Patent Grant
10947870
Example aspects described herein relate to couplings for camshaft phasers, and, more particularly, to camshaft phasers utilized within an internal combustion (IC) engine having a concentric camshaft assembly.
Camshaft phasers are utilized within IC engines to adjust timing of an engine valve event to modify performance, efficiency and emissions. Hydraulically actuated camshaft phasers can be configured with a rotor and stator arrangement. The rotor can be attached to a camshaft and actuated hydraulically in clockwise or counterclockwise directions relative to the stator to achieve variable engine valve timing. Electric camshaft phasers can be configured with a gearbox and an electric motor to phase a camshaft to achieve variable engine valve timing.
Many different camshaft configurations are possible within an IC engine. Some camshaft configurations include an intake camshaft that only actuates intake valves, and an exhaust camshaft that only actuates exhaust valves; such camshaft configurations can often simplify efforts to independently phase the intake valve events separately from the exhaust valve events. Other camshaft configurations can utilize a single camshaft to actuate both intake and exhaust valves; however, a single camshaft configured with both intake and exhaust lobes proves difficult to provide independent phasing of the intake and exhaust valves. For single camshaft configurations, a concentric camshaft assembly can be implemented that utilizes an inner camshaft and an outer camshaft, each arranged with one of either exhaust lobes or intake lobes, with each of the camshafts having a designated camshaft phaser to vary the respective engine valve timing.
One known camshaft phaser arrangement for a concentric camshaft assembly includes a first and a second camshaft phaser that are stacked coaxially at an end of the concentric camshaft assembly. A solution is needed that facilitates connection of this camshaft phaser arrangement to the concentric camshaft assembly while torsionally or rotationally coupling the two camshaft phasers to a crankshaft of the IC engine.
A camshaft phaser arrangement configured for a concentric camshaft assembly having inner and outer camshafts is provided. The camshaft phaser arrangement includes a first camshaft phaser, a second camshaft phaser, and a coupling. The first camshaft phaser is configured to be connected to one of the inner or the outer camshafts. The second camshaft phaser is configured to be connected to the other of the inner or outer camshafts. The coupling has a first end non-rotatably connected to a coupling end of a center hub of the first camshaft phaser and a second end configured to be non-rotatably connected to the one of the inner or outer camshafts. The coupling is configured to accommodate at least one of a radial offset or an axial offset between the first and second camshaft phasers; or, alternatively stated, the coupling is configured to accommodate at least one of a radial offset or an axial offset between first camshaft phaser and the concentric camshaft assembly. At least one first fastener connects the first camshaft phaser to the second camshaft phaser. The at least one first fastener can connect a first stator of the first camshaft phaser to a second stator of the second camshaft phaser. In an example embodiment, the at least one first fastener connects the first stator to a second outer cover of the second camshaft phaser, the second outer cover non-rotatably connected with the second stator. At least one support boss can extend axially from the second outer cover to receive the at least one first fastener.
The coupling can be configured to accommodate a first radial offset and a second radial offset between the first camshaft phaser and the second camshaft phaser, or between the first camshaft phaser and the concentric camshaft assembly. The first radial offset can be perpendicular to the second radial offset.
The coupling can include a through-aperture that is configured to fluidly connect the concentric camshaft assembly to the first camshaft phaser. In an example embodiment, the coupling fluidly connects the inner camshaft to the center hub of the first camshaft phaser, supplying hydraulic fluid to a hydraulic fluid control valve.
The camshaft phaser arrangement can also include: a first compliant radial seal that is arranged to seal the center hub to the first end of the coupling; and, a second compliant radial seal that is arranged to seal the second end of the coupling to the one of the inner or outer camshafts. The first compliant radial seal can be configured to maintain engagement with both the center hub and the coupling while the coupling accommodates the at least one of a radial offset or an axial offset between the first camshaft phaser and the second camshaft phaser; or, alternatively stated, at least one of a radial offset or an axial offset between the first camshaft phaser and the concentric camshaft assembly. The second compliant radial seal can be configured to maintain engagement with both the coupling and the one of the inner or outer camshafts while the coupling accommodates the at least one of a radial offset or an axial offset.
The first end of the coupling and the coupling end of the center hub can cooperate to form a first rotational poka-yoke, and the second end of the coupling can be configured to form a second rotational poka-yoke with the one of the inner or outer camshaft.
The first end of the coupling can include at least one hub tab that is configured to be received by the center hub. The at least one hub tab and the center hub can define a pathway for at least one of a first radial offset or a first axial offset. The second end of the coupling can include at least one camshaft tab that is configured to be received by the one of the inner or outer camshafts. The at least one camshaft tab and the one of the inner or outer camshafts can define a pathway for at least one of a second radial offset or a second axial offset.
In an example embodiment, the at least one hub tab comprises a first tab and a second tab, and the at least one camshaft tab comprises a third tab and a fourth tab. The first tab can have a first width that is different than a second width of the second tab, and the third tab can have a third width that is different than a fourth width of the fourth tab. A center of the first tab can be located within a range of 175 to 185 degrees from a center of the second tab, and a center of the third tab can be located within a range of 175 to 185 degrees from a center of the fourth tab. A first line that connects the center of the first tab to the center of the second tab can be perpendicular to a second line that connects the center of the third tab to the center of the fourth tab.
The coupling end of the center hub and the first end of the coupling can cooperate to accommodate at least one of: (i) a first axial offset between the first camshaft phaser and the concentric camshaft assembly; or, (ii) a first radial offset between the first camshaft phaser and the concentric camshaft assembly. The second end of the coupling can be configured to cooperate with the one of the inner or outer camshafts to accommodate at least one of: (i) a second axial offset between the first camshaft phaser and the concentric camshaft assembly; or, (ii) a second radial offset between the first camshaft phaser and the concentric camshaft assembly. The first radial offset can be perpendicular to the second radial offset.
The camshaft phaser arrangement can also include a hydraulic fluid control valve that is arranged within the first camshaft phaser, with the first camshaft phaser arranged axially outward of the second camshaft phaser. In an example embodiment, the center hub is configured to be attached to the first camshaft phaser via a threaded interface with the hydraulic fluid control valve.
The above mentioned and other features and advantages of the embodiments described herein, and the manner of attaining them, will become apparent and better understood by reference to the following descriptions of multiple example embodiments in conjunction with the accompanying drawings. A brief description of the drawings now follows.
Identically labeled elements appearing in different figures refer to the same elements but may not be referenced in the description for all figures. The exemplification set out herein illustrates at least one embodiment, in at least one form, and such exemplification is not to be construed as limiting the scope of the claims in any manner. Certain terminology is used in the following description for convenience only and is not limiting. The words “inner,” “outer,” “inwardly,” and “outwardly” refer to directions towards and away from the parts referenced in the drawings. Axially refers to directions along a diametric central axis. Radially refers to directions that are perpendicular to the central axis. The words “left”, “right”, “up”, “upward”, “down”, and “downward” designate directions in the drawings to which reference is made. The terminology includes the words specifically noted above, derivatives thereof, and words of similar import.
The term “non-rotatably connected” can be used to help describe various connections of camshaft phaser components and is meant to signify two elements that are directly or indirectly connected in a way that whenever one of the elements rotate, both of the elements rotate in unison, such that relative rotation between these elements is not possible. Radial and/or axial movement or offset of non-rotatably connected elements with respect to each other is possible, but not required.
Referring to
The camshaft phaser arrangement 10 includes a rotational axis 12, the first camshaft phaser 20, the second camshaft phaser 30, the center hub 60, and the coupling 80 that non-rotatably connects the first camshaft phaser 20 to the concentric camshaft assembly 40. The first camshaft phaser 20 is arranged axially adjacent to the second camshaft phaser 30 such that the first camshaft phaser 20 is axially outward of the second camshaft phaser 30. Additionally, the first camshaft phaser 20 can be concentric with the second camshaft phaser 30, as shown. The concentric camshaft assembly 40 includes an outer camshaft 42 and an inner camshaft 44. The first camshaft phaser 20 and the second camshaft phaser 30 of
Referring specifically to
The second camshaft phaser 30 includes a second timing wheel 31, a second bias spring 32, a second outer cover 33, a second rotor 34, a second stator 35, and a second inner cover 36. The second camshaft phaser 30 can be assembled with fasteners (not shown) like that of the first camshaft phaser 20, which non-rotatably connect the second outer cover 33 and the second inner cover 36 to the second stator 35 while permitting rotation of the second rotor 34 relative the second stator 35. The second stator 35 of the second camshaft phaser 30 is non-rotatably connected to a drive wheel 45 with a power transmission interface 46. The power transmission interface 46 can engage with an endless drive band 13 (
The second stator 35 of the second camshaft phaser 30 is non-rotatably connected to the first stator 25 of the first camshaft phaser 20 by the first fasteners 19. This connection is aided by first target wheel clearance holes 96 that allow tool access to the first fasteners 19, and further facilitated by outer cover clearance holes 97, stator clearance holes 98, inner cover clearance holes 99, second target wheel circumferential slotted holes 87, and support boss holes 55 that are configured within support bosses 54 that extend axially from the second outer cover 33.
Attachment of the camshaft phaser arrangement 10 to the concentric camshaft assembly 40 will now be described. The second camshaft phaser 30 is non-rotatably connected to the outer camshaft 42 by a cam bolt 70 that attaches to an inner diameter of the outer camshaft 42, via threaded interface or other suitable means. More specifically, the cam bolt 70 axially clamps the second timing wheel 31 and the second rotor 34 of the second camshaft phaser 30 to a journal bearing 38 that is non-rotatably connected to the outer camshaft 42. To ensure proper timing of the second rotor 34 to the outer camshaft 42, a reception cavity 37 is arranged on a second axial face 72 of the second rotor 34 to receive a timing pin 48 that protrudes from a first axial face 39 of the journal bearing 38. Other timing arrangements between the second rotor 34 and the outer camshaft 42 are also possible.
The cam bolt 70 has a longitudinal through-aperture 71 through which the inner camshaft 44 extends to facilitate the non-rotatable connection with the first camshaft phaser 20. This connection will be described with view to
The coupling 80 non-rotatably connects a coupling end 62 of the center hub 60 to a drive end 43 of the inner camshaft 44, while facilitating a flow of hydraulic fluid F from the inner camshaft 44 to the valve body 17 of the first hydraulic fluid control valve 14.
A first end 81 of the coupling 80 is non-rotatably connected to the coupling end 62 of the center hub 60, accommodating a first radial offset R1 and a first axial offset A1. The first end 81 of the coupling includes a first hub tab 83A and a second hub tab 83B that are received by a respective first slot 64A and a second slot 64B arranged at the coupling end 62 of the center hub 60. The first and second hub tabs 83A, 83B and the first and second slots 64A, 64B define a pathway for the first radial offset R1 and a pathway for the first axial offset A1. The first hub tab 83A has a first hub tab perimeter surface 89A and the second hub tab 83B has a second hub tab perimeter surface 89B; the first slot 64A has a first slot perimeter surface 69A and the second slot 64B has a second slot perimeter surface 69B. Therefore, it could be stated that the first and second hub tab perimeter surfaces 89A, 89B together with the respective first and second slot perimeter surfaces 69A, 69B define a pathway for the first radial offset R1 and a pathway for the first axial offset A1. The first and second hub tabs 83A, 83B and the respective first and second slots 64A, 64B provide a non-rotatable connection between the coupling 80 and the center hub 60, while accommodating: (i) the first axial offset A1 between the coupling 80 and the center hub 60; and, (ii) the first radial offset R1 between the coupling 80 and the center hub 60. It could also be possible to modify the first and second hub tab perimeter surfaces 89A, 89B and the respective first and second slot perimeter surfaces 69A, 69B to accommodate one of either the first axial offset A1 or the first radial offset R1.
A second end 82 of the coupling 80 is non-rotatably connected to the drive end 43 of the inner camshaft 44, accommodating a second radial offset R2 and a second axial offset A2. The second end 82 of the coupling 80 includes a third camshaft tab 84A and a fourth camshaft tab 84B that are received by a respective third slot 88A and a fourth slot 88B arranged at the drive end 43 of the inner camshaft 44. The third and fourth camshaft tabs 84A, 84B and the third and fourth slots 88A, 88B define a pathway for the second radial offset R2 and a pathway for the second axial offset A2. The third camshaft tab 84A has a third camshaft perimeter surface 93A and the fourth camshaft tab 84B has a fourth camshaft perimeter surface 93B; the third slot 88A has a third slot perimeter surface 73A, and the fourth slot 88B has a fourth slot perimeter surface 73B. Therefore, it could be stated that the third and fourth camshaft tab perimeter surfaces 93A, 93B together with the respective third and fourth slot perimeter surfaces 73A, 73B define a pathway for the second radial offset R2 and a pathway for the second axial offset A2. The third and fourth camshaft tabs 84A, 84B and the respective third and fourth slots 88A, 88B provide a non-rotatable connection between the coupling 80 and inner camshaft 44, while accommodating: (i) the second axial offset A2 between the coupling 80 and inner camshaft 44; and, (ii) the second radial offset R2 between the coupling 80 and the inner camshaft 44. It could also be possible to modify the third and fourth camshaft tab perimeter surfaces 93A, 93B and the respective third and fourth slot perimeter surfaces 73A, 73B to accommodate one of either the second axial offset A2 or the second radial offset R2.
As shown in
“Poka-yoke” is a common term that means “mistake-proofing” or “inadvertent error prevention.” Multiple orientation possibilities for assembly of the coupling 80 within the camshaft phaser arrangement 10 should be avoided, as a specific orientation of the first rotor 24 relative to the inner camshaft 44 is vital to the function of the internal combustion engine. To ensure proper rotational orientation (or proper timing) of the first rotor 24 of the first camshaft phaser 20 to the inner camshaft 44 of the concentric camshaft assembly 40, the first end 81 of the coupling 80 and the coupling end 62 of the center hub cooperate to form a first rotational poka-yoke, and the second end 82 of the coupling 80 and the drive end 43 of the inner camshaft 44 cooperate to form a second rotational poka-yoke. An additional rotational poka-yoke could also be applied between the center hub 60 and the first rotor 24, possibly between the phaser end 61 of the center hub 60 and the first rotor face 53 of the first rotor 24.
With reference to
With reference to
In addition to the previously described features of the coupling 80, an additional attribute includes facilitation of flow of hydraulic fluid F from a first fluid cavity 76 of the inner camshaft 44 to the valve body 17 of the first hydraulic fluid control valve 14, by way of a second fluid cavity 79 of the center hub 60. For the example embodiment shown, the hydraulic fluid F delivered to the valve body 17 serves as a pressurized fluid supply to the first hydraulic fluid control valve 14, however, any form of hydraulic fluid transfer by the coupling 80 is possible. The transfer of hydraulic fluid F from the inner camshaft 44 to the first hydraulic fluid control valve 14 is facilitated by a through-aperture 77 of the coupling 80 that fluidly connects the first fluid cavity 76 of the inner camshaft 44 to the second fluid cavity of the center hub 60. To prevent leakage of the hydraulic fluid F from the through-aperture 77, a first compliant radial seal 67A is arranged to seal the coupling 80 to the coupling end 62 of the center hub 60, and a second compliant radial seal 67B is arranged to seal the coupling 80 to the inner camshaft 44.
The first compliant radial seal 67A is arranged within a first groove 66A formed on a nose 65 of the center hub 60, and the second compliant radial seal 67B is arranged within a second groove 66B formed on the drive end 43 of the inner camshaft 44. Both the first and second compliant radial seals 67A, 67B seal against a sealing surface 78 of the through-aperture 77 of the coupling 80. A first diameter D1 of the through-aperture 77 is larger than a second diameter D2 of the nose 65 of the center hub to accommodate radial offset and/or axial offset between the center hub 60 and the coupling 80. Likewise, the first diameter D1 of the through-aperture 77 is also larger than a third diameter D3 of a drive end 43 of the inner camshaft 44 to accommodate radial offset and/or axial offset between the coupling 80 and the inner camshaft 44.
The first compliant radial seal 67A is configured to maintain engagement with both the center hub 60 and the coupling 80 while the coupling 80 accommodates radial offset and/or axial offset of the coupling 80 relative to the center hub 60; stated otherwise, the first compliant radial seal 67A is configured to maintain engagement with both the center hub 60 and the coupling 80 while the coupling 80 accommodates radial offset and/or axial offset of the first rotor 24 of the first camshaft phaser 20 relative to the inner camshaft 44 of the concentric camshaft assembly 40. Furthermore, since the second rotor 34 of the second camshaft phaser 30 is non-rotatably connected to the concentric camshaft assembly 40, it could also be stated that the first compliant radial seal 67A is configured to maintain engagement with both the center hub 60 and the coupling 80 while the coupling 80 accommodates radial offset and/or axial offset between the first camshaft phaser 20 and the second camshaft phaser 30.
The second compliant radial seal 67B is configured to maintain engagement with both the inner camshaft 44 and the coupling 80 while the coupling 80 accommodates radial offset and/or axial offset of the coupling 80 relative to the inner camshaft 44; stated otherwise, the second compliant radial seal 67B is configured to maintain engagement with both the inner camshaft 44 and the coupling 80 while the coupling accommodates radial offset and/or axial offset of the first rotor 24 of the first camshaft phaser 20 relative to the inner camshaft 44 of the concentric camshaft assembly 40. Furthermore, since the second rotor 34 of the second camshaft phaser 30 is non-rotatably connected to the concentric camshaft assembly 40, it could also be stated that the second compliant radial seal 67B is configured to maintain engagement with both the inner camshaft 44 and the coupling 80 while the coupling 80 accommodates radial offset and/or axial offset between the first camshaft phaser 20 and the second camshaft phaser 30.
Discussion of the non-rotatable connections between components of the camshaft phaser arrangement 10 and the concentric camshaft assembly 40 can provide insight into the challenges of assembling these components within an internal combustion engine. Manufacturing tolerances of the individual components of the camshaft phaser arrangement 10 and concentric camshaft assembly 40 together with manufacturing tolerances of an engine cylinder head that receives the concentric camshaft assembly 40 can necessitate a compliant non-rotatable connection such as that provided by the previously described coupling 80. The second rotor 34 of the second camshaft phaser 30 is axially clamped and non-rotatably connected to the outer camshaft 42 by the cam bolt 70; the second stator 35 that circumferentially surrounds the second rotor 34 is rigidly and non-rotatably connected to the first stator 25 via the first fasteners 19. Thus, the first and second stators 25, 35 move axially and radially together as one unit, separately and relative to the second rotor 34 that is rigidly connected to the outer camshaft 42. Given that the first rotor 24 is non-rotatably connected with the inner camshaft 44, and the significant tolerance stack-up of the many components that reside between the first rotor 24 and the inner camshaft 44, the coupling 80 and its provided axial and radial compliant non-rotatable connections with the second camshaft phaser 30 and the inner camshaft 44, offers a viable solution. In addition to providing a manufacturing solution, the coupling 80 also offers a functional solution during use of the IC engine. For example, dynamic axial and radial valve train forces that act on the inner camshaft 44 are likely different than dynamic axial and radial valve train forces that act on the outer camshaft 42, which can translate to unequal axial and radial movements of the inner camshaft 44 relative to the outer camshaft 42. In addition, a power transmission force that is applied to the drive wheel 45 of the second camshaft phaser 30, is likely to further influence the relative movement of components of the system. For these conditions, the coupling 80 provides an axially and radially compliant non-rotatable connection between the inner camshaft 44 and the first rotor 24, while permitting a non-compliant non-rotatable connection between the second rotor 34 and outer camshaft 42.
The camshaft phaser arrangement 10 for the concentric camshaft assembly 40 provides independent phasing of the inner camshaft 44 relative to the outer camshaft 42. The camshaft phaser arrangement 10 can be controlled by the electronic controller 18; the electronic controller 18 can possibly be an electronic control unit (ECU) that controls an IC engine. The concentric camshaft assembly 40 includes intake lobes 74 and exhaust lobes 75, each of which can be arranged on either the inner camshaft 44 or the outer camshaft 42. In some engine design instances, it may prove advantageous to have the outer camshaft 42 configured with the exhaust lobes 75 and the inner camshaft 44 to be configured with the intake lobes 74, however, this arrangement could also be reversed.
The first camshaft phaser 20 and second camshaft phaser 30 can be actuated hydraulically with hydraulic fluid such as engine oil, electrically with an electric motor, or by any other actuation means. The camshaft phaser arrangement 10 in
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms encompassed by the claims. The words used in the specification are words of description rather than limitation, and it is understood that various changes can be made without departing from the spirit and scope of the disclosure. As previously described, the features of various embodiments can be combined to form further embodiments that may not be explicitly described or illustrated. While various embodiments could have been described as providing advantages or being preferred over other embodiments or prior art implementations with respect to one or more desired characteristics, those of ordinary skill in the art recognize that one or more features or characteristics can be compromised to achieve desired overall system attributes, which depend on the specific application and implementation. These attributes can include, but are not limited to cost, strength, durability, life cycle cost, marketability, appearance, packaging, size, serviceability, weight, manufacturability, ease of assembly, etc. As such, to the extent any embodiments are described as less desirable than other embodiments or prior art implementations with respect to one or more characteristics, these embodiments are not outside the scope of the disclosure and can be desirable for particular applications.
This application claims the benefit of U.S. Provisional Patent Application No. 62/676,709 filed May 25, 2018, the disclosure of which is incorporated in its entirety by reference herein.
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