The invention relates to a finger lever of a valve drive of an internal combustion engine, which can be switched to different lifts for at least one gas-exchange valve, with an outer arm between whose limbs an inner arm extends. Both arms can be pivoted relative to each other and can be coupled to each other through a coupling means, so that when coupled a larger valve lift is generated and when decoupled a smaller or 0 valve lift is generated. A stop for a gas-exchange valve is applied at one end on a bottom side of the finger lever and a complementary surface for a support element is applied on the other end. In addition, at least one counter surface for a large lifting lobe is provided on a top side of the outer arm and a counter surface for a small or 0 lifting lobe is provided on a top side of the inner arm.
A finger lever of this type is already known from DE-OS 27 53 197. As coupling means, a catch is provided, which catches underneath the inner arm and can be displaced by means of a complicated linkage mechanism. In a disadvantageous way, the catch increases the overall height of the switchable finger lever. At the same time, the external loading by means of the linkage has proven to be relatively complicated.
From DE 102 11 038 A1, a switchable rocker arrangement also emerges, in whose outer arm a slide for coupling is arranged. This slide can be displaced by electromagnetic means arranged externally. Here, it is also clear that this external loading of the slide unnecessarily increases the required installation space for the switchable finger lever in the cylinder head region. Thus, the previously mentioned finger lever is also built undesirably long. In addition, it has been determined that relatively large forces and thus component loads in the coupling region must be taken into account due to the relatively short inner arm when it is coupled to the outer arm.
Therefore, the object of the invention is to create a finger lever of the previously mentioned type, for which the cited disadvantages are overcome through simple means.
According to the invention, this problem is solved, in that the limbs of the outer arm are connected by a crossbar in a region of the end at a complementary surface for the support, wherein in the inner arm, a smooth surfaced blind borehole is located above the complementary surface and extends from the end and includes a slide that can be displaced therein in the longitudinal direction as coupling means. This slide for the coupling of the arm can be displaced out of the blind borehole so that it catches below a driver surface of the crossbar provided as the bottom side, wherein the inner arm has an essentially smooth surface on its top side up to the counter surface and at least one finger-like height stopping means for the outer arm extends over the crossbar from the inner arm that is at least for the most part aligned with a top side thereof on the side of its complementary surface, and wherein the inner arm is connected to the limbs of the outer arm in a region of an end on the side of the gas-exchange valve so that it can pivot.
Thus, a switchable finger lever is provided, for which the cited disadvantages are eliminated through simple means.
Viewed overall, also in its height direction, the finger lever is built very compact, so that for subsequent implementation in completed cylinder heads for non-switchable valve drives, no major problems are to be expected or several lines of engines can be equipped.
Due to the coupling means (slide) with its pressure space lying directly above the complementary surface for the support element, only very short hydraulic paths are provided. Also, it is determined that only relatively small component loading must be taken into account due to the favorable arm ratios in the coupling region. The blind borehole for the coupling means can also be produced simply in one processing step, wherein it is especially advantageous that the inner arm has height stops that project “flat” from the inner arm. For the coupling case, this can represent outstanding positional correspondence for the blind borehole with the catch surface and simultaneously a safety device against loss.
The slide should be displaced outwards in the longitudinal direction for the coupling position, but it is also conceivable to displace this inwards to produce a coupling. For the coupling position, the slide catches preferably under the bottom side of a crossbar of the outer arm lying in the region using simple means and methods. However, it is also conceivable to provide a corresponding recess for the slide in the crossbar.
Stopping means for limiting the coupling motion on the crossbar can be located opposite the slide. Thus, a sleeve in the blind borehole is provided, on whose one end the slide is subjected to path limitation. However, tab-like projections or stops of a general type can also be provided on the bottom side of the crossbar. In the case of a borehole or the like, the borehole can be provided with a stop as the coupling surface in the crossbar. For this purpose, it is also provided to form the borehole with steps.
It is especially preferred when the slide is pushed in only one displacement direction via hydraulic medium pressure and in its other direction by the force of a spring means, such as a coil compression spring. However, it is also conceivable to displace this slide in both directions hydraulically or to provide the force of another servo means, such as, for example, an electromagnet, a magnet, or the like, in at least one direction.
Due to the integral formation of the circular expanded portion of the slide with the section actually implementing the coupling, according to another dependent claim, a slide that is economical to produce is provided. Optionally, a multi-part formation is also conceivable.
To minimize the production expense, especially for a sheet-metal formation, alternatively the blind borehole for the slide can also be applied in a separate insert. This is connected to the inner arm by a connection known to someone skilled in the art, thus, for example, through welding, swaging, press-in, or the like. However, an integral production is preferred.
Instead of the coil compression spring for the slide, other pressure-exerting means, such as plate springs, spiral springs, etc., are also conceivable. A use of magnetic means is also conceivable.
According to another aspect of the invention, it is proposed to have a tab-like projection extend from a top side of the crossbar of the outer arm in the region of the slide. This projection prevents undesired extension of the slide over the top side of the crossbar for the decoupled movement of the outer arm.
In addition, according to the invention the arm is to be produced from a lightweight material, such as sheet metal. This has an advantageous effect on the total mass of the finger lever and also on the production costs. However, a casting formation (precision casting) of the finger lever is also conceivable. Alternatively, the finger lever can also be produced in a metal injection-molding process (MIM—“Metal Injection Molding”).
The invention is explained in more detail preferably with reference to the drawings. Shown are:
The Figures show a finger lever 1 that can be switched for different cam lifts. This arm includes an outer arm 2, which is connected to one end 9 by a crossbar 15. An inner arm 4 lies between limbs 3 of the outer arm 2 and is connected in an articulated way to the outer arm 2 in the region of the other end 7. For this purpose, the inner arm 4 moves on an axle 32, whose outer ends extend axially into boreholes of the limbs 3 of the outer arm 2.
A swivel-pin spring, which surrounds the axle 32 within the inner arm 4, is provided as the lost-motion spring 33. In the decoupled case of the outer arm 2 from the inner arm 4, a restoring motion is exerted through the action on the limbs of the inner arm, not explained in further detail, on the outer arm 2.
In the approximate region of the center, the limbs 3 of the outer arm 2 each have on their top side 11 a counter surface 12 for large lifting lobes. This counter surface 12 is embodied as a sliding surface. In contrast, the inner arm 4 also has in the region of this center area, in the section of its top side 13, a counter surface 14 for a small lifting lobe. Here, this counter surface 14 is shown as a rotatable roller. Also to be seen here is that the outer arm 2 is closed in the region of the end 7 by a crossbar 31, so that, viewed overall in top view, it forms a rectangular-like profile.
On a bottom side 6 (see
The slide 17 includes the mentioned circular expanded portion 17a, which is positioned directly in the blind borehole 16. A smaller sized section 23 contacts the circular expanded portion 17a on the side facing out of the blind borehole 16. This section has an end 35 axially on the outside.
Stopping means 18a extend in the blind borehole 16 in a region of the section 23. Here, the stop is produced as a thin-walled ring, which is fixed with its outer surface directly in the blind borehole 16. Here,
Also to be seen is that a spring means 22 is on the section 23. This is supported axially on the inside on the circular expanded portion 17a. Axially outwardly, the spring means 22 contact a sleeve 24. The section 23 projects directly through the sleeve 24, which extends with its outer surface in a bore of the stopping means 18a.
As follows from
Also noted is that a tab-like projection 37 extends from the top side 38 of the crossbar 15. Thus, for the pivoting motion of the outer arm 2 in the decoupled case, the outer end 35 of the slide 17 is always opposite an inner side 36 of the projection 37 or the crossbar 15. Undesired movement of the slide 17 over the top side 38 of the crossbar 15 is thus prevented.
Number | Date | Country | Kind |
---|---|---|---|
103 18 295.0 | Apr 2003 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP04/02369 | 3/9/2004 | WO | 1/31/2006 |