DE19839431A1 - Tappet for valve gear of internal combustion engine comprises circular ring-shaped section activated in its base area by at least one cam with large lift - Google Patents

Abstract

The tappet (1) with its shirt (5) oscillates in an accommodation hole of a cylinder head and concentrically encloses a circular section (6) with a guide socket (7) movable axially to the circular ring-shaped section (2). The circular section in its base area (18) is activated by a cam (8) of smaller lift. Two superimposed rotatable discs (9,10) act as coupling components between the circular ring-shaped section and the circular section. In the circular ring-shaped section is a stop component (13) working in conjunction with the discs for timewise securing the rotary position of them.

Description

Field of application of the invention

The invention relates to a plunger according to the preamble of the patent saying 1.

Background of the Invention

From DE-OS 195 43 659 a plunger with several adjustable stroke emerge. Pistons are used as the actuating means insert into coupling means designed as disks via connecting means fen. By rotating the discs, an annular first Ab cut and a circular second section of the plunger in different Chen axial positions can be locked or uncoupled. On The disadvantage of this tappet is that the disks twist is not prevented in the case of an unfavorable cam position.

In DE-PS 44 05 189 a tappet for a valve that can be switched off be wrote in which is achieved via a cam-controlled locking element  that a coupling member for valve shutdown in a first cam track locked area and slidable in a second cam track area is. This plunger cannot be reversed between different stroke profiles be switched.

Object of the invention

The object of the invention is therefore a plunger of the type described To create in which multiple stroke courses are adjustable and in which an actuation of the coupling means only in a favorable rotational position of the Cam can take place.

Summary of the invention

According to the invention, this object is characterized by the features of nenden part of claim 1 solved. Advantageous embodiments of the ram are realized by subclaims 2-12.

The tappet according to the invention has at least one locking element, wel ches is actuated by the cam and cooperates with the locking element Kende coupling means designed as disks only for rotation releases when there is a favorable rotational position of the cam.

When the locking element is actuated, the disks are locked, so that despite an activation of the actuating means designed as a piston no Ver rotation of the disks takes place.

Instead of the piston, slides, wedges or similar embodiments are used.

In a first embodiment of the invention there are a total of two blocking elements elements provided, each separately with one of the two discs interact and lock or release them.  

The tappet according to the invention can also have only a single disk, which interacts with one or more locking elements. When used However, two disks lying one above the other can be made shorter Realize switching paths.

In a concretization of the invention, the locking element is used as a trigger pin with a lower axially movable in the plunger via a spring formed a shaft and a tapered head relative to the shaft area actuated by the cam. The head area of the Trig protrudes gerstifts in the non-actuated state over the upper floor area of the Tappet and is activated by the gün final cam track area axially in the plunger for locking the respective Disc moved.

A solution with three disks is also within the scope of the invention comprises, which interacts with three respectively assigned trigger pins and locked and released separately. This allows more Stroke profiles can be realized.

In a further specification of the invention, the trigger pin reaches through upper and lower disc recesses with the widened shaft Locking and with the tapered head area for release. Depending speed of the axial position of the trigger pin thus shift the shaft and Head area of the trigger pin opposite the disc recesses, where through the desired locking or release.

In an advantageous embodiment, the two disks are penetrated by both trigger pins, but each trigger pin only lock one and the respectively assigned of the two disks and release ben and the other disc regardless of the axial position of the trigger pin grips continuously without locking.

In a further embodiment, the inner guide sleeve  circular section of the plunger noses with nose recesses for Recording disc projections of the discs when actuated (Twisting) of the disks. When the disks are operated, they serve Nose recesses for receiving disc projections, which makes the outer annular portion of the plunger in an axial position against is fixed over the inner circular section.

In a further rotational position of the disks, the disk recesses are brought into overlap with the nose recesses, so that the circular and the circular portion of the plunger from each other are decoupled.

Another embodiment of the plunger provides that the washers Jumps are wedge-shaped, so that when engaging in the nose recesses by turning the washers a further axial from Cam moving displacement of the annular portion takes place so that the latter is completely removed from the cam and lifted off is locked.

With this setting, the ram has a small stroke in the bottom area of the circular section actuated without contacting the lowered and locked circular section through the cam large hub takes place. There are therefore no steps in the annular section Spring forces increase and there are no friction losses.

Brief description of the drawing

The invention is shown in more detail in the drawing figures poses. Show it:

Fig. 1 is a section AA of Figure 3 by a plunger with egg nem first stroke characteristic.

Fig. 2 section AA of Figure 3 through the plunger with a second stroke.

Fig. 3 is a plan view of the plunger with the specified section AA;

Figure 4 is a plan view of the plunger with a further section BB.

FIG. 5 shows a section BB according to FIG. 4 through the tappet;

Figure 6 is a plan view of the plunger with a further section CC.

Fig. 7 is an owner of half-section CC of Figure 6 by the plunger in the locked positions.;

Fig. 8a is a detail of FIG. 7;

FIG. 8b shows a section DD of FIG. 8a;

Fig. 9 is an owner of half-section CC of Figure 6 by the plunger in the decoupled switching positions.

Fig. 10 is a plan view of the plunger with a locked he most switching stage;

Figure 11 is a plan view of the plunger with a decoupled second shift stage.

Figure 12 is a plan view of the plunger with a locked third switching stage.

Fig. 13 is a section through the cam 15 and the locking element and

Fig. 14 is a section through the cam 4 and the locking element.

Detailed description of preferred embodiments

Fig. 1 shows a tappet 1 with an outer annular portion 2 and an inner circular portion 6 with a guide sleeve 7. The tappet 1 is provided for a valve train of an internal combustion engine, and runs with its shirt 5 in a bore of a cylinder head, not shown. The annular section 2 has a bottom region 3 with a locking element 13 actuated by the cam 4 and a locking element 14 actuated by the cam 15 . The bottom region 18 of the circular section 6 is contacted by the cam 8 . The cams 4 , 15 have ge compared to the cam 8 a large, z. B. the double stroke.

The annular section 2 is axially movably received on the circular section 6 via the compression spring 20 . In the guide sleeve 7 of the circular section 6 there is a conventional hydraulic lash adjuster 19 which is not explained in detail.

In Fig. 1, the cam 4 operates the trigger pin 13 formed as a first locking element 13 and moves the latter upon actuation of the pin spring 44 axially into the annular sections 2. The first trigger pin 13 engages with its widened shaft 27, the lower disc recess 52 of the lower disc 9 and the upper disc recess 51 of the upper disc 10 . The upper disk 10 is thus released by the actuation of the trigger pin 13 and can be activated by actuating means, namely the pistons 11 or 12 ( FIG. 5).

In the illustration of FIG. 1, the first recess 23 of the cam 15 prevents actuation of the locking element 14 designed as a second trigger pin 14. The head region 26 of the trigger pin 14 projects from the bottom region 3 of the annular section 2 into the recess 23 , the trigger pin 14 being actuated by the pin spring 45 . The head region 26 extends through the upper disc recess 53 of the upper disc 10 and the shaft 28 widened relative to the head region 26 through the lower disc recess 54 of the lower disc 9 . The lower disk 9 is thereby locked and cannot be operated.

The trigger pin 13 serves to lock or release the upper disk 10 and the trigger pin 14 to lock and release the lower disk 9 . The lower disk 9 is pierced by the trigger pin 13 in the lower disk recess 52 , but is never locked and remains freely movable. To the same extent, the head region 26 of the second trigger pin 14 extends through the upper disc recess 53 of the upper disc 10 , but does not lock the latter at any time.

In FIG. 2, the second trigger pin 14 is actuated by the cam 15. The trigger pin 14 is axially displaced into the annular section 2 by actuating the pin spring 45 , so that the lower disk recess 54 of the lower disk 9 is penetrated by the tapered head region 26 relative to the shaft 28 and is thus released.

The trigger pin 13 is in the cam position according to FIG. 2 in the recess 24 of the cam 4 and is therefore not actuated. Thus, the pin spring 44 is largely relaxed and moves the widened shaft 27 axially in the direction of the cam 4 , so that the upper disc recess 51 of the upper disc 10 is gripped by locking the upper disc 10 through.

Overall, the upper disk 10 can be actuated in FIG. 1, while the lower disk 9 is locked. In Fig. 2, the upper disc 10 is locked and the lower disc 9 is released.

In the released state, the disks 9 , 10 can be rotated in spite of the gripping trigger pins 13 , 14 . The disc recesses 51 , 52 , 53 and 54 are formed in the manner of elongated holes with widening for receiving the shafts 27 , 28 (not shown).

Fig. 3 shows a plan view of the trigger pins 13 , 14 and the first receiving bore 21 for the piston 11 and the second receiving bore 22 for the piston 12th The guide sleeve 7 of the circular section 6 has lugs 32 a-d.

From Fig. 4 along the section BB goes for FIG. 5 forth.

The actuating means arranged in the receiving bores 21 , 22 and configured as the first piston 11 and second piston 12 are connected via connecting means 16 , 17, namely a first pin 16 and a second pin 17 , to the coupling means designed as disks 9 , 10 . The pin 16 engages in a first receptacle 30 for actuating the lower disk 9 and the pin 17 in a second receptacle 31 for actuating the upper disk 10 . The pin 17 passes through the lower disk 9 in the recess 29 without restricting the rotational movement of the lower disk 9 .

Fig. 6 shows the plot of the section CC of Fig. 7-9.

In Fig. 7 the lugs 32 a, 32 c are shown as reinforcements of the guide sleeve 7 . The half-section according to FIG. 7 shows on the left side the ring-shaped section 2 locked in the upper position by engagement of the disk projection 36 of the upper disk 10 in the nose recess 34 ( FIG. 9).

On the right side of the disc 35 projection engages the lower disc 9 is d, locked in the nose recess 33 (Fig. 9) of the nose 32 so that the annular portion 2 in a lowered position on the annular portion 2. The spring 20 is compressed.

In an enlarged illustration of the right side of FIG. 7, FIG. 8 a shows the engagement of the disk projection 35 in the nose recess 33 .

In section DD according to FIG. 8a, FIG. 8b shows the disk projection 35 with a wedge 37 with the wedge angle γ. The disc projection 35 is inserted with axial displacement of the annular portion 2 in the Nasenaus savings 33 in the locking direction 46 by turning the lower disc 9 . The annular section 2 is removed from the cam 15 and locked in a raised position.

When unlocking against the locking direction 46 , the wedge 37 is removed from the nose recess 33 of the nose 32 d and the disc recess 38 covers the nose 32 c, so that the annular section 2 is decoupled from the circular section 6 and is not locked.

In hälftigen section according to FIG. 9, the upper plate 10 does not interfere with the nose recess 34 of the nose 32 on the left wheel a one, so that the annular portion is coupled ent opposite the circular portion 6 2. When the cam 4 (not shown) is acted upon, the annular section 2 loses by actuating the compression spring 20 .

On the right side of FIG. 9 there is the annular section 2 in a position lowered from the circular section 6 . This is done by actuating the cam 15 (not shown). The disc 9 does not engage in the nose recess 33 of the nose 32 c of the guide sleeve 7 .

In Fig. 9, on the left and right side the Scheibenaussparun conditions 38 , 39 ( Fig. 10-12) are brought into overlap with the lugs 32 a, 32 c ge, so that the annular section 2 is decoupled from the circular section 6 is.

Based on the sequence of FIGS. 10-12, three switching stages of the plunger 1 can be represented.

In Fig. 10 (switching stage 1 ) the pistons 11 , 12 are relaxed by the piston springs 47 , 48 . The upper disc 10 is in the locking position 40 , so that the upper disc projections 36 (not visible in Fig. 10) are in the locking position in the corresponding Na senausstands 33 , 34 below the lugs 32 a-d. At the same time there are the disc recesses 39 due to the locking of the upper disc 10 in plan view next to the lugs 32 a-d.

In Fig. 10, the annular portion 2 is in its uppermost position and is locked to the circular portion 6 , so that the entire plunger 1 is actuated by the cams 4 , 15 larger strokes.

In Fig. 11 (switching stage 2 ), the piston 12 is actuated so that the upper disc 10 assumes the unlocking position 42 and the annular section 2 is oscillated on the outside of the inner circular section 6 by actuating the cams 4 , 15 with a larger stroke. The plunger 1 is actuated by the cam 8 smaller stroke in the Bodenbe rich 18 of the circular portion 6 . From the annular section 2 and the circular section 6 are decoupled from each other.

Both in FIG. 10 and in FIG. 11, the lower disk 9 is in an unlocking position 41 .

At an appropriate time, e.g. B. at lower speed, the Kol ben 11 can be actuated, whereby the lower disc 9 is displaced and moves from the unlocking position 41 into the locking position 43 ( Fig. 12, switching stage 3 ). The disc protrusions 35 of the unte ren disc 9 in the corresponding nose recess 33 of the lugs 32 a-d, so that the lower disc 9 is locked and the annular section from 2 in a lowered state on the circular portion 6 is arre tiert.

In the top view, the disc recesses 38 of the lower disc 9 are located next to the lugs 32 a-d. By the wedge shape of the disc projections 35 described in FIG. 8b, the annular section 2 is completely lifted off the cams 4 , 15 , so that the tappet 1 is actuated by the cam 8 with a smaller stroke and the annular section 2 is in contact with the cams 4 and 15 oscillates due to the connection with the section 6 with a small stroke.

The Fig. 13, 14 show the interaction of the cams 15, 4 and the trigger pins 14, 13.

The cam 15 of Fig. 13 has a circumferential first recess 23 and a recess-cam region 50. In the cam position shown, the trigger pin 14 is not actuated, so that the lower disk 9 is locked by the shaft 28 due to the relaxed pin spring 45 (see FIG. 1, right side).

In Fig. 14, the trigger pin 13 is also still in the region of the second recess 24 without an actuation of the trigger pin 13 is carried by the cam portion 49 having no recesses. The trigger pin 13 is relaxed by the pin spring 44 , so that the head region 25 still protrudes from the bottom region 3 of the annular section 2 . The upper disk 10 is locked by the shaft 27 (cf. FIG. 2, left side).

Reference list

1

Pestle

2nd

circular section

3rd

Floor area

4th

cam

5

shirt

6

circular section

7

Guide sleeve

8th

cam

9

first disc

10th

second disc

11

first piston

12th

second piston

13

Locking element, first trigger pin

14

Locking element, second trigger pin

15

cam

16

Lanyard, first pin

17th

Lanyard, second pin

18th

Floor area

19th

Game compensation element

20th

Compression spring

21

first mounting hole

22

second location hole

23

first recess

24th

second recess

25th

Head area

26

Head area

27

shaft

28

shaft

29

Recess

30th

first shot

31

second shot

32

nose

33

Nose recess

34

Nose recess

35

Disc protrusion

36

Disc protrusion

37

wedge

38

Disc recess

39

Disc recess

40

Locking position

41

Unlocking position

42

Unlocking position

43

Locking position

44

Pen nib

45

Pen nib

46

Locking direction

47

Piston spring

48

Piston spring

49

Cam area

50

Cam area

51

upper disc recess

52

lower disc recess

53

upper disc recess

54

upper disc recess
γ wedge angle

Claims (12)

1. plunger ( 1 ) for a valve train of an internal combustion engine, consisting of an annular section ( 2 ) rich on its Bodenbe ( 3 ) by at least one cam ( 4 ) large stroke is struck with his shirt ( 5 ) in one Receiving bore of a cylinder head oscillates and concentrically includes a circular section ( 6 ) which is axially movable with respect to the annular section ( 2 ) and has a guide sleeve ( 7 ) which is optionally actuated on its base region ( 18 ) by a cam ( 8 ) with a small stroke and with it said bottom region (6) in the axial direction be remote from reaching at least indirectly at least one gas exchange valve associated, wherein the tappet (1) to the circuit of this superposed on the cam (4, 8) large or small stroke two ver rotatable discs (9, 10 ) as a coupling means between the annular section ( 2 ) and the circular section ( 6 ) and cooperating with them in at least one direction of displacement for rotating the disks ( 9 , 10 ) displaceable first and second pistons ( 11 , 12 ) run as actuating means, characterized in that in the annular section ( 2 ) at least one cooperating with the disks ( 9 , 10 ) and from the cam ( 4 ) at the momentary locking of the rotational position of the disks ( 9 , 10 ) actuatable locking element ( 13 ) is provided. 2. Tappet according to claim 1, characterized in that a further locking element ( 14 ) which can be actuated by a cam ( 15 ) and cooperates with the disks ( 9 , 10 ) is provided. 3. Tappet according to claim 1 or 2, characterized in that the locking element ( 13 , 14 ) is equipped as a trigger pin ( 13 , 14 ), the shaft ( 27 , 28 ) via a spring ( 44 , 45 ) axially movable in an annular shape Section ( 2 ) is received and the head region ( 25 , 26 ) of the cam ( 4 , 15 ) in the non-actuated state projects into a recess ( 24 , 23 ) and in the actuated state of a recess-free cam region ( 49 , 50 ) of the cam ( 4 , 15 ) is actuated and is axially displaced into the annular section ( 2 , 3 ). 4. Tappet according to claim 3, characterized in that the first trigger pin ( 13 ) for locking / releasing the upper disc ( 10 ) and the second trigger pin ( 14 ) for locking / releasing the lower disc ( 9 ). 5. Tappet according to claim 4, characterized in that the first trigger pin ( 13 ) in the actuated state with its head region ( 25 ) projects through an upper disc recess ( 51 ) and thus releases the upper disc ( 10 ) and in the non-actuated state with its ge compared to the head region ( 25 ) widened shaft ( 27 ) passes through the upper disc recess ( 51 ) and locked. 6. Tappet according to claim 4 or 5, characterized in that the second trigger pin ( 14 ) in the actuated state with its head region ( 26 ) passes through a lower disc recess ( 54 ) and thus releases the lower disc ( 9 ) and in the non-actuated state with its shaft ( 28 ) widened relative to the head region ( 26 ), it engages and locks the lower disc recess ( 52 ). 7. Tappet according to one of claims 4-6, characterized in that the first trigger pin ( 13 ) and the second trigger pin ( 14 ) a lower disc recess ( 52 ) or an upper disc recess ( 53 ) reach through without locking. 8. Tappet according to one of claims 1-7, characterized in that the guide sleeve ( 7 ) has lugs ( 32 ), wherein Nasenausspa clearances ( 33 , 34 ) for receiving disc projections ( 35 , 36 ) of the discs ( 9 , 10 ) are provided for locking the annular section ( 2 ) on the annular section ( 6 ). 9. Tappet according to claim 8, characterized in that the Schei benvorsprünge ( 35 , 36 ) in a rotation of the discs ( 9 , 10 ) in the tangential direction in the nose recesses ( 33 , 34 ) are insertable bar. 10. Plunger according to claim 9, characterized in that the Schei benvorsprung ( 35 ) is designed as a wedge ( 37 ) so that when pushing into the nose recesses ( 33 , 34 ) a further axial displacement of the circular portion ( 2 ) under Lift off the cam ( 4 , 15 ). 11. Tappet according to one of claims 8-10, characterized in that the disks ( 9 , 10 ) the disk projections ( 35 , 36 ) neigh disclosed disk recesses ( 38 , 39 ). 12. Tappet according to claim 11, characterized in that the disc benauslösungen ( 38 , 39 ) by rotating the discs ( 9 , 10 ) with the nose ( 32 ) of the guide sleeve ( 7 ) can be brought into overlap, whereby the annular portion ( 2nd ) and the circular section ( 6 ) remain movable in the axial direction to each other.