Valve drive train device for an internal combustion engine

Abstract

In a valve drive train device for an internal combustion engine of motor vehicle, wherein at least one axially movably mounted cam element including at least one cam set with at least two cam parts and a shifting gate with at least two gate track for converting a rotary movement of the cam element into an axial shifting motion, at least one of the cam parts and the adjacent gate track are disposed in an at least partially axially overlapping relationship for reducing thereby the axial length and the mass of the cam element or permitting the use of a larger, highly durable, actuating mechanism.

Claims

1. A valve drive train device for an internal combustion engine of a motor vehicle, comprising: a camshaft with at least one axially movably mounted cam element (10), each axially movably mounted cam element (10) being provided with at least one cam set (11, 15) and each cam set (11, 15) including at least two cam parts (12, 13, 14; 16, 17, 18) and a shifting gate (19) with at least two gate tracks (20, 21) for converting a rotary movement of the at least one axially movably mounted cam element (10) into an axial shifting motion of the at least one cam element (10), with at least one of the cam parts (14, 16) and at least one of the gate tracks (20, 21) being disposed partially in an axially overlapping relationship.

2. The valve drive train device according to claim 1, wherein the cam part (14, 16) has a base circle area, and the gate track (20, 21) and a respective cam part (14, 16) are disposed axially overlapping in the base circle area of the respective cam part (14, 16).

3. The valve drive train device according to claim 2, wherein an overlap width (22) of the gate track (20, 21) and the respective cam part (14, 16) of at least 10% of a cam part width (24) is provided.

4. The valve drive train device according to claim 2, wherein an overlap width (22) of 50% of the gate track (20, 21) and the respective a cam part (14, 16) is provided.

5. The valve drive train device according to claim 1, wherein the at least one axially movably mounted cam element (10) has at least two cam sets (11, 15) each with at least two cam parts (12, 13, 14; 16, 17, 18) and the at least two gate tracks (20, 21) of the shifting gate (19) are disposed axially between the at least two cam sets (11, 15).

6. The valve drive train device according to claim 5, wherein each of the gate tracks (20, 21) of the shifting gate (19) is disposed at least partially axially overlapping with a respective adjacent cam part (14, 16) of the respective cam set (11,15).

7. The valve drive train device according to claim 1, wherein the gate tracks (20, 21) each include an engagement segment and, respectively, a disengagement segment at least one of which is disposed axially overlapping with the respective adjacent cam part (14, 16).

8. The valve drive train according to claim 1, wherein each cam set (11, 15) has a first cam part (12, 16), a second cam part (13, 17) and a third cam part (14, 18).

9. The valve drive train according to claim 1, wherein a support shaft (23) is provided on which the at least one cam element (10) is non-rotatably but axially displaceably mounted.

10. The valve drive train according to claim 1, wherein the at least one axially movable cam element (10) is axially movable by an actuator unit with gate engagement elements for engagement in the respective gate track (20, 21) for axially shifting the cam element (10) upon rotation thereof.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a perspective representation of a valve drive train device according to the invention and

(2) FIG. 2 shows the valve train device in a plan view.

DESCRIPTION OF A PARTICULAR EMBODIMENT OF THE INVENTION

(3) FIGS. 1 and 2 show a valve train device for an internal combustion engine. The valve train device comprises a support shaft 23 which is connected by means of a crankshaft drive (not shown in greater detail) to a crankshaft of the internal combustion engine. In addition, a camshaft phase adjuster, which is provided to adjust a phase position between the crankshaft and the support shaft 23, can be disposed between the support shaft 23 and the crankshaft.

(4) Furthermore, the valve train device comprises a plurality of cam elements 10 which are axially displaceably disposed on the support shaft 23. The cam elements 10, only one of which is illustrated, are non-rotatably connected to the support shaft 23. The illustrated cam element 10 comprises two sets of cams 11, 15, which are provided for actuation of gas change valves of an individual cylinder. The support shaft 23 with the cam elements 10 mounted thereon forms a camshaft for actuating the gas change valves of different cylinders of the internal combustion engine.

(5) For changing over between different types of valve actuation, the cam element 10 has a shifting gate 19 with two gate tracks 20, 21. The gate tracks 20, 21 are provided in order to convert a rotary movement of the cam element 10 into an axial shifting motion. The gate tracks 20, 21 each have an engagement segment, at least one shifting segment and one disengagement segment. The engagement segments and the disengagement segments each extend in the circumferential direction. The shifting segments additionally have an axial component. The gate tracks 20, 21 are designed in the form of grooves which are formed or cut into the cam elements 10.

(6) For shifting the cam element 10, the valve train device also has an actuator unit with two gate engagement elements. Each of the gate engagement elements is associated with one of the gate tracks 20, 21. The gate engagement elements are designed as shift pins which, in the extended state, extend into the gate tracks 20, 21. The gate engagement elements are merely mounted displaceably along their main extension direction. The gate tracks 20, 21 and the associated gate engagement element are provided in each case for a shifting direction. Depending upon the shifting direction in which the cam element 10 is to be shifted, the corresponding gate engagement element is brought into engagement with the associated gate track 20, 21. The rotary movement of the cam element 10 causes the cam element 10 to be displaced in the axial direction by the axial component of the shifting segment of the corresponding gate track 20, 21 in conjunction with the stationary gate engagement element. All the cam elements 10 of the valve train device are designed in an analogous manner.

(7) In the illustrated exemplary embodiment, the gate tracks 20, 21 are provided for shifting three different shift positions. The cam sets 11, 15 each have three part cams 12, 13, 14 and 16, 17, 18 with different cam curves. The respective first cam part 12, 16 is designed as a deactivation cam. It has a zero stroke and thus is provided for deactivation of a cylinder. The respective second cam part 13, 17 is designed as a full load cam. The respective third cam part 14, 18 is designed as a partial load cam.

(8) In the axial direction, the shifting gate 19 with the two gate tracks 20, 21 is disposed between the two cam sets 11, 15. There is a first gate track 20 and an adjacent cam part 14 of the first cam set 11, which, in the axial direction, is disposed immediately adjacent to the gate track 20. Also, the second gate track 21 and the cam part 16 of the second cam set 15 are disposed immediately adjacent each other. However, the gate track 21 and the cam part 16 are shown in the axial direction to be disposed partially overlapping. A configuration of the gate track 20 and of the cam part 14 as well as a configuration of the gate track 21 and of the cam part 16 are in each case the same, and, for this reason, only the arrangement of the gate track 21 and of the cam part 16 are described below.

(9) The cam parts 12, 13, 14 and 16, 17, 18 each have a base circle phase and the cam parts 13, 14 and 17, 18 have a certain lift range. In the base circle phase, the associated gas change valve is completely closed. In the axial direction, the gate track 21 extends into a part-region of the cam element 10 in which the cam part 16 of the cam set 15 is disposed. The cam part 16 and the gate track 21 are therefore disposed an overlapping relationship over an angular range of a camshaft angle of at least 20°. Over the angular range in which the cam part 16 and the gate track 21 are disposed axially overlapping, the cam part 16 has a reduced cam part width 24 with respect to the rest of its configuration.

(10) In the base circle phase, the cam part 16 has a constant height. The gate track 21 and the cam part 16 are disposed partially axially overlapping in the base circle phase of the cam part 16. The angular range in which the gate track 21 and the cam part 16 are disposed in an axially overlapping relationship lies completely inside the base circle phase of the cam part 16.

(11) The cam part 16 and the gate track 21 have an overlap width 22, which is between 10% and 50% of the cam part width 24, with respect to the cam part 16. With respect to the gate track 21, the overlap width 22 is likewise between 10% and 50% of a gate track width 25. As a result, the gate track 21 protrudes only partially into the axial part-region of the cam part 14.

(12) In the illustrated exemplary embodiment, the disengagement segment of the gate track 21 is disposed axially overlapping with the cam part 16. The disengagement segment, which merely extends in the circumferential direction, is completely inside the angular region in which the gate track 21 and the cam part 16 are disposed overlapping.

(13) Moreover, the shifting segment of the gate track 21 may also be disposed partially in the angular range in which the gate track 21 and the cam part 16 are disposed in axially overlapping relationship. In this angular range, the shifting segment of the gate track 21 merges into the disengagement segment in the angular range. A camshaft angle, by means of which the shifting segment is disposed overlapping with the cam part 16, is substantially less than the camshaft angle over which the disengagement segment overlaps with the cam part 16.

(14) The valve train device has a cam follower (not shown in greater detail) which in the event of a rotation of the cam element 10 is actuated by the respective cam and provides for a valve lift that is opening of the respective gas change valve predetermined by the cam curve of the corresponding cam part 12, 13, 14 and 16, 17,18. The cam follower may be designed for example in the form of a roller cam follower or a roller type rocker arm. If the cam element 10 is shifted into a shift position in which the cam follower runs on the cam part 16 which is designed to axially overlap with the gate track 21, the gate track 21 extends only partially in each case below the cam follower.

LIST OF REFERENCE NUMERALS

(15) 10 cam element 11 cam 12 cam part 13 cam part 14 cam part 15 cam 16 cam part 17 cam part 18 cam part 19 shifting gate 20 gate track 21 gate track 22 overlap width 23 support shaft 24 cam part width 25 gate track width