-permeable intake tract 16 by means of which a medium in the form of air the cylinders 14 is supplied. Out 1 it can be seen that in the intake tract 16 an air filter 18 is arranged, by means of which the air, which the intake tract 16 flows through, is filtered, before the air enters the cylinder 14 flows. The cylinders 14 the air and fuel, in particular liquid fuel, supplied, so that in each cylinder 14 a fuel-air mixture is formed. The respective fuel-air mixture is burned, resulting in exhaust gas of the internal combustion engine 10 results. In this case, the internal combustion engine 10 an exhaust gas tract through which the exhaust gas can flow 20 on, by means of which the exhaust gas from the cylinders 14 is dissipated. Further, in the intake tract 16 a suction tube 19 arranged, by means of which the air on the cylinder 14 split and the cylinders 14 is supplied. The suction tube 19 acts as an air collector, by means of which the compressed air collected and on the cylinder 14 is distributed.

In the exhaust tract 20 is a manifold 22 arranged in which the exhaust gas from the cylinders 14 flows in and by means of which the exhaust gas from the cylinders 14 is dissipated. The internal combustion engine 10 further comprises an exhaust gas turbocharger 24 , which one in the intake tract 16 arranged compressor 26 includes. The compressor 26 is in the intake tract 16 arranged and includes an in 1 unrecognizable compressor housing and arranged in the compressor housing compressor wheel 28 which is rotatable about an axis of rotation relative to the compressor housing.

The compressor wheel 28 includes an in 1 unrecognizable blading with a plurality of compressor blades, also referred to as blades or impeller blades. The compressor blades each comprise at least one leading edge over which the intake tract 16 air flowing through the respective compressor blade and thus the compressor wheel 28 flows against. Furthermore, the respective compressor blade comprises at least one outlet edge, via which the air during operation of the compressor 26 the respective compressor blade flows out. The intake tract 16 air flowing through is by means of the compressor 26 compressed, so that the compressed air the cylinders 14 is supplied. This can be a particularly efficient operation of the internal combustion engine 10 will be realized. By compressing the air, it is heated. Nevertheless, to realize a particularly high degree of supercharging, is in the intake 16 downstream of the compressor wheel 28 and upstream of the suction pipe 19 a cooling device in the form of a charge air cooler 30 arranged, by means of which the compressed and thus heated air is cooled, before finally into the cylinder 14 flows.

The turbocharger 24 also includes one in the exhaust tract 20 arranged and from the exhaust tract 20 flowing exhaust gas drivable turbine 32 which one in 1 unrecognizable turbine housing and arranged in the turbine housing turbine wheel 34 includes. That the exhaust tract 20 exhaust gas flowing through the turbine wheel 34 flow, causing the turbine wheel 34 is driven. The turbine wheel 34 and the compressor wheel 28 are part of a whole with 36 designated rotor of the exhaust gas turbocharger 24 , where the rotor 36 also a wave 38 includes. The turbine wheel 34 and the compressor wheel 28 are impellers, which are connected to the shaft 38 rotatably connected, so that the rotor 36 is generally rotatable about an axis of rotation relative to the turbine housing and relative to the compressor housing. The compressor wheel 28 is about the wave 38 from the turbine wheel 34 driven, whereby the air by means of the compressor wheel 28 is compressed. As a result, energy contained in the exhaust gas can be used to compress the air.

Downstream of the turbine wheel 34 is in the exhaust tract 20 an exhaust aftertreatment device 40 arranged, by means of which the exhaust gas is treated before it finally flows to the environment. The compressor 26 has an in 1 unrecognizable flow channel, which is limited for example by the compressor housing. The flow channel is traversed by the air, wherein the compressor wheel 28 is arranged in the flow channel, so that the air flowing through the flow channel by means of the compressor wheel 28 is compressed.

In addition, the internal combustion engine includes 10 an exhaust gas recirculation device 42 by means of which exhaust gas from the exhaust tract to the intake tract 16 traceable and in the intake tract 16 can be introduced. The intake tract 16 flowing air takes that into the intake tract 16 introduced exhaust gas with and transports the exhaust gas into the cylinder 14 , For this purpose, the exhaust gas recirculation device comprises 42 at least one exhaust gas recirculation line 44 and one in the exhaust gas recirculation line 44 arranged exhaust gas recirculation valve 46 , which is also referred to as EGR valve. By means of the exhaust gas recirculation valve 46 is an exhaust gas recirculation line 44 flowing through amount of exhaust gas as needed adjustable. Furthermore, the exhaust gas recirculation device comprises 42 one in the exhaust gas recirculation line 44 arranged cooling device in the form of an exhaust gas recirculation cooler 48 , which in the flow direction of the exhaust gas through the exhaust gas recirculation line 44 downstream of the exhaust gas recirculation valve 46 is arranged. That the exhaust gas recirculation line 44 flowing exhaust gas is by means of the exhaust gas recirculation cooler 48 cooled before the exhaust gas into the intake 16 flows.

So now the so-called compressor pumps of the compressor 26 actively counteract and thus a particularly advantageous surge limit or position of the surge line of the compressor 26 To realize includes the internal combustion engine 10 an actuator 50 by means of which at least at one upstream of the respective exit edges arranged first point A pulsations, that is, for example, at least substantially periodic fluctuations, at least one property of the air flow with a frequency of at least five hertz, preferably at least 20 hertz and advantageously in a range of 20 Hertz up to 500 hertz, are feasible. In this at least one property of the air flow, that is, the intake tract 16 By flowing air is preferably the mass flow and / or pressure of the air, so that by means of the adjusting element 50 Mass flow pulsations and / or pressure pulsations at said location are effected.

In the first embodiment, said first location A is located upstream of the exit edges and downstream of the entry edges, that is, in the flow direction of the air through the flow passage between the entry edges and the exit edges. Preferably, a plurality of such locations is provided, at which corresponding pulsations of the at least one property with the frequency can be effected.

The compressor 26 in this case comprises a different from the flow channel, additionally provided for guide channel 52 which is formed for example by a corresponding line or a line element. The guide channel 52 is permeated by a medium, wherein the medium via the guide channel 52 at the first point A the flow channel can be fed, that is, in the flow channel can be introduced. It is by means of the control element 50 a pulsating inflow of the medium from the guide channel 52 into the flow channel at the first point A with the frequency effected. Out 1 it can be seen that the guide channel 52 at said first point A flows into the flow channel, that is fluidly connected to the flow channel. For this purpose, the guide channel 52 at least one outlet opening over which the the guide channel 52 flowing medium from the guide channel 52 off and can flow into the flow channel. For example, the guide channel 52 have a plurality of such outlet openings. The at least one outlet opening is arranged at said first point A, so that the compressor wheel 28 in the first embodiment in the radial outward direction at least partially from the first point A and the outlet opening of the guide channel 52 is covered. The medium is thus by means of guide channel 52 over the outer contour of the compressor wheel 28 introduced into the flow channel.

In the first embodiment, the guide channel 52 at a downstream of the first point A, in particular downstream of the outlet edges, arranged second point S with the air flow through the intake tract 16 fluidly connected, wherein the intake tract 16 is a flow path through which air can flow. In the present case, the point S is arranged downstream of the flow channel formed or bounded by the compressor housing. Alternatively, it is conceivable that the second point S is arranged in the flow channel and thereby downstream of the first point A, in particular downstream of the outlet edges.

At the second point S, at least part of the intake tract 16 flowing air from the intake 16 be diverted and into the guide channel 52 flow. The branched and the guide channel 52 flowing air is by means of the guide channel 52 led back to the first point A and introduced at the first point A in the flow channel, wherein this introduction takes place pulsating or clocked. This pulsating or pulsed introduction is by means of the control element 50 set or effected. That the guide channel 52 flowing medium is thus in the first embodiment by means of the compressor wheel 28 compressed air or a part of the means of the compressor wheel 28 compressed air.

The actuator 50 For example, an actuator which is movable at a frequency in a range of 20 Hertz to 500 Hertz. As a result of these movements of the actuator, the pulsations of the at least one property can be effected by pulsing the medium into the flow channel.

2 shows a second embodiment of the internal combustion engine 10 , in particular of the compressor 26 , The second embodiment differs in particular from the first embodiment in that the first location designated by A is arranged upstream of the outlet edges and also upstream of the inlet edges, so that the first location A upstream of the compressor wheel 28 is arranged. As a result, for example, the inflow of air to the compressor 28 be influenced pulsating.

Finally shows 3 a third embodiment of the internal combustion engine 10 , While in the first embodiment, the introduction of the medium in the compressor 26 that is, in the compressor housing or in the flow channel, the introduction of the medium in the second embodiment takes place in the third embodiment upstream of the compressor wheel 28 and in particular, for example, upstream of the compressor housing.

The third embodiment differs only in particular from the second embodiment that the guide channel 52 not with the intake tract 16 but with one of the compressor 26 different and that of the compressed air by means of the compressor wheel different medium providing source in the form of a pressure accumulator 54 connected is. The accumulator 54 provides the medium with a pressure so that the medium from the accumulator 54 the guide channel 52 can be supplied or is supplied. The medium is preferably a gas, in particular air. The accumulator 54 for example, one of the compressor 26 different compressor of a compressed air system of the motor vehicle supplied with the medium in the form of compressed air, the compressed air system is for example also designed to provide at least one brake, in particular a service brake of the motor vehicle with compressed air for actuating the brake. As a result, the medium can be provided with a particularly high pressure. In addition, a particularly needs-based supply of the guide channel 52 can be displayed with the medium, so that the compressor pumps can be counteracted particularly advantageous, active.

LIST OF REFERENCE NUMBERS

10

Internal combustion engine

12

cylinder housing

14

cylinder

16

intake system

18

air filter

19

suction tube

20

exhaust tract

22

elbow

24

turbocharger

26

compressor

28

compressor

30

Intercooler

32

turbine

34

turbine

36

rotor

38

wave

40

exhaust treatment device

42

Exhaust gas recirculation device

44

Exhaust gas recirculation line

46

Exhaust gas recirculation valve

48

Exhaust gas recirculation cooler

50

actuator

52

guide channel

54

accumulator

A

first place

S

second place

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 60310142 T2 [0002]

Claims (7)

Compressor ( 26 ), in particular for an exhaust gas turbocharger ( 24 ) an internal combustion engine ( 10 ), with a flow-through in air flow channel of the compressor ( 26 ) arranged compressor wheel ( 28 ) for compressing the air, which comprises at least one compressor blade with a trailing edge over which the air during operation of the compressor ( 26 ) flows from the compressor blade, characterized in that an actuating element ( 50 ) is provided, by means of which at least at a location upstream of the trailing edge location (A) pulsations of at least one property of the air flow with a frequency of at least five Hertz are effected. Compressor ( 26 ) according to claim 1, characterized in that as the property a mass flow and / or a pressure of the air flow by means of the actuating element ( 50 ) is influenced by the frequency. Compressor ( 26 ) according to claim 1 or 2, characterized in that the compressor ( 26 ) one of the flow channel different and can be traversed by a medium guide channel ( 52 ), via which the medium at the point (A) can be fed to the flow channel, wherein by means of the actuating element ( 50 ) a pulsating inflow of the medium from the guide channel ( 52 ) in the flow channel at the point (A) with the frequency is effected. Compressor ( 26 ) according to claim 3, characterized in that the guide channel ( 52 ) by means of the actuating element ( 50 ) with the frequency alternately openable and fluidic lockable. Compressor ( 26 ) according to claim 3 or 4, characterized in that the guide channel ( 52 ) at a downstream of the point (A), in particular downstream of the outlet edge, arranged second point (S) is fluidically connected to a flow-through by the air flow path, in particular the flow channel, wherein the guide channel ( 52 ) at the second location (S) the air can be supplied as the medium. Compressor ( 26 ) according to one of claims 3 to 5, characterized in that the guide channel ( 52 ) with one of the compressor wheel ( 28 ) different from that by means of the compressor ( 26 ) compressed air providing different medium ( 54 ), from which the medium to the feed channel ( 52 ) can be fed. Compressor ( 26 ) according to one of the preceding claims, characterized in that the pulsations by means of the actuating element ( 50 ) with a frequency of at least 20 hertz, in particular in a range of 20 hertz to 500 hertz, are effected.

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