DE10230428A1 - Eccentric adjusting device for crank mechanisms for IC engines has eccentric sleeve with locking structure engaging with locking unit to form blocking mechanism - Google Patents

Abstract

The device has an eccentric sleeve (6) with unit with locking elements (13,14), to lock it in two different positions. The sleeve has a formed locking structure (9a) engaging with the locking unit to form a blocking mechanism, to prevent a return movement of the sleeve behind the locking position against forward switching direction. The locking device is integrated in the connecting rod, or in the connecting rod cover (4) of the crankshaft journal eye. It has a locking bolt arrangement moving axially and parallel to the crank pin axis.

Description

The invention relates to an eccentric adjustment device for one Crank drive, in particular to provide different compression ratios in a reciprocating piston internal combustion engine by changing the dead center positions of the piston.

Out DE 197 03 948 C1 an eccentric adjusting device is known which has an eccentric bearing shell arranged in the region of a crank pin bore of a connecting rod, the distance of a piston pin axis from the associated crank pin axis of the crankshaft being variable within the framework of the eccentricity of the bearing shell by pivoting the bearing shell within the crank pin bore. By changing the distance between the piston pin axis and the crank pin axis, it becomes possible, in particular to change the top dead center position of the piston - and thus the compression ratio. The provision of different compression ratios makes it possible to take better account of the engine operating conditions which vary when operating a motor vehicle, in particular with regard to exhaust gas quality, efficiency and in the high-load range, to avoid engine knock.

In the aforementioned conventional Eccentric adjustment device is the arrangement their foreign and interior surfaces eccentrically designed bearing shell in two extreme positions on one Conrod shaft lockable. The determination of the bearing shell in the each desired Extreme position is done by a locking pin, which on a Connecting rod cover arranged shift lever can be actuated. The gear lever is over one arranged in the oil pan Switching trough can be deflected in two different locking positions. In a In the first locking position, the locking pin locks the bearing shell in a position that brings about minimal compression ratios. In In a second position, the locking pin locks the bearing shell in a swiveled by 180 ° Position providing maximum compression ratios. The pivoting of the bearing shell is carried out by engaging the bearing shell Reaction forces.

Out EP 0 438 121 A1 an eccentric adjustment device for the crank mechanism of an internal combustion engine is also known. In a departure from the embodiment described above, actuation of a locking pin provided for fixing the bearing shell takes place through pressure oil chambers, the oil pressure selectively prevailing in these pressure oil chambers being able to be applied via separate oil bores provided on the crankshaft side.

In the previously described Eccentric adjustment devices have the problem that the locking the bearing shell under certain circumstances after several load cycles, and the bearing shell in the unlocked State undefined oscillates in the corresponding connecting rod eye.

The invention has for its object a Eccentric adjusting device to create, in which one for change the effective connecting rod length Eccentric cup, on reliable Way achieved a required functional position.

According to the invention, this object is achieved by an eccentric adjustment device for a crank mechanism with a in a connecting rod eye eccentric bushing and a locking device for Locking the eccentric bushing in different rotational positions, wherein the locking device has engaging elements that are selective can be brought from a locking position into a release position, in which a pivoting movement of the eccentric bushing is made possible this eccentric adjustment device is characterized by that at the eccentric bush an engagement structure is formed, which in Interaction with the locking device a locking device forms, to prevent a, which exceeds a specified angular range, the Switching direction opposite reverse rotation of the eccentric bush.

This will make it beneficial Way possible the change the distance between a piston pin axis and a crank pin axis provided eccentric bushing, by means of the one on the eccentric bushing attacking camp reaction forces, reliable in the desired one Swivel switch position.

According to a particularly preferred embodiment the invention, the locking device is incorporated into the connecting rod. One under assembly technology as well as under production technology Aspects of particularly advantageous embodiment of the invention given that the Locking device in a connecting rod cover near the crank pin Area is included. This makes it possible to use the locking device and to combine the connecting rod cover as a pre-assembled unit, as part of an engine assembly process as such placed on the eccentric bushing and with the connecting rod shaft can be screwed. The locking device comprises according to one particularly preferred embodiment of the invention, one formed in a parallel to the crankpin axis Location hole, axially displaceable locking pin arrangement.

The locking pin arrangement is preferably designed such that it can be actuated via a switching device arranged in the region of the crankcase. This switching device can in particular have a coil arrangement for switching the locking pin arrangement by means of a selectively applied magnetic field. Alternatively - or also in combination with this measure - it is possible to actuate the locking pin arrangement in a hydrostatic manner, for example via oil pressure chambers. The oil pressure required for this can be applied, for example, via selectively controllable pressure oil channels, so that the locking pin arrangement can be switched as a result of the oil pressure prevailing in the oil pressure chambers.

The locking pin arrangement comprises preferably spring-loaded engaging elements, if agreed with corresponding engaging counter structures spring-loaded in the engaged position to step. This is advantageous in terms of particularly high robustness embodiment the invention is given in that the eccentric bushing with an annular flange structure is provided, and the engagement structure in the region of the ring flange structure is formed, the locking pin arrangement with the engagement structure can be brought into engagement. about the ring flange structure mentioned makes it possible to position it correctly Positioning the eccentric bushing required circumferential forces reliable Way into the eccentric bushing.

Further details and features the invention result from the following description in Connection with the drawing.

Show it:

1 A perspective view of a connecting rod with a selectively lockable eccentric bushing arranged in the region of the crank pin bearing;

2a An axial section through the locking device arranged in the connecting rod cover to explain the locking state in a first fully locking position;

2 B A sectional view similar 2a however with an engagement element which has been displaced into a release position;

2c A section through the locking device in a second locking position.

This in 1 The connecting rod shown comprises a connecting rod shaft 1 , a piston pin eye designed here in a trapezoidal design 2 and one of a connecting rod shaft end portion 1 and a connecting rod cover 4 limited crank pin eye 3 ,

In the piston pin eye 2 is a piston pin bush made from a bearing material 5 anchored non-rotatably.

In the crank pin eye 3 is an axially split eccentric bush 6 pivoted so that the eccentric bushing 6 selectively around the central axis of the crank pin eye 3 is pivotable.

The eccentric bushing 6 comprises a running surface made of a bearing material on the crank pin of a crankshaft, not shown here, as a rule on a hydrodynamic lubricating film 6a , The lubricant required to form the hydrodynamic lubricating film is provided via oil holes 30 that depend on the rotational position of the eccentric bushing 6 in the crank pin eye 3 are in fluid connection with the pressure oil channels provided on the connecting rod.

The eccentric bushing 6 is designed such that the cylindrical crank pin tread formed by it 6a , eccentric to that also through the eccentric bushing 6 formed in the crankpin eye 3 seated, eccentric bushing outer surface is arranged.

The eccentric bushing 6 is in this embodiment in the region of its axial ends each with an annular flange 7 . 8th provided, the end face of the ring flange, which faces outward in the axial direction, forms a side guide device in cooperation with a crank pin cheek.

The axially split eccentric bushing 6 is through the connecting rod cover 4 in the crank pin eye 3 held together to form a bearing bush element.

The ring flanges 7 . 8th are in the area of diametrically opposite circumferential positions with an engagement structure 9 provided with a locking pin arrangement 10 can be selectively engaged.

The locking pin arrangement 10 is in one approach in this embodiment 11 the connecting rod cover 4 added.

The eccentric bushing 6 is in this embodiment by the on the eccentric bush 6 attacking bearing reaction forces, in the direction indicated by the arrow symbol P ₁ , pivotable. A pivoting movement of the eccentric bushing in the direction indicated by the arrow symbol P _{2 occurs} immediately after the eccentric bushing is unlocked 6 , prevented by a locking mechanism activated in connection with the unlocking of the eccentric bushing. Details of the unlocking of the eccentric bushing according to the invention 6 in the crank pin eye 3 are described below with reference to the 2a ; 2 B and 2c described, which are sectional views at the level of in 1 shown section plane A is.

In the 2a locking device shown 12 comprises a locking pin arrangement with engagement elements which can be brought selectively into a locking position or a release position 13 . 14 ,

The engaging elements 13 . 14 are designed as spring-loaded cylinder journals and each have an engagement end section, which selectively with one on the adjacent ring flange 7 . 8th the eccentric bushing 6 trained intervention structure 9 can be brought into engagement. In the embodiment shown here, the eccentric bushing side is in front seen intervention structure 9 as essentially semi-cylindrical, in the respective ring flange 7 . 8th radially immersed bulge formed from the outer circumference.

The engaging elements 13 . 14 are by spring devices 15 . 16 biased. The spring devices 15 . 16 are supported in this embodiment between the engagement elements 13 . 14 and a central bearing body 17 from. The central bearing body 17 sits in a sliding bush 18 which, via an actuating mechanism, not shown here, between the first switching position shown here and the position shown in FIGS 2 B and 2c indicated second switching position, is displaceable.

The sliding bush 18 is through one, in the connecting rod cover 4 integrated holding device 19 , fixable in the respective switch position.

The holding device 19 includes holding elements 20 by holding springs 21 radially against a circumferential groove section of the sliding bush 18 are crowded.

In the circumferential groove section, two deeper grooves are formed, into which those spring-loaded holding elements 20 can immerse and while doing so the sliding bush 18 fix in the axial direction.

The operation of the previously described Locking device can for example by oil pressure - or as for the present embodiment provided to be done by electromagnetic means.

In the in 2a shown switching position is the engagement element 13 with the first ring flange 7 , or with the engagement structure formed therein 9 , positive engagement. The central body 17 with the first engagement element 13 coupled, second engagement element 14 , in this switch position so far into the connecting rod cover 4 that this second engaging element 14 no locking caused. The eccentric bushing 6 is in this switching position in the circumferential direction rotatable in the crank pin eye 3 locked.

For switching the eccentric bushing 6 the sliding bush is first in an operative position rotated by 180 ° 18 in the in the 2 B shown position shifted. This is done on the slide bush 18 a force is applied to the holding elements 20 first in the radial direction from the lower circumferential groove of the circumferential groove of the sliding bush in this illustration 18 is pushing out. After the sliding bush 18 , which has reached the end position shown here, the holding elements are immersed 20 into the upper circumferential groove and fix the slide bush 18 in the position shown. In this switching position, the first engagement element comes into play 13 out of engagement with the engagement structure 9 that in the first ring flange 7 is trained.

The second engaging element 14 is by the between this second engaging element 14 and the central bearing body 17 provided spring device 16 , against a section of a career 22 urged, in an inside of the connecting rod shaft facing the inside of the second ring flange 8th is trained. This track section extends over a circumferential angle of approximately 180 ° (starting from an axial projection of the engagement structure 9 on the opposite ring flange) to a diametrically opposite circumferential position with respect to the crank pin axis. At this circumferential position is the in 2c visible, in the second ring flange 8th trained, interventional structure 9b , The spring device 16 is designed such that the spring force applied by this is weaker than that by the holding elements 20 on the slide bush 18 applied locking holding forces. The engaging element 14 sits spring-loaded on the track section in this switch position 22 on.

At the end of the career section 22 is a career level 23 which here is one with the engaging element 14 engaging stop surface forms, and a pivoting movement of the eccentric bushing 6 only in the direction of rotation indicated here by the arrow symbol P ₁ .

Will the eccentric bush 6 rotated by 180 ° due to the bearing reaction forces acting on it, it can reach this position on the track section 22 sliding end face portion of the engaging member 14 into the mesh structure 9b occur like this in 2c is shown.

Once the engaging element 14 into the mesh structure 9b immersed is the second ring flange 8th , and over this the entire eccentric bushing 6 in the crank pin eye 3 fixed in the circumferential direction.

To the in 2c shown locking state must first remove the sliding bush 18 back in like in 2a indicated axial position can be shifted. Here, as previously in 2 B for the engagement element 14 described, now the engagement element 13 under load of the spring devices 15 , against a section of a career 24 pushed in the area of an inner surface of a connecting rod shaft facing the first ring flange 7 located. This section of the career 24 extends from the recognizable here, the engagement element 13 adjacent circumferential section, up to the in 2a shown intervention structure 9a , An impermissible rotation of the eccentric bushing against the in 2 B direction of rotation indicated by the arrow symbol P ₁ is in this case by that at the end of the track section 24 analogous to the career section 22 trained career level 25 prevented.

It is possible the career section 24 form such that this at least one additional career level 23 forms, in interaction with the spring-loaded engaging element running on it 14 forms a backstop device, by means of which an inadmissible pivoting back of the eccentric bushing is avoided.

The bearing shell designed as an eccentric bushing and the one forming part of a switching device In the exemplary embodiment shown, the locking pin arrangement is designed in such a way that a reverse locking mechanism is activated, essentially simultaneously, when the unlocking process is triggered. As in the 2a . 2 B and 2c is shown, when switching over, on the flange side opposite the respectively locked flange, a contact of a locking section is brought about. The contact made here under spring load means that a locking structure can interact positively with a stop provided in the region of the flange and thereby prevent the eccentric shell from rotating in an undesired direction after the eccentric shell has been released. As soon as the eccentric shell has rotated through the changeover angle of in particular 180 ° into the desired new operative position, the spring-loaded locking structure, which initially prevents the reverse rotation, can engage in a locking engagement with the flange and in turn fix the eccentric bushing in the connecting rod eye. In this case, the required anti-rotation locking action is advantageously achieved in the interaction of the bearing shell and the locking members that can be selectively brought into engagement with it.

The invention is not based on those described above embodiments limited. It is also possible, the interaction in the embodiment described above Reverse lock realized with the locking device differs in design perform. In particular, it is possible the locking of the eccentric bushing by radially deflectable locking members to accomplish.

1

connecting rod shaft

2

Piston pin boss

3

Crank pin eye

4

connecting rod

5

Piston pin axis

6

eccentric

6a

Crankpin tread

7

annular flange

8th

annular flange

9a

engagement structure

9b

engagement structure

10

Locking pin arrangement

11

approach

13

engaging members

14

engaging members

15

spring means

16

spring means

17

centrally bearing body

18

bush

19

holder

20

holding body

21

retaining springs

22

Race section

23

Career Level

24

Race section

25

Career Level

30

oil drilling

Claims (8)

Eccentric adjustment device for a crank mechanism with an eccentric bushing accommodated in a connecting rod eye ( 6 ) and a locking device for locking the eccentric bushing ( 6 ) in at least two different rotational positions, the locking device engaging elements ( 13 . 14 ), which is selectively in a locking position in which the eccentric bushing ( 6 ) is fixed, or in a release position in which a pivoting movement of the eccentric bushing ( 6 ) is possible, can be brought, characterized in that on the eccentric bushing ( 6 ) an interventional structure ( 9a ) is formed, which, in cooperation with the locking device, forms a locking device for preventing a backward rotation of the eccentric bushing which, contrary to the switching direction, returns behind the unlocking position. Eccentric adjusting device according to claim 1, characterized in that that the Locking device is integrated into the connecting rod. Eccentric adjusting device according to at least one of claims 1 to 2, characterized in that the locking device in the connecting rod cover ( 4 ) of the crank pin eye ( 3 ) is included. Eccentric adjustment device after at least one of claims 1 to 3, characterized in that the locking device has a locking pin arrangement which can be displaced axially and parallel to the crank pin axis ( 10 ) having. Eccentric adjusting device according to at least one of claims 1 to 4, characterized in that the locking pin arrangement ( 10 ) can be switched electromagnetically from a first switching position to a second switching position. Eccentric adjusting device according to at least one of Claims 1 to 5, characterized in that the locking pin arrangement has spring-loaded engagement elements ( 13 . 14 ) having. Eccentric adjusting device according to at least one of claims 1 to 6, characterized in that the eccentric bushing ( 6 ) with a ring flange structure ( 7 . 8th ) is provided, and the engagement structure ( 9a . 9b ) in the area of the ring flange structure ( 7 . 8th ) is trained. Eccentric adjustment device for a crank mechanism with an eccentric bushing accommodated in a connecting rod eye ( 6 ) and a locking device for locking the eccentric bushing ( 6 ) in at least two different rotational positions, the locking device engaging elements ( 13 . 14 ), which is selectively in a locking position in which the eccentric bushing ( 6 ) is fixed, or in a release position in which a pivoting movement of the eccentric bushing ( 6 ) is possible, can be brought, characterized in that the locking device is designed in such a way that it can be brought into a release state when it is switched over, in which it forms a locking device, to prevent a reverse rotation movement of the eccentric bushing that goes back against the switching direction behind the unlocking position.