The present application relates generally to a motor vehicle valve train and, more particularly, to a valve train arrangement with dual shifting camshaft cartridges operated by a single actuator.
Vehicle valve trains typically include a camshaft to control the timing and duration of an opening and closing of intake and exhaust valves associated with engine cylinders. The camshaft typically includes a plurality of cam lobes or cam profiles each having a shape configured to provide the desired valve lift and duration. Some camshafts are axially shiftable by an actuator to provide variable valve lift and timing. However, many systems require multiple actuators or have limited options for actuator placement. Therefore, while such systems do work well for their intended purpose, it is desirable to provide continuous improvement in the relevant art.
In accordance with one example aspect of the invention, a camshaft assembly for a vehicle valvetrain having first and second engine valves is provided. In one example implementation, the camshaft assembly includes a camshaft, and a first camshaft cartridge axially displaceable along the camshaft and including a plurality of first cam lobes configured to selectively impart movement to the first engine valve. A second camshaft cartridge is axially displaceable along the camshaft and includes a plurality of second cam lobes configured to selectively impart movement to the second engine valve. An actuator is configured to axially displace the first camshaft cartridge along the camshaft. A coupling is between the first camshaft cartridge and the second camshaft cartridge. Axial displacement of the first camshaft cartridge selectively imparts movement to the second camshaft cartridge for axial displacement of the second camshaft cartridge such that only the single actuator is needed to axially shift the first and second camshaft cartridges without having to directly engage both of the first and second camshaft cartridges.
In addition to the foregoing, the described assembly may include one or more of the following features: wherein the first camshaft cartridge includes a first shaft having the plurality of first cam lobes, and wherein the second camshaft cartridge includes a second shaft having the plurality of second cam lobes; wherein a first end of the first shaft is configured to engage a first end of the second shaft to form the coupling; and wherein the first shaft first end includes a first axially extending portion and a first finger portion, and the second shaft first end includes a second axially extending portion and a second finger portion, which is configured to selectively engage the first finger portion to establish the coupling therebetween.
In addition to the foregoing, the described assembly may include one or more of the following features: wherein when the first and second camshaft cartridges are at a maximum axial distance apart from each other allowed by the coupling, a space is established between the first and second finger portions; wherein the space has a width substantially equal to both a width of the first finger portion and a width of the second finger portion; wherein the first camshaft cartridge is configured to selectively push or pull the second camshaft cartridge when imparting movement to the second camshaft cartridge; wherein the camshaft assembly only includes a single actuator; and wherein the first and second camshaft cartridges are rotationally fixed to the camshaft.
In addition to the foregoing, the described assembly may include one or more of the following features: wherein the plurality of first cam lobes includes four first cam lobes, and wherein the plurality of second cam lobes includes three second cam lobes; wherein the four first cam lobes include a single first cam lobe configured to provide a low lift to the first engine valve, and three first cam lobes configured to provide a high lift to the first engine valve; wherein the three second cam lobes include a single second cam lobe configured to provide a high lift to the second engine valve, and two second cam lobes configured to provide a low lift to the second engine valve; and wherein in a first position, the first camshaft cartridge is positioned such that the single first cam lobe provides the low lift to the first engine valve, and the second camshaft cartridge is positioned such that a first of the two second cam lobes provides the low lift to the second engine valve.
In addition to the foregoing, the described assembly may include one or more of the following features: wherein when the first camshaft cartridge is axially shifted to a second position, a first of the three high lift first cam lobes is positioned to provide high lift to the first engine valve, and the first camshaft cartridge does not impart axial movement to the second camshaft cartridge; wherein when the first camshaft cartridge is axially shifted to a third position, a second of the three high lift cam lobes is positioned to provide high lift to the first engine valve, and the first camshaft cartridge axially pulls the second camshaft cartridge such that a second of the two second cam lobes provides low lift to the second engine valve; and wherein when the first camshaft cartridge is axially shifted to a fourth position, a third of the three high lift cam lobes is positioned to provide high lift to the first engine valve, and the first camshaft further axially pulls the second camshaft cartridge such that the high lift second cam lobe is positioned to provide high lift to the second engine valve.
Further areas of applicability of the teachings of the present disclosure will become apparent from the detailed description, claims and the drawings provided hereinafter, wherein like reference numerals refer to like features throughout the several views of the drawings. It should be understood that the detailed description, including disclosed embodiments and drawings references therein, are merely exemplary in nature intended for purposes of illustration only and are not intended to limit the scope of the present disclosure, its application or uses. Thus, variations that do not depart from the gist of the present disclosure are intended to be within the scope of the present disclosure.
According to the principles of the present application, systems and methods are described for a camshaft assembly with two shifting camshaft cartridges controlled by a single actuator. The single actuator controls axial shifting of a master camshaft cartridge, which is operably coupled to a follower camshaft cartridge for selective movement thereof. This advantageously allows the actuator to be located anywhere along the master camshaft cartridge.
With initial reference to
In the example embodiment, the controlling cartridge 12 and the controlled cartridge 14 are axially displaceable along a longitudinal axis CA′ of the camshaft 11, but non-rotatably coupled thereto. In the illustrated example, each of the first and second cam cartridges 12, 14 have an internally splined aperture (not shown) with teeth configured to meshingly engage with corresponding external teeth (not shown) formed on and extending radially outward from an outer diameter of the camshaft 11. In the example embodiment, the controlling cartridge 12 is configured to be axially displaceable between four positions along the longitudinal axis ‘A while the controlled cartridge 14 is configured to be axially displaceable between three positions along the longitudinal axis CA’. It will be appreciated, however, each cartridge 12, 14 may have a greater or lesser number of positions depending on the type of and desired operation of the valvetrain the camshaft assembly 10 will be utilized with, as described herein in more detail.
In the illustrated example, the controlling cartridge 12 is operably associated with a first valve mechanism 20 for actuating a first engine valve (not shown), and the controlled cartridge 14 is operably associated with a second valve mechanism 22 for selectively actuating a second engine valve (not shown). In one example, the first and second valve mechanisms 20, 22 are roller finger followers (RFF) configured to provide lift to the associated engine valves. Each of the first and second engine valves may be associated with the same or different cylinders of an internal combustion engine (not shown).
In the example embodiment, the controlling cartridge 12 includes a first shaft 24 with a plurality of cam lobes 26a-d. The first shaft 24 is a tubular member configured to receive the camshaft 11 therethrough and includes a first end 28 and an opposite second end 30. In the example embodiment, the shaft first end 28 is operably associated with the actuator assembly 16, and the shaft second end 30 forms part of the coupling 18, as described herein in more detail. The cam lobes 26a-d are sized and shaped to selectively actuate the valve mechanism 20 with a particular valve lift and duration to thereby provide a desired valve lift profile of the first engine valve. In the illustrated example, cam lobe 26a is configured to provide a low lift profile, while cam lobes 26b-d are configured to provide a high lift profile. As shown, each cam lobe 26a-d has an equal or substantially equal spacing or width ‘w’. Moreover, it will be appreciated that controlling cartridge 12 may have any number of cam lobes 26 to be adapted to various different systems.
As noted above, the controlling cartridge 12 is axially displaceable along the camshaft 11, but rotatably fixed thereto. In the example embodiment, the controlling cartridge 12 is axially displaceable between four different positions. In the first position (
In the example embodiment, the controlled cartridge 14 includes a second shaft 32 with a plurality of cam lobes 34a-c. The second shaft 32 is a tubular member configured to receive the camshaft 11 therethrough and includes a first end 36 and an opposite second end 38. In the example embodiment, the shaft first end 36 forms part of the coupling 18, as described herein in more detail. The cam lobes 34a-c are sized and shaped to selectively actuate the valve mechanism 22 with a particular valve lift and duration to thereby provide a desired valve lift profile of the second engine valve. In the illustrated example, cam lobes 34a-b are configured to provide a low lift profile, while cam lobes 34c is configured to provide a high lift profile. As shown, each cam lobe 34a-c also has an equal or substantially equal spacing or width ‘w’. Moreover, it will be appreciated that controlled cartridge 14 may have any number of cam lobes 34 to be adapted to various different systems.
As noted above, the controlled cartridge 14 is axially displaceable along the camshaft 11, but rotatably fixed thereto. In the example embodiment, the controlled cartridge 14 is axially displaceable between three different positions. In the first position (
With continued reference to
In the example embodiment, the actuator assembly 16 includes an actuator 39 with one or more actuator pins 40 (only one shown) configured to selectively engage a first ramp profile 42, a second ramp profile 44, and a third ramp profile 46. It will be appreciated, however, that the described configuration of actuator assembly 16 and operational integration is only one example configuration and that actuator assembly 16 and cartridge 12 may have any suitable components/configuration that enables controlling cartridge 12 to be axially shifted as described herein. In the example embodiment, the actuator pin 40 is disposed perpendicular to or substantially perpendicular to the longitudinal axis ‘A and is selectively translated toward the axis CA’ into engagement with the first ramp profile 42 to move the controlling cartridge 12 from the first position to the second position. If only the second position is desired, the actuator pin 40 is withdrawn away from the first ramp profile 42 such that controlling cartridge 12 remains in the second position.
If the third position is desired, the actuator pin 40 engages the second ramp profile 44 to move the controlling cartridge 12 from the second position to the third position. If only the third position is desired, the actuator pin 40 is withdrawn away from the second ramp profile 44 such that controlling cartridge 12 remains in the third position. If the fourth position is desired, the actuator pin 40 engages the third ramp profile 46 to move the controlling cartridge 12 from the third position to the fourth position. The actuator pin 40 may then be withdrawn toward the actuator 39 so the controlling cartridge 12 remains in the fourth position. The process may be reversed to move the controlling cartridge 12 back to any of the third, second, or first positions.
In the example embodiment, the coupling 18 is established by engaging cooperation between the first shaft second end 30 and the second shaft first end 36. As shown, the first shaft second end 30 includes a first axially extending portion 50 and a first inwardly extending hook or finger portion 52. Similarly, the second shaft first end 36 includes a second axially extending portion 54 and a second inwardly extending hook or finger portion 56. As illustrated in
In this max distance position, a space 58 is established between the first and second finger portions 52, 56. Notably, at least one of the finger portions 52, 56 and the space 58 each have a width ‘w’ equal or substantially equal to the width ‘w’ of each cam lobe 26 and 34. Moreover, in some embodiments, each of the first and second axially extending portions 50, 54 have a width 2w such that, as shown in
In one example method of operation of the camshaft assembly 10, the controlling cartridge 12 and the controlled cartridge 14 begin at their maximum axial distance relative to each other, as shown in
In a first switching operation, actuator assembly 16 axially shifts the controlling cartridge 12 to the second position where cam lobe 26b provides high lift to the valve mechanism 20. During this shift movement, the first finger portion 52 is moved axially leftward one width ‘w’ (as shown in
In a subsequent second switching operation, actuator assembly 16 further axially shifts the controlling cartridge 12 to the third position where cam lobe 26c engages and provides high lift to the valve mechanism 20. During this shift movement, the first finger portion 52 engages the second finger portion 54 and pulls the controlled cartridge 14 axially leftward one width ‘w’ such that cam lobe 34b engages and provides low lift to the valve mechanism 22. As such, the controlling cartridge 12 imparts axial movement to the controlled cartridge 14 through the coupling 18 such that controlling cartridge 12 is in the third position and the controlled cartridge 14 is in the second position. In this way, the valve mechanism 20 is operated in the high lift mode and the valve mechanism 22 is operated in the low lift mode.
In a subsequent third switching operation, actuator assembly 16 next axially shifts the controlling cartridge 12 to the fourth position where cam lobe 26d engages and provides high lift to the valve mechanism 20. During this shift movement, the first finger portion 52 engages the second finger portion 54 and further pulls the controlled cartridge 14 axially leftward one width ‘w’ such that cam lobe 34c engages and provides high lift to the valve mechanism. As such, the controlling cartridge 12 imparts axial movement to the controlled cartridge 14 through the coupling 18 such that controlling cartridge 12 is in the fourth position and the controlled cartridge 14 is in the third position. In this way, camshaft assembly 10 now operates both valve mechanisms 20, 22 in the high lift mode. The shifting operations may then be reversed such that the first finger portion 52 engages an end surface 60 of the controlled cartridge 14 to impart rightward axial movement (as shown in
Described herein are systems and methods for shifting dual camshaft cartridges with a single actuator, which does not need to be disposed between the camshaft cartridges. Rather, the single actuator can be positioned anywhere along one of the camshaft cartridges, which can be translated axially to push or pull on the other camshaft cartridge to thereby impart axial movement thereto. In this way, the system can switch between two or more axial positions to provide variable valve lift or other variable engine operation.
It will be understood that the mixing and matching of features, elements, methodologies, systems and/or functions between various examples may be expressly contemplated herein so that one skilled in the art will appreciate from the present teachings that features, elements, systems and/or functions of one example may be incorporated into another example as appropriate, unless described otherwise above. It will also be understood that the description, including disclosed examples and drawings, is merely exemplary in nature intended for purposes of illustration only and is not intended to limit the scope of the present disclosure, its application or uses. Thus, variations that do not depart from the gist of the present disclosure are intended to be within the scope of the present disclosure.
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Number | Date | Country |
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102009056224 | Jun 2011 | DE |
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Entry |
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DE-102018000435-A1, English Language Machine Translation (Year: 2019). |
Number | Date | Country | |
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20220397045 A1 | Dec 2022 | US |