DE10308995B4 - Drag lever of a valve train of an internal combustion engine - Google Patents

Abstract

Drag lever (1) of a valve train of an internal combustion engine, which is switchable to different strokes for at least one gas exchange valve, with an outer lever (2) and between the arms (3) extending inner lever (4), wherein both levers (2, 4) relative to each other pivotable and coupling means (5) are coupled to each other, so that when coupling a large and decoupling a small or zero valve lift is generated, wherein at a bottom (6) of the finger lever (1) at one end (7) a plant ( 8) for a gas exchange valve and at the other end (9) a complementary surface (10) for a support element applied and on an upper side (11) of the outer lever (2) at least one mating surface (12) for a Großhubnocken and at an upper side (13) of the Inner lever (4) is provided a mating surface (14) for a small or zero lifting cam, characterized in that the outer lever (2) on at least one end face (14a) open The inner lever (4) in the region of this open end face (14a) has a longitudinal bore (15) with a slide (16) displaceable longitudinally therein as a first component of the coupling means (5), which slide (16) the open end face (15). 14a) with a transverse bar (17) as a second component of the coupling means (5) surmounted, which transverse bar (17) is axially outwardly provided with a bar-like and vertically extending projection (18) as a third component of the coupling means (5) Lugs (18) on the arms (3) of the outer lever (2), wherein each arm (3) has a driver surface (20) for a corresponding mating surface (22) of lever-side end surfaces (24) of the lugs (18).

Description

Field of the invention

The invention relates to a drag lever of a valve train of an internal combustion engine, which is switchable to different strokes for at least one gas exchange valve, with an outer lever and extending between the arms inner lever, wherein both levers are pivotable relative to each other and coupled via coupling means with each other, so that when coupling a large and decoupling a small or zero valve lift is generated, wherein applied to an underside of the rocker arm at one end a system for a gas exchange valve and at the other end a complementary surface for a support and at an upper side of the outer lever at least one mating surface for a Großhubnocken and on a top side of the inner lever, a mating surface is provided for a small or zero lifting cam.

Background of the invention

Such a drag lever is out of the DE 27 53 197 A1 previously known. As a coupling means, a pawl is provided, which engages below the inner lever and is displaceable via a complex linkage mechanism. The latch increases disadvantageously the overall height of the switchable rocker arm. Likewise, the external application of the linkage proves to be relatively complex.

In addition, goes from the US 5 544 626 A1 a turn-off rocker arm out, which has a so-called longitudinal locking in the region of the support element. The disadvantage here, on the one hand, that only switching between 0 and full stroke is possible. On the other hand, there is a relatively large surface pressure on the coupling mechanism, since the coupling is realized via only one piston. Also, the aforementioned drag lever builds up in a disadvantageous manner.

Object of the invention

The object of the invention is therefore to provide a drag lever of the aforementioned type, wherein the surface pressure is reduced to the coupling means.

Solution of the task

According to the invention, this object is achieved in that the outer lever is open on at least one end face, wherein the inner lever in the region of this open end has a longitudinal bore with a longitudinally displaceable slider as the first part of the coupling means, which slide the open end with a crossbar as the second part of the coupling means projects beyond which transverse bar is axially outwardly provided with a respective beam-like and vertically extending approach as the third part of the coupling means, which approaches run towards the arms of the outer lever, each arm a driver surface for a corresponding mating surface of the lever-side end surfaces of the Approaches has, so that upon displacement of the slide in the inner lever, the coupling via engagement of the cam surfaces on the mating surfaces and displacement of the slider from the inner lever away the decoupling via non-engagement of the driver surfaces on the Counter surfaces is made.

Thus, the disadvantages cited above are effectively avoided. It is clear that the scope of the invention also applies to other types of lever drives, including tilting and rocker arm drives. The skilled person will then mainly adapt the support of the lever in a suitable manner.

Due to the thus proposed two-sided longitudinal locking only relatively low surface pressures are observed in the coupling state. On the other hand is guaranteed by the bilateral coupling that tilting and thus an introduction of shear forces is prevented in the lever system. The inventively proposed longitudinal locking also allows a simple hydraulic loading, for example, from the head of the support element on the complementary surface on the lever for this or also an external, such as electromagnetic displacement of the coupling means. Likewise, if the hydraulic displacement is favored, the hydraulic fluid need not necessarily be taken out of the head of the support element. Also conceivable are other Zuleitmaßnahmen, such as separate hoses and the like.

Although a displacement of the coupling means in only one direction via hydraulic means is proposed, however, a displacement in decoupling and coupling direction can be realized via hydraulic means. Preferably, a provision against decreasing hydraulic fluid pressure is to be realized via the force of a compression spring such as a coil spring.

The coupling means according to the invention are formed in three parts in total and form a top view of a T-profile with the transverse bar outside adjacent lugs extending in the lever direction. Possibly. This coupling agent can be made in one piece, however, it is equally provided a multi-part design.

As coupling surfaces to be provided according to the invention driver surfaces on the arms of the outer lever, which are flattened, which communicate with flat mating surfaces of the approaches of the coupling means. Optionally, the lugs, which need not necessarily be formed flat, also engage in corresponding recesses on the front side of the arms in the coupling case.

An excellent guide for the approaches is realized according to a further subclaim that they are included in longitudinal guides, which emanate in their area from the inner lever. Optionally, these longitudinal guides can also be dispensed with, in which case, for example, an engagement under the driver surface of the arms of the outer lever is realized directly above the transverse bar.

As a torsion-proof recording for the longitudinal guides here offers a cross section as a T-profile or the like. In addition, it is provided according to an advantageous embodiment of the invention to connect the longitudinal guides in one piece with the inner lever, but these can also be formed separately.

In a further development of the invention, simple venting measures are proposed for the space enclosed by the longitudinal bore. Here, for example, is intended to a lying behind the piston of the slide vent.

In addition, it is proposed that the system for the gas exchange valve is located on one of the open end opposite the end face on the inner lever. However, it is also conceivable to apply the open end side of the outer lever with the longitudinal locking on the side of the gas exchange valve, in which case the articulated connection of the two lever parts is arranged on the opposite side.

Should the lever system alternatively be designed as a rocker arm system, then the hydraulic means for the displacement of the coupling means can be fed via the rocker arm axis or, in the case of rocker arm formation, via the rocker arm axis.

In order to avoid faulty circuits as far as possible, it is furthermore provided that the ends of the arms are beveled in a pawl-like manner together with end faces of the facing lugs so that a coupling means displaced too early in the coupling position is pushed back again when the outer lever moves relative to the inner lever.

As a lost-motion spring, a torsion spring is provided, which encloses the axis within the inner lever. This is another contribution in the direction of compactly constructed rocker arms. Alternatively, however, other return means may be provided, such as helical compression springs u. ä.

Finally, it is intended to manufacture the levers of a lightweight material such as sheet metal. This lowers the production costs on the one hand. On the other hand, there is a drag lever, which keeps the oscillating masses relatively low.

Short description of the drawing

The invention is expediently explained in more detail with reference to the drawing, in which:

1 a spatial view of a finger lever;

2 a longitudinal section through the drag lever along its longitudinal center line and the

3 a side view of the rocker arm.

Detailed description of the drawing

The figures disclose a switchable to different cam strokes drag lever 1 , This consists of an outer lever 2 that at one end 9 is formed fork-shaped open. An inner lever 4 lies between arms 3 of the outer lever 2 and is in the range of a front side 33 articulated with the outer lever 2 connected. For this purpose, the inner lever runs 4 on an axis 34 axially outward in holes of the arms 3 of the outer lever 2 sitting.

As a lost-motion spring 36 Here is a torsion spring provided, which is the axis 34 inside the inner lever 4 encloses and with their unspecified to be explained arms in the decoupling of the outer lever 2 from the inner lever 4 a return movement to the outer lever 2 exercises.

The arms are roughly in the middle of the middle 3 of the outer lever 2 at its top 11 one mating surface each 12 for high-lift cams. This mating surface 12 Although shown here as a sliding surface, but may also be shown as a role tap. The inner lever 4 on the other hand, it has in the area of this center, in the section of its upper side 13 , also a mating surface 14 for a small lift cam. This mating surface 14 is designed here as a rotatable roller. It can also be seen that the outer lever 2 in the area of the end 7 is closed bow-shaped, so that it forms a U-profile in plan view.

At a bottom 6 (see in particular 2 ) has the inner lever 4 in the area of the end 7 a plant 8th for a gas exchange valve. At the opposite end 9 is in the bottom 6 of the inner lever 4 a complementary area 10 dome-shaped type introduced. About this complementary area 10 is the inside and thus the entire rocker arm 4 . 1 on a head of a supporting member not shown in the drawing. It can also be seen that from the complementary surface 10 a path 31 leads away. This serves a supply of hydraulic fluid to the coupling means explained later 5 , starting from the head of the support element.

As the figures also show, the inner lever dominates 4 in the area of the end 9 front sides 14a the poor 3 of the outer lever 2 , Approximately in this towering area is above the complementary area 10 a longitudinal bore 15 applied. In this longitudinal bore 15 runs axially movable a slider 16 as the first component of the coupling agent 5 , The slider 16 has one here in the longitudinal direction of the finger lever 1 seen outside piston surface 29 , In front of this piston surface 29 can over the path 31 Hydraulic means for shifting the slide 16 be passed in the bore direction. A reset of the slider 16 takes place via the force of a compression spring 30 , here at a bottom of the longitudinal bore 15 supported. A simple vent 32 , on the basis of the above reason, prevents unnecessary construction of an air cushion in the longitudinal bore 15 during an axial movement of the slide 16 ,

Axially outside is the slider 16 with a crossbeam 17 as a second component of the coupling agent 5 firmly connected. From ends of the crossbeam 17 tower towards the poor 3 of the outer lever 2 roughly aligned bar-like approaches 18 as the third component of the coupling agent 5 back. These approaches 18 are in longitudinal guides 26 picked up by the inside lever 4 out. Here are the approaches 18 overhead counter surfaces 22 that are flat here.

In particular 3 shows, the facing ends of the arms 3 of the outer lever 2 on the bottom 6 flat driving surfaces 20 , These are thus in the coupling case on the surfaces 22 the approaches 18 in the area of their end face 24 on.

It can also be seen that end faces 14a the poor 3 Beveled, the slope here complementary to also obliquely executed end faces 35 the approaches 18 run. This quasi-jack-like design has the advantage that the opposite the inner lever 4 Uncoupled in the decoupling outer lever 2 in its reverse pivoting here counterclockwise and simultaneously undesirable extended coupling agent 5 (about the approach 18 ) this coupling agent 5 shifted back into the Entkoppelstellung.

Should the from the 2 . 3 resulting coupling of the outer lever 2 with the inner lever 4 be canceled, so at base circle run the cam pressure chamber 28 relieved of hydraulic fluid. This pushes the compression spring 30 the entire coupling agent package 5 axially from the drag lever 1 so gone, that the lugs 18 with their mating surfaces 22 disengaged from the driver surfaces 20 the poor 3 of the outer lever 2 reach. Thus, the acted gas exchange valve only takes a stroke in the sense of the inner lever 4 impinging on small cam.

LIST OF REFERENCE NUMBERS

1

cam follower

2

external lever

3

poor

4

internal lever

5

coupling means

6

bottom

7

The End

8th

investment

9

The End

10

complementary surface

11

top

12

Mating surface

13

top

14

Mating surface

14a

front

15

longitudinal bore

16

pusher

17

crossbeam

18

approach

19

not forgiven

20

entraining

21

not forgiven

22

counter surface

23

not forgiven

24

end face

25

not forgiven

26

longitudinal guide

27

not forgiven

28

pressure chamber

29

piston area

30

compression spring

31

path

32

vent

33

front

34

axis

35

front

36

Lost-motion spring

Claims (14)

Drag lever ( 1 ) of a valve train of an internal combustion engine, the different strokes for at least one gas exchange valve is switchable, with an outer lever ( 2 ) and one between its arms ( 3 ) extending inner lever ( 4 ), both levers ( 2 . 4 ) pivotable relative to each other and via coupling agent ( 5 ) are coupled to each other, so that when coupling a large and decoupling a small or zero valve lift is generated, wherein at a bottom ( 6 ) of the rocker arm ( 1 ) at one end ( 7 ) an annex ( 8th ) for a gas exchange valve and at the other end ( 9 ) a complementary surface ( 10 ) applied to a support element and on an upper side ( 11 ) of the outer lever ( 2 ) at least one mating surface ( 12 ) for a high-lift cam and on a top ( 13 ) of the inner lever ( 4 ) a mating surface ( 14 ) is provided for a small or zero lifting cam, characterized in that the outer lever ( 2 ) on at least one end face ( 14a ) is open, wherein the inner lever ( 4 ) in the region of this open end face ( 14a ) a longitudinal bore ( 15 ) with a longitudinally displaceable slider ( 16 ) as the first constituent of the coupling agent ( 5 ), which slider ( 16 ) the open front side ( 14a ) with a crossbeam ( 17 ) as a second constituent of the coupling agent ( 5 ) dominates which transom ( 17 ) axially outwardly, each with a bar-like and vertically extending approach ( 18 ) as the third constituent of the coupling agent ( 5 ), which approaches ( 18 ) on the arms ( 3 ) of the outer lever ( 2 ), each arm ( 3 ) a driver surface ( 20 ) for a corresponding mating surface ( 22 ) of lever-side end surfaces ( 24 ) of approaches ( 18 ) Has. Cam follower according to claim 1, characterized in that the lugs ( 18 ) in longitudinal guides ( 26 ), which in the area of approaches ( 18 ) across the inner lever ( 4 ) away. Drag lever according to claim 2, characterized in that the longitudinal guides ( 26 ) have a profiled cross-section such as a T-profile, in which the complementary executed approaches ( 18 ). Drag lever according to claim 2, characterized in that the longitudinal guides ( 26 ) in one piece with the inner lever ( 4 ) are connected. Cam follower according to claim 1, characterized in that one of the components slides ( 16 ), Transom ( 17 ), Approaches ( 18 ) in one piece with at least one other of the aforementioned components ( 16 . 17 . 18 ) is made. Drag lever according to claim 1, characterized in that in the longitudinal bore ( 15 ) of the inner lever ( 4 ) a pressure chamber ( 28 ) is formed for hydraulic means, wherein the slide ( 16 ) a piston surface ( 29 ), which has the pressure chamber ( 28 ) is limited in an axial direction, so that when supply of hydraulic fluid, the slide ( 16 ) is hydraulically displaceable in one direction, wherein a return displacement of the slide ( 16 ) via the force of at least one compression spring ( 30 ) is realized. Drag lever according to claim 6, characterized in that in the inner lever ( 4 ), below the longitudinal bore ( 15 ) for the slider ( 16 ), the complementary area ( 10 ) for the storage of the finger lever ( 1 ) is applied to the head of the support element, wherein of the complementary surface ( 10 ) to the pressure chamber ( 28 ) at least one path ( 31 ) is formed for supplying the hydraulic fluid, starting from the head of the support element. Drag lever according to claim 6, characterized in that from the longitudinal bore ( 15 ) of the inner lever ( 4 ), at the pressure chamber ( 30 ) side facing away, at least one vent ( 32 ) leads. Drag lever according to claim 7, characterized in that the system ( 8th ) for the gas exchange valve at the open end ( 14a ) opposite end ( 7 ) on the inner lever ( 4 ) is arranged, wherein the inner lever ( 4 ) in the section of the opposite end ( 7 ) from one axis ( 34 ) which projects axially outward in the arms ( 3 ) of the outer lever ( 2 ) for producing the pivotable connection of the levers ( 2 . 4 ) to each other. Drag lever according to claim 7, characterized in that the driver surfaces ( 20 ) the poor ( 3 ) of the outer lever ( 2 ) flattened on bottoms ( 6 ) the poor ( 3 ), the flat mating surfaces ( 22 ) of approaches ( 18 ) on tops ( 11 ) are arranged and wherein the end faces ( 14a ) the poor ( 3 ) together with end faces ( 35 ) of the approaches ( 18 ) are so bevelled chimney-like, that during a relative movement of the outer lever ( 2 ) back to the position in which it can be coupled to the inner lever, as well as at contact of these end faces ( 14a . 35 ), a wedge effect, a shift of approaches ( 18 ) is effected in Entkoppelstellung. Cam follower according to claim 9, characterized in that it is at the opposite end ( 7 ) is closed. Cam follower according to claim 9, characterized in that the axle ( 34 ) within the inner lever ( 4 ) of a torsion spring as a lost-motion spring ( 36 ) for the outer lever ( 2 ) is projected. Drag lever according to claim 1, characterized in that the mating surface ( 14 ) of the inner lever ( 4 ) as a rotatable roller and the at least a mating surface ( 12 ) of the outer lever ( 2 ) is made as a sliding surface. Cam follower according to claim 1, characterized in that at least one of the levers ( 2 . 4 ) consists at least for the most part of a lightweight material, such as deep-drawn or tiefziehfähigem sheet metal, plastic or fiber-reinforced plastic.

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