DE112011102627T5 - turbocharger - Google Patents

Abstract

The invention relates to an exhaust-gas turbocharger (1) having a turbine (2) which has the following parts: a turbine wheel (3); a turbine housing (4), in which at least one turbine trough (5, 5 ') is arranged, which has a, as seen in the exhaust gas flow direction, upstream of the turbine wheel (3) arranged through opening (6, 6'); and a shut-off device (7) which is arranged downstream of the turbine trough (5, 5 ') and upstream of the turbine wheel (3) for opening and closing the passage opening (6, 6'), wherein the shut-off device (7) comprises a shut-off sleeve (12). has, in a directly into the turbine housing (4) incorporated groove (13) is guided translationally movable.

Description

The invention relates to an exhaust gas turbocharger according to the preamble of claim 1.

Such an exhaust gas turbocharger is from the DE 10 2007 060 415 A1 known. This known exhaust gas turbocharger has a shut-off device with first and second guide grid elements, wherein the second guide grid element is guided translationally movable in a sleeve or socket, which must be inserted into the turbine housing.

Since this sleeve thus represents a separate component that must be previously manufactured and then mounted in the turbine housing, the manufacturing and assembly costs of the generic exhaust gas turbocharger is relatively high.

It is therefore an object of the present invention to provide an exhaust gas turbocharger specified in the preamble of claim 1 way, which is simpler in terms of the number of required components and accordingly easier to install.

The solution of this object is achieved by the features of claim 1.

Characterized in that the shut-off device has a shut-off, which is inserted into a groove of the turbine housing and guided translationally movable in this, it is no longer necessary to produce a separate sleeve or socket and to arrange in the turbine housing. Because the groove in which the shut-off is guided, is incorporated directly into the material of the turbine housing itself from the bearing housing side. Here, the groove has only one depth, which is chosen as short as possible. This groove depth corresponds to the width of the barrier sleeve. The outer diameter of the shut-off sleeve is smaller than the diameter of the turbine housing on the bearing housing side, so that after the introduction of the groove in the material of the turbine housing, the blocking sleeve can be inserted from the bearing housing side into the groove.

This results in an integration of the shut-off device in the turbine housing before the turbine inlet to make, for example, the realization of a so-called "turbo-engine brake" with the possibility of increasing the exhaust gas recirculation rate by a controlled shut-off or throttling of the turbine tide and turbine troughs possible ,

So it is possible in an exhaust gas turbocharger with single-stage and two-stage controlled design to block the turbine flood, or in the case of two turbine floods, one or both floods or regulated to throttle and open.

• – Steigerung der Abgasrückführrate zur Verbesserung der Abgasemission durch Steigerung des Abgasgegendruckes bei Teillast und/oder niedrigen Motordrehzahlen;
• – Verbesserung des dynamischen Ansprechverhaltens des Motors durch Beeinflussung der Zuströmrate zum Turbinenrad;
• – Verbesserung eines geregelten Bremsbetriebes mit Steigerung der Bremsleistung und Verbesserung der dynamischen Beschleunigung des Turboladers und damit auch des Motors aus dem Motorbremsbetrieb heraus;
• – Verminderung der Bauteile, da es im Gegensatz zum Stand der Technik nicht mehr nötig ist, ein separates Bauteil in Form einer Hülse oder Buchse zur Führung der Absperrhülse in das Turbinengehäuse einzubauen.

This results in the following advantages:

• - Increase the exhaust gas recirculation rate to improve the exhaust emission by increasing the exhaust back pressure at part load and / or low engine speeds;
• - Improvement of the dynamic response of the engine by influencing the inflow rate to the turbine wheel;
• - Improvement of a regulated braking operation with increase of the braking power and improvement of the dynamic acceleration of the turbocharger and thus also of the engine from the engine braking operation out;
• - Reduction of components, since it is no longer necessary in contrast to the prior art to install a separate component in the form of a sleeve or bushing for guiding the shut-off in the turbine housing.

The subclaims have advantageous embodiments of the invention to the content.

Preferably, the shut-off sleeve has two webs arranged diametrically opposite one another, the free ends of which are connected to an actuating device which effects the translatory movement of the blocking sleeve within the groove.

In order to be able to connect the webs to the actuating device, the groove integrated in the turbine housing above the turbine wheel contour has housing openings through the turbine housing. The number of housing openings corresponds to the number of webs, which means that at least one housing opening is provided, the position of which can be chosen arbitrarily, or in the case of two webs whose position is to be selected approximately diametrically opposite each other.

When inserting the sleeve into the groove results in an air bearing and the webs are passed through the housing openings, so that they protrude on the side of the turbine outlet from the turbine housing. Thus, it is possible to connect the shut-off sleeve via a suitable lever arrangement and a fork connected to this with the actuating device, wherein the fork is connected on the one hand with the lever arrangement and on the other hand with the free, protruding from the turbine housing ends of the webs.

The inventive design of the shut-off device results in a further advantage that it can be integrated into existing turbine housing by rework, since it is only necessary to incorporate the explained groove for the shut-off in the turbine housing and one of the number Webs of the shut-off provide appropriate number of housing openings.

Further details, advantages and features of the invention will become apparent from the following description of embodiments with reference to the accompanying drawings. It shows:

1 a schematically greatly simplified representation of an exhaust gas turbocharger according to the invention,

2 an enlarged sectional view of a part of the turbine housing of the exhaust gas turbocharger to explain the structure of a shut-off device,

3 a simplified perspective view of a locking sleeve of the shut-off device according to the invention together with a lever assembly and a fork, and

4 a simplified plan view of the lever assembly and fork according to 3 ,

In 1 is a schematic highly simplified representation of an inventive exhaust gas turbocharger 1 shown. The turbocharger 1 has a turbine 2 with a turbine wheel 3 on that in a turbine housing 4 is arranged. In the example shown, the turbine housing 4 a turbine tide 5 but preferably two separate turbine flows are preferably provided, which are described below with reference to FIGS 2 be described in more detail. The turbine tide 5 has a passage opening 6 on, seen in the exhaust gas flow direction, upstream of the turbine wheel 3 in the turbine housing 4 is provided.

Furthermore, a shut-off device is schematically simplified representation 7 shown downstream of the turbine tide 5 and upstream of the turbine wheel 3 for opening and closing the passage opening 6 is provided.

Furthermore, the exhaust gas turbocharger 1 the otherwise usual parts, in particular a compressor 8th with a compressor wheel 9 in a compressor housing 10 and a wave 11 on, on the turbine wheel 3 and the compressor wheel 9 are arranged in the usual way. In addition to these parts are, of course, all other parts of conventional turbocharger, such as a bearing housing with storage for the shaft 11 provided, however, which are neither shown nor described, since they need not be described to explain the principles of the present invention.

In 2 is a schematically simplified sectional view of a part of the turbine housing 4 in the area of the shut-off device 7 shown. The embodiment according to 2 shows a turbine housing 4 with two adjacent floods 5 . 5 ' passing through a footbridge 20 are separated from each other. The turbine floods 5 and 5 ' have associated passages 6 respectively. 6 ' ,

2 clarifies that the shut-off device 7 downstream from the two turbine floods 5 . 5 ' and upstream of the turbine wheel 3 in the turbine housing 4 integrated, a locking sleeve 12 which has in a groove 13 is translationally movable, which is symbolized by the double arrow T. Furthermore, the sectional view of the shows 2 that the locking sleeve 12 is provided with bars, of which in 2 due to the chosen representation only the bridge 14 is visible. The groove 13 from the bearing housing side L forth in the turbine housing 4 is incorporated directly, is provided with housing openings, of which in 2 only the housing opening or the passage opening 21 is visible. The number of housing breakthroughs 21 depends on the number of webs with which the locking sleeve 12 is provided. The housing breakthrough 21 through the turbine housing 4 allows the passage of the webs, in the case of the representation of the 2 of the footbridge 14 , in the area of the turbine outlet A, leaving the free end 16 of the footbridge 14 with a fork to be described in detail below 19 can be connected.

From the representation of 3 in which the locking sleeve 12 alone without the turbine housing 4 is shown, it follows that in the example chosen trap the shut-off 12 with two bars 14 and 15 is provided diametrically opposite each other at one edge 22 the locking sleeve 12 are arranged. Preferably, the blocking sleeve 12 and the footbridges 14 . 15 an integral part.

As 3 clarified, are the free ends 16 and 17 of the bridges 14 respectively. 15 with the free ends 23 respectively. 24 the fork 19 connected, in turn, in a central area 25 with a lever arrangement 18 connected with an in 3 not shown actuator or actuator for actuating the locking sleeve 12 connected is. The double arrows B1, B2 and B3 illustrate the movements of the lever arrangement 18 and the fork 19 which ultimately translates to T within the groove 13 to lead.

4 additionally illustrates by a plan view of the lever assembly 18 and fork 19 their structure and functioning.

By the previously described embodiment of the shut-off device 7 and the directly into the turbine housing 4 from the bearing side L ago incorporated groove 13 it becomes possible without other parts, such as a known from the prior art guide bushing for the shut-off 12 to get along, which reduces the production cost of the exhaust gas turbocharger according to the invention and the cost of its installation considerably over known constructions.

In addition to the written disclosure of the invention is hereby explicitly on their graphic representation in the 1 to 4 Referenced.

LIST OF REFERENCE NUMBERS

1

turbocharger

2

turbine

3

turbine

4

turbine housing

5, 5 '

turbine flows

6, 6 '

Through openings

7

shut-off

8th

compressor

9

compressor

10

compressor housing

11

wave

12

shutoff

13

groove

14, 15

Stege

16, 17

free ends of the webs

18

lever assembly

19

fork

20

Divider of the turbine housing between the floods 5 . 5 '

21

Housing openings / passages

22

Edge of the locking sleeve 12

23, 24

free ends of the fork 19

25

Mid-range of the fork

L

Bearing housing side

A

turbine outlet

T

Double arrow to symbolize the translational mobility of the locking sleeve 12

B1-B3

Movements of the lever arrangement 8th and the fork 19 for actuating the blocking sleeve 12

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 102007060415 A1 [0002]

Claims (7)

Exhaust gas turbocharger ( 1 ) - with a turbine ( 2 ) comprising: • a turbine wheel ( 3 ); A turbine housing ( 4 ), in which at least one turbine tide ( 5 . 5 ' ), which, viewed in the exhaust gas flow direction, upstream of the turbine wheel ( 3 ) arranged passage opening ( 6 . 6 ' ) having; and a shut-off device ( 7 ) downstream of the turbine tide ( 5 . 5 ' ) and upstream of the turbine wheel ( 3 ) for opening and closing the passage opening ( 6 . 6 ' ), characterized in that - the shut-off device ( 7 ) a locking sleeve ( 12 ), which in a directly into the turbine housing ( 4 ) incorporated groove ( 13 ) is guided translationally movable. Exhaust gas turbocharger according to claim 1, characterized in that the blocking sleeve ( 12 ) at least one bridge ( 14 ), whose free end ( 16 ) is connected to an actuating device. Exhaust gas turbocharger according to claim 1, characterized in that the blocking sleeve ( 12 ) preferably two, approximately diametrically opposed webs ( 14 . 15 ) whose free ends ( 16 respectively. 17 ) are connected to an actuating device. Exhaust gas turbocharger according to claim 2 or 3, characterized in that the locking sleeve ( 12 ) with the actuating device via a lever arrangement ( 18 ) and a fork ( 19 ) connected at the free ends ( 16 . 17 ) of the webs ( 14 . 15 ) is attached. Exhaust gas turbocharger according to one of claims 2 to 4, characterized in that the groove ( 13 ) one of the number of webs ( 14 . 15 ) corresponding number of housing openings ( 21 ) to the turbine outlet (A) out. Exhaust gas turbocharger according to one of claims 1 to 5, characterized in that the turbine housing ( 4 ) two mutually adjacent and separate turbine flows ( 5 . 5 ' ) with associated passage openings ( 6 respectively. 6 ' ) having. Exhaust gas turbocharger according to one of claims 1 to 6, characterized in that the turbine floods ( 5 . 5 ' ) of the turbine housing ( 4 ) are different in size.

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