The present disclosure relates to a variable valve train for an internal combustion engine.
It is generally known to use variable valve trains for changing the switching times and valve lifts of gas exchange valves of an internal combustion engine during operation of the internal combustion engine. A plurality of variable valve trains are known.
US 2005/0150472 A1 discloses an example of a variable valve train. The variable valve train has a camshaft, which is rotatably mounted on a fixed part of the engine and comprises a cam. A first rocker arm is pivotably mounted on a fixed part of the engine. The first rocker arm engages a shaft an engine valve. A rotatable drum is carried by a fixed part of the engine, and at least partially envelops the cam. A second rocker arm is pivotably mounted on the drum. A control element is provided for turning the drum. The second rocker arm has a cam follower, which follows the cam of the camshaft. The first rocker arm has a roller in contact with a bearing surface of the second rocker arm.
The disadvantage to known variable valve trains, such as the variable valve train from US 2005/0150472 A1, is that the latter often have a complicated structural design, a large number of parts and/or a large installation space.
Therefore, the object of the present disclosure is to create an improved variable valve train with which the disadvantages in the prior art can be overcome. In particular, the variable valve train is to have a simple structural design, few parts and/or only a small installation space.
The variable valve train is suitable for an internal combustion engine. The variable valve train has a camshaft with a cam. The variable valve train has a rocker arm for activating at least one gas exchange valve of the internal combustion engine. The variable valve train has a swivelling lever element, in particular a swivelling lever gate, which has a support surface and a cam follower. The support surface is operatively connected, in particular in contact, with the rocker arm, and the cam follower follows a cam contour of the cam. The variable valve train has a first rocker arm, which pivotably mounts the swivelling lever element, and is connected with a driven swivelling shaft for swivelling around a longitudinal axis of the swivelling shaft.
The variable valve train enables a variable transmission of the cam contour to the rocker arm by changing a position of a swivelling axis, which pivotably connects the swivelling lever element with the first lever arm. Specifically, displacing the lever arm with the swivelling shaft changes the position of the swivelling axis, which leads to a displacement motion of the swivelling lever element. The contact positions between the rocker arm, swivelling lever element and cam change in the process. The altered contact positions can be used to realize various “transmissions” of the cam contour onto the rocker arm via the swivelling lever element, and thus influence the height of the maximum valve lift.
In order to ensure the variability of the valve train, only a few additional parts are required in relation to a non-variable valve train. These include in particular the first lever arm and the swivelling lever element. The comparatively simple construction also allows for a robust system, and depending on configuration, requires only a little additional installation space.
The support surface of the swivelling lever element and the cam follower of the swivelling lever element can preferably operatively connect the rocker arm with the cam for activating the at least one gas exchange valve.
In an exemplary embodiment, the rocker arm is mounted so that it can pivot around the swivelling shaft. Additionally or alternatively, the swivelling shaft serves as a rocker arm axis for the rocker arm. Such a configuration significantly reduces the installation space of the variable valve train, since a shaft for swivelling the first rocker arm and a rocker arm axis for pivotable connection with the rocker arm need not be provided separate from each other.
In a further exemplary embodiment, turning the swivelling shaft causes the first lever arm and the swivelling lever element to pivot, making it possible to vary the transmission of the cam contour of the cam from the swivelling lever element to the rocker arm, in particular continuously. The valve lift curve transmitted to the at least one gas exchange valve can be varied by changing the position of the swivelling axis that pivotably connects the first lever arm and swivelling lever element by swivelling the first lever arm.
In a further development, the transmission for changing a maximum valve lift of the at least one gas exchange valve is variable, in particular up to a zero lift of the at least one gas exchange valve. The advantage to this is that the quantity of gas flowing through the gas exchange valve can be varied by the variable valve train, in particular going as far as blocking the quantity of gas by keeping the gas exchange valve closed, which for example can be used for cylinder deactivation.
In an embodiment variant, the first lever arm is non-rotatably connected with the swivelling shaft. The rigid connection makes it possible to impart a rotational movement of the swivelling shaft directly to the first lever arm for swivelling the latter. The first lever arm can be non-rotatably connected directly with the swivelling shaft, or non-rotatably connected indirectly with the swivelling shaft by interspersing one or several intermediate elements, for example a sleeve enveloping the swivelling shaft.
It is also possible to use another connection between the first lever arm and the swivelling shaft, which causes the first lever arm to swivel while rotating the swivelling shaft.
In another embodiment variant, the swivelling lever element is swiveled relative to the first lever arm while following the cam contour of the cam via the cam follower. Alternatively or additionally provided is a swivelling axis that pivotably joins the first lever arm and swivelling lever element together. As a consequence, the pivotable connection (swivelling axis) between the swivelling lever element and first lever arm can perform two tasks. On the one hand, it allows a swivelling of the swivelling lever element so as to follow the cam contour of the cam. On the other hand, the connection (swivelling axis) serves as a suspension for the swivelling lever element, whose position can be changed by means of the first lever arm, so as to vary the valve lift curve of the at least one gas exchange valve.
In an embodiment, the rocker arm has a rotatable roller for contacting the support surface. The rotatable roller can rest on the support surface. The support surface can have a continuous progression. The rotatable roller can enable a continuous displacement of the variable valve train.
In a further development, the cam follower of the swivelling lever element and the rotatable roller of the rocker arm can have the same design. As a result, the cam follower and the roller of the rocker arm can be configured as identical parts. This reduces the diversity of parts.
In another exemplary embodiment, the support surface has a concave design. However, the support surface can also be flat or convex. This depends on the selected lever ratios of the valve train.
In an embodiment variant, the swivelling shaft can only be turned within a limited angular range of less than 360°, in particular within an angular range of less than 120°. This can stem from the fact that the first lever arm need only be swiveled within a small angular range for swivelling the swivelling lever element so as to change the transmission of the cam contour on the rocker arm. The limited necessary angular range for turning the swivelling shaft can influence a drive unit of the swivelling shaft and a connection between the drive unit and the swivelling shaft.
The swivelling shaft can preferably be rotatably mounted in bearing blocks, which preferably are secured on a cylinder head of the internal combustion engine.
In another embodiment variant, the variable valve train has a second lever arm, which is connected with the first lever arm via the swivelling shaft, and in particular via the swivelling axis. In particular, the first lever arm and second lever arm can be arranged on opposing sides of the rocker arm. Two lever arms can allow for an especially reliable mount for the swivelling lever element. The arrangement on opposing sides of the rocker arm can be favorable for reasons of installation space.
The first lever arm can preferably be designed like the second lever arm. As a consequence, the first lever arm and second lever arm can be configured as identical parts. This reduces the diversity of parts.
In an embodiment, the variable valve train further has a sleeve, which is non-rotatably arranged on the swivelling shaft. The first lever arm and/or second lever arm is non-rotatably arranged on the sleeve. The rocker arm is arranged so that it can pivot around the sleeve. This can significantly simplify the assembly of the variable valve train, since an assembly comprised of a sleeve, lever arm(s) and rocker arm can be preassembled and then non-rotatably connected with the swivelling shaft. This can improve mountability in particular in embodiments with a plurality of variable valve trains for a plurality of cylinders of the internal combustion engine.
In another embodiment, the swivelling lever element is arranged between the rocker arm and the camshaft. This is advantageous for reasons of installation space.
In another exemplary embodiment, the variable valve train has a drive unit for turning the swivelling shaft. The drive unit is drivingly connected with the swivelling shaft. The drive unit can be connected with the swivelling shaft in such a way and/or the drive unit can be designed in such a way as to allow the swivelling shaft to turn only within a limited angular range. For example, a corresponding electric servomotor with an angular range can be used.
Alternatively, the variable valve train can have an actuator, for example, which is designed to contact the first lever arm for swivelling the first lever arm. The lever arm can be adjusted via the actuator in multiple stages (in particular two stages), for example. When using the actuator for adjusting the first lever arm, at least one actuator must be provided for each cylinder. Stops for limiting the adjustment of the first lever arm can further be provided.
In another embodiment variant, the variable valve train has a camshaft adjuster, which is connected with the camshaft for adjusting a phase of the camshaft. This makes it possible to increase a variability of the variable valve train, since in particular the valve lift curves can be shifted, i.e., the opening and closing times of the gas exchange valves or gas exchange valve can be altered.
The present disclosure can be used to special advantage in a motor vehicle, in particular a commercial vehicle (for example a bus or truck). The motor vehicle has the variable valve train as disclosed herein.
However, it is also possible to use the variable valve train in internal combustion engines that are not included in motor vehicles. For example, this can involve stationary internal combustion engines, internal combustion engines on ships or in locomotives.
The embodiments and features of the present disclosure described above can be combined with each other however desired.
Additional details and advantages of the present disclosure will be described below with reference to the attached drawings. In the drawings:
The embodiments shown in the figures at least partially coincide, so that similar or identical parts are provided with the same reference number, and reference is also made to the description of the other embodiments or figures for describing the latter, so as to avoid repetition.
The variable valve train 10 has a camshaft 14, a swivelling lever element 16, two lever arms 18 and 20 as well as a rocker arm 22.
The camshaft 14 is rotatably mounted, and has a cam 24. In several embodiments, the camshaft 14 can be connected with a camshaft adjuster 26 for adjusting a phase of the camshaft 14. The camshaft adjuster 26 is schematically indicated in
The swivelling lever element 16 carries a cam follower 28. The cam follower 28 follows a cam contour of the cam 24 while the camshaft 14 turns. The cam follower 28 is designed as a roller mounted so that it can rotate around a cam follower axis 30. The cam follower axis 30 is carried by a fork 32 of the swivelling lever element 16 at opposite ends of the cam follower axis 30. The fork 32 is arranged at a first end of the swivelling lever element 16.
The swivelling lever element 16 is pivotably joined with the lever arms 18, 20 at one of the ends of the swivelling lever element 16 lying opposite the fork 32. While the cam follower 28 follows the cam contour of the cam 24 while the camshaft 14 turns, the swivelling lever element 16 is swiveled relative to the lever arms 18, 20. The swivelling lever element 16 has a support surface 34. The support surface 34 serves as a contact surface for the rocker arm 22. The support surface 34 extends concavely, and is arranged on an upper side of the swivelling lever element 16. The swivelling lever element 16 thus serves as a gate for the rocker arm 22.
The lever arms 18, 20 are non-rotatably connected with a swivelling shaft 36, so that they turn together with the swivelling shaft 36. Specifically, the lever arms 18, 20 turn while the swivelling shaft 36 rotates around a longitudinal axis A of the swivelling shaft 36. The swivelling shaft 36 simultaneously serves as a rocker arm axis for the rocker arm 22. This is especially advantageous for reasons of installation space, since no separate axes must be provided for swivelling the lever arms 18, 20 and for pivotably mounting the rocker arm 22.
The lever arms 18, 20 are connected with each other via the swivelling shaft 36 and a swivelling axis 38. The lever arms 18, 20 are arranged at opposite sides of the rocker arm 22. The lever arms 18, 20 grip the swivelling lever element 16 at the end of the swivelling lever element 16 opposite the fork 32. The lever arms 18, 20 carry the swivelling lever element 16 via the swivelling axis 38, so that the swivelling lever element 16 can swivel relative to the lever arms 18, 20. The swivelling lever element 16 can here be non-rotatably connected with the swivelling axis 38, for example, wherein the swivelling axis 38 is in turn rotatably mounted in the lever arms 18, 20. Alternatively, the swivelling lever element 16 can be provided so as to swivel around the swivelling axis 38. It is also possible to provide just one lever arm, for example, which carries the swivelling lever element.
As shown in
An actuator 43 can also be provided as an alternative to the drive unit 42. For example, the actuator 43 can contact the first lever arm 18 and/or the second lever arm 20, so as to swivel the first and second lever arm 18, 20. Swivelling the lever arms 18, 20 in turn causes the swivelling lever element 16 to swivel, as already described above. In such an embodiment, the lever arms 18, 20 can be rotatably connected with the swivelling shaft 36, which thus only serves as a swivelling axis.
To enable a rotation of the swivelling shaft (rocker arm axis) 36, the swivelling shaft 36 is rotatably mounted in bearing blocks 44, for example via slide bearings or roller bearings (see
Again drawing reference to
The rocker arm 22 has a fork 46, which carries a rotatable roller 48 via a roller axis 50. The rotatable roller 48 is in contact with the support surface 34 of the swivelling lever element 16. The cam follower 28 of the swivelling lever element 16 and the rotatable roller 48 of the rocker arm 22 can have the same design, since they transmit roughly the same forces, and so as to reduce the diversity of parts. The rocker arm 22 activates the gas exchange valves 12, for example via a ball foot (elephant foot, not shown).
Swivelling the swivelling lever element 16 around the swivelling axis 38 causes the rocker arm 22 to swivel around the swivelling shaft 36, since the roller 48 is in contact with the support surface 34. In particular, when the swivelling lever element 16 is swiveled upwardly, the ascending ramp of the cam 24 causes the roller 48 to roll upwardly on the support surface 34. The rocker arm 22 is swiveled around the swivelling shaft 36. The gas exchange valves 12 are activated (opened) while swivelling the rocker arm 22. While swivelling the swivelling lever element 16 downwardly as the result of the descending ramp of the cam 24, the roller 48 rolls downwardly on the support surface 34. The rocker arm 22 is swiveled back. By contrast, the base circle area of the cam contour of the cam 24 produces no swivelling of the swivelling lever element 16, and thus also no swivelling of the rocker arm 22.
The support surface 34 of the swivelling lever element 2 is to be specially designed for achieving the valve lift curves depicted in
In combination with the camshaft adjuster 26, the valve lift curves can also be shifted (along the abscissa in
The present disclosure is not limited to the exemplary embodiments described above. Rather, a plurality of variants and modifications is possible, which also make use of the concepts and ideas, and thus fall within the protective scope. In particular, the present disclosure is also directed to the presence and design of the support surface, swivelling shaft and/or pivotable connection between the first lever arm and swivelling lever element.
10 Variable valve train
12 Gas exchange valve
14 Camshaft
16 Swivelling lever element
18 First lever arm
20 Second lever arm
22 Rocker arm
24 Cam
26 Camshaft adjuster
28 Cam follower
30 Cam follower axis
32 Fork
34 Support surface
36 Swivelling shaft
38 Swivelling axis
40 Sleeve
42 Drive unit
43 Actuator
44 Bearing block
46 Fork
48 Roller
50 Roller axis
A Longitudinal axis
Number | Date | Country | Kind |
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102017119348.0 | Aug 2017 | DE | national |