WO2013060405A1 - Valve train for an internal combustion engine - Google Patents

Abstract

The adjusting of various cam contours (10a; 10b; 11a; 11b) by axially shifting cam pieces (3) on the camshaft (22) is known. It is disadvantageous that an engaging element in the form of a spring is constantly effective and the engaging mechanism must be overcome during every initiation of the shift of the cam piece (3), having the consequence that increased shifting forces are required. In order to improve same with respect to wear and increased operational reliability, according to the invention the locking element (6) is unlocked solely for the axial shifting of the cam piece (3) and is locked solely in the region of the occupied end positions of the cam piece (3). The invention is intended for valve trains for internal combustion engines.

Description

 Valve train for an internal combustion engine

The invention relates to a valve drive for an internal combustion engine according to the preamble of claim 1.

From DE 102004056290 A1 a generic valve train is already known. The cam piece has several different cam contours, which are in operative connection with a lift valve. The different cam contours are adjusted by axial displacement of the cam piece on the camshaft.

The locking of the cam pieces against unintentional axial displacement on the camshaft takes place by means of a spring-loaded detent element, which is arranged radially in the camshaft, and engages in latching contours in the cam piece. The cam piece is thereby displaced beyond the force of the spring. The disadvantage here is that the locking element is constantly effective via a spring and the latching mechanism must be overcome at each initiation of the displacement of the cam piece, with the result that increased displacement forces are required. This leads to premature wear. The switching elements, latching contours and the locking element must therefore be dimensioned larger, resulting in increased weight, volume and energy consumption.

Also known from DE 19702389 A1 is a valve train in which the cam piece has a plurality of different cam contours, which are in operative connection with a lift valve. The different cam contours are adjusted by axial displacement of the cam piece on the camshaft. A locking element secures the cam pieces against unwanted axial displacement on the camshaft. For this purpose, the locking element is designed as a two-part, substantially cylindrical pin, whose parts are arranged radially in the camshaft or in the interior of the cam piece. One part of the pin stands by means of one inside the camshaft arranged spring under bias against the other part of the pin, which protrudes beyond the contour of the cam piece. Each time the camshaft is rotated, the locking element is pushed inwards against the force of the spring by a roller picker located between the lift valve and the cam, thus unlocking it, even if there is no displacement. This leads to increased wear of the locking mechanism and unnecessary noise. In addition, at each camshaft rotation, in which there is no simultaneous displacement of the cam piece, the cam piece temporarily unguided in the axial direction, which can lead to unwanted displacement of the cam piece on the camshaft, for example by vibrations. At standstill of the internal combustion engine, the locking element can even be in an unlocked position and the cam piece so that it can be displaced by external shocks, eg rail transport of a vehicle with this engine unintentionally.

The invention has for its object to provide a valve train for an internal combustion engine, the locking mechanism has a lower wear and increased reliability.

According to the invention the object is achieved by the features of claim 1. The valve train according to the invention consists of a camshaft, which consists of a support shaft with at least one rotatable and axially displaceable on the support shaft cam piece, which is displaceable by a switching element which engages in a shift gate. The cam piece is displaceable by the contour of the shift gate from a first axial end position to a second axial end position and durable by a locking element in these end positions. In this case, the locking element is unlocked exclusively during axial displacement of the cam piece and locked exclusively in the region of the end positions of the cam piece. The displacement forces are therefore very low, resulting in lower construction volume, longer life, lower costs and low noise. Likewise, in all operating conditions, the cam pieces are locked, except when displaced on the carrier shaft, so that no undesired shifting of the cam pieces can occur, e.g. due to vibrations or vibrations. The cam pieces are thus guided axially at all times, in the end positions by the locking element, when moving through the switching element, which engages in the shift gate.

Further embodiments emerge from the subclaims. A particularly safe valve train is obtained when the locking element unlocked when operating the switching element and automatically locked when reaching the end positions of the cam piece.

It is particularly advantageous if the unlocking of the locking element takes place by a mechanical coupling of the switching element and the locking element.

In a preferred embodiment, the locking element of a bolt, for example, a locking bolt, a spring, a guide, which may be formed as a cylindrical protuberance, and at least two detent openings formed.

Preferably, the switching element comprises an actuator and an example designed as an actuating pin actuator.

 The mechanical coupling of the switching element and the locking element is most easily formed from a rocker and a connecting piece.

 Further advantages emerge from the following description of the drawing. In the drawing, an embodiment of the invention is shown.

Showing:

 Fig. 1 detail of the valve train for an internal combustion engine in partial

 Sectional view with schematically simplified locking mechanism in a first end position and

 2 shows a detail of the valve drive as in FIG. 1 in a second end position.

The valve train according to the invention comprises a camshaft 22, which consists of a carrier shaft 1, which is mounted in at least two camshaft bearings 2a, 2b corresponding left and right. The carrier shaft 1 has at least one cam piece 3 per cylinder of the internal combustion engine, which consists of a central part 15 and on each of the left and right end subsequent cam sections 10, 11, followed by a respective shift gate 5a; 5b. Each shift gate 5a; 5b has a switching contour 12a; 12b, for example in the form of a helical circumferential groove whose groove depth is variable. The switching contour 12b shown on the left in FIG. 1 has a helical shape to the right or to the inner cam portion 10 or to the cam contours 10a, 10b Groove. The switching contour 12a shown on the right also runs mirror-symmetrically from right to left towards the cam contours 11a, 11b. The cam sections 10, 11 each have two different cam contours 10a, 10b; 11a, 11b. The cam contours 10a, 10b; 11a, 11b have different outer contours and thus cause different operating characteristics for gas exchange valves. To the cam portions 10, 11 engage takers or cam follower, for example in the form of rocker arms 17a; 17b, actuate the appropriate gas exchange valves. In the exemplary embodiment, these are intake valves, but it is also possible to connect exhaust valves with the valve drive according to the invention. Due to the different operating characteristics of the gas exchange valves can be adjusted depending on the power requirements of the engine different valve strokes. This is done by moving the cam piece 3 with its cam contours 10a, 10b, 11a, 1b on the carrier shaft 1. The two cam contours 10a, 10b of the one cam portion 10 are depending on the position of the cam piece 3 on the carrier shaft 1 alternately with a first inlet side Gas exchange valve, the two cam contours 11a, 11b of the other cam portion 11 with a second inlet-side gas exchange valve via the cam followers 17a, 17b in operative connection. The cam piece 3 is rotatably connected to the support shaft 1 and axially displaceable by means of a spline, not shown. The inside provided for longitudinal toothing of the cam piece 3 engages in a corresponding external toothing of the support shaft 1, so that longitudinal displacements of the cam piece 3 on the support shaft 1 are possible, but in the circumferential direction a rotationally fixed connection.

Next, the valve train according to the invention has two switching elements 26a, 26b, each with an actuator 4a; 4b, which is, for example, electromagnetically actuated. The actuator 4a; 4b shifts an axially extending to the cam piece 3 actuator, such as an actuating pin 18a; 18b, which then into the switching contour 12a; 12b of the shift gate 5a; 5b engages. The engagement of the actuating element 18a, 18b is possible only in a certain position of the shift gates 12a, 12b. The respective switching position is specified via a locking element 6. The locking element 6 fixes the cam piece 3 on the support shaft 1 for this purpose in two end positions by the locking element 6 engages in two, the end positions exactly associated latching openings 7a, 7b in the support shaft 3. According to the invention, the latching openings 7a, 7b holes, grooves or the like. The locking element 6 is, for example, shown as a bolt guided radially to the carrier shaft 1 in a cylindrical protuberance 23 in the cam piece 3, for example locking bolt 19, which displaces against a force of a spring 9 housed in the cylindrical protuberance 23 into the cylindrical protuberance 23. is rerable. At the lower end, the locking element 6 projects out of the cam piece 3, where according to the invention there is an operative connection of the bolt 19 with the actuators 4 a, 4 b, for example via a mechanical coupling. The operative connection can be embodied in the form of a direction-reversing element, exemplified by rockers 13, 14, which convert a movement of the actuating element 18a, 18b towards the cam piece 3 into a movement of the bolt 19 away from the carrier shaft 1, so that an unlocking takes place. The rockers 13, 14 each consist of a bearing 25a; 25b and two levers 13a, 13b, respectively; 14a, 14b. The levers 13a, 14a of the rockers 13, 14 are loosely on a connecting piece 24 on the latch 19 and the lever 13b, 14b of the rockers 13, 14 are fixedly connected to the actuating element 18a, 18b. The connecting piece 24 is connected to the latch 19 in such a way that the latch 19 is fixedly connected axially to the connecting piece 24 and permits a displacement parallel to the carrier 1 of the bolt 19 in the connecting piece 24. The illustrated active compound is to be seen only as an example. There are also other direction reversing elements used or another locking mechanism conceivable.

In Fig. 1, the locking element 6 fixes the cam piece 3 on the support shaft 1 in the first end position. The following describes how the cam piece 3 enters its second end position shown in FIG. The cam piece 3 is displaced axially by the actuation of the left switching element 26b on the carrier shaft 1 in the second, shown in FIG. 2 end position by the actuator 18b engages in the direction of arrow 20 in the shift gate 5b in the cam piece 3 and the switching contour 12b of the shift gate 5b follows. When the second end position is reached, the actuating element 18b is deactivated by the shift gate 5b, by reducing the depth of the groove of the switching contour 5b, pushing the actuating element 18b back into its starting position. Due to the engagement and the shape of the shift gate 5b, there is a displacement of the cam piece 3 to the left. At the same time the unlocking of the cam piece 3 is made on the support shaft 1. Moves for switching the actuator 18b and thus the left actuator 18b associated lever 13b of the rocker 13 towards the cam piece 3, moves the the connecting piece 24 associated lever 13a of the rocker 13 away from the cam piece 3. The connecting piece 24 is also moved away from the carrier shaft 1 by the lever 13a of the rocker 13, thereby taking the bolt 19 with it. The bolt 19 is displaced via this operative connection against the force of the spring 9 in the direction of arrow 21 from the detent opening 7a shown on the right in the carrier shaft 1 in the guide of the bolt 23 in the cam piece 3 and unlocks it. In this case, the latch 19 is only completely unlocked from the latching opening 7a, when the actuator 18b has reached its end position in the switching contour 12b, adjacent to this. After the displacement of the cam piece 3 is completed on the support shaft 1 to the left by the engagement of the actuating element 18b in the shift gate 12b, the locking takes place in the then reached, second end position, as shown in Fig. 2, by the spring 9, the bolt 19th in the left illustrated, second detent opening 7b in the support shaft 1 presses. This takes place in the deactivated state of the actuating element 18b, in which a movement of the left lever 13b of the rocker 13 away from the cam piece 3 and the movement of the right lever 13a of the rocker 13 to the cam piece 3 and thereby releases the latch 19. This happens exactly at the time when the cam piece 3 has reached its axial end position and thus the bolt 19 is at the level of the left detent opening 7b in the carrier shaft 1. The two latching openings 7a, 7b are stationary on the carrier shaft 1, since only the cam piece 3 with the radial latches 19 moves axially on the carrier shaft 1. The spacing of the latching openings 7a, 7b corresponds exactly to the displacement path between the two end positions of the cam piece on the carrier shaft 1.

For re-axial displacement of the cam piece 3 in the first, shown in Fig. 1 end position on the support shaft 1 engages the right actuator 18a in the shift gate 5a in the cam piece 3 a. The latch 19 is unlocked upon actuation of the switching element 26a via the operative connection 8 against the force of the spring 9 from the detent opening 7b and locked upon reaching the first end position by the spring 9 pushes the latch 19 in the latching opening 7a after the switching element 26a through Deactivation releases the latch 19.

Claims

claims

1. Valve drive for an internal combustion engine with a camshaft, which consists of a

 Carrier shaft with at least one rotationally fixed and axially displaceable on the camshaft cam piece, which is displaceable by a switching element from a first axial end position to a second axial end position and by a locking element in these end positions,

 characterized in that the locking element (6) unlocked exclusively for the axial displacement of the cam piece (3) and locked exclusively in the area of the assumed end positions of the cam piece (3).

2. Valve drive according to claim 1, characterized in that upon actuation of the

 Switching element (26a, 26b) unlocks the locking element (6) and automatically locks the locking element (6) when the end positions are reached.

3. Valve drive according to claim 1 or 2, characterized in that by a

 mechanical coupling (13; 14; 22) of the switching element (26a; 26b) and of the locking element (6) the unlocking of the locking element (6) takes place.

4. Valve gear according to one of claims 1 to 3, characterized in that a locking mechanism with locking element (6), a bolt (19), a spring (9), a guide of the bolt (23) and at least two latching openings (7a, 7b ). Valve gear according to one of claims 1 to 4, characterized in that the switching element (26a, 26b) comprises an actuator (4a, 4b) and an actuating element (18a, 18b).

Valve gear according to one of claims 3 to 5, characterized in that the mechanical coupling rockers (13; 14) and a connecting piece (24).