The present application claims priority under 35 U.S.C. §119 to German Patent Application No. 10 2011 103 495.5 (filed on Jun. 3, 2011), which is hereby incorporated by reference in its respective entirety.
The present invention relates to a clutch shaft for a camshaft controller, an actuator for controlling a camshaft adjustment transmission, a camshaft adjustment transmission which is also referred to hereinbelow as an “adjustment transmission,” and a camshaft adjustment device for an internal combustion engine.
German Patent Publications DE 10 2004 041 751 A1, DE 10 2007 049 072 A1 and DE 102 48 351 A1 disclose various clutches for equalizing an eccentricity (axial offset) between an axis of an actuating shaft of an actuator and an axis of an adjustment transmission. These clutches exert, in the case of corresponding radial axial offset of the corresponding shafts, forces of inertia on these shafts and their bearings. In the case of Oldham clutches, the large axial installation space requirement is also disadvantageous.
An object of the present invention is to provide a dutch shaft for a camshaft controller with which forces of inertia on these shafts and their bearings can be reduced. It is furthermore an object of the invention to provide an actuator, a camshaft adjustment transmission and a camshaft adjustment device structured to facilitate this advantage.
This object is achieved with a clutch shaft which includes at least one of the following:
This object is achieved with a clutch shaft which includes at least one of the following:
This object is achieve with a clutch shaft which includes at least one of the following:
In accordance with the invention, the clutch shaft for a camshaft controller is developed further in that the clutch shaft has at each of its two ends, in each case a clutch component, for in each case a rotating joint which equalizes the angle between the axes. Due to the fact that the clutch shaft in accordance with the invention has a clutch component at each of its two ends, it is possible to equalize an axial offset without a bringing about or enlargement of an axial angle between the actuator and the adjustment transmission having to be accepted as a result of this measure.
By dividing the axial offset adjustment between two clutches, the designer is given a greater degree of freedom which to exploit a reduction in the axial angle for the introduction of force into the actuator or into the adjustment transmission. By reducing the axial angle for the introduction of force into the actuator or into the adjustment transmission, a rotational symmetry of the force transmission is improved and a magnitude of the disadvantageous forces of inertia is reduced. The clutch shaft can, but need not be, in one-piece.
A (total) axial length of the clutch shaft can be greater than w % of a maximum diameter of the larger clutch component, wherein w % is at least 130%, in particular at least 150%. The clutch shaft can be tapered between its two ends across more than w % of its (total) axial length, wherein w % is at least 30%, in particular at least 60%. The clutch shaft can comprise on at least one of its two face sides a cylinder-symmetrical, convex formation which is arranged concentrically with respect to the main longitudinal axis of the clutch shaft. The clutch shaft can comprise a flange for a bearing.
The first rotating joint which equalizes the angle between the axes can comprise a fastening bolt or a component of a denture clutch, a claw clutch, a plug clutch, a driver clutch, a radial gearwheel clutch, a disc gearwheel clutch, a flexible disc, a bellows clutch, an elastomer clutch, a helix clutch, a spring clutch, a spring disc clutch, a fixed link clutch, a balancing clutch, a cardan transmission or a homokinetic joint. Independently of this, the second rotating joint which equalizes the angle between the axes can comprise a fastening bolt or a component of a denture clutch, a claw clutch, a plug clutch, a driver clutch, a radial gearwheel clutch, a disc gearwheel clutch, a flexible disc, a bellows clutch, an elastomer clutch, a helix clutch, a spring clutch, a spring disc clutch, a fixed link clutch, a balancing clutch, a cardan transmission or a homokinetic joint. The denture clutch component can comprise an arcuate denture clutch. The denture clutch component can have a spherical or spherical portion-shaped basic shape on which the teeth of the denture clutch component are arranged.
In accordance with the invention, the actuator is developed further in that a clutch shaft for controlling the camshaft adjustment transmission is coupled to the actuator by way of a first rotating joint which equalizes the angle between the axes in a region of the actuator which faces away from the adjustment transmission. As a result of this, in the case of an unchanged distance between actuator and camshaft adjustment transmission, the distance between the location of the connection, which can be angled, to the rotor and the camshaft adjustment transmission can be increased, as a result of which a reduction in the axial angle for the introduction of force into the adjustment transmission is achieved, a rotational symmetry of the transmission of force is improved and a magnitude of the disadvantageous forces of inertia is reduced.
The clutch shaft can extend across more than 50% of a (total) axial length of a rotor of the actuator. The clutch shaft can be arranged rotatably in the pitch direction in the actuator on each circumferential angle, wherein a pitch angle of the clutch shaft with respect to an axis of the actuator can be up to at least 1°, in particular up to at least 2°, particularly preferably up to at least 3°. The clutch shaft can be arranged axially displaceably in the rotor.
The actuator can comprise an axial bearing component for pretensioning the clutch shaft in the direction of the main longitudinal axis of the clutch shaft. The actuator can comprise a clutch shaft in accordance with the invention.
The first rotating joint which equalizes the angle between the axes can comprise, for coupling to the rotor, a fastening bolt or a component of a denture clutch, a claw clutch, a plug clutch, a driver clutch, a radial gearwheel clutch, a disc gearwheel clutch, a flexible disc, a bellows clutch, an elastomer clutch, a helix clutch, a spring clutch, a spring disc clutch, a fixed link clutch, a balancing clutch, a cardan transmission or a homokinetic joint.
In accordance with the invention, the camshaft adjustment transmission is further developed in that an inner or outer toothing of a transmission drive gearwheel of the camshaft adjustment transmission is formed or is suitable for the engagement of the denture clutch component of a clutch shaft or that the camshaft adjustment transmission comprises a clutch shaft.
The denture clutch component of the clutch shaft can form a floating transmission drive gearwheel of the camshaft adjustment transmission.
In accordance with the invention, the camshaft adjustment device is developed further in that it comprises an actuator and/or a cam adjustment transmission.
The invention is described below by means of exemplary embodiments illustrated in the drawings in which show:
The same reference numbers are used in each case for corresponding components in the figures. Explanations relating to reference numbers therefore apply across the figures unless otherwise apparent from the context.
Camshaft controller 10 shown in
At an end 30 of the clutch shaft 26 on the servomotor side, clutch shaft 26 is articulated at rotor 14 by way of a fastening bolt 34 for a transmission of torque to adjustment transmission 32. Clutch shaft 26 has at its end 30 on the servomotor side a passage 25 for a fastening bolt 34. Fastening bolt 34 is mounted in opposing holes 36 in the wall of hollow shaft 18. In the region of passage 25 for fastening bolt 34, clutch shaft 26 can have a spindle-shaped or spherical thickening 38, the outer diameter of which is only slightly smaller than inner diameter 40 of hollow shaft 18. As a result of this, it is achieved that clutch shaft 26 (independently of its gyrating motion) is fastened in hollow shaft 18 such that, at the location of fastening bolt 34, a main longitudinal axis 27 of clutch shaft 26 has a common point of intersection 42 with the main longitudinal axis 19 of hollow shaft 18.
Fastening bolt 34 is rotatably mounted in hollow shaft 18 about its main longitudinal axis 35. As illustrated in
As illustrated in
Dashed lines indicate ridges of the interengaging teeth of bevel gears 60, 72.
As illustrated in
As illustrated in
As already explained in relation to
In accordance with embodiments of the present invention, a clutch shaft 26, an actuator 12, a camshaft adjustment transmission 32 and a camshaft controller 10 are provided, with which radial forces between the clutch and the transmission input shaft can be reduced or prevented. This applies in particular in combination with a floatingly mounted transmission input shaft (transmission drive gearwheel 72). Independently of this, the space-saving design enables a reduction in the axial installation space requirement for camshaft controller 10. Installation space which can be saved for the clutch by servomotor 12 with adjustment transmission 32 enables the use of a lower cost adjustment transmission 32 or a lower cost servomotor 12.
Although embodiments have been described herein, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.
Number | Date | Country | Kind |
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10 2011 103 495.5 | Jun 2011 | DE | national |