The invention relates to a device for adjusting camber and/or toe of a vehicle wheel of a motor vehicle according to the preamble of patent claim 1.
In a generic motor vehicle with a wheel suspension, the rotary parts of an actuating member are determinative for the camber and/or toe of the vehicle wheel and adjusted via actuators (for example a spur gear mechanism) and electric motors in both rotation directions in opposite directions or in same direction. However, it must be ensured that reaction torques from the dynamic or static wheel loads do not cause unwanted adjustment. Such reaction torques are transmitted by the rotary parts of the actuating element via a gear stage to a drive motor. This means that the drive motor is required to continuously provide a counter torque (during operation partly with changing directions) in order to maintain the set target position of the two rotary parts. If the set target position of the rotary parts should be maintained also when the vehicle is parked, even in this case there would be a need to apply the counter torque, i.e. the drive motor has to be acted upon by a holding energy.
DE 10 2009 031 344 A1 discloses a generic device having a wrap spring brake interposed in driving relationship between the drive motor and the actuating element for camber and/or toe adjustment. Using the wrap spring brake, a torque transmission can be enabled from the drive motor to the actuating element. Conversely, the wrap spring brake blocks a transmission of reaction torques in the opposite direction without external energy.
The structure of the wrap spring brake and the resultant problem will now be described: The wrap spring brake includes on the input side and output side an opening part and a closing part, respectively, which formfittingly engage in both rotation directions with one another in the presence of a circumferential clearance. Moreover, a wrap spring is provided having spring legs, respectively projecting between the opening part and the closing part. The wrap spring brake is configured so as to assume its locking position only after building up a reaction torque that acts from the actuating element in direction of the drive motor, in which locking position a further transfer of the reaction torque is blocked. Such a transition to the locking position is implemented as a result of an expansion of the wrap spring when acted upon by the reaction torque. This generates a friction fit with an outer sleeve, sufficient to prevent a torque transmission to the electric motor. In the DE 10 2009 031 344 A1, the transition of the wrap spring to its locking position is realized only after buildup of the reaction torque so that there is a risk that the reaction torque acts upon the drive motor before reaching the locking position, possibly causing the actuating element to move from its target position.
Object of the invention is to provide a device for camber and/or toe adjustment, which is able to maintain the set target position of the actuating element in a reliable and simple manner, even when the vehicle is parked.
The invention is based on the recognition that in the prior art the transition of the wrap spring brake to its locking position is implemented only during buildup of a reaction torque. This means that the locking element has not yet assumed its locking position during buildup of the reaction torque, so that a reaction torque can be transmitted, at least in part, onto the drive motor. Against this background, the device according to the characterizing part of patent claim 1 does not have a wrap spring brake as locking element but a double-acting freewheel which opens in the presence of a driving torque of the rotary drive unit and closes in the presence of a reaction torque of the actuating element. Preferably, the freewheel can already in its rest position, i.e. before being acted upon by a reaction torque, lastingly assume its locking position in which a transmission of the reaction torque onto the rotary drive unit is prevented. Against this background, the freewheel has a clamp body unit which holds the freewheel with a predefined locking torque in its locking position, without being acted upon by an external torque, i.e. in the absence of both a reaction torque and a driving torque.
The freewheel can have on its output side a closing part and on its input side an opening part. The closing part and the opening part can engage in both rotation directions within one another in the presence of a circumferential clearance. Preferably, the clamp body unit is associated to the closing part. The clamp body unit may act upon the closing part with the locking torque already in the afore-described manufacturing state of the freewheel.
Only when a driving torque is built-up by the rotary drive unit and additionally exceeds also the opposing locking torque, is the freewheel, i.e. in particular its closing part, capable to move to the release position. Conversely, a self-amplifying effect is established in the freewheel, when the opposing reaction torque is being built-up, that increases the already existing locking torque by the reaction torque.
According to a constructively preferred embodiment, the clamp body unit can have at least one pair of clamp bodies, wherein the clamp bodies can be biased by a spring element on the closing part in circumferential direction in opposition to one another, thereby being urged into a clamping position by the locking torque. In this clamping position, each of the clamp bodies is securely clamped between a raceway, integrated in fixed rotative engagement in the freewheel housing, and a radially outwardly ascending clamping ramp of the closing part.
To unlock the closing part, the opening part can include at least one catch which can be moved via the circumferential clearance between two movement stops of the closing part. The catch of the opening part may additionally include at least one axial web. When impacting the movement stop of the closing part, this axial web is able to push the facing clamp body from its clamping position to its release position.
Once the catch of the opening part has impacted upon the movement stop of the closing part, the opening part jointly with the dynamically coupled closing part continues to rotate. As a result of this rotation movement, also the clamp body which is distal to the axial web of the catch slides from its clamping position to the release position.
When installed, the freewheel is connected in driving relationship on its input side, i.e. the opening part, with a shaft portion leading to the rotary drive unit. On its output side, i.e. the closing part, the freewheel is coupled in driving relationship with a shaft portion leading to the actuating element.
Preferably, the opening part can have several radial catches evenly spaced about the circumference and projecting in recesses of the closing part, respectively. As a result, the formfitting connection in circumferential direction of the opening part and the closing part is realized in a simple manner, wherein the circumferential clearance can be best suited to the driving conditions.
In addition, the clamp bodies can be pushed by elastically biased elements, preferably spring elements, up the clamping ramp (i.e. inclined plane) in order to lastingly apply the locking function. The thus realized friction fit between the clamp bodies, the raceway (or the freewheel housing) and the clamping ramps, causes a clamping and therefore a locking action. Using suitable material and surface pairings of the involved elements, the degree of reaction of the locking action can be advantageously influenced. The clamp bodies have preferably a cylindrical configuration, although any other geometry may also be possible, as known from commercially available freewheels. Moreover, the spring elements may be made of metal, plastic, or elastomers. The spring elements are preferably supported on the output-side closing part, preferably, however, not in opposition to one another.
Finally, to provide a pre-fabricated unit, which is beneficial in terms of manufacture and simple, the shaft portion in driving relationship with the opening part and the shaft portion in driving relationship with the closing part can be arranged within the freewheel housing. The freewheel housing can be connected with the housing of the electric motor.
The advantageous configurations and/or refinements of the invention, as described above and/or set forth in the sub-claims, can—except for example in the cases of unambiguous dependencies or irreconcilable alternatives—find application individually or also in any combination with one another.
The invention and its advantageous configurations and/or refinements as well as its advantages will now be described in greater detail with reference to the drawings.
It is shown in:
The wheel carrier 12 rotatably receiving the wheel 20 is subdivided in a guide part 12 articulated to the transverse control arms 14, 16, a carrier part 24 receiving the wheel 20 via a respective wheel bearing (not shown), and in two rotary parts 26, 28 rotatably mounted on the guide part 22 and on the carrier part 24 and adjustable about a rotation axis 32 which extends perpendicular to confronting slanting surfaces 30. A rotation of one or both rotary parts 26, 28 causes the carrier part 24 to tilt in relation to the wheel rotation axis 34 and thus an adjustment of the toe and/or camber of the wheel 20 of the wheel suspension 10. The wheel load is supported in a manner known per se via a support spring or the suspension strut 36 in relation to the structure 18.
A freewheel 52 acting as locking element is disposed between each of the electric motors 38 and their driving gears 42 (
Individual parts of the freewheel 52 are shown with reference to
The output-side shaft portion 58a of the driveshaft 58 extends through the housing 54 and supports the driving gear 42 of the spur gear mechanism 40, on one hand. On the other hand, the shaft portion 58a is in, not shown, force-transmitting plug connection with a spline 58c of the closing part 63. The input-side shaft portion 58b corresponds to the motor shaft of the not shown electric motor and is also in a plug connection with a spline 58d of the opening part 62. The housing 54 is bolted to the housing of the electric motor 38 via the adapter plate 56. The shaft portion 58a of the driveshaft 58 is rotatably supported in the housing 54 by a double-row roller bearing 66.
As is apparent from
In a rest position (
When powering the electric motors 38 for an adjustment of the rotary parts 26, 28, the electric motor drives the double-acting freewheel 52 in the one or the other rotation direction via the input-side shaft portion 58b. As a result, the electric motor 38 introduces a driving torque MA (
The introduced driving torque MA releases the clamp bodies 64 only when exceeding an opposing reaction torque MR or when their rotation directions are the same. In this case, the axial webs 62b of the opening part 62 are able to push the clamp bodies 64, confronting each other in the rotation direction, down the clamping ramp (inclined plane) 63b, i.e. release them. When the opening part 62 now continues to rotate, the catches 63a thereof impact against the corresponding movement stops 63b of the recesses 63a of the closing part 63 and continue to move them in the rotation direction. As a result, also the clamp bodies 64, facing away from the axial web 62b, become detached and block the other rotation direction. The driving torque is thus transmitted to the output side, i.e. the shaft portion 58a. When reversing the rotation direction, the afore-described process is carried out accordingly vice versa.
When the electric motor 38 is not activated and does not transmit a driving torque MA, potentially occurring reaction torques MR from the wheel load, which have an effect via the rotary parts 26, 28 and the spur gear mechanism 40 upon the driveshaft 58, are supported according to
The reaction torque MR acts hereby via the driving gear 42, the shaft portion 58a, and the closing part 63 upon the clamp bodies 64 which are held by the spring elements 65 in the locking position at the upper end of the clamping ramps (inclined planes) 63b. In view of the absence of a release by the axial webs 61a, the introduced reaction torque MR amplifies the locking action, and the double-acting freewheel remains in the locking position II (
To increase the transmittable locking torque of the double-acting freewheel 52, as many clamp bodies 64 as possible are dispersed in pairs about the circumference. Materials, surface finish, and pairs of friction values of the clamp bodies 64, the closing part 63 and the opening part 62 are configured depending on calculated stress of the freewheel 52.
Number | Date | Country | Kind |
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10 2013 008 652.3 | May 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/001098 | 4/24/2014 | WO | 00 |