DE4108955A1 - Manual or motorised adjuster for vehicle seat - has gear mechanism with hypocycloid element to limit movement - Google Patents

Abstract

An adjustment mechanism for the seat of a road vehicle has a drive spindle supported in bearing locations in a pair of plates. A hand wheel is mounted at the end of the spindle. A main gear wheel meshes with the drive gear of a second actuator spindle. Mounted eccentrically on the main spindle is a gear wheel that together with a ring gear forms a hypocycloid transmission. When rotated this locks the unit in position. The adjustment mechanism may be driven by an electric motor (125) via a worm drive (114, 124). ADVANTAGE - Limits force on mechanical parts.

Description

The invention relates to an adjusting device, ins special for adjusting vehicle seats, which in the preamble of the main claim specified Art.

Such an adjustment device is the DE-GM 79 13 046 be can already be seen as known, being the inclination setting development of a seat back of a vehicle seat opposite the seat pillow is suitable. For this, the drive shaft is in one Integrated hinge over which the seat fitting of the Swivel seat back attached to the seat cushion of the seat cushion beat is. The drive shaft to be driven via a handwheel transfers the rotary motion to the in-wheel via an eccentric a hypocycloid gearbox, which works simultaneously in two rotations wheels combs. The supporting wheel is immovable on Seat fitting attached, in which the drive shaft can also be rotated is stored. The other wheel is the seat with the fitting backrest connected and thus rotatable relative to the supporting wheel. This Rela connected with a swiveling movement of the seat back tiv rotation is via the meshing engagement of the Inrad be works because the wheels have different numbers of teeth. Thus, the hypocycloid gear serves only as Un Reduction gear, which rotates the drive shaft in converts a pivotal movement of the seat back, making it endless can circulate. A rotation limit for the gearbox is only indirectly over the limited  Swiveling of the seat back relative to the seat cushion, which in their end positions on connecting components. Through the up running process of the driven component is inevitable Tension of the rotary transmission train, through which the Rotary transmission train in addition to for the adjustment process necessary torque is mechanically high. These Additional load must be taken into account constructively and leads to a significant oversize of the transmission construction parts. Torsionally elastic and are particularly problematic transmission components with rotational play such as B. flexible wel len, timing belts or cardan shafts.

The invention has for its object a generic Adjustment device to further develop that Occurrence of an additional stop torque in the turning over transmission line between the drive shaft and the over this driven adjustment component can be reliably prevented can.

The achievement of this task results from the characteristic features of the main claim.

The adjustment device is both for a manual as well as a motorized rotary drive of the drive shaft ge is suitable, the possible number of revolutions of the drive shaft between the two end positions of the reduction ratio of the Hypocycloid gear is determined. Thus, the possible Number of revolutions by changing the number of teeth between Inrad and Umrad be structurally adapted to the application.

If the application has a very large number of revolutions Drive shaft required is also a multi-stage hypocyclo conceivable gearbox. To do this, the inner wheel of the first Ge in turn drive an in-wheel via an eccentric, that combed in another wheel. It is understood that in  in this case the circulation positions of the second stage in-wheel would be decisive for the adjustment path limitation.

Advantageous embodiments of the invention go from the ex claims.

A very simple and particularly reliable design the adjustment device is reached when the position tactile devices consist of purely mechanical slings that at the same time to determine the position of the end positions cause locking against further rotation of the Inrad. A particularly compact design is achieved if one the scanning means consists of a control pin or the like protrudes from a side surface of the inner wheel or the cover plate and in an opposite recess of the cover plate or of the wheel intervenes.

Especially in connection with an electromotive rotation Drive the drive shaft, it can be useful, precise To use switching devices as position sensing means, through which the electric motor in the end positions of the adjustment direction is switched off.

So the control pin could instead of rigid stops with two switches responsive to pressure, e.g. B. microswitches together men affect.

Another possibility is contactless switching facilities such as B. called light barriers, which Inrad could be designed as a shadow mask.

The one with a purely mechanical position sensing and rotation blocking required overload shutdown of the electric motor can be omitted here.

So that when you turn off the electric motor at the same time There is a lock on the inner wheel to prevent it from turning further,  however, the electromotive rotary transmission train must be switched on include mechanical transmission element with self-locking.

Such a transmission element can be, for example Screw-wheel gear or a worm gear with corre sponding accordingly small thread pitch of the screw spindle or Be worm gear.

The following are two exemplary embodiments of the invention hand explained in more detail in a drawing.

The illustration shows:

Fig. 1 shows a central section through a manual Ver adjustment device for a vehicle seat,

Fig. 2 is a view of the adjusting device according to FIG. 1, from the output side of

Fig. 3 shows a central section through an electric motor adjustment device for a vehicle seat and

Fig. 4, the adjustment device according to FIG. 3 in a view from the driven side.

The facilities described below are not in their Installation position but drawn in individual representation, as this is for the understanding of the invention is sufficient.

Furthermore, this is to underline that the in the Examples of vehicle seats designed by Einrich in no way be restricted to this area of application should. Rather, the facilities got there everywhere turn where the rotation of a reversible drive level shaft should be limited after several revolutions.  

Among other things, the rotation limit according to the Er also for steering spindles of vehicle steering systems, Reversible controllable geared motors, automatic use reversible geared motors or similar.

This is also in connection with adjustable vehicle seats Invention with all manually or motor-driven rotary Adjustment functions conceivable. Examples are the Seat back tilt adjustment, the lumbar support adjustment, the seat height and seat angle adjustment, as well as the head called column height adjustment.

The visible in FIG. 1 means 1 serves for seat height adjustment and depending on gleichzei term seat tilt adjustment. It consists of a pre-assembled unit, which is releasably connectable to an associated seat fitting of a vehicle seat in a manner not shown. Deviating from this, one of the support plates 2 or 3 can also be formed by an existing structural part. This unit comprises as a housing two mutually parallel support plates 2 and 3 , which are screwed together at a uniform distance at all four corners at a distance from each other. To this end, a spacer sleeve is in each corner region between the supporting plates 2 and 3 is axially supported with an internal thread, the plates coaxial with through-bores in the support is arranged. 2 and 3 Through these through holes mounting screws 5 are inserted, which are screwed into the inner thread of the spacer sleeve 4 . In the center, the two support plates 2 and 3 are each provided with a bearing bore 6 and 7 , in which a drive shaft 8 is rotatably supported. These two support plates 2 and 3 transversely enforcing drive shaft 8 stands out with a stub shaft from the support plate 2 , the peripheral surface is provided with a serration. A handwheel 9 is pushed onto the stub shaft, the sleeve-shaped shaft of which has serrations on the inside circumference. Due to the positive locking of the serrations, the handwheel 9 is thus connected to the drive shaft 9 in a rotationally secure manner. For axially securing the handwheel 9 on the stub shaft of the drive shaft 8 , a fastening screw of a conventional type, not shown, is provided. The drive shaft 8 itself is secured axially by a support bearing between the support plates 2 and 3 axially, which takes place via an integral part of the drive shaft 8 eccentric 10 . This consists of a parallel to the central longitudinal axis of the drive shaft 8 cylindrical pin, which is offset by the amount of eccentricity E to the central longitudinal axis of the drive shaft 8 and which is supported abge with its broad side facing the support plate 3 abge against this. On the cylindrical circumferential surface of the eccentric 10 , an in-wheel 11 of a hypocycloid gear is slidably mounted with the same width, the teeth of which mesh in the circumferential teeth of a corresponding wheel 12 , the wheel 12 being immovably connected to the support plate 3 . Since the inner wheel 12 has a larger diameter than the inner wheel 11 and thus also a higher number of teeth, the toothing engagement is limited to a circumferential region of the inner wheel 11 or the inner wheel 12 that comprises several teeth. Over the arrangement area of the wheel 12 , the support plate 3 protrudes pot-shaped to the outside. Since the inside diameter of the recess speaks the tip diameter here of the wheel 12 ent, its teeth are recessed in a cost-effective manner from the circumference of the recess. The ring bottom of the depression is formed by a cover plate 13 , which extends parallel to the main plane of extension of the support plate 3 and represents a lateral guide surface for the inner wheel 11 . On the opposite side, the inner wheel 11 is axially supported by a further guide surface, which is formed here by a ring-shaped side surface of a spur gear 14 . This spur gear 14 corresponding to the root diameter of the circumferential wheel 12 is held directly next to the eccentric 10 by a serration on a longitudinal section of the drive shaft 8 , the axial support of the spur gear 14 itself via the eccentric 10 and in the opposite direction via a spacer 15 on the inside of the support plate 2 . The spur gear 14 in turn meshes in a smaller spur gear 16 , which is non-rotatably connected to a further drive shaft 17 . This drive shaft 17 is rotatably mounted in an axially parallel manner to the drive shaft 8 and for this purpose passes through a bearing bore 18 in the support plate 3 . Since the spur gear 16 is axially supported in both directions by the inner sides of the two support plates 2 and 3 and a press fit is provided between the drive shaft 17 and the spur gear 16 , there is an indirect locking of the drive shaft 17 via the spur gear 16 .

The protruding from the support plate 3 ends of the drive shafts 8 and 17 are shown broken off. They are each in a no longer visible end area with a plug-in coupling part of a known type, such as. B. a triangular or square shank provided that interacts with the installation of the Verstellein device 1 on the vehicle seat with a counterpart plug coupling development part and thus produces a rotary connection to the adjustment transmission means of the vehicle seat.

From the visible middle position, the handwheel 9 can be turned in both directions in order to find a suitable setting for the seat height or seat inclination. The adjustment path of the adjusting device 1 is limited on the drive side since the in-wheel 11 can only carry out a limited number of revolutions.

To limit rotation protrudes from the inside of the cover plate 13 from a rigid control pin 19 which protrudes into an opposite recess 20 recessed from the side surface of the inner wheel 11 . As can be seen in connection with FIG. 2, this recess 20 extends in a rectangular cross section essentially concentrically to the drive shaft 8 over an angular range of approximately 100 °, after which it ends on both sides at a radially extending stop 21 . The recess 20 is one of a total of three on both sides of the in-wheel 11 from these recessed recesses 20 of the same size, through which the weight of the in-wheel 11 made of a cast material is considerably reduced. Two of the three stiffening ribs provided for stiffening the inner wheel 11 between the United recesses 20 can thereby be used simultaneously as stops 21 for the control pin 19 .

So that the control pin 19 can be moved without contact in the recess 20 during the adjustment process, it ends at a distance from the bottom of the recess 20 and the clear width of the recess 20 , i.e. its extension in the radial direction, is a multiple of the control pin diameter. Due to the rotation of the drive shaft 8 by means of the handwheel 9 , a reduced wobble rotation is transmitted to the inner wheel 11 via the eccentric 10 , the inner wheel 11 being moved back and forth in the radial direction relative to the control pin 19 . Therefore, it is understood that the eccentricity E, the arrangement of the control pin 19 and the engagement width of the control pin 19 and the inside width of the recesses 20 must be matched to each other constructively.

Due to the meshing engagement of the inner wheel 11 in the wheel 12 , the inner wheel 11 rotates depending on the number of revolutions of the eccentric 10 , whereby it rotates relative to the control pin 19 and the control pin 19 thus moves in the circumferential direction of the recess 20 . With He reach the intended end positions of the adjusting device 1 , the control pin 19 runs on the opposite direction of rotation of the inner wheel 11 stop 21 and thus locks the inner wheel 11 against further rotation in the same direction, whereby the two drive shafts 8 and 17 are also blocked. For impact absorption, both stops 21 are each padded with a buffer element 22 , which is made of rubber-elastic material. The here soft elastomeric buffer elements 22 are glued into the recess 20 and in the course of their com pression by the accrued control pin 19 a progressive damping process. This not only ensures soft braking of the control pin 19 , but also ensures a completely noiseless run-up on the stop 21 .

FIGS. 3 and 4 show a variant of the adjustment device 1, which is intended for a motorized rotary drive. To simplify the description, only the structural differences compared to the manual embodiment are indicated below. Components with the same effect in the variant are, however, provided with the same reference symbols for easier assignment, which are identified by adding one hundred to distinguish them.

The adjusting device 101 has only a single drive shaft 108 , which does not protrude from the bearing bore 106 and is driven reversibly via the spur gear 114 . The eccentric 110 is formed laterally on the spur gear 114 and the serration to secure the spur gear 114 against rotation extends to the end of the eccentric 110 . As a result, the drive shaft 108 can have a largely constant diameter, which is advantageous for manufacturing reasons. To axially secure the drive shaft 108 in one direction, an annular groove is inserted into the drive shaft 108 , into which a conventional expandable locking ring 123 engages, which is supported on the outside of the cover plate 113 in a lying position. The axial support in the opposite direction is guaranteed via the plug-in coupling to the adjustment transmission elements of the vehicle seat.

The Inrad 111 is made of an impact-resistant plastic and has no recess here. Principle, in a reversal of the engaging rather the control pin 119 extends perpendicularly from the slide guided on the cover plate 113 side surface of the Inrades 111, and engages with a cover plate 113 by releasing window 120 a that corresponds in its clear surface extension with the indentation 20th The control pin 119 is integrally formed on the in-wheel 111 and, in the two assigned rotational positions of the in-wheel 111, acts in a rotationally locking manner in the end positions of the adjusting device 101 corresponding to the lateral boundary surfaces of the window 120 , which form the stops 121 . Due to the elasticity and damping behavior of the control pin 119 , an arrangement of additional buffer elements can be dispensed with here. On the damping behavior of the control pin 119 can be taken to the same through a changed cross-sectional design. As indicated by broken lines, the control pin 119 does not have to have a cylindrical cross-section, but could be designed as an elongate web with a small thickness, which would result in improved bendability. This would further improve its damping behavior.

In the toothing of the spur gear 114 engages a gear worm 124 which is rotatably mounted between the two support plates 102 and 103 . To accommodate the gear worm 124 , the support plates 102 and 103 are bulged outward, then completely enclose the gear worm 124 on the circumferential side facing away from the spur wheel 114 and each end in a screw flange parallel to their main extension plane, on which they are screwed directly to one another . The gear worm 124 is rotatably connected to a coaxial shaft of an electric motor 125 , the housing of which is flanged onto the "tube area" of the two support plates 102 and 103 . The electric motor 125 is provided with conventional overload switches and can be controlled in a reversible direction via a rocker switch. As soon as the control pin 119 runs onto one of the stops 121 , the electric motor 125 switches off automatically.

Claims (10)

1. adjusting device, in particular for adjusting vehicle seats, with a reversible rotary drive of a drive shaft for the adjustment process, which is rotatably mounted in a support member, with a hypocycloid gear, the inner wheel of which is rotatably supported on an eccentric of the drive shaft, and the wheel of which is concentric Arrangement for the drive shaft is held non-rotatably on the support member, and with an overlap of a side face of the inner wheel by a cover plate of the support member, the adjustment path of the adjusting device being limited, characterized in that the adjustment path of the adjusting device ( 1 , 101 ) is limited by the number of revolutions the Inrades ( 11 , 111 ) is Festge, for which purpose between the side surface of the Inrades ( 11 , 111 ) and the cover plate ( 13 , 113 ) of the support member (support plate 3 , 103 ) corresponding position sensing means are provided, by the interaction of which the two end positions assigned Circulation positions of the in-wheel ( 11 , 111 ) are detected and a blocking of the in-wheel ( 11 , 111 ) against further rotation is triggered in the same direction. 2. Adjusting device according to claim 1, characterized in that from one of the components (cover plate 13 , 113 ; Inrad 11 , 111 ) is a mechanical scanning means (control pin 19 , 119 ) from which in one of the side surface of the counterpart (Inrades 11 , 111 ; cover plate 13 , 113 ) recessed recess ( 20 , window 120 ) protrudes, in which the scanning means (control pin 19 , 119 ) can be moved back and forth without contact during its tumbling rotation between the end positions, the scanning means (control pin 19 , 119 ) in the end were the Inrades ( 11 , 111 ) on associated stops ( 21 , 121 ), which are lateral boundary surfaces of the recess ( 20 , window 120 ). 3. Adjusting device according to claim 2, characterized in that both stops ( 21 ) with an associated buffer element ( 22 ) for impact absorption of the scanning means (control pin 19 ) are clad. 4. Adjusting device according to claim 1, characterized in that the scanning means (control pin 119 ) consists of impact-resistant plastic. 5. Adjusting device according to claim 4, characterized in that the scanning means (control pin 119 ) is integrally formed on the Inrad ( 111 ). 6. Adjustment device according to claim 2, characterized in that the provided with the recess (20) component (Inrad 11) is a cast part, with two stiffening ribs of the casting are formed as stops (21). 7. Adjusting device according to claim 1, characterized in that a gear (spur gear 114 ) is arranged on the drive shaft ( 108 ) in a rotationally fixed manner directly next to the inner wheel ( 111 ), and that the eccentric ( 110 ) is integrally formed on the gear (spur gear 114 ) is. 8. Adjusting device according to claim 1, characterized in that the adjusting device ( 1 ) comprises a plurality of gears via a Zahnradge (spur gears 14 , 16 ) rotatably coupled to drive shafts ( 8 , 17 ). 9. Adjusting device according to one or more of the preceding claims, characterized in that the adjusting device ( 101 ) is motor-driven. 10. Adjusting device according to claim 9, characterized in that a worm gear (spur gear 114 , Ge gear screw 124 ) is provided for the rotary connection of the drive shaft ( 108 ) and motor (electric motor 125 ).