WO2018001867A1 - Valve train for an internal combustion engine, and method for producing a valve train - Google Patents

Abstract

The invention relates to a valve train (1) for an internal combustion engine, having at least one main camshaft and a first cam carrier (2) and a second cam carrier (3), wherein the cam carriers (2, 3) are arranged fixedly on the main camshaft so as to rotate with it and in an axially movable manner between at least two axial positions, and have in each case a plurality of valve actuating cams (5, 6, 7, 8), wherein the cam carriers (2, 3) are assigned a common shift guide plate (9) for axial movement. It is provided here that the shift guide plate (9) has a first shift guide plate part (12) which is configured in one piece with the first cam carrier (2) and a second shift guide plate part (13) which is configured in one piece with the second cam carrier (3), wherein the two shift guide plate parts (12, 13) are produced separately from one another and are fastened to one another. The invention also relates to a method for producing a valve train (1) for an internal combustion engine.

Description

 Valve train for an internal combustion engine as well

 Method for producing a valve train

The invention relates to a valve train for an internal combustion engine, with at least one base camshaft and a first cam carrier and a second cam carrier, wherein the cam carrier rotatably and axially displaceable between at least two axial positions are arranged on the base camshaft and each having a plurality of valve actuation cams, wherein the Cam carriers for axial displacement associated with a common switching backdrop, wherein the shift gate has a one piece and integrally formed with the first cam carrier first shift gate part and integral with the second cam carrier integrally formed and second gear shift part, wherein the two shift gate parts made separately and attached to each other are. The invention further relates to a method for producing a valve train of an internal combustion engine.

The valve train is assigned to the internal combustion engine or forms part of the same. The internal combustion engine is used, for example, for driving a motor vehicle, in this respect, therefore, providing a torque directed to driving the motor vehicle. The valve drive has the base camshaft, which is rotatably mounted about a rotation axis. On the base camshaft, the first cam carrier and the second cam carrier are each arranged to be displaceable in the axial direction. Each of the two cam carriers can in this respect occupy two different axial positions relative to the axis of rotation. The cam carrier are also arranged rotationally fixed relative to the base camshaft; during a rotary movement of the basic camshaft, therefore, the cam carriers also describe a rotary movement. Each of the cam carriers has a plurality of valve actuation cams which serve to actuate at least one gas exchange valve, preferably a plurality of gas exchange valves. The valve train is used for an internal combustion engine, in which the cycle of gas exchange valves of individual cylinders of the internal combustion engine can be influenced to improve the thermodynamic properties. The cam carriers can also be referred to as cam pieces.

Each cam carrier is usually associated with a plurality, that is to say at least two, valve actuation cams. Each of these valve actuating cam has an eccentricity, which serves to actuate one of the gas exchange valves of the internal combustion engine at a certain angle of rotation of the basic camshaft. Accordingly, the valve actuating cam run together with the base camshaft so that the respective gas exchange valve of the internal combustion engine is actuated by the associated valve actuating cam or its eccentricity at least once per revolution of the basic camshaft. The valve actuating cam cooperates preferably with a roller rocker arm of the gas exchange valve by entering into abutting contact therewith. However, at least one of the valve actuating cam can also be embodied as a so-called zero-stroke cam and, to that extent, without eccentricity. Such Nullhubnocken can be used for example for cylinder deactivation.

Preferably, each of the cam carriers has a plurality of valve actuation noses, which may be assigned to different cam groups. The valve actuation cams of a cam group differ, for example, with regard to the angular position of their eccentricity and / or the extension thereof in the radial direction (height) and / or in the circumferential direction (length), in each case with respect to the axis of rotation of the base camshaft. By the axial displacement of the cam carrier they can in the at least two Axial positions, for example, in the first and second axial position brought. In the first axial position, the gas exchange valve is actuated by a first one of the valve actuation cams and in the second axial position by a second one of the valve actuation cams associated with the same cam group.

The valve actuating cam, which are assigned to the same cam group, are preferably arranged directly next to one another, that is, for example, abut each other. As a result of the displacement of the cam carrier or the cam carriers, in particular the opening time, the opening duration and / or the lift of the gas exchange valve, in particular as a function of an operating state of the internal combustion engine, can be selected and set. From the application DE 10 2015 01 1 243, for example, a valve train for an internal combustion engine is known which has at least one base camshaft and a first cam carrier and a second cam carrier, the cam carrier rotatably and axially displaceable between at least two axial positions are arranged on the base camshaft and respectively have multiple valve actuation cams. It is provided that the first cam carrier and the second cam carrier are connected on opposite sides with a common, a displacement in the axial direction by means of an actuator serving shift gate. Furthermore, the document DE 10 2013 210 486 A1 describes a sliding cam system for a valve train of an internal combustion engine, the document DE 10 2010 060 766 A1 a sliding cam system for use in a valve train of an internal combustion engine, the document DE 10 2007 037 358 A1 a switching device and the document DE 10 2007 052 251 A1 a valve drive device. It is an object of the invention to provide a valve train for an internal combustion engine, which has advantages over known valve trains, in particular allows easy installation. This is achieved according to the invention with a valve train having the features of claim 1. It is provided that the shift gate parts are positively connected to each other by means of a behind the shift gate parts and these are connected together in the axial direction with respect to each fixing fixing element. In principle, it is provided that the shifting gate has a first shifting gate part formed integrally with the first cam carrier and a second shifting gate part integrally formed with the second cam carrier, wherein the two shifting gate parts are manufactured separately from one another and fastened to one another.

The displacement or displacement of the cam carrier in the axial direction takes place with the aid of an adjusting device, which comprises the cam carriers associated with the cam and a fixedly arranged actuator, usually stationary in a cylinder head of the internal combustion engine. The actuator has an extendable driver that can be engaged with at least one example helical or spiral slide track of the shift gate. The at least one slide track is provided on the shift gate or formed in this. The slide track is along a course of a preferably, but not necessarily continuous cam track and has a certain width, which is particularly matched to the width of the driver of the actuator. Usually, the at least one slide track is slightly wider than the driver, so that a smooth passage through the slide track is possible by the driver. The slide is located For example, as a radial groove, which passes through the circumference of the shift gate, so is open-edge formed in this. The curved path, for example, is centrally located in the slide track and is a line in the mathematical sense. This line can be composed of several line segments.

It can be provided that a plurality of slide tracks are formed on or in the shift gate. This slide tracks preferably extend at least partially in the axial direction in opposite directions. The slide tracks are spaced apart from each other, so they do not overlap directly.

The common shift gate now serves both the displacement of the first cam carrier and the second cam carrier, in other words, the common displacement of the two cam carrier. To ensure easy manufacturability and assembly of the valve train, the shift gate is designed in several parts. So it has the first shift gate part and the second shift gate part, which are made separately from each other. The first shift gate part is preferably formed in one piece and in the same material as the first cam carrier and the second shift gate in one piece and of the same material as the second cam carrier.

During assembly of the valve drive, the two cam carriers are arranged to each other such that the two shift gate parts form the common shift gate. In this case, the two shift gate parts preferably abut one another on the front side. In order to enable a coupling of the displacement of the two cam carrier in the axial direction and by means of the common shift gate, consisting of the first shift gate part and the second shift gate part, the two shift gate parts are not only arranged together, but additionally attached to each other. These Attachment can for example be made positively and / or cohesively.

A further embodiment of the invention provides that the attachment of the shift gate parts is reversible or insoluble, in particular by materially connecting the shift gate parts, is. The reversible attachment allows a damage-free release of the attachment. Such attachment is realized for example by means of a positive fastening. Alternatively, however, the attachment can also be insoluble. This is to be understood that the release of the attachment is not possible without trace, but must, for example, chip removal or generally material removal takes place. The permanent attachment is made for example by materially connecting the Schaltkulissenteile. As part of a further embodiment of the invention it is provided that the shift gate parts are positively connected to each other, in particular by means of a fastener. On the positive connection of the Schaltkulissenteile has already been mentioned above. With her, the reversible attachment of the Schaltkulissenteile can be done together. The positive connection is preferably carried out by means of the fastening element which engages behind each of these after mounting on the Schaltkulissenteilen this and holds each other, so sets in the axial direction with respect to each other. A further advantageous embodiment of the invention provides that the fastening element is present as a mounting clamp or spring clip. The mounting clamp is characterized for example by the fact that it is hinged, that is, consists of two clamp members, which are rotatably mounted to each other about an axis of rotation. This storage can be in the form of a film hinge or the like, for example. The fastening However, transmission element can also be present as a spring clamp, which is applied detenting on the shift gate parts and this subsequently pushes each other in the axial direction. Finally, in the context of a further preferred embodiment of the invention, provision is made for a first form-fitting device, in particular a form-fitting projection, to be formed on the first shifting gate part, and a second form-closure device, in particular a form-fitting receptacle, on the second shifting gate part. The form-fitting and thus preferably reversible attachment of the shift gate parts to each other can be made in this respect by means of the two form-locking devices, which are formed on the Schalkulissenteilen itself. The form-fitting projection is in the form of an annular collar, for example, in particular a ring collar extending in the circumferential direction. The positive connection receptacle can be in the form of a partial ring-shaped depression, which is present over only a part of the circumference of the second switchgear part.

Particularly preferably, the form-fitting receptacle extends in the circumferential direction over at most 180 °, preferably less than 180 °. Preferably, however, the positive locking receptacle runs in the circumferential direction over more than 45 °, more than 90 ° or more than 135 °. In such an embodiment of the form-locking devices, it is provided that the annular collar is introduced into the form-fitting receiving means before the cam carriers are mounted on the base camshaft and then the two cam carriers are jointly applied to the basic camshaft. After the arrangement of the cam carrier on the base camshaft, the positive locking projection in the form of the annular collar can no longer be displaced out of the positive locking receptacle. The invention further relates to a method for producing a valve drive for an internal combustion engine having the features of claim 5.

The advantages of such an embodiment of the valve train or such an approach have already been pointed out. Both the valve train and the method for its production can be developed according to the above statements, so that reference is made to this extent. The production of the two shift gates is done separately from each other, wherein the first Schalkulissenteil is formed together with the first cam carrier and the second shift gate part together with the second cam carrier. Only then are the two shift gate parts attached to each other, for example, positively and / or cohesively.

The invention will be explained in more detail with reference to the embodiments illustrated in the drawings, without any limitation of the invention. 1 shows an illustration of a valve drive for an internal combustion engine with two cam carriers in a first embodiment,

Figure 2 is a fastener for attachment of two shift gate parts together and

3 shows an illustration of a part of the valve drive with two cam carriers in a second embodiment.

FIG. 1 shows a representation of a region of a valve drive 1, namely a first cam carrier 2 and a second cam carrier 3 Representation takes place in the form of a partial sectional view. Each of the cam supports 2 and 3 has a bearing 4 for receiving a bearing, in particular a radial bearing on. The bearing serves to support the cam carrier 2 and 3 with respect to a cylinder head of an internal combustion engine. Furthermore, each of the cam carriers 2 and 3 has a plurality of valve operating cams 5, 6, 7 and 8.

In each case two of the valve actuating cams 5, 6, 7, 8, namely the valve actuating cams 5 and 6 and the valve actuating cams 7 and 8, are grouped, and in the process are arranged directly adjacent to one another. The grouped valve actuation cams 5 and 6 or 7 and 8 respectively serve to actuate the same gas exchange valve as a function of an axial position of the cam carriers 2 and 3 with respect to a basic camshaft, not shown here, on which the cam carriers 2 and 3 are arranged axially displaceable.

For displacement of the cam carrier 2 and 3 on the base camshaft is a common shift gate 9, which has several slide tracks 10 and 1 1 in the embodiment shown here. The slide track 10 is in a first shift gate part 12 and the slide track 1 1 in a second shift gate part 13 before. The first Schalkulissenteil 12 is integrally formed of the same material with the first cam carrier 2, while the second Schalkulissenteil 13 is one piece and of the same material with the second cam carrier 3. The shift gate parts 12 and 13 and thus the cam carrier 2 and 3 are made separately from each other.

During assembly of the valve drive 1, the shift gate parts 12 and 13 are arranged to form the common shift gate 9, in particular such that an end face 14 of the first shift guide senteils 12 rests against an end face 15 of the second shift gate part 13. Subsequently, the two shift gate parts 12 and 13 are positively connected to each other, for example by means of a fastener 16, not shown here, which engages behind two form-fitting projections 17 and 18 of the shift gate parts 12 and 13 in the axial direction and the Schalkulissenteile 12 and 13 fixed together in the axial direction, in particular axial direction towards each other.

FIG. 2 shows a schematic representation of the fastening element 16. It becomes clear that this is present as a fastening clamp, which has two clamp parts 19 and 20, which each have a receptacle 21 or 22 for accommodating one of the form-fitting projections 17 and 18 and a hinge 23 , In particular a film hinge, are rotatably mounted to each other. A closing of the fastening element 16 is provided by means of a clasp 24.

3 again shows a schematic representation of a region of the valve drive 1, namely the cam carrier 2 and 3. Basically, reference is made to the above statements and discussed below only the differences. These are that the fastening of the shift gate parts 12 and 13 does not take place by means of the fastening element 16, but rather that a first positive locking device 25 in the form of a positive locking projection and formed on the second shift gate part 13 on the first Schalkulissenteil 12 a second form-fitting device 26 in the form of a positive connection is.

The positive locking projection 25 is preferably designed as a circumferentially continuous annular collar. The positive locking receptacle 26, however, extends in the circumferential direction preferably over at most 180 °, preferably over less than 180 °, so that a simple introduction of the Positive locking projection 25 in the form-fitting receptacle 26 is possible. This introduction takes place before the application of the cam carrier 2 and 3 on the base camshaft. After applying the cam carrier 2 and 3 on the basic camshaft of the positive locking projection 25 can no longer get out of the positive locking receptacle 26.

The valve drive 1 described here allows on the one hand a simple production and easy installation. In addition, other elements of the valve train 1 can be designed simpler because the cam carrier 2 and 3 are fixed in the axial direction to each other.

Claims

claims

1 . Valve train (1) for an internal combustion engine, with at least one base camshaft and a first cam carrier (2) and a second

Cam carrier (3), wherein the cam carrier (2, 3) rotatably and axially displaceable between at least two axial positions are arranged on the base camshaft and each having a plurality of valve actuating cam (5, 6, 7, 8), wherein the cam carriers (2, 3) for axial displacement is associated with a common shift gate (9), wherein the shift gate (9) integrally formed with the first cam carrier (2) and the same material first shift gate part (12) and one with the second cam carrier (3) integrally formed of the same material second switching gate part ( 13), wherein the two Schalkulissenteile (12, 13) are made separately from each other and secured to each other, characterized in that the shift gate parts (12, 13) positively by means of a the Schaltkulissenteile (12,13) respectively engages behind and this in the axial direction with respect fixing each other fixing element (16) are interconnected.

2. Valve drive according to claim 1, characterized in that the attachment of the shift gate parts (12, 13) is reversible.

3. Valve drive according to one of the preceding claims, character- ized in that the fastening element (16) is present as a mounting clamp or spring clip.

4. Valve drive according to one of the preceding claims, characterized in that on the first shift gate part (12) has a first shape closing device (25) and on the second Schalkulissenteil (13) a second form-fitting device (26) is formed.

 5. A method for producing a valve train (1) for an internal combustion engine according to one or more of the preceding claims, wherein the valve train (1) has at least one base camshaft and a first cam carrier (2) and a second cam carrier (3), wherein the cam carrier (2, 3) rotationally fixed and axially displaceable between at least two axial positions are arranged on the base camshaft and in each case a plurality of valve actuating cam (5, 6, 7, 8), wherein the Nocken- carriers (2, 3) for axial displacement a common shift gate ( 9), wherein the Schalsch link (9) integral with the first cam carrier (2) and formed of the same material first Schaltkulissenteil (12) and one with the second cam carrier (3) integrally formed of the same material and second switching gate part (13), wherein the both shift gate parts (12, 13) are manufactured separately from each other and fastened together, characterized in that the shift gate parts (12, 13) are positively connected by means of one of the shift gate parts (12,13) each engaging behind and these in the axial direction with respect to each other festsetzenden fastener (16).