This application claims the benefit of German Patent Application No. 10 2011 080 267.3, filed Aug. 2, 2011, which is incorporated herein by reference as if fully set forth.
An internal combustion reciprocating piston engine comprising a crank mechanism having at least one cylinder head whose intake and exhaust channels are regulated, each one, by at least one gas exchange valve configured as an intake and exhaust valve which can be activated by cams of at least one camshaft and by transmission elements driven by said cams, said cams being configured as sliding cams with at least one cam per sliding cam assembly while being arranged fixed against rotation but axially displaceable on a base shaft, said base shaft being guided, fixed on the internal combustion engine and comprising at least one actuator unit fixed on the internal combustion engine and comprising at least one actuator pin for displacing said sliding cam assemblies into different axial positions with help of at least one displacement groove which cooperates with said actuator pin, said displacement groove being arranged on a periphery of said sliding cam assemblies or on a periphery of a component which is fixed on said sliding cam assembly, said displacement groove being configured with a helical shape and comprising a run-in region and a run-out region for said actuator pin and also a displacement flank and an opposing support flank, said engine further comprising a detent device for locking the sliding cam assemblies in said different axial positions relative to a component fixed on the internal combustion engine.
Sliding cam assemblies of the above-noted type comprising displacement grooves as part of a camshaft for internal combustion reciprocating piston engines are known from DE-10 2004 008 670 A1. The displacement grooves in this case comprise lateral displacement flanks and opposing support flanks between which the actuator pin engages and displaces the sliding cam assembly in correspondence to the displacement contour on the displacement flank and the counter contour on the support flank and, again, decelerates the movement of displacement. The width of the run-in region for the actuator pin is chosen such that, taking into account the different tolerances between the actuator pin and the displacement groove, the actuator pin can always penetrate into the displacement groove. Directly following the run-in region, the displacement groove becomes narrower and narrower till it substantially equals the diameter of the actuator pin. Such displacement grooves are realized in that two milling operations with two mill running paths are performed, one of the mill running paths producing the run-in region with support flank as well as the run-out region, while the second one of the mill running paths produces the opposing flank of the run-in region, the support flank and the opposing side of the run-out region.
It is only in the direct displacement region that the two mill running paths are situated practically on top of each other. This means that high production costs for milling the displacement groove or grooves with help of two mill running paths extending over an angle of 360° are incurred.
In addition, high negative acceleration forces occur during deceleration of the actuator pin on the support flank.
The object of the invention is to improve the displacement groove so that it can be produced in a considerably more economic manner. In addition, the contact forces occurring between the displacement and support flanks and the actuator pin in the acceleration and deceleration regions should be situated, at the most, at the hitherto usual level, but preferably at a considerably lower level.
The invention achieves the above object by the fact that the distance between the displacement flank and the support flank remains constant along the entire extent of the displacement groove parallel to the direction of displacement of the sliding cam assembly.
In this way, the displacement groove can be produced in a single mill running path which leads to a considerable reduction of manufacturing costs. The distance between the flanks of the displacement groove is matched to the width of the run-in region, said width being chosen such that the actuator pin, taking into account the maximum tolerances between the displacement groove and the actuator pin, reaches the run-in region of the displacement groove. As a result, a displacement groove is produced that corresponds to the width of the run-in region and this width remains constant, which naturally means that a milling cutter with a larger thickness than in the prior art is used. Thus, the displacement groove can be made with help of a milling cutter, particularly an end-milling cutter, in a single milling operation. This also applies to all types of displacement grooves on the periphery of a sliding cam assembly, for example a double S-groove or a Y-groove. Moreover, all the displacement grooves of all the sliding cam assemblies of a camshaft, e.g. of an internal combustion engine, are made in this way, so that a considerable overall saving is achieved.
According to a further development of the invention, the displacement groove following immediately after the run-in region comprises, without an gradient, an acceleration region, a transition region and a deceleration region. The acceleration region includes an acceleration ramp and an adjoining acceleration flank, while the deceleration region comprises a deceleration flank and an adjoining deceleration ramp. The acceleration flank has a larger gradient than the acceleration ramp, while the deceleration ramp has a smaller gradient than the preceding deceleration flank, said gradients being measured relative to the respective cross-sectional plane of the sliding cam assembly starting from the run-in region. Depending on the speed of rotation of the reciprocating piston engine, a free flight phase of the sliding cam assembly relative to the stationary actuator pin occurs in the transition region between the acceleration flank and the deceleration flank, so that an alternation of contact of the actuator pin between the displacement flanks and the support flanks results. However, by an optimization of the acceleration flanks, a maximum differential speed of no more than 2.5 m/sec is produced between the actuator pin and the sliding cam assembly at an engine speed of, for example, 4000 rpm, so that the resulting deceleration forces on the opposing deceleration flank are significantly reduced to values below 700 N.
At low speeds of rotation of the sliding cam assembly, no free flight phase occurs, so that the alternation of contact on the opposing support flank takes place only when the locking device has snapped in.
The gradient of the acceleration ramp has been optimized such that, at higher speeds of rotation of the internal combustion reciprocating piston engine, the deceleration forces acting on the actuator pin are substantially reduced.
For further elucidation of the invention, reference should be made to the appended drawings in which one exemplary of embodiment of the invention is shown in a simple representation.
Mill running paths shown in
The run-out region, visible at the ends of the depth curves 3 and 3a, in which the depth again approximates the outer periphery of the sliding cam assembly, serves for a controlled exit of the actuator pin out of the displacement grooves 1 and 1a to thus enable a secure fixing of the actuator pin in the actuator assembly at the end of the run-out ramp.
1, 1a Displacement grooves
2, 2a Run-in regions
3, 3a Depth curves
4, 4a Acceleration ramps
5, 5a Acceleration flanks
6, 6a Transition phases
7, 7a Deceleration flanks
8, 8a Deceleration ramps
Number | Date | Country | Kind |
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102011080267.3 | Aug 2011 | DE | national |