Patent Application
20150377085
The present invention relates to a vane-type hydraulic camshaft adjusting device, including a stator and a rotor which is concentrically and rotatably situated therein, a locking device being situated axially between the rotor and the stator for the purpose of preventing a rotation between the rotor and the stator or a stator-fixed component, so that a locking element of the locking device produces a form-locked fit which blocks the rotation of the rotor relative to the stator. Vane-type hydraulic camshaft adjusting devices including locking devices which use bolt-like or pin-like locking elements are sufficiently well known.
The rotor is normally secured against a relative rotation with respect to the stator, either in a position in which one vane of the rotor is in contact with the stator or is secured in a center-locking position, i.e., in a position in which the vane is situated between its extreme positions.
Due to their special functionality, locking bolts or locking pins unfortunately have very large dimensions in the axial direction and take up a relatively large amount of the axial installation space of the entire camshaft adjuster. However, this installation space is limited. And yet the bolts require a minimum amount of locking depth to establish a secure lock. The axial length of the camshaft adjuster/camshaft adjusting device is also not conducive thereto. Under load, the system also experiences high forces, which necessitates complex counter-measures. Moreover, the manufacture of the individual parts is unfortunately relatively expensive.
It is an object of the present invention to implement a lock which is cost-optimized in its manufacture, preferably requires few components and yet is able to transmit high forces. A reduction of the axial installation space of the camshaft adjuster/camshaft adjusting device is also to be facilitated. In particular, it should be possible to achieve a center-locking mechanism, which preferably makes do without rotor limit stops.
The present invention provides that in a generic hydraulic camshaft adjuster or a generic hydraulic camshaft adjusting device, wherein the locking element is designed in the manner of a plate.
The rotor is locked against rotation relative to the stator, as needed, using the plate-shaped/plate-like locking element. If multiple locking elements are used together in a logical interconnection, the rotor may, as needed, be locked against rotation centrally relative to the stator. A particularly space-saving design of the locking element is implemented.
It is thus advantageous if the locking element designed as a plate has two sides/side surfaces (which are essentially planar, preferably running parallel to each other), which are connected to each other via an outer contour, the outer contour of the locking element being provided with a concave, convex/crowned, smooth or fluted design, for example by designing the locking element as an ellipsoidal section or as a spherical section. If the locking element is designed as an ellipsoidal section or as a spherical section, a spherical section, in particular, is selected, with the aid of which a uniform, low-friction and fault-free swing-out of the locking element is achieved from a bracket in which it is accommodated. The formation of a seal is also made easier thereby. For example, the outer contour of the spherical section of the locking element has a crowned/convex design. The convex outer contour is characterized as a rounded shape in two dimensions positioned vertically to each other.
In the event that no locking is desired to facilitate a frictionless relative rotation between the stator and the rotor, it is advantageous to insert the locking element into a blind hole by interposing a spring element, the blind hole being provided on a front side of the rotor or on a front side of a stator-fixed component facing the rotor, such as a cover fastened to the stator.
In particular, it is advantageous if the blind hole accommodating the spring element is introduced into the rotor or into a receiving bushing, which is separate from the rotor and is connected to the rotor in the operating state. Of these two variants, however, the insertion of the locking element into a blind hole introduced into the rotor is clearly advantageous, the blind hole being able to be designed as a bore. Of course, it is also possible to design the blind hole as a through-hole, also as a bore, although in this case attention must be paid to the oil lines inside the rotor to ensure that they are not damaged.
To enable the spring element to be securely accommodated, it is advantageous if the blind hole has a spring element receiving section, such as an indentation, in its base, in which the spring element is at least partially supported. The blind hole preferably has a cuboid indentation on its base, into which a spring element, which is designed separately from the rotor, is at least partially inserted. Of course, a cube-shaped indentation may also be selected, in principle, however, the rectangular shape of the base surface of the indentation being advantageous, since it is particularly easy to introduce and ensures a great deal of design flexibility.
One advantageous exemplary embodiment is also characterized in that the locking element engages with a recess on the stator-fixed component, such as the cover, in a rotation-inhibiting manner, or it engages with a recess on the front side of the rotor in a rotation-inhibiting manner. Once again, the first of the two variants is particularly advantageous. One refinement is also characterized in that the recess has a U-shaped or horseshoe-shaped outer contour (the legs being connected to each other), and/or a recess base extends to the surface of the stator-fixed component or the front side of the rotor in an inclined or angled manner. A good form-locked fit may be achieved, due to the inclination or the angle.
It is furthermore advantageous if at least two locking elements are present for the purpose of implementing a center-locking mechanism. The increased requirements of modern internal combustion engines may be met thereby.
If the locking elements and the particular spring element are each situated in a hole provided for both components in such a way that the particular spring element axially moves or pivots at least one part of the locking element assigned thereto in such a way that a rotation of the rotor may be prevented in any direction, it is possible to dispense with the stop of a vane against the stator.
It is also advantageous if a locking device is present on each front side of the rotor, and/or if two or more locking devices are present on the same side or opposite sides of the rotor. This results in a particularly efficient utilization of the axial installation space. Maintenance and assembly may also be further facilitated.
The costs may be reduced if the spring element is preferably designed as a bent sheet metal strip, a helical compression spring or a rubber, composition rubber or elastomer element.
The structural arrangement of a spherical section for preventing the rotation of the rotor relative to the stator is thus a novel method and results in an improved hydraulic camshaft adjusting device. The rotor of the camshaft adjuster is mounted in the stator and is axially closed by two disks or covers. An indentation, into which the spherical section-like locking element is placed, together with a spring element, is situated on the front side of the rotor itself. The indentation is dimensionally designed in such a way that, during the assembly of the disk/cover, the spherical section dips all the way into the indentation and is terminated flush against a planar surface or the rotor or the disk/cover. The spring element is thereby tensioned in this position.
A ramp-shaped indentation having a one-sided stop surface is situated at a defined position in the disk. If the rotor is now rotated relative to the stator and to the disks fastened thereto, the spherical section also moves relative to the disks and the stator. When the spherical section reaches the indentation, the spring element relaxes according to the ramp in the indentation. The spherical section thus engages with the indentation and thereby prevents the rotor from continuing to rotate. If the rotor is now moved counter to the preceding rotation direction, the spherical section follows the ramp and pretensions the spring element again. This unlocks the rotor again. The rotor may also be unlocked again hydraulically (with the aid of oil pressure/oil).
One or multiple limit stops for the rotor are integrated into the stator, which limit the ability of both components to rotate. If the rotor is now placed against a limit stop, the rotor may be completely locked in with the aid of the spherical section. A rotation is then no longer possible.
To be able to unlock the complete system again, oil pressure must be applied to the spherical section from the cover side to press the spherical section back into the indentation. The rotor is freed thereby and is able to rotate.
If a center-locking mechanism is implemented with the aid of two or more locking elements, a slight variation must be undertaken. Since the spherical section is normally able to block the rotation in only one direction, and operation must be possible in the center position without other limit stops, it is absolutely necessary to use at least two spherical sections simultaneously, situated in opposite directions. Since each spherical section may thus capture one rotation direction, this is an appropriate option.
Once both spherical sections are engaged, the rotor is trapped in both rotation directions and its position is fixed. To be able to unlock the complete system again, oil pressure must be applied to the spherical sections from the cover side on the one front side and/or the other front side to press the spherical sections back into the particular indentation. The rotor is freed thereby and is able to rotate.
The two spherical sections may be mounted either on the same vane on one side, on different vanes opposite the same vane or opposite each other. They may also be mounted on the same side of the bearing diameter of the rotor or opposite each other.
For the function, it is advantageous if the spherical sections are on the same semicircle, since different circumferential forces will otherwise take effect.
In principle, the locking element may be situated outside or inside the bearing diameter.
The present invention is also explained in greater detail with the aid of a drawing in which different exemplary embodiments are illustrated.
The figures are only of a schematic nature and are used only for the sake of understanding the present invention. Identical elements are provided with identical reference numerals.
Several components of a first specific embodiment of a hydraulic camshaft adjusting device 1 are illustrated in
With reference to
In the embodiment illustrated, recess 9 is furthermore directly introduced/incorporated, for example drilled into, rotor 3. Alternatively, recess 9 may, however, also be introduced into a receiving bushing which is designed separately from rotor 3, this receiving bushing, in turn, being captively inserted, e.g., in a form-locked manner, into a hole in rotor 3 during operation.
In the embodiment illustrated, a spring element receiving section for accommodating spring element 8 is also present in recess 9, which is designed, in particular, for absorbing the pretensioning forces applied by spring element 8. In the specific embodiment which is the subject matter of the present invention, the spring element accommodating section is designed as a cuboid indentation 10 projecting into the rotor interior. Alternatively, spring 8 may, however, also be integrally connected to the section of rotor 3/recess 9 which forms the blind hole. For example, spring 8 may be designed as a resilient sheet metal strip which protrudes from the base/bottom of the blind hole, one end of spring 8 then being integrally designed with the bottom/base of recess 9.
The spatial extension of stator 2 and rotor 3 is apparent in the overall view in
As is clear, in particular, in conjunction with
The cross-shaped arrangement of vanes 4 on the outside of rotor 3 is indicated in
A cover 13, which may be fastened to the stator, also has a recess 14, with which locking element 7, i.e., spherical section 11, is able to engage. Recess 14 is provided with a ramp-shaped base 15 of recess 14 of cover 13.
As is apparent in
A singular representation of locking element 7 is illustrated in
The unlocked state and the locked state of rotor 3 on cover 13 are illustrated in
Another specific embodiment is illustrated in
While the second specific embodiment is illustrated without a cover in
In the exemplary embodiment illustrated in
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2013 203 955.7 | Mar 2013 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/DE2014/200004 | 1/17/2014 | WO | 00 |
