DE202006013423U1 - Adjustment grapple with spindle and spindle bearing - Google Patents

Abstract

variator (1), in particular for one Vehicle seat, with a static bearing spindle on both ends (2) and one along the spindle (2) in a direction of displacement (4) movable gear unit (3), characterized in that as units for static support of the spindle (2) a fixed bearing (5) and a floating bearing (6) are provided, wherein the floating bearing (6) with a bearing element (9) is provided, which acts as a damping element for the Spindle movement is configured.

Description

The The invention relates to an adjusting mechanism, in particular for a Vehicle seat, with a static bearing spindle on both ends and a movable along the spindle in a direction of displacement Transmission unit.

Such adjusting is from the DE 103 53 245 A1 known. The adjusting mechanism described therein comprises a spindle which is fixedly mounted at both ends in each case an angle holding element, and a gear unit movable along the spindle, in which a drive system is integrated. When the drive system is activated, the gear unit moves on the stationary spindle along the direction of displacement. While the angle support members are mounted on the base side, the transmission unit is connected upwardly with a rail which determines the position of a vehicle seat mounted thereon.

The The problem of such a storage method lies in the overdetermination the spindle fixation, as the spindle through the angle holding elements firmly clamped at the end. This makes them sensitive to system tolerances in particular, the thermally induced expansion of the spindle be derived only conditionally by the angle holding elements. The latter This is especially true when the components of the system are different Materials with different thermal reaction behavior consist. Disadvantageously lead the insufficiently derived tension forces to a lateral bending the spindle, the so-called bulging, as well as premature fatigue. On the one hand is the Abfahrverhalten the gear unit along the spindle affected by bulging, On the other hand, the sound development and sound dissipation through Material tensions adversely changed.

task The invention is an adjustment of the aforementioned Specify type in which the overdetermination the spindle bearing at fulfillment safety relevant stability criteria of Storage possible is avoided.

The Task is for an adjusting according to the preamble of claim 1 according to the invention thereby solved, that the bearing element is designed such that as Units for static storage of the spindle a fixed bearing and a Floating bearings are provided, wherein the floating bearing with a bearing element is provided as a damping element for the Spindle movement is configured. In other words, an adjusting gear specified, wherein for the storage of the spindle, a fixed bearing floating bearing principle by means of a damping bearing implemented.

The Spindle could for the purpose of dissolution over-determination in the area of a bearing angle with this no longer be connected, what could be achieved by that, for example, the hole size in the bearing angle sufficiently large compared to the Spindle diameter selected would. Although would reduces spindle sensitivity to system tolerances in particular the bulging of the spindle would be avoided, but at a cost both the static stability as well as the dynamic guiding stability of the variable speed gearbox, because the spindle end in the floating bearing would be free to move within limits. The fulfillment predefined safety-related stability criteria would be difficult, the especially with regard to crash situations are of importance, where large for a short time Inertial forces act can.

to solution the problem of over-determination without a static and dynamic loss of stability of the variable transmission the invention provides a storage element for static storage of Spindle, which is designed so that it also as a damping element for the spindle movement acts. This is a fixed-bearing floating principle implemented by the strain-induced spindle movement, in particular in the axial direction is allowed. At the same time, the spindle movement becomes particular in all directions orthogonal to the axial direction by damping so limited, that the guiding stability of the variable transmission preserved. In addition, over the Storage element static forces be derived well.

For the invention it does not matter which specific shape the spindle has. In particular, this relates to the cross section of the spindle.

Further advantageous embodiments of the invention are concerned with the geometric shape of the bearing element such that the mechanical Interaction between this and the spindle is optimized. there is for the storage element first Determining how the contact with the spindle is mechanically converted.

preferably, is the storage element for forming a contact bearing a suitably elastic material, in particular of an elastomeric Plastic, preferably a thermoplastic or a thermoset made.

In an advantageous embodiment, the bearing element is realized as a spindle encompassing the hollow cylinder which is inserted into a hole of a holder of the floating bearing. This embodiment of the bearing element is hereinafter referred to as Designated cylinder geometry. The force transmitted in the axial direction by the spindle is absorbed by a shearing of the hollow cylinder, that is, a radially dependent deformation of the hollow cylinder in the longitudinal direction. The forces in all directions orthogonal to the axial direction, ie in the radial direction of the hollow cylinder, are absorbed by a compression of the hollow cylinder. Recorded in this context means that the mechanical deformation of the bearing element partially compensate for the forces acting and partially transferred to the floating bearing. The contact surface of the bearing element to the spindle corresponds substantially constant to the inner surface of the hollow cylinder.

In another advantageous embodiment than the latter is the bearing element as a spindle enclosing conical tapered hollow capsule realized in a correspondingly conical tapered Hole is inserted in a holder of the floating bearing. This embodiment of the bearing element is referred to below as spring geometry. In the relaxed state, the contact between the spindle and the hollow capsule end in the region of the smallest inner diameter the hollow capsule instead. With axial force acting in the direction, in which the hollow capsule tapers, becomes increased by deformation of the hollow capsule, the contact surface and a suitable balancing Restoring force generated. As compared to force effects in other directions, the contact surface to the length the hollow capsule remains small, the spring geometry is suitable for systems where the force is substantially axial in one direction takes place. The hollow capsule can be made of solid material suitable elasticity be formed, as well as between axial webs lying intermediate spaces.

Conveniently, the spindle is at both ends of the bearing element in the direction of displacement by Spindelverbreiternde means, in particular by on the spindle mounted nuts or sleeves, provided that complete the storage element at both ends. These Spindelverbreiternden means serve on the one hand to the axial power transmission the storage element, for what they are optimized accordingly, and on the other hand, a loss of security. Also can the spindle widening means for biasing the bearing element be used, whereby an adaptation of the damping properties is possible. At high axial force effects stabilize the spindle widening agents the system, if necessary, by a possible direct reciprocal power transmission from the holder of the floating bearing on the spindle. preferably, there is essentially no direct contact between the spindle widening Means and the holder of the floating bearing.

In a suitable design the cylinder geometry or the spring geometry is the length of the bearing element greater than the thickness of the holder of the floating bearing, so that the bearing element in Pasted Condition on both sides over the holder of the floating bearing protrudes. Thus, by the above-described spindle widening means the bearing element biased and the axial force better transmitted from the spindle to the bearing element, namely avoiding direct contact between the funds and the holder of the floating bearing. In the case of high forces, such as at abrupt Brakes are released, a direct interaction occurs the means and the holder of the floating bearing only after a tolerance-defining Settling path, by the supernatant of the storage element is given. Slipping out of the storage element from the holder of the floating bearing is also difficult.

Furthermore is expediently realized the storage element as a separate component and is as Such a component can be inserted into the overall system. This is high quantity economically producible.

In A preferred embodiment of the variable transmission is a holder at least one spindle bearing, the fixed bearing or the floating bearing, realized in the form of a bracket.

One embodiment The invention is explained below with reference to a drawing. there each show in a schematic representation

1 an adjusting mechanism in its entirety,

2 Partial view of the variable transmission according to 1 with a floating bearing and a bearing element in cylinder geometry,

3 Partial view of another variable transmission with a movable bearing and a bearing element in spring geometry.

In 1 is an exemplary embodiment, an adjustment 1 shown in entirety. On the thread of the spindle 2 can be an autonomously driven gear unit 3 in the direction of displacement 4 move. On this gear unit 3 For example, a seat bottom rail fixedly mounted with a vehicle seat is fixed, so that the vehicle seat by driving the gear unit 3 can be moved along the spindle. The spindle 2 is static in a fixed camp 5 and in a floating warehouse 6 held, their brackets in the form of a respective bracket 7 . 8th respectively, are realized. In a hole of the bracket 8th of the floating bearing 6 is for static spindle bearing and spindle damping the storage element 9 inserted from an elastic plastic. The storage element 9 is on both sides of the bracket 8th over, and is there screwed on the spindle thread sleeves 10 . 11 made of metal. These serve to stabilize the entire system, in particular in the case of crash loads, and to safeguard against loss of the bearing element 9 ,

In 2 is a partial view of the variable speed according to 1 shown the side of the floating bearing 6 shows. The holder of the floating bearing 6 is through the bracket 8th given. The spindle 2 becomes through the storage element 9 in a hole of the bracket 8th statically stored. Well visible here is the supernatant of the storage element 9 over the bracket 8th , The on the thread of the spindle 2 screwed on spindle widening nuts or sleeves 10 respectively. 11 close the storage element 9 each at the end pages and clamp it. The storage element 9 is given in cylinder geometry and consists of a suitably elastic plastic, preferably of a thermosetting or thermosetting elastomer. The storage element 9 dampens due to its elasticity movements of the spindle 2 especially in the direction of the arrow 12 ie orthogonal to the axial direction. In a crash load, the spindle widening nuts or sleeves 10 respectively. 11 the storage element 9 to move the supernatant and directly to the bracket 8th Interact. In the axial direction, ie in the direction of the arrow 13 becomes an extension of the spindle 2 by a shear of the storage element 9 allows.

In 3 is a partial view of another variable transmission shown, the side of the floating bearing 5 shows. The holder of the floating bearing 6 is through the bracket 8th given. The spindle 2 becomes through the storage element 9 in a hole of the bracket 8th statically stored. Well visible here is again the supernatant of the storage element 9 over the bracket 8th , One spindle widening nut or sleeve 10 . 11 close the storage element 9 each at the end pages and clamp it. The storage element 9 is now in a spring geometry, present as a hollow capsule with a in the axial direction (arrow 13 ) tapered cross-section, configured and in turn consists of a suitably elastic plastic, preferably of a thermoplastic or a thermosetting plastic. The storage element 9 dampens movements of the spindle 2 by the given contact surface in particular orthogonal to the axial direction (arrow 12 ). In a power surge in the direction of taper of the designed in spring geometry bearing element 6 this is additionally deformed while an increased restoring force on the spindle 2 generated. In a crash load, the spindle widening nuts or sleeves 10 respectively. 11 the storage element 9 to move the supernatant and directly to the bracket 8th Interact.

1

variator

2

spindle

3

gear unit

4

shift direction

5

fixed bearing

6

movable bearing

7

bracket of the fixed camp

8th

bracket of the floating bearing

9

storage element

10

mother or sleeve

11

mother or sleeve

12

orthogonal movement direction

13

axial movement direction

Claims (7)

Adjusting gear ( 1 ), in particular for a vehicle seat, with a spindle mounted statically on both sides ( 2 ) and one along the spindle ( 2 ) in a direction of displacement ( 4 ) movable gear unit ( 3 ), characterized in that as units for static mounting of the spindle ( 2 ) a fixed warehouse ( 5 ) and a floating bearing ( 6 ) are provided, wherein the movable bearing ( 6 ) with a bearing element ( 9 ), which is designed as a damping element for the spindle movement. Adjusting gear according to claim 1, characterized in that the bearing element ( 9 ) to form a contact bearing made of an elastic material. Adjusting gear according to claim 1 or 2, characterized in that the bearing element ( 9 ) formed as a substantially cylindrical hollow capsule in a hole of a holder of the floating bearing ( 6 ) is introduced, whose contact surface to the spindle ( 2 ) substantially corresponds to the inner surface of the hollow capsule. Adjusting gear according to claim 2, characterized in that the bearing element ( 9 ) formed as a substantially conical hollow capsule in a hole of a holder of the floating bearing ( 6 ) is introduced such that the contact surface of the hollow capsule to the spindle ( 2 ) is determined variably by elastic deformation. Adjusting gear according to claim 3 or 4, characterized in that the bearing element ( 9 ) at both ends in the direction of displacement by spindle-broadening means, in particular by on the spindle ( 2 ) mounted nuts or sleeves ( 10 . 11 ), is completed. Adjusting gear according to one of claims 1 to 5, characterized in that the bearing element ( 9 ) releasably in the holder of the floating bearing ( 6 ) is introduced. Adjusting mechanism according to one of claims 3 to 6, characterized in that one or each holder of the units for static spindle bearing ( 5 . 6 ) in the form of a bracket ( 7 . 8th ) is trained.