DE102012112432A1 - Mounting device for mounting exhaust gas turbocharger on internal combustion engine, has decoupling element arranged between holding elements, where decoupling element is designed in two parts and formed from wire mesh - Google Patents

Abstract

The device has first holding element connected with an attachment point that is attached to an internal combustion engine. A second holding element (1) is attached with an exhaust gas turbocharger and provided with a reinforcing agent (9). The first holding element is connected with the second holding element through a connecting unit along an axis. A decoupling element is arranged between the holding elements, where the decoupling element is designed in two parts and formed from a wire mesh. Two fingers are formed with two openings and parallel to each other.

Description

The invention relates to a holding device, in particular for fastening an exhaust gas turbocharger to an internal combustion engine, with a first holding element, which is assigned to an internal combustion engine and a second holding element, which is associated with an exhaust gas turbocharger.

To optimize the performance and efficiency of combustion engines, exhaust gas turbochargers are often used. These use the energy in the exhaust gas flow to introduce a larger amount of fresh air into the working cylinder, whereby the power of the internal combustion engine can be increased or the efficiency of the internal combustion engine can be improved.

Exhaust gas turbocharger has for this purpose an exhaust gas turbine and a fresh air turbine, which are coupled together via a common shaft. The fresh air side turbine is driven by the shaft, which is driven by the exhaust gas turbine. It compresses the fresh air in front of the working cylinder and generates an increased boost pressure, which leads to a better filling of the working cylinder.

In current exhaust gas turbochargers very high speeds are achieved at the turbines. These can be several hundred thousand revolutions.

In order to decouple the exhaust gas turbocharger from the vibrations of the internal combustion engine this is often fixed via a mounting device on the engine. The holder may have a damping element for decoupling. For this purpose, a variety of solutions in the prior art is known.

A disadvantage of the solutions according to the prior art is that the structure and the costs are relatively high when a decoupling element is provided. In mounting devices without decoupling the protection of the exhaust gas turbocharger from vibrations is not given sufficiently.

Therefore, it is the object of the present invention to provide a holder with a damping element, which is optimized over the prior art.

The object with regard to the discharge device is achieved with the features of claim 1.

An embodiment of the invention relates to a mounting device, in particular for fastening an exhaust gas turbocharger to an internal combustion engine, with a first holding element, which is associated with a fastening point, such as the internal combustion engine, and a second holding element, which is associated with an exhaust gas turbocharger, wherein the first holding element with the second Holding element is connected via a connecting means, wherein between the first holding element and the second holding element, a decoupling element is arranged, which at least partially comprises at least one of the holding elements, wherein the decoupling element is made in two parts, wherein the decoupling element is formed of a wire mesh.

By means of a holding device with a first holding element and a second holding element, which are connected to one another via a decoupling element, an effective isolation of the exhaust-gas turbocharger from the internal combustion engine can take place. Advantageously, the first holding element and the second holding element are only in contact via the decoupling element. Any direct contact between the two holding elements inevitably leads to vibration transmission from the engine to the exhaust gas turbocharger.

A wire mesh is particularly temperature resistant to an elastomeric element. In particular, in the combustion engine near area very high temperatures can occur during operation, which have a negative effect on elastomeric elements in the long term. In particular, the proximity to the exhaust system further aggravates this situation. In addition, a decoupling element of a wire mesh may have a higher strength.

In addition, it may be advantageous if the first holding element has a substantially Y-shaped form, wherein the fork-like region is formed by a first finger and a second finger, which extend substantially parallel to each other, wherein the fork-like region facing away from the engine End region forms and the first finger has a first opening and the second finger has a second opening, wherein the first opening and the second opening are in alignment.

The Y-shaped configuration of the first holding element is particularly advantageous, since the second holding element, the decoupling element and a possibly existing fixing element can be arranged between the two fingers of the fork-like region.

The fingers are advantageously designed so massive that they can be applied to a sufficiently high clamping force to fix the remaining elements between the fingers, without damaging the fingers themselves damaging.

It may also be expedient for the second holding element to have a substantially U-shaped form, wherein the end region facing away from the exhaust-gas turbocharger lies in the region of the vertex of the U-shaped form and a third opening is arranged in the vertex.

Via the third opening, the second holding element can be particularly advantageously connected to the decoupling element and the first holding element.

About the two legs of the U-shaped retaining element, the exhaust gas turbocharger can be advantageously connected to the second support member. The second holding element can for example be punched out of a metal sheet, produced in a flame cutting process or in a casting process.

Furthermore, it is preferable if the second holding element in the region of the third opening has a reinforcing means which increases the material thickness around the third opening.

About such a reinforcing element, which can be formed for example by a disc, the stability of the holding element can be increased. It is particularly advantageous that not the material thickness must be increased over the entire holding element, but only partially in the areas that require reinforcement. As a result, the holding element is lighter overall and requires less material.

In a particularly favorable embodiment of the invention, it is also provided that the decoupling element engages in the third opening of the second holding element.

By engaging the decoupling element in the third opening, a positioning of the holding element relative to the decoupling element takes place. In addition, this ensures that the two holding elements do not come into direct contact with each other. The decoupling element practically forms an interface between the first holding element and the second holding element.

In an alternative embodiment of the invention, it can be provided that the decoupling element has a first channel, which completely penetrates the decoupling element.

The channel in the interior of the decoupling element is advantageous because a connecting means can be guided through it. This makes it possible to produce a secure positioning of the decoupling element relative to the holding elements, through the openings of which the connecting means is also guided for the purpose of the connection.

It is also preferable if the decoupling element and / or the second holding element are enclosed by a fixing element.

A fixing element may in particular be formed by a sleeve with a flange-like end region and a fixing disc. Advantageously, the sleeve is guided through the channel of the decoupling element, so that the flange-like end region and the fixing disc enclose the decoupling element.

This serves to stabilize the decoupling element, which engages in the third opening of the second holding element. The connecting means can advantageously be guided through the sleeve while still through the first opening and the second opening of the first and second fingers. The two fingers are, viewed in the direction of the central axis of the sleeve, positioned in front of and behind the sleeve.

In a further advantageous embodiment, it can be provided that a biasing force can be generated by the connecting means, by which the elements of the holding device can be connected to one another and fixed to one another.

By a biasing force acting on the first and the second finger from the outside, a pressure on the entire composite, consisting of first and second holding element, sleeve and decoupling element, are generated. As a result, the individual elements can be fixed to each other.

In particular, a rotation of the individual elements relative to each other can be avoided by a sufficiently high biasing force.

Furthermore, it may be expedient if the connecting means is formed by a screw connection.

A screw connection as a connecting means is particularly advantageous, since both a simple installation and a simple disassembly is possible. In addition, the biasing force generated by the screw connection can be easily varied.

Advantageous developments of the present invention are described in the subclaims and the following description of the figures.

In the following the invention will be described with reference to an embodiment with reference to FIGS Drawings explained in detail. In the drawings show:

1 a perspective view of the second holding element with the decoupling element and the fixing element, which is formed from a sleeve with flange-like end portion and a fixing disc,

2 a side view of 1 .

3 a sectional view of 2 .

4 a perspective view of the holding device, with the first holding element, the second holding element, the decoupling element, the fixing element and the connecting element,

5 a side view of 4 .

6 a sectional view of 5 , and

7 another side view of 4 ,

The 1 shows a perspective view of the second holding element 1 , On the second holding element 1 is a decoupling element 4 , which is in the first part 4a and in the second part 4b shares a sleeve 6 as well as a fixing disc 5 , which together with the sleeve 6 represents a fixing element arranged.

The second holding element 1 has a U-shaped basic shape. This is formed by the first leg 2 and the second leg 3 , which meet in a vertex. At the apex point facing away from the first leg 2 and the second leg 3 are reception areas 8a respectively. 8b provided for the exhaust gas turbocharger.

At these reception areas 8a . 8b have the first leg 2 as well as the second leg 3 also an additional opening through which the second holding element 1 can be connected to an exhaust gas turbocharger. Advantageously, while the receiving areas 8a . 8b each engaging in a contour of the exhaust gas turbocharger to establish a secure connection with the exhaust gas turbocharger.

The end portions of the legs 2 . 3 has a greater width than the rest of the legs 2 . 3 , In a supervision is every thigh 2 . 3 in itself L-shaped, wherein the end portion is formed by the short portion of the L-shape. The reception areas 8a . 8b have a slightly curved contour in the plan.

The second holding element 1 has a third opening in the area of its vertex. This is due to the overlap by the decoupling element 4 or the fixing disc 5 not recognizable. However, it runs concentric with the in 1 shown hole 7 which passes through both the fixation disc 5 as well as through the sleeve 6 runs. More detailed information on the arrangement of the individual elements follow in the following figures.

In addition, the second holding element 1 in the area of his vertex a reinforcing disk 9 on which partially the material thickness of the second holding element 1 elevated.

The reinforcement disc 9 For example, by soldering with the second holding element 1 get connected. A particular advantage of the reinforcing disk is given by the fact that the material thickness of the second holding element is increased only in the region of the apex, without the material thickness on the remaining second holding element 1 to increase. As a result, material can be saved, which also leads to a cost reduction and a weight reduction of the component.

The 2 shows a side view of the second holding element 1 as it already is in 1 was shown. In the side view it can be seen that the reinforcing disk 9 flat on a surface of the second holding element 1 is applied. Right to the reinforcement disc 9 closes a second part 4b of the decoupling element 4 on, left to the first leg 2 of the second holding element 1 closes the first part 4a of the decoupling element 4 at.

By the decoupling element 4 and by the second holding element 1 leads the sleeve 6 which has an axial extent through the decoupling element 4 and the second holding element 1 and a radial flange-like extension which forms a contact surface for the decoupling element 4a forms.

To the right follows the second part of the decoupling element 4b a fixing disc 5 , which serves as a contact surface for the second part 4b of the decoupling element 4b serves.

The fixing disc 5 has a bore concentric with the in 1 shown hole 7 is aligned.

The sleeve 6 , the fixing disc 5 , the decoupling element 4 , the reinforcing disc 9 and the second holding element 1 are arranged in such a way that runs through the entire arrangement a rectilinear channel. In an ideal embodiment, the openings or holes the individual elements aligned so that they are concentric with each other.

The 3 shows a sectional view through the in 2 shown representation of the second holding element 1 ,

In the 3 you can see how the individual elements sleeve 6 , Decoupling element 4 , second holding element 1 , Reinforcing disc 9 and fixation disc 5 consecutive.

The sleeve 6 has for this purpose an axially extending region, which by the decoupling element 4 leads. Furthermore, the sleeve 6 a radially extending flange-like region which extends radially. Together with the fixing disc 5 forms the sleeve 6 one around the axial portion of the sleeve 6 circumferential receiving area for the two parts 4a . 4b of the decoupling element 4 ,

Between the first part 4a of the decoupling element 4 and the second part 4b of the decoupling element 4 runs a dividing line 10 ,

The hole 7 is through the inner wall of the sleeve 12 limited to the outside in the radial direction. The sleeve 6 itself is plugged into a channel, which through the decoupling element 4 is formed. This channel is through the inner wall 13 limited. The axially extending portion of the sleeve 6 lies directly on the inner wall 13 of the canal. The decoupling element 4 has a circumferential groove, in which the second holding element 1 and the reinforcing disk 9 are used. The second holding element 1 has to a third opening, which through the inner wall 11 is limited to the outside in the axial direction.

On average it can be seen that the decoupling element 4 in particular in the third opening of the second holding element 1 engages, thereby ensuring that the second retaining element 1 only in direct contact with the decoupling element 4 is and not with the sleeve 6 or the fixing disc 5 , This is particularly advantageous with regard to the vibration decoupling to be achieved by the mounting device.

The radially aligned portion of the sleeve 6 as well as the fixing disc 5 lie directly on the lateral end portions of the decoupling element 4 at. About applying a force to the sleeve 6 and / or the fixing disc 5 can be a force on the decoupling element 4 are generated, whereby on the one hand, the second holding element 1 in the decoupling element 4 is fixed and on the other hand, a rotation of the individual elements to each other difficult or completely avoided. The length of the axial portion of the sleeve 6 is on the width of the decoupling element 4 adjusted so that a press fit can be achieved, which complicates or prevents the relative movement of the individual elements to each other.

About the on the decoupling element 4 applied force can also the isolation and damping effect of the decoupling element 4 be influenced by yourself. When designing the length of the sleeve 6 and the dimensioning of the contact pressure is to pay attention.

The 4 shows a perspective view of the holder device 20 , In addition to those already in the 1 to 3 described elements, the mounting device 20 now a first holding element 21 on. This first holding element 21 has a Y-shaped shape.

The fork-like region of the first holding element 21 is through a first finger 22 and a second finger extending substantially parallel thereto 23 educated.

The fork-like area is designed such that in the 1 to 3 described arrangement of the second holding element 1 , the decoupling element 5 , the reinforcing disc 9 , the sleeve 6 and the fixing disc 5 fit between the first finger 22 and the second finger 23 can be used.

The first holding element 21 is essentially formed from a sheet metal strip, which has two introduced bends from its main plane 29 is distracted. The finger 22 runs essentially parallel to the main plane 29 of the first holding element 21 ,

The first finger 22 has a first opening 25 on. The second finger 23 has a second opening 26 on which in the view of 4 is covered. Through the first opening 25 and the hole 7 the sleeve 6 is a connecting screw 24 led, which on the back of the second finger 23 about the mother 27 is fixed. By using a connecting screw 24 as well as a mother 27 is the contact pressure, which is on the first finger 22 as well as the second finger 23 and the interposed elements acts changeable. The assembly of the second holding element 2 and the first holding element 21 By using a bolting element is particularly easy.

In alternative embodiments, instead of a connecting screw also a different connection method can be used. For example, a rivet may be provided instead of the connecting screw.

The first opening 25 as well as the second opening 26 are each formed by a slot. These slots allow an adjustment of the first holding element 21 relative to the elements arranged therebetween. In this way, a tolerance compensation or a length compensation can be realized.

The second finger 23 is formed over a second sheet metal strip, which is connected to the first sheet metal strip, below the fork-like portion. The second sheet metal strip runs in the embodiment shown in a straight line. For connecting the first and the second sheet metal strip, known connection methods, such as, for example, welding, gluing or soldering, can be used.

The 5 shows a side view of the already in 4 shown holding device 20 , The side view shows how the connecting screw 24 through the first holding element 21 , the second holding element 1 , the decoupling element 4 , the sleeve 6 , the reinforcing disc 9 and the fixing disc 5 is guided. About the connection by means of a screw, the first holding element 21 at any time relative to the second holding element 1 be twisted by the screw is loosened. This allows, for example, a simple final assembly on the internal combustion engine or in the vehicle. The connecting screw 24 and the mother 27 are easy to loosen or tighten during assembly.

The 6 shows a sectional view of the previously shown 5 , Out 6 goes the structure of the junction between the second holding element 1 and the first holding element 21 out. Successively from the left side follows the connecting screw 4 a washer 30 , whereupon the first finger 22 of the first holding element 21 follows. This is followed by the sleeve 6 as well as a first part 4a of the decoupling element 4 followed by the second holding element 1 and the reinforcing disk 9 , whereupon the second part 4b of the decoupling element 4 connects and the fixing washer 5 , On the fixing disc 5 follows the second finger 23 and finally the mother 27 ,

In 6 it can be seen that between the second holding element 1 and the first holding element 21 There is no direct physical contact. All force transmission via the first holding element 21 to the second holding element 1 or vice versa find about the decoupling element 4 instead of.

On average, the 6 is the first opening 25 as well as the second opening 26 to recognize. The formation of the first opening 25 and the second opening 26 as a slot allows a relative displacement of the first holding element 21 to the rest of the arrangement.

In the 6 forms the central axis 28 each center axis for all openings or holes. Both the sleeve 6 runs concentric to the central axis 28 as well as the channel inside the decoupling element 4 , Likewise, the third opening of the second holding element 1 and the hole in the fixing washer 5 ,

In alternative embodiments, it may also be deviated from this concentric alignment of the individual elements.

The dividing line 10 of the decoupling element 4 runs in alignment with the dividing line between the second holding elements 1 and the reinforcing disk 9 , This can also be provided deviating in alternative embodiments. In particular, if a reinforcing disk is dispensed with.

That in the 1 to 7 shown decoupling element 4 is advantageously designed as a wire mesh. The advantage of a wire mesh is in particular that it has a higher temperature resistance than, for example, elastomeric elements.

In particular, for an arrangement in a mounting device for an exhaust gas turbocharger is to be expected that the mounting position is provided within the vehicle in the vicinity of exhaust gas lines or the internal combustion engine. Therefore, the occurrence of elevated temperatures can be expected, which in the long term can adversely affect the durability of elastomer elements. In addition, wire mesh can have a higher strength than comparable elastomeric elements.

The 7 shows a further side view of the mounting device 20 as in the previous ones 1 to 6 already described. The viewer's gaze is on the first finger 22 directed, which lies in the plane of the paper.

The embodiments shown in the figures have no limiting character.

LIST OF REFERENCE NUMBERS

1

Second holding element

2

First leg

3

Second thigh

4a, 4b

decoupling element

5

disc

6

shell

7

drilling

8a, 8b

Receiving area exhaust gas turbocharger

9

reinforcing washer

10

parting line

11

Inner wall third opening

12

Inner wall sleeve

13

Inner wall channel

20

mounting device

21

First holding element

22

First finger

23

Second finger

24

connecting screw

25

First opening

26

Second opening

27

mother

28

central axis

29

level

30

washer

Claims (9)

Mounting device ( 20 ), in particular for fastening an exhaust-gas turbocharger to an internal combustion engine, with a first retaining element ( 21 ), which is associated with an attachment point, such as the internal combustion engine, and a second retaining element ( 1 ), which is associated with an exhaust gas turbocharger, characterized in that the first retaining element ( 21 ) with the second holding element ( 1 ) along an axis via a connecting means ( 24 ), wherein between the first holding element ( 21 ) and the second holding element ( 1 ) a decoupling element ( 4 ) is arranged, which at least one of the holding elements ( 1 . 21 ) at least partially, wherein the decoupling element ( 4 ) is made in two parts, wherein the decoupling element ( 4 ) is formed of a wire mesh. Mounting device ( 20 ) according to claim 1, characterized in that the first holding element ( 21 ) has a substantially Y-shaped shape, wherein the fork-like area is defined by a first finger ( 22 ) and a second finger ( 23 ), the fingers ( 22 . 23 ) which extend substantially parallel to one another, wherein the fork-like region forms the end region remote from the internal combustion engine and the first finger ( 22 ) a first opening ( 25 ) and the second finger ( 23 ) a second opening ( 26 ), wherein the first opening ( 25 ) and the second opening ( 26 ) are in a flight. Mounting device ( 20 ) according to one of the preceding claims, characterized in that the second holding element ( 1 ) has a substantially U-shaped form, wherein the exhaust gas turbocharger remote end portion in the region of the apex of the U-shaped form and in the apex, a third opening is arranged. Mounting device ( 20 ) according to one of the preceding claims, characterized in that the second holding element ( 1 ) in the region of the third opening a reinforcing means ( 9 ), which increases the material thickness around the third opening. Mounting device ( 20 ) according to one of the preceding claims, characterized in that the decoupling element ( 4 ) in the third opening of the second holding element ( 1 ) intervenes. Mounting device ( 20 ) according to one of the preceding claims, characterized in that the decoupling element ( 4 ) has a first channel, which the decoupling element ( 4 ) penetrates completely. Mounting device ( 20 ) according to one of the preceding claims, characterized in that the decoupling element ( 4 ) and the second holding element ( 1 ) of a fixing element ( 6 . 5 ) are enclosed. Mounting device ( 20 ) according to one of the preceding claims, characterized in that by the connecting means ( 24 ) is a biasing force generated by the elements of the support device ( 20 ) are connectable to each other and fixable to each other. Mounting device ( 20 ) according to one of the preceding claims, characterized in that the connecting means ( 24 ), by a screw connection ( 24 . 27 ) is formed.

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