DE102007056692A1 - Valve drive device - Google Patents

Abstract

The invention relates to a valve drive device, in particular an internal combustion engine, having at least one first cam element (11), which is axially displaceable via at least one shift gate (10) and which is adapted to realize an adjustable valve drive. It is proposed that di3), which is intended to axially displace the first cam element (11) in a first switching direction, and a second switching sleeve (14), which is provided, the first cam element (11) in a second switching direction to move axially.

Description

The The invention relates to a valve drive device according to the preamble of Claim 1.

It are already valvetrain devices, in particular an internal combustion engine, with at least one over at least one shift gate axially displaceable first cam element, which is intended to realize an adjustable valve train, known.

Of the The invention is in particular the object of a low-wear valve drive device to provide with a small number of actuators. she will according to the invention solved by the features of claim 1. Further embodiments emerge from the dependent claims.

The The invention is based on a valve drive device, in particular an internal combustion engine, with at least one via at least one shift gate axially displaceable first cam element which is intended to realize an adjustable valve train.

It It is proposed that the valve drive device a first shift sleeve, the is provided, the first cam element in a first switching direction axially displace, and a second shift sleeve, which is intended axially displace the first cam element in a second switching direction, having. Under a "shift sleeve" is intended in particular a switching element to be understood that an annular cross-section and preferably arranged coaxially with the cam element is. Advantageously, the cam element and the switching sleeves are separated executed. "Axial" should here and hereinafter, unless explicitly stated otherwise, in particular with respect to an axis of rotation of the cam member. By an embodiment of the invention may be a valvetrain device with a small number of actuators be provided, while minimizing wear of the shift sleeves can be, since they are for each for a switching direction are designed.

Further It is proposed that the valve drive device a second Has cam element, the means of at least one of the shift sleeves axially is displaceable. This allows for an additional actuator for the second Cam element can be dispensed with. Preferably, the second Moved cam element by means of the two switching sleeves, advantageously the first shift sleeve is provided, the second cam element in a first switching direction to move axially, and the second switching sleeve is provided, the second To move cam element axially in a second switching direction. Preferably, the two cam elements in a switching operation, the by means of a switching sleeve accomplished is moved in opposite directions. Partial cams on the cam elements are Therefore advantageously arranged in mirror image, d. H. Partial cams, which are assignable to a switching position, are in relation to the shift gate arranged axially inboard or axially outboard.

Further It is proposed that at least one of the shift sleeves axially is displaceable to at least one cam element. This can a valve drive device according to the invention structurally very simple to run. Preferably the switching sleeves and both cam elements arranged axially displaceable, for example on a camshaft, causing the shift sleeves and the cam elements independently can be moved axially from each other. Preferably, the Cam elements and the switching sleeves arranged rotationally fixed to the camshaft.

Further It is suggested that the shift sleeves be axially between the cam elements are arranged. Under "axial between "should in In particular, it should be understood that the first Cam element arranged substantially on one side of the shift sleeves is and that the second cam element substantially on one The first cam element side facing away from the shift sleeves arranged is, with the switching sleeves are preferably arranged directly adjacent. By "essentially" is meant in particular being understood to be more than 50%, being more than 70% advantageous and more than 90% are particularly advantageous. In particular, should so that under "im Essentially "too be understood that the shift sleeves axially between the cam elements are arranged while doing an overlap may have with the cam elements. By an embodiment of the invention can by means of the switching sleeves Advantageously, both cam elements are switched.

Preferably has the first switching sleeve one first slide track on. This makes the first shift sleeve easy be switched. Advantageously, there is the first slide track Completely on the first shift sleeve.

there It is suggested that the first slide track as a circumferential Schaltnut executed is. This can be structurally simply provided a slide track become. Alternatively, however, other slide tracks, such as Slide tracks with a positive profile or slide tracks, the a Einspursegment and a Ausspursegment had, conceivable.

has Furthermore, the first slide track at least a first switching segment on, which is intended to switch the first cam element can simply defined a defined switching point for the first cam element become.

In addition, will suggested that the first slide track a second switching segment which is intended to switch the second cam element. This can simply be a defined switching point for the second Cam element can be defined, wherein advantageously the switching point for the first cam element and the switching point for the second cam element offset from each other.

Preferably For example, the first slide track has a substantially S-shaped structure on, which also has a particularly advantageous slide track can be realized.

Further It is proposed that the second shift sleeve a second slide track having. As a result, the second shift sleeve can be easily switched. Advantageously, the second slide track is completely on the second shift sleeve.

Preferably is also the second slide track designed as a circumferential shift groove. Thereby can be structurally simply provided a slide track for the second shift sleeve. Alternatively, however, other slide tracks, such as Slide tracks with a positive profile or slide tracks, the a Einspursegment and a Ausspursegment had, conceivable.

Further It is suggested that the second slide track at least a first Switching segment, which is provided to the first cam element to switch. This can simply be a defined switching point for the first Cam element can be defined.

In addition, will suggested that the second slide track also a second Switching segment, which is provided to the second cam member to switch. This can simply be a defined switching point for the second Cam element can be defined, wherein advantageously the switching point for the first cam element and the switching point for the second cam element against each other are offset.

has Also, the second slide track on a substantially S-shaped structure, can also be a Particularly advantageous slide track can be realized.

Preferably The first slide track and the second slide track are mirror-symmetrical executed to each other. By doing so leaves to achieve a particularly advantageous switching behavior of the shift sleeves.

Further Advantages are shown in the following description of the drawing. In the drawing is an embodiment represented the invention. The description and the claims contain numerous features in combination. The skilled person will become the characteristics expediently also consider individually and summarize to meaningful further combinations.

there demonstrate:

1 A section of a valve drive device according to the invention in a planar view,

2 a course of switching scenes of the valve drive device,

3 a cross section through switching sleeves of the valve drive device along the cutting plane AA 2 .

4 a cross section through the switching sleeves along the section plane BB 2 .

5 in the subfigures a to c a switching operation in a first switching direction,

6 in the subfigures a to c a switching operation in a second switching direction and

7 an exploded view of the valve drive device.

The 1 to 7 a section of a valve drive device according to the invention is shown. The 1 to 4 show the basic structure of the valve drive device, in the 5a to 5c a switching operation is shown in a first switching direction, in the 6a to 6c a switching operation in a second switching direction. For a better understanding, the valve drive device in the 1 to 6 shown in a planar view. 7 shows a section of an exploded view of the valve drive device.

1 shows in a planar view the valve drive device with two via a shift gate 10 axially displaceable cam elements 11 . 12 , by means of which an adjustable valve train is realized. The cam elements 10 . 11 are made separately from each other and arranged axially displaceable on a camshaft. The camshaft is not shown here.

Axially between the cam elements 11 . 12 are two shift sleeves 13 . 14 arranged. The switching sleeves 13 . 14 and the cam elements 11 . 12 have an overlap. By means of the first switching sleeve 13 may be the first cam element 11 be moved axially in a first switching direction. By means of the second switching sleeve 14 For example, the first cam element can be displaced in a second switching direction, which is directed opposite to the first switching direction. The first switching direction is directed axially outwards. The terms "axially outward", or "axially inward" is intended here and below with respect to the switching sleeves 13 . 14 be understood.

The second cam element 12 is also on the switching sleeves 13 . 14 axially displaceable. By means of the first switching sleeve 13 may be the second cam element 12 be moved axially in a first switching direction. By means of the second switching sleeve 14 may be the second cam element 12 in a second switching direction, which is directed opposite to the first switching direction, are moved. The first switching direction is also directed axially outward.

In one by means of one of the switching sleeves 13 . 14 executed switching process, the two cam elements 11 . 12 shifted in opposite directions. To such a displacement of both cam elements 11 . 12 by means of the two switching sleeves 13 . 14 to allow, are the first switching sleeve 13 , the second shift sleeve 14 , the first cam elements 11 and the second cam member 12 each carried out separately and axially displaceable but rotatably mounted on the camshaft. Since by in particular, the switching sleeves 13 . 14 to the cam elements 11 . 12 axially displaceable.

About the first switching sleeve 13 are the cam elements 11 . 12 axially displaceable in a first switching direction. A first slide track 15 , by means of the switching sleeve 13 can be switched, is completely on the first sounding sleeve 13 arranged and formed as a circumferential shift groove. The first slide track 15 has a first switching segment 16 on, by means of which the first cam element 11 switched and in relation to the switching sleeves 13 . 14 can be moved axially outwards. Next points the first slide track 15 a second switching segment 16 which is directed axially in an opposite direction and via which the second cam element 12 in relation to the shift sleeves 13 . 14 can also be moved radially outward. The first slide track 15 thus has a substantially S-shaped structure.

The second shift sleeve also has a substantially S-shaped slide track 18 on. The second slide track 18 is mirror-symmetrical to the first slide track 15 the first shift sleeve 13 executed ( 2 ). Also the second slide track 18 completely on the second shift sleeve 14 is arranged, is formed as a circumferential shift groove and has two in opposite directions directed switching segments 19 . 20 on. By means of the first switching segment 19 may be the first cam element 11 in relation to the shift sleeves 13 . 14 be moved axially inwards. By means of the second switching segment, the second cam element 12 be moved axially inwards.

Because the cam elements 11 . 12 through the switching segments 16 . 17 . 19 . 20 are shifted in a shift in opposite directions, are part cams 21 . 22 of which two each form a pair of cams for an adjustable valve train, mirror images of the cam elements 11 . 12 arranged. The partial cams 21 , the first switching position of the cam elements 11 . 12 are to be assigned are each arranged axially inboard. The partial cams 22 , the second switching position of the cam elements 11 . 12 are to be assigned, are each arranged axially outside, with "axially inside" and "axially outside" here again in relation to the switching sleeves to be understood.

In the 3 and 4 are two different cross sections through the switching sleeves 13 . 14 shown.

In 3 is a cross section along the sectional plane AA 2 shown. 3 shows all the essential switching elements for a circuit by means of the first switching sleeve 13 , The first cam element 11 has a switch lift in this cross section 23 which is executed as a paragraph. In the direction of the second cam element 12 has the first cam element 11 a flat area 25 on. The second cam element 12 also has a switch lift in this cross-section 24 on, which is formed as a radial increase.

The first shift sleeve 13 is in the shallow area 25 of the first cam element 11 arranged. The first shift sleeve 13 and the first cam element 11 are doing in the in 3 shown switching position over the flat area 25 of the first cam element 11 completely radially arranged one above the other. The first shift sleeve 13 points for one in the direction of the first cam element 11 directed movement make a positive contact with the first cam element 11 on. By a corresponding movement of the shift sleeve 13 can thus the first cam element 11 by means of the switching sleeve 13 and the switch lift 23 be moved outwards. For one in the direction of the second cam element 12 directed movement is the first switching sleeve 13 over the switch lift 24 of the second cam element 12 with the second no ckenelement 12 coupled and can thus via a corresponding movement, the second cam element 12 also move axially outwards. For an axially inward movement are the first shift sleeve 13 and the cam elements 11 . 12 decoupled from each other.

In 4 is a cross section along the section BB shown off 2 , 4 shows all the essential switching elements for a circuit by means of the second switching sleeve 14 , In this cross section, both the first cam element 11 as well as the second cam element 12 one each switch lift 26 . 27 on, which is formed as a radial increase. In particular, the in 3 shown switch lift 24 of the second cam element 12 integral with the in 4 shown switch lift 27 of the second cam element 12 be executed as a circulating switch lift.

The second shift sleeve 13 has a substantially U-shaped cross section, wherein the switch bumps within a recess 28 , through which the U-shaped cross section is formed, are arranged. The second shift sleeve 14 engages from the outside in the switch lifts 26 . 27 one. Are the cam elements 11 . 12 axially displaced outwards, are the cam elements 11 . 12 for an axially inward movement, ie the first cam element 11 for an axial movement in the direction of the second cam element 12 and the second cam member 12 for an axial movement in the direction of the first cam element 11 , positively with the second shift sleeve 14 connected. By a corresponding movement of the shift sleeve 14 thus can the cam elements 11 . 12 be moved axially inwards. For an axially outward movement are the second shift sleeve 14 and the cam elements 11 . 12 decoupled from each other.

In the 5a to 5c is a switching operation by means of the first switching sleeve 13 shown. In this switching process, the two cam elements 11 . 12 moved axially outward in the first switching direction. An actuation of the first shift sleeve 13 takes place via a first actuating pin 29 in the first slide track 15 on the first shift sleeve 13 is arranged, einspurt. Actuators for such an actuating pin 29 are not shown here.

Starting from a switch position, as in 4 is shown and in which the second shift sleeve 14 is in a middle position, the first actuating pin spurts 29 in the first slide track 18 one. About the first switching segment 16 the first slide track 18 becomes the first shift sleeve 13 axially in the direction of the first cam element 11 shifted, causing the first cam element 11 is moved axially outwards ( 5a ). Through an intermediate segment 30 becomes the shift sleeve 13 back to the middle position and then through the second switching segment 17 in the direction of the second cam element 12 shifted, whereby also the second cam element 12 is moved axially outwards ( 5b ). Then the shift sleeve 13 moved back to the middle position and the actuating pin 29 is withdrawn by means of the actuator ( 5c ).

In the 6a to 6c is a switching operation in which the cam elements by means of the second switching sleeve 14 again radially inward into the in 4 shown switching position are shown, shown.

Starting from the in 5c shown switching position in which the second switching sleeve 14 is in a middle position, spurting a second actuating pin 31 in the second slide track 18 on the second shift sleeve 14 is arranged, a. Through the first switching segment 19 the second slide track 18 becomes the first cam element 11 in the direction of the second cam element 12 moved axially inwards. Through an intermediate segment 32 becomes the second shift sleeve 14 back to the middle position and continue in the direction of the first cam element 11 moved, which also causes the second cam element 12 is moved axially inwards. Then the shift sleeve 14 by means of the actuating pin 31 moved back to the middle position and the actuating pin 31 will be withdrawn again.

Claims (16)

Valve train device, in particular an internal combustion engine, with at least one via at least one shift gate ( 10 ) axially displaceable first cam element ( 11 ), which is intended to realize an adjustable valve drive, characterized by a first shift sleeve ( 13 ), which is provided to the first cam element ( 11 ) axially in a first switching direction, and a second shift sleeve ( 14 ), which is provided to the first cam element ( 11 ) to move axially in a second switching direction. Valve drive device according to claim 1, characterized by a second cam element ( 12 ), which by means of at least one of the switching sleeves ( 13 . 14 ) is axially displaceable. Valve drive device according to claim 1 or 2, characterized in that at least one of the switching sleeves ( 13 . 14 ) axially displaceable to at least one cam element ( 11 . 12 ). Valve train device at least according to claim 2, characterized in that the switching sleeves ( 13 . 14 ) axially between the cam elements ( 11 . 12 ) are arranged. Valve drive device according to one of the preceding claims, characterized in that the first shift sleeve ( 13 ) a first slide track ( 15 ) having. Valve drive device according to claim 5, characterized in that the first slide track ( 15 ) is designed as a circumferential shift groove. Valve train device at least according to claim 5, characterized in that the first slide track ( 15 ) at least a first switching segment ( 16 ), which is provided to the first cam element ( 11 ) to switch. Valve train device at least according to claims 2 and 7, characterized in that the first slide track ( 15 ) a second switching segment ( 17 ), which is intended, the second cam element ( 12 ) to switch. Valve train device at least according to claim 5, characterized in that the first slide track ( 15 ) has a substantially S-shaped structure. Valve drive device according to one of the preceding claims, characterized in that the second shift sleeve ( 14 ) a second slide track ( 18 ) having. Valve drive device according to claim 10, characterized in that the second slide track ( 18 ) is designed as a circumferential shift groove. Valve train device at least according to claim 10, characterized in that the second slide track ( 18 ) at least a first switching segment ( 19 ), which is provided to the first cam element ( 11 ) to switch. Valve train device at least according to claims 2 and 12, characterized in that the second slide track ( 18 ) a second switching segment ( 20 ), which is intended, the second cam element ( 12 ) to switch. Valve train device at least according to claim 10, characterized in that the second slide track ( 18 ) has a substantially S-shaped structure. Valve train device at least according to claims 5 and 10, characterized in that the first slide track ( 15 ) and the second slide track ( 18 ) are mirror-symmetrical to each other. Method for a valve drive device, in particular an internal combustion engine, with at least one via at least one shift gate ( 10 ) axially displaceable first cam element ( 11 ), which is intended to realize an adjustable valve train, in particular for a valve drive device according to one of the preceding claims, characterized in that the first cam element ( 11 ) via a first shift sleeve ( 13 ) is axially displaced in a first switching direction and that the first cam element ( 11 ) via a second switching sleeve ( 14 ) is axially displaced in a second switching direction.