DE102007037332A1 - Switchable support device for a valve train of an internal combustion engine - Google Patents

Abstract

The invention relates to a switchable supporting device for a valve train of an internal combustion engine, comprising: - an outer part (10) with a guide channel (12); - An inner part (14) which is arranged at least over a length range within the guide channel (12) and along a major axis (H) of the guide channel (12) is movable; and - a locking element (18) which is movable relative to the outer part (10) between a movement of the inner part (14) in at least one direction of movement impossible blocking position and a movement of the inner part (14) releasing the release position, wherein the locking element (18) a component axis (B), which in the blocking position is coaxial and in the release position at least approximately coaxial to the main axis (H) of the guide channel (12).

Description

The The invention relates to a switchable supporting device for a valve train of an internal combustion engine in the preamble of Patent claim 1 specified type.

Such a support device, which is used for automatic compensation of a valve clearance of a valve train of internal combustion engines, for example, already from the DE 102 47 949 A1 as known and includes an outer part with a guide channel and an inner part, which is arranged with a small clearance over a length range within the guide channel. The inner part is movably guided along a main axis of the guide channel and in turn comprises a known hydraulic lash adjuster for supporting a cam follower element of the valve train of the internal combustion engine. The inner part is acted upon by a arranged within the guide channel clearance compensating spring with a spring force, so that the cam follower element, which may be formed, for example, as a drag lever, rocker arm, plunger body or the like, always rests without play on a cam of a camshaft of the internal combustion engine. In order to be able to selectively connect or disconnect a valve or a cylinder of the internal combustion engine, the support device comprises a locking element, which is movable relative to the outer part between a blocking position and a release position. As a locking element serve two pistons whose component axes extend perpendicular to the main axis of the guide channel in a radial bore of the inner part. Between the piston is a compression spring element, by means of which the pistons are pressed against each other to the outside. In the release position both pistons are moved by means of a hydraulic medium against the force of the compression spring element symmetrically in the inner part, whereby the axially guided movement of the inner part is released. The hydraulic medium is usually the already existing engine oil, which is supplied via a pressure circulation lubrication to the valve train. In this way, the transfer of the cam lift is released on the valve, so that the lifting movement of the cam is indeed transmitted to the cam follower element, the associated valve, however, remains closed due to sinking of the cam follower element. In the blocking position, the compression spring element presses the pistons through passages in the inner part into a circumferential inner groove of the outer part and thereby prevents movement of the inner part relative to the guide channel or to the outer part. The lifting movement of the cam can thus be transferred to the cam follower element and the supporting device associated with the valve of the internal combustion engine can be actuated accordingly.

When is disadvantageous of this switchable supporting device to look at the fact that the two the locking element forming piston together with the associated compression spring element have a relatively high space requirement, thereby consuming and costly constructive integration measures the supporting device in the internal combustion engine required are.

task The present invention is therefore a switchable supporting device to create the type mentioned, which reduced a Has space requirements.

The The object is achieved by a switchable Support device with the features of the claim 1 solved. Advantageous embodiments with appropriate and non-trivial developments of the invention are in the subclaims specified.

A switchable supporting device, which has a reduced space requirement, according to the invention is created in that the locking element has a component axis, which extends in the locking position and coaxial with the release position at least approximately coaxial with the main axis of the guide channel. In other words, the component axis of the locking element moves when moving it between the locking and the release position in contrast to the prior art between a coaxial with respect to the main axis and a substantially coaxial with the main axis course. This eliminates the need to form the locking element in several parts, so that the entire support device formed much more space-saving and can be correspondingly easier integrated into an internal combustion engine. In addition, eliminates the design effort, which is required for the coordinated movement of the known from the prior art piston between the locking and the release position. Due to the possibility of being able to form the locking element more easily, a reduced reaction time and thus a faster switching of the supporting device can be ensured due to the reduced moving mass. Furthermore, due to the reduced complexity and the lower tolerance requirements, the risk of jamming when moving the locking element is significantly reduced, whereby a significantly increased reliability of the supporting device is achieved. In addition, the guide length is extended for the locking element, whereby a further reduction of the risk of jamming is given. A significant advantage of the locking element is also that the support device when hitting on an upper edge of the support device a reduced axial and radial construction has space requirements, since in contrast to the prior art, no axial space for an internal groove to ensure the required guide length is needed. The support device can therefore be formed in particular with a reduced outer diameter. In the present case, the term "off-coaxial" subsumes various types of progression between the component axis and the main axis, meaning that the term "off-coaxial" essentially means an axis-parallel progression of the component axis and the main axis. Likewise, "off-coaxial" is understood to mean that the component and main axes are such that they intersect significantly outside of the support, meaning that the locking element is disposed slightly inclined relative to the guide channel in the locked position. coaxial "also design a skewed course of the component and the major axis to each other. Also in this case, the locking element is arranged inclined in the blocking position relative to the guide channel. The person skilled in the art is also aware that the term "coaxial" includes within the scope of the technically possible small angular and distance deviations between the component axis and the main axis the release position is accomplished by moving and / or deforming the locking element.

In an advantageous embodiment of the invention is provided that a jacket contour of the locking element in dependence the switching position at least temporally and partially corresponding is formed with a contour of the guide channel. Thereby can provide a reliable seal between both components achieved and, for example, the suction of air into a hydraulic medium be prevented when moving the inner part.

there it has been found to be advantageous that the locking element at least in sections, in cross-section circular sector-shaped is trained. This ensures in particular in connection with a cylindrical guide channel optimal sealing of the guide channel as well as a uniform Force distribution over the entire locking element.

In a further advantageous embodiment of the invention is provided that the locking element by means of a hydraulic medium and / or by means of a mechanical switching device and / or by means of a pneumatic switching device and / or by means of an electromagnetic Switching device between the blocking position and the release position to move. In this way, the support device variably formed and easy to different valve train configurations be adjusted.

In a further advantageous embodiment of the invention is provided that the outer part an anti-rotation element, in particular a cylindrical roller, comprising, by means of which a rotation of the outer part relative to the valve gear and / or a rotation of the inner part opposite the guide channel and / or a twisting of the locking element relative to the guide channel to be impossible. With such an anti-rotation element can be on constructively simple and inexpensive Way defined component orientations are ensured.

there it has been shown in a further embodiment to be advantageous that the inner part and / or the locking element a corresponding comprising groove formed with the anti-rotation, which to bring into coincidence with the anti-rotation element is. Such a groove provides a structurally simple and inexpensive method in order, in cooperation with the anti-rotation element, a relative Twisting the inner part and / or the locking element to make it impossible without the mobility of the inner part along the guide channel and / or the mobility of the locking element between locking and to block release.

In a further advantageous embodiment of the invention is provided that the inner part comprises a stop, by means of which a Mobility of the inner part along the main axis of the guide channel can be limited by striking the anti-rotation element. By such a stop may be, for example, a "falling out" the inner part of the guide channel reliable be prevented. Alternatively or additionally, of course with the help of the stop and the movement of the inner part in the Guide channel to be limited in it.

A particularly precise movement of the locking element is characterized ensures that the locking element in an outer groove of the inner part is guided. Through such a leadership is In addition, a tilting of the locking element when moving between the blocking and the release position reliably prevented.

It has been found to be advantageous that the locking element and the outer groove are associated with each other corresponding stops, by means of which the locking position and / or the release position is determined. Such attacks provide a robust, cost-effective and structurally simple way to define the blocking position and / or the release position and thus the Be defined to limit the movability of the locking element.

In a further advantageous embodiment of the invention is provided that the locking element is associated with a spring element, against the spring force of the locking element from the locked position in the release position or from the release position in the locked position is movable. With the help of such a spring element, the Support device depending on the constructive Requires either the movement of the inner part along the Lock the main axis of the guide channel without pressure or without pressure release.

there In particular, it has proven to be advantageous that the spring element is formed as a leaf spring, wherein both ends of the leaf spring preferably bent. A leaf spring allows a simple and cost-effective adjustment of the force with which the Locking element must be applied to the respective constructional conditions and requirements. By turning the ends of the leaf spring is advantageously a reduced Friction between locking and spring element and thus a ensures low switching time of the support device.

In a further advantageous embodiment of the invention is provided that the inner part of a hydraulic lash adjuster for supporting a cam follower element of the valve train assigned. With the help of such, known play compensation device a reliable backlash of the valve train is ensured. By assigning the lash adjuster to the inner part In addition, the largest possible stroke of the support device guaranteed at the lowest possible component length.

there it has been shown in a further embodiment to be advantageous that the locking element and the lash adjuster over to apply a common line system with hydraulic medium are. This allows the support device einflutig train, so over a common pipe system both the support function and the switching function the support device are to accomplish. Thereby The support device can be used in existing valve drives without any problems used and offered for example as a retrofit be since no redesign of the cylinder head of the internal combustion engine is required.

Vice versa may be provided in a further embodiment of the invention, that the locking element via an associated line system is to be acted upon with hydraulic medium. Such, if necessary doubly trained support allowed due to the decoupling of support and switching function a particularly fast and reliable control of the switchable locking element at low pressure levels.

there it has been found to be advantageous that the locking element in the blocking position at least in sections on an upper Supported edge surface of the outer part is. In this way, the design requirements to the switchable support device in terms of low space requirement at the same time tilting and anti-pinch movement of the locking element reliably realized between blocking and release position become. By supporting the locking element on the upper edge of the outer part is also ensure that the locking element is not in the range of inner clearance springs must be arranged, in any position protrudes laterally or the total length of the supporting device certainly.

alternative can be provided that the locking element in the locked position at least in sections within an inner groove of the guide channel is arranged. This allows at least partially a form-fitting Supporting the locking element on the inner groove of the Guide channels and thus a mechanically stable blocking the movement of the inner part.

After all it has proved to be advantageous that another locking element is provided, which - for example, in the blocking position - on a Outer circumference of the locking element is arranged and at least in sections within the inner groove of the guide channel is arranged. Such a further locking element allows a particularly reliable locking of the inner part towards the outer part, so that the supporting device can absorb high forces in the locked position.

Further Advantages, features and details of the invention will become apparent the following description of several embodiments and with reference to the drawings in which the same or the same function Elements are provided with identical reference numerals.

there demonstrate:

1 an oblique perspective view of a switchable supporting device according to a first embodiment;

2a a perspective sectional view of the supporting device along in 1 represented section plane IIa-IIa;

2 B a perspective sectional view of the supporting device along in 1 represented sectional plane IIb-IIb;

3a a sectional view of the supporting device along the in 1 represented sectional plane IIa-IIa, the background is not shown;

3b a sectional view of the supporting device along the in 1 represented sectional plane IIb-IIb, the background is not shown;

4a a perspective oblique views of the supporting device according to 1 to 3 , wherein the locking element is in the locking position;

4b a perspective oblique views of the supporting device according to 4a , wherein the locking element is in the release position;

4c a perspective oblique views of the supporting device according to 4a and 4b , wherein the locking element is in the release position and the inner part is moved into the guide channel;

5 a sectional view of the supporting device along the in 4c represented section plane VV;

6 an oblique perspective view of the outer part of the supporting device according to 1 to 5 ;

7 an oblique perspective view of the inner part of the supporting device according to 1 to 5 ;

8th an oblique perspective view of the locking element according to 1 to 5 ;

9 a schematic Schnittaufsicht the support element along in 3a represented section line IX-IX;

10 an oblique perspective view of the supporting device according to a second embodiment;

11a a perspective sectional view of the supporting device along in 10 represented sectional plane XIa-XIa;

11b a perspective sectional view of the supporting device along in 10 represented section plane XIb-XIb;

12a a sectional view of the supporting device along the in 10 represented sectional plane XIa-XIa, wherein the locking element is in the locked position;

12b a sectional view of the supporting device along the in 10 represented section plane XIb-XIb;

13 a sectional view of the supporting device according to 12a and b, wherein the locking element is in the release position and the inner part is moved into the guide channel;

14 a schematic Schnittaufsicht the support element along in 12a represented section line XIV-XIV;

15 an oblique perspective view of the inner part of the supporting device according to 10 to 13 ;

16a a schematic perspective view of the supporting device according to a third embodiment, wherein two locking elements are in the locked position;

16b a schematic perspective view of the supporting device according to 16a , wherein the locking elements are in the release position; and

16c a schematic perspective view of the supporting device according to 16a and 16b , wherein the locking elements is in the release position and the inner part is moved into the guide channel.

1 shows an oblique perspective view of a switchable supporting device according to a first embodiment. The support device comprises an outer part 10 with a substantially cylindrical guide channel 12 , inside which an inner part 14 arranged over a length range and slidable along a main axis H is movable. The inner part 14 comprises a horizontally opposite the main axis H arranged outer groove 16 (S. 7 ), in which a between a locking and a release position slidably movable locking element 18 is guided (s. 9 ). The locking element 18 comprises a component axis B, which in the blocking position shown is axially parallel to the main axis H of the guide channel. The locking element 18 is a leaf spring 19 assigned, by the spring force of the locking element 18 from the release position (s. 4b ) is moved in the blocking position shown. The support device is thereby locked without pressure in the present example. Alternatively, it can also be provided that the locking element 18 by the force of the leaf spring 19 is pressed from the locked position into the release position and the support device is thus unlocked without pressure.

The locking element 18 is in the blocking position shown in sections on an upper edge surface 20 of the outer part 10 supported and made impossible thereby a movement of the inner part 14 in the guide channel 12 into it. The inner part 14 carries a known hydraulic lash adjuster 22 for single end support of a cam follower element of a valve train of an internal combustion engine (not shown). The inner part 14 is arranged by inside the outer part cone springs 24a , b subjected to a force. The outer part 10 comprises a trained as a cylindrical roller anti-rotation element 26 which passes through the side wall of the outer part 10 is pressed in and at the same time as a longitudinal stop for the inner part 14 acts (s. 3a ). The anti-rotation element 26 makes it impossible to rotate the support device relative to a housing of the valve drive (not shown) and a rotation of the outer part 10 opposite the inner part 14 and the locking element 18 , For this purpose, the inner part comprises 14 a running in the direction of movement groove, which with the anti-rotation element 26 to bring in overlap. The locking element 18 , which is formed in cross-section substantially circular sector-shaped (s. 8th ), includes in the area of the leaf spring 19 a recess, which upon immersion of the locking element 18 in the guide channel 12 also with the anti-rotation element 26 to bring in overlap. It may alternatively be provided that the locking element 18 is formed deformable and is to move under deformation between the locking and the release position. Because the locking element 18 not within the outer part 10 or in the area of conical springs 24a , b must be accommodated, the support device can be made very compact.

2a shows a perspective sectional view of the supporting device along the in 1 represented section plane IIa-IIa. In particular, in the game balance device 22 integrated valve block 30 recognizable, which ensures that when running a cam that so long hydraulic fluid in the valve block 30 nachströmt until the lash adjuster 22 again without play. As a result, a hydraulically rigid connection is ensured, so that the support device behaves like a rigid body and in the locked position always presses on the cam follower element. The supply and discharge of the hydraulic medium, which is usually the already existing engine oil, via corresponding holes 32a -G, wherein the loading of the locking element 18 with hydraulic medium and the supply of the lash adjuster 22 in the present example via separate piping systems 34a , b (s. 3a . 3b ) takes place, so that the supporting device is formed double-flow.

2 B shows a perspective sectional view of the supporting device along the in 1 represented sectional plane IIb-IIb. Here are in particular the two line systems 34a , B associated holes 32a -G from a different angle.

3a shows a sectional view of the supporting device along the in 1 represented sectional plane IIa-IIa, the background is not shown for clarity. In this case, in particular, the line system 34a recognizable, which for moving the locking element 18 from the locking to the release position against the force of the leaf spring 19 with the help of hydraulic medium. The hydraulic medium can do this via the bore 32f in the outer part 10 into the pipe system 34a of the inner part 14 be derived or derived from this. Also recognizable is the inner part 14 associated stop 36 , By means of which the mobility of the inner part 14 in cooperation with the anti-rotation element 26 is to limit, making the inner part 14 not from the guide channel 12 can fall out. The inner part 14 is also located with a support area 38 on the guide channel 12 on, whereby both a support of the inner part 14 as well as a seal of the guide channel 12 is guaranteed. The dimensions of the support area 38 or the guide channel 12 In this case, they can be coordinated with one another such that a thermal expansion caused by the operation of the internal combustion engine can be compensated for and excess hydraulic medium can optionally escape in small quantities.

3b shows a sectional view of the supporting device along the in 1 represented sectional plane IIb-IIb, where again the background is not shown. Here is in particular that of the lash adjuster 22 associated piping system 34b recognizable over which through the holes 32e , g in the outer part 10 Hydraulic medium can be added or removed. As a result, as already mentioned, in the locking position befindendem locking element 18 an automatic valve clearance compensation accomplished.

4a shows an oblique perspective views of the supporting device according to 1 to 3 , wherein the locking element 18 in the locked position. In synopsis with 4b . 4c and 9 The following is the movement of the locking element 18 be described in the release position and thereby causing shutdown of the support device. About the pipe system 34a Hydraulic medium is in the inner part 12 pressed, causing the leaf spring 19 opposite side of the locking element 18 against whose power is applied. As in 4b to see, this is the locking element 18 moved to the release position shown there, in which the previously parallel to the axis with the main axis H extending component axis B is now coaxial with the main axis H. In other words, the locking element 18 and thus shifted its center of gravity transversely to the main axis H, whereby the mobility of the inner part 14 in the guide channel 12 is made possible, since the locking element 18 in the release position no longer on the upper edge surface 20 of the outer part 10 supported. The locking element 18 is how out 9 visible when moving in the outer groove 16 of the inner part 14 guided. 4c finally shows that by the movement of the locking element 18 in the release position enabled immersion of the inner part 14 in the guide channel 12 whereby a valve associated with the support device (not shown) remains in its closed position and is thus shut down. When moving the inner part 14 is by overlapping the groove 28 with the anti-rotation element 26 a twisting of the inner part 14 opposite the guide channel 12 or the outer part 10 makes possible, which in the present example required separation of the pipe systems 34a , b is guaranteed. By the attachment of the locking element 18 on the contour of the guide channel 12 In addition, a tilting or tilting of the inner part 14 opposite the outer part 10 reliably prevented and created the desired seal. The switchable support device thus makes it possible to provide internal combustion engines with a fuel economy potential of 15% or more. It should be emphasized that the support device can also be used in hybrid technology and easily combined with other fuel saving techniques. Because of the high numbers in which such support devices are manufactured and installed, thus a significant consumption and CO ₂ reduction is made possible without the performance or stability of the internal combustion engine would be adversely affected.

5 shows for further clarification a sectional view of the support device along in 4c represented sectional plane VV, with no background is shown for reasons of clarity.

6 shows an oblique perspective view of the outer part 10 the support device according to 1 to 5 , This is, inter alia, a passage 40 recognizable by which the cylindrical anti-rotation element 26 can be pressed. The outer part 10 owns in the area of the lower holes 32a , b a housing feeder for a gas exchange channel release.

7 shows an oblique perspective view of the present integrally formed inner part 14 the support device according to 1 to 5 , In particular, the horizontal outer groove is 16 recognizable, in which the locking element 18 guided is movable. Furthermore, the vertical groove 28 recognizable, which with mounted support device with the anti-rotation element 26 interacts. Also visible is an opening of the pipe system 32e ,

8th shows an oblique perspective view of the locking element 18 according to 1 to 5 , In this case, the present case in the region of the center of gravity of the locking element 18 extending component axis B recognizable. However, it may depend on the geometric configuration of the locking element 18 also be provided that its component axis B extends directly through the center of gravity. It can also be seen in associated receptacles of the locking element 18 arranged and preloaded leaf spring 19 at which optionally hydraulic fluid can flow. The arrangement of the locking element 18 on the inner part 14 For example, by simply clipping on the outer groove 16 ,

9 shows a schematic Schnittaufsicht of the support element along the in 3a represented section line IX-IX. The general structure is already known from the previous descriptions. In particular, the present illustration shows the separate line systems 34a , b recognizable. Through the transverse to the motion vector of the locking element 18 arranged supply of the hydraulic medium and the present pressureless locked embodiment is a reliable movement of the locking element 18 ensured in the release position, since compared to the single-flow embodiment (see. 10 ) lower pressure levels of the hydraulic medium are required. Also recognizable are the mutually correspondingly shaped guide surfaces 42 the outer groove 16 and the locking element 18 , by means of which the guided movement of the locking element 18 to accomplish is. At the same time serve the guide surfaces 42 also as sealing surfaces. Also recognizable are the outer groove 16 and the locking element 18 associated, mutually corresponding stops 44a , by means of which the release position of the locking element 16 is defined. In contrast, the blocking position shown here is of the locking element 18 by means of the likewise corresponding stops 44b Are defined. To reduce the friction and thus to ensure fast switching operations, the most sharp-edged ends of the leaf spring can 19 be bent accordingly.

10 shows an oblique perspective view of the supporting device according to a second embodiment. In contrast to the supporting device known from the first embodiment, the locking element 18 formed as a closed ring and has a corresponding groove 46 which when immersing the inner part 14 in the guide channel 12 in overlap with the anti-rotation element 26 to bring is. Another difference from the first embodiment is that the play compensation device 22 and the locking element 18 a common, hydraulic pipe system 34c (S. 11a , Federation 12a C), via which both the automatic compensation of a valve clearance and the movement of the locking element 18 from the blocking to the release position to accomplish is. In other words, the support device is of single-flow design, whereby it is opposite to the one in FIG 9 shown twin-cylinder design has friction advantages and can be easily integrated into existing cylinder heads, since the engine side no new supply and discharge lines of hydraulic medium must be provided. In addition, cost savings are achieved due to the reduced complexity.

11a shows a perspective sectional view of the supporting device along the in 10 represented sectional plane XIa-XIa. In synopsis with 11b showing a perspective sectional view of the support device along the in 10 Section XIb-XIb shows that is the locking element 18 in the blocking position oppressive leaf spring 19 and in particular the course of the pipe system 34c taking into account the holes 32a -F to recognize.

12a and 12b show sectional views of the supporting device along the in 10 represented sectional plane XIa-XIa and XIb-XIb, respectively, for reasons of clarity, no backgrounds are shown. The general structure is also to be taken from the previous descriptions. From the present illustrations, in particular the design of the common line system 34c good to see.

13 shows a sectional view of the supporting device according to 12a and b, wherein the locking element 18 is in the release position, its component axis B coaxial with the main axis H and the inner part 14 in the guide channel 12 or the outer part 10 is moved into it. Also in the present example is the locking element 18 at least partially positive fit on the contour of the guide channel 12 at.

14 shows a schematic Schnittaufsicht of the support element along the in 12a represented section line XIV-XIV. Again, the general structure is in particular from the description 9 known. As a difference, only the circumferentially closed, substantially annular configuration of the locking element 18 in the locking element 18 provided groove 26 for preventing rotation and the single-pipe system 34c to call. The ends of the leaf spring are shown bent in the present example.

15 shows an oblique perspective view of the inner part 14 the support device according to 10 to 13 , Because the locking element 18 formed circumferentially closed in the present example, there is the inner part 14 from an upper part 14a on which the locking element 18 during assembly is first postponed. Subsequently, a lower part 14b attached and, for example by means of laser welding with the upper part to the inner part 14 connected.

16a -C show schematic perspective views of the supporting device according to a third embodiment. In contrast to the previous embodiments, the locking element 18 in the present case ring-shaped. In addition, another locking element 18 ' provided, which in the in 16a shown blocking position and in an unlocked position flush with the shell contour of the locking element 18 is applied. Furthermore, the guide channel comprises 12 of the outer part 10 a circumferential inner groove 50 , within which the further locking element 18 ' and the locking element 18 are each arranged in sections in the blocking position. At the same time, the locking element 18 and the further locking element 18 ' each section in the outer groove 16 of the inner part 14 arranged and thus impossible thus a movement of the inner part 14 opposite the outer part 10 , In other words, with the help of the two locking elements 18 . 18 ' a positive connection of approximately 180 ° on opposite sides of the inner part 14 generated, whereby a particularly reliable locking is given and the support device can absorb high forces. The component axis B of the locking element 18 and the component axis B 'of the further locking element 18 ' run in this example, both axially parallel to the main axis H.

In 16b are the locking element 18 and the further locking element 18 ' moved to the release position, whereby their component axes B, B 'coaxial with the main axis H. Here is the locking element 18 completely inside the outer groove 16 of the inner part 14 arranged and allows moving the same. The further locking element 18 ' is in turn completely within the inner groove 50 of the outer part 10 arranged.

16c shows a schematic perspective view of the supporting device according to 16a and 16b , wherein the locking element 18 as well as the further locking element 18 ' in the release position and the inner part 14 in the guide channel 12 is moved into it. The advantage of this embodiment is that the movement of the locking element 18 between the locking and the release position optionally from the inside (inner part 14 ) or from the outside (inner groove 50 ). Also conceivable is a mechanically or electromagnetically induced movement of the locking element 18 or the further locking element 18 ' ,

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 10247949 A1 [0002]

Claims (17)

Switchable support device for a valve train of an internal combustion engine, comprising: - an outer part ( 10 ) with a guide channel ( 12 ); - an inner part ( 14 ), which at least over a length range within the guide channel ( 12 ) and along a major axis (H) of the guide channel ( 12 ) is movable; and - a locking element ( 18 ), which relative to the outer part ( 10 ) between a movement of the inner part ( 14 ) at least in one direction of movement impossible blocking position and a movement of the inner part ( 14 ) releasable release position, characterized in that the locking element ( 18 ) has a component axis (B), which in the blocking position outside coaxially and in the release position at least approximately coaxial to the main axis (H) of the guide channel ( 12 ) runs. Switchable supporting device according to claim 1, characterized in that a jacket contour of the locking element ( 18 ) depending on the switching position at least in time and in regions corresponding to a contour of the guide channel ( 12 ) is trained. Switchable supporting device according to claim 1 or 2, characterized in that the locking element ( 18 ) is at least partially formed in cross section circular sector-shaped. Switchable supporting device according to one of claims 1 to 3, characterized in that the locking element ( 18 ) is to be moved by means of a hydraulic medium and / or by means of a mechanical switching device and / or by means of a pneumatic switching device and / or by means of an electromagnetic switching device between the blocking position and the release position. Switchable supporting device according to one of claims 1 to 4, characterized in that the outer part ( 10 ) an anti-rotation element ( 26 ), in particular a cylindrical roller, by means of which a rotation of the outer part ( 10 ) relative to the valve drive and / or a rotation of the inner part ( 14 ) opposite the guide channel ( 12 ) and / or a twisting of the locking element ( 18 ) opposite the guide channel ( 12 ) is impossible. Switchable supporting device according to claim 5, characterized in that the inner part ( 14 ) and / or the locking element ( 18 ) a corresponding to the anti-rotation element ( 26 ) formed groove ( 28 . 46 ), which with the anti-rotation element ( 26 ) is to be brought into overlap. Switchable supporting device according to claim 5 or 6, characterized in that the inner part ( 14 ) a stop ( 36 ), by means of which a mobility of the inner part ( 14 ) along the main axis (H) of the guide channel ( 12 ) by striking the anti-rotation element ( 26 ) is limited. Switchable supporting device according to one of claims 1 to 7, characterized in that the locking element ( 18 ) in an outer groove ( 16 ) of the inner part ( 14 ) is guided. Switchable supporting device according to claim 8, characterized in that the locking element ( 18 ) and the outer groove ( 16 ) corresponding stops ( 44a . 44b ) are assigned, by means of which the blocking position and / or the release position is determined. Switchable supporting device according to one of claims 1 to 9, characterized in that the locking element ( 18 ) is associated with a spring element against whose spring force the locking element ( 18 ) is movable from the blocking position into the release position or from the release position into the blocking position. Switchable supporting device according to claim 10, characterized in that the spring element as a leaf spring ( 19 ) is formed, wherein both ends of the leaf spring ( 19 ) are preferably bent. Switchable supporting device according to one of claims 1 to 11, characterized in that the inner part ( 14 ) a hydraulic lash adjuster ( 22 ) is assigned to support a cam follower element of the valve train. Switchable supporting device according to claim 12, characterized in that the locking element ( 18 ) and the lash adjuster device ( 22 ) via a common management system ( 34c ) are to be acted upon with hydraulic medium. Switchable supporting device according to one of claims 1 to 12, characterized in that the locking element ( 18 ) via an associated line system ( 34a ) is to be acted upon with hydraulic medium. Switchable supporting device according to one of claims 1 to 14, characterized in that the locking element ( 18 . 18 ' ) in the blocking position at least in sections on an upper edge surface ( 20 ) of the outer part ( 10 ) is supported. Switchable supporting device according to one of claims 1 to 14, characterized in that the locking element ( 18 ) in the blocking position at least in sections within an inner groove ( 50 ) of the guide channel ( 12 ) is arranged. Switchable supporting device according to claim 16, characterized in that a further locking element ( 18 ' ) is provided, which in the blocking position on an outer periphery of the locking element ( 18 ) is arranged and at least partially within the inner groove ( 50 ) of the guide channel ( 12 ) is arranged.