DE3831642C2 - - Google Patents

Description

The invention relates to a valve train for a globe valve in an internal combustion engine with the in the preamble of Features specified claim 1.

Such a valve train is from JP Abstract 55-1 51 106 known. In this known valve train there is Swing cams and in particular its pivot axis to the side of the Rocker arm so that the camshaft far to the side of the longitudinal axis of the globe valve and the valve train is very wide. Furthermore, swing cams and rocker arms are activated by the camshaft or by the adjustment device pivoted in the opposite direction so that large Slideways with poor line contact between the two Parts arise.

From WO 83/04 070 is a similar valve train as above described known, but with the swing cam has no base orbit, so that a hike of the investment point the swing cam on the tappet of the globe valve not on such a base orbit through this valve train is known.

The invention has for its object a valve drove the generic type in such a way that a narrow, space-saving design is achieved and that as possible small relative movements of the moving parts to each other  an adjustment both by the adjustment device as well caused by the camshaft. Also a change in Stroke curve of the lift valves not only in terms of lift height and Stroke duration may be possible.

The task is for a valve train of the type mentioned Art by the characterizing features of claim 1 solved.

In the valve train according to the invention is indicated by the Arrangement of the moving parts to each other a very small Width reached, essentially only by the length of the Rocker arm is determined. The camshaft can also be used usual space in or close to the longitudinal axis of the globe valve maintained. Furthermore results from the invention Arrangement of the moving parts swiveling in the same direction the rocker arm and the rocking cam during adjustment both by the adjustment device and by the camshaft, so that only small relative movements between these parts arise. The already low friction is caused by the Rotation of the rocker cam on the rocker arm is further reduced, this also enables better power transmission between the rocker arm and the rocker cam as the line contact in the known valve trains.  

Furthermore, the described pivoting causes an adjustment of the valve stroke after the rocker arm early, so that with a reduction in lifting height and lifting time Beginning and end of stroke not equal amounts to be moved towards each other, but with only a little shifted start of stroke the end of the stroke by a considerable amount Amount is adjusted earlier. The side ver shift of the overall stroke curve improved in particular when used with an inlet valve, the filling of the Internal combustion engine cylinders.

By designing the valve train according to the patent Claim 2 are particularly with the greatest lifting height and the stroke duration of the valve train members before the start of the stroke of the globe valve accelerates and ver hesitates, so that their acceleration or deceleration duration is greater than the stroke duration of the globe valve, whereby smaller acceleration values and mass forces, which in particular the supports and articulations of the  Load valve train members, result.

The valve train designed according to claim 3 enables the stroke curve to be shifted, possibly in over storage of the by the design of claim 2 achieved shift without the in general sought symmetrical course of the stroke curve abandoned must become.

In the claims 4 and 5 are versions of the Adjustment device specified that a safe Ab support for the rocker arm and in turn are easy and precise to adjust.

The design of the valve train according to the patent saying 6 results in a large force-transmitting connection between the rocker arm and the rocker cam, by which also ensures the transverse position relative to the camshaft is determined.

With the configuration of the specified in claim 7 Valve train can exert large forces on the support are transmitted with a clear definition at the same time the pivot axis of the vibrating cam.

According to claim 8, the valve clearance compensation element arranged in a place where there is no additional space taken up by being eliminated often in a tappet at the end of the valve stem brought compensation elements still space in the valve length direction can be saved.  

The design of the valve train according to the patent saying 9 ensures simultaneous and even Actuation of all intake or exhaust valves of a cylinder with a single swing cam. According to the Claims 10 and 11 also in this multi-valve off sufficient space for the ball joint and the Valve clearance compensation elements created.

In the following the invention based on one in the drawing illustrated embodiment explained in more detail. Here shows:

Fig. 1 is the same element in a valve train according to the invention specific matic representation without valve clearance,

Fig. 2 element a partial longitudinal section through the cylinder head of an internal combustion engine having the valve train of Fig. 1 with a valve lash adjuster,

Fig. 3 is a partial cross-section through the cylinder head of Fig. 2 along the line III-III,

Fig. 4 is a partial cross section through the cylinder head of Fig. 2 along the line IV-IV and

Fig. 5 is an illustration of achievable with the inventive valve train valve lift with α on the camshaft angle _NW-applied valve lift H.

A camshaft 1 with a cam 2 rotates counterclockwise according to arrow 3 . The cam 2 is formed asymmetrically, so that its leading edge 4 is steeper than its trailing edge 5 . The cam 2 acts on the central region of a rocker arm 6 extending transversely to the camshaft 1 , which is supported with its right end region in the drawing on a Verstellein device 7 . This consists essentially of an actuating shaft 8 with a cam 9 with a decreasing distance to the axis of rotation 10 of the actuating shaft 8 , on which the oscillating lever 6 rests. At its other longitudinal end, the rocking lever 6 is articulated by means of a ball joint 11 on a rocking cam 12 which consists of a ball head 13 on the rocking cam 12 and a ball socket 14 in the rocker arm 6 be. The swing cam 12 is pivotable about a pivot axis 15 bar, which is supported on the housing 16 of the cylinder head ( Fig. 2 to 4). It engages with a base circular path 17 or an adjoining cam path 18 , the meeting of which is marked by the point 19 , on a sliding surface 20 of a tappet 21 , against which a lift valve 22 with its valve stem 23 rests on the inside.

The axis of rotation of the camshaft 1 and the pivot axis 15 of the oscillating cam 12 intersect at least approximately the axis of the valve stem 23 . The vibrating cam 12 is accommodated in its entirety including the ball head 13 and the pivot axis 15 in the space between the rocker arm 6 and the bucket tappet 21 . As a result of these measures, the valve train including the oscillating cam 12 is very narrow. The space required for the rocker arm 6 and the rocking cam 12 in height can be won by the fact that a valve clearance compensation element is not, as is often used, accommodated in the tappet 21 , but supports the pivot axis 15 of the rocking cam 12 ( FIGS. 2 to 4 ). This makes it possible to leave the space of the camshaft unchanged with respect to an arrangement with un direct drive of the tappet by the camshaft.

In Fig. 1, the actuating shaft 8 is set in the position for the stroke curve with the greatest possible lifting height and stroke duration. The camshaft 1 is in a position in which the cam 2 rests on the rocker arm 6 with the beginning of the leading edge 4 . The point of contact 24 between the swing cam 12 and the tappet 21 is on the base circle of the rocker cam 12 track 17, with distance from point 19 at the transition from the basic circular path 17 to the cam track 18th This means that at the beginning and towards the end of the actuation of the rocker arm 6 and the rocker cam 12 by the cam 2, the point of contact 24 on the base circular path 17 moves to the point 19 , so that the bucket tappet 21 and the lift valve 22 are not lifted, so that the movement and acceleration of the rocker arm 6 and rocker cam 12 extend over a considerably greater period of time than the stroke duration of the lifting valve 22 , for example, as shown, over 180 ° camshaft angle with a generally common stroke duration of the lift valve 22 of about 140 ° camshaft angle. The greater acceleration duration results in lower accelerations and thus smaller forces acting on the rocker arm 6 and the rocking cams 12 and their supports and connections.

If the stroke duration and the lift height of the lift valve 22 are to be reduced, for example at a lower speed and / or load of the internal combustion engine, the actuating shaft 8 is rotated clockwise (arrow 25 ), the support point of the oscillating cam 6 on the cam track 9 moves downwards, the oscillating lever 6 is pivoted around the camshaft 1 and with it the oscillating cam 12 in a clockwise direction. As a result, the point of contact 24 on the base circle path 17 moves to the right, moving away from point 19 . When actuated by the cam 2 , the point of contact 24 migrates for a shorter time and less on the cam track 18 , which results in the shorter stroke duration and lifting height of the lifting valve 22 . In addition, the cam 2 can actuate the rocker arm 6 earlier by pivoting the rocker arm 6 against the direction of rotation 3 of the camshaft when the actuating shaft 8 is adjusted in the direction of the arrow 25 , resulting in a displacement of the lift curves ( FIG. 5) overall earlier. This results in a considerably earlier closing of the lift valve 22 with only a slight shift in the opening time, which is particularly desirable for intake lift valves with a low load and speed of the internal combustion engine. The caused by the asymmetrical shape of the cam 2 displacement of the stroke curve can be overlaid on the described form of displacement and thus reinforce or reduce it in the desired manner.

As can be seen in Fig. 2, the valve drive according to the invention with a variable stroke is particularly suitable for the common drive of two inlet lift valves 22 per cylinder 26 of the internal combustion engine.

The with the bearing pin 27 in the housing 16 of the cylinder head mounted camshaft 1 drives with the two cams 2 each have a rocker arm 6 , which jointly drive a single approximately U-shaped rocking cam 12 via two ball joints 11 , each with a leg 28 on the Bucket 21 each stroke valve 22 abuts so that they are moved completely uniformly be. As can be seen particularly on the right-hand side of FIG. 2, the rocking levers 6 are reinforced laterally by a rib 29 projecting downwards, next to which a recess 30 remains, into which the leg 28 is immersed when the rocking cam 12 is actuated. The web connecting the legs 28 is designed as a ball socket 31 which, together with a ball head 32, forms a ball joint 33 . In the ball socket 31 and ball head 32 , two pins 34 are inserted parallel to the axis of the camshaft 1 , which ensure pivoting of the oscillating cam 12 about the pivot axis 15 ( FIG. 1). In the ball head 32 a known hydraulic valve play compensation element 35 is housed, which is supported on an insert part 36 which is inserted in the housing 16 and is firmly connected to this by means of a bayonet lock 37 and possibly welding. The insert part 36 has a cylindrical recess 38 in the upper middle region in order to create sufficient space for the camshaft 1 . As can be clearly seen in FIG. 2, the two oscillating levers 6 and the two legs 28 move of the swing cam 12 on both sides of the ball joint 33 so that 12 it is sufficient on the one hand, a symmetrical support of the rocker cam and on the other hand the space between the parts and the camshaft 1 is used as best as possible by the ball joint 33 , the valve clearance compensation element 35 and the insert part 36 which supports this and partially encompasses the camshaft 1 .

In Fig. 3, a spring 39 can be seen, which is supported on the housing 6 and which presses the rocking cams 12 and the rocking levers 6 upwards, so that their contact with the camshaft 1 and the cam track 9 is ensured at all times.

Claims (11)

1.Valve drive for a lifting valve in an internal combustion engine with a camshaft with a cam, with a rocking lever pivoting when actuated by the cam around a support, the position of which can be adjusted by an adjusting device depending on operating variables such as the speed or the load of the internal combustion engine , which is supported with its one longitudinal end on the adjusting device and with its other longitudinal end on a rocking cam, while the cam of the camshaft engages on the intermediate central region of the rocking lever, the rocking cam actuated by the rocking lever being pivotable about a pivot axis supported on the machine housing a base orbit and a cam track adjoining it rests on a tappet of the lift valve and the contact point when the adjustment device is adjusted in the direction of a shorter lift duration and lift height by pivoting the oscillating cam to de r Basic circular path moves away from the cam path , characterized in that the oscillating cam ( 12 ) including its pivot axis ( 15 ) is arranged essentially between the respective points of contact between the cam ( 2 ) - oscillating lever ( 6 ) and oscillating cam ( 12 ) - bucket tappet ( 21 ) is that the rocker arm ( 6 ) is articulated on the rocker cam ( 12 ) by means of a swivel joint ( 11 ) and that the rocker arm ( 6 ) counteracts an adjustment of the adjusting device ( 7 ) in the direction of a shorter lift duration and lift height of the lift valve ( 22 ) the direction of rotation (arrow 3 ) of the camshaft ( 1 ) is pivoted. 2. Valve train according to claim 1, characterized in that in the base circuit of the camshaft ( 1 ) on the oscillating lever ( 6 ) the point of contact ( 24 ) of the oscillating cam ( 12 ) on the globe valve ( 22 , bucket tappet 21 ) at each position of the adjusting device ( 7 ) on the base circular path ( 17 ) of the vibrating cam ( 12 ) at a distance from the cam path ( 18 ). 3. Valve train according to claim 1 or 2, characterized in that the cam ( 2 ) of the camshaft ( 1 ) is formed asymmetrically with respect to the trailing edge ( 5 ) steeper leading edge ( 4 ). 4. Valve train according to one of claims 1 to 3, characterized in that the adjusting device ( 7 ) is an actuating shaft ( 8 ) with a support for the rocker arm ( 6 ) serving as cam track ( 9 ) which has different radial distances over the circumference Axis of rotation ( 10 ) of the adjusting shaft ( 8 ). 5. Valve train according to one of claims 1 to 3, characterized in that the adjusting device ( 7 ) is a hydraulic element with a hydraulically adjustable piston serving as a support for the rocker arm ( 6 ). 6. Valve gear according to one of claims 1 to 5, characterized in that the articulated connection between the rocker arm ( 6 ) and the rocking cam ( 12 ) from a pan in a ball ( 14 ) of the rocker arm ( 6 ) mounted ball head ( 13 ) of the Swing cam ( 12 ) exists. 7. Valve train according to one of claims 1 to 6, characterized in that the support of the oscillating cam ( 12 ) takes place in a ball joint ( 33 ) whose pivot axis ( 15 ) by in particular pins ( 34 ) through the ball socket ( 31 ) in the ball head ( 32 ) are used, is set parallel to the axis of rotation of the camshaft ( 1 ). 8. Valve train according to claim 7, characterized in that the swing cam ( 12 ) in its pivot axis ( 15 ) on a largely in the ball head ( 32 ) of the ball joint ( 33 ) is arranged hydraulic valve lash compensation element ( 35 ). 9. Valve train according to one of claims 1 to 8, characterized in that the internal combustion engine is designed as a reciprocating internal combustion engine with several, in particular two intake or exhaust valves per cylinder ( 26 ) and that the all intake or exhaust valves of a cylinder actuating swing cams ( 12 ) forms an approximately U-shaped part in plan view with a base circular path ( 17 ) and cam path ( 18 ) on each leg ( 28 ). 10. Valve train according to claim 9, characterized in that the ball socket ( 31 ) of the ball joint ( 33 ) is arranged in the web of the U-shaped part. 11. Valve train according to claim 8, characterized in that the one rocking cam ( 12 ) actuating rocker arm ( 6 ) laterally next to the valve clearance compensation element ( 35 ) move symmetrically to this.