The invention relates to a reinforcing member for a belt shaft, a belt shaft as well as an end fitting tensioner comprising such belt shaft.
A seat belt by which a vehicle occupant is restrained in an automotive vehicle, if necessary, can be wound onto the belt shaft. The belt shaft is arranged in a belt winder that may be configured in two variants.
In a first variant the belt winder is an end fitting on which the webbing is arranged and in which the belt shaft does not rotate in the normal state. Only when belt tensioning is to be performed, is the belt shaft rotated about several revolutions in a winding direction so as to remove the belt slack from the seat belt.
In a second variant, the belt winder is a belt retractor in which the belt shaft is rotatably mounted. The length of webbing required for fastening the seat belt, for example, can be wound off the belt shaft, and during unbuckling the webbing is rewound. In addition, also in the belt retractor a belt tensioner may be integrated so as to tension the seat belt if necessary. Belt shafts for belt retractors usually have a definitely larger diameter than those for end fittings.
Such belt shaft is known, for example, torn DE 10 2011 117 052 A1. This belt shaft includes a body into which the reinforcing member may be hung. The body includes two flanges which are connected to a land for bearing the belt shaft. Between the flanges a recess for receiving the reinforcing member is formed. Hooking silts for hooking portions of the reinforcing member are provided at each of the flanges.
The webbing may be slipped onto the reinforcing member and, resp., a retaining portion of the reinforcing member by a sewn eye so that the webbing is safely fixed to the reinforcing member. Subsequently, the reinforcing member is hung into the hooking slits of the body. This design facilitates simple fastening of the webbing.
The known reinforcing members consist of a substantially planar sheet metal part for reasons of costs. When the webbing is wound, the webbing first wraps the land of the body and is supported by the same. The load transfer from the webbing thus is performed via the hooking slits and the land to the body. Due to the geometry of the land and, resp., the reinforcing member, a strongly Irregular load, especially bending stresses, of the body and the reinforcing member are entailed. In addition, when a straight sheet metal part is used as a reinforcing member, the belt shaft is not completely round so that imbalance may occur when the webbing is wound.
It is the object of the invention to provide a reinforcing member for such belt shaft as well as a belt shaft which allows for better load distribution and thus exhibits better stability. It is a further object of the invention to provide an end fitting tensioner comprising such belt shaft.
For achieving the object a reinforcing member is provided for a belt shaft, comprising an elongate central portion and two hooking portions provided at the ends of the central portion which can be hooked into a slit of a webbing shaft, wherein the central portion includes a retaining portion adapted to be encompassed by the webbing and a supporting portion extending in the longitudinal direction substantially over the entire central portion and being offset relative to a plans defined by the retaining portion. Retaining lands defining a passage window for the webbing extend between the supporting portion and the retaining portion.
In accordance with the invention, the reinforcing member rests on the body not only by the flanges and, resp., the hooking slits but by the appropriately modified geometry of the reinforcing member also directly on the land interconnecting the flanges of the body. The support on the body thus is performed over the entire width of the belt shaft so that bending of the reinforcing member or the land can be reduced. Preferably the support is performed by the supporting portion on the land opposed to the area of the land which is first wrapped by webbing during winding so that no or merely low bending forces act on the land by the forces acting in the opposite direction. The additional support of the reinforcing member by the supporting portion thus provides altogether belter distribution of the load transfer to the body so that less punctual load is transferred to the latter.
The reinforcing member is formed, for example, in one piece from a bent sheet metal part by bending and/or folding. Especially the retaining portion may be double-layered. By appropriate rounded portions of the individual layers and, resp., the distance of the layers from each other the retaining portion may be designed to be more stable, for example. Appropriate rounded portions may also reliably prevent sharp edges on the retaining portion so that the load acting on the webbing may be reduced. In addition, such double-layered retaining portion enables better adaptation of the reinforcing member to the outer radius of the belt shaft so that the latter may be designed to be rounder in total when viewed in cross-section.
The retaining portion may be formed, for example, by two integrally connected lands, each of the lands forming one layer.
The two lands may be connected by a bending portion, for example. Especially, the lands may be formed by folding and, resp., bending a planar sheet metal portion.
The hooking portions preferably extend starting from one of the lands and the supporting portion extends starting from the respective other land. This allows better load distribution of the force acting on the reinforcing member and the body via the webbing.
It is also possible, however, that the hooking portions and the supporting portion extend starting from either of the lands.
The retaining lands may extend, for example, from one side of the plane defined by the retaining portion over the same to the other side. When viewed in cross-section, the reinforcing member has an e-shaped cross-section, wherein at the free end of the “e” the supporting portion isprovided, while the “closed area” of the “e” forms the retaining portion. The passage window is provided so that webbing wrapped around the retaining portion may extend through the passage window without contacting the supporting portion. This shape of the reinforcing member enables a symmetric load transfer to the body, when viewed in cross-section, so that the punctual load on the body is lower.
For achieving even belter load distribution the hooking portions may be provided with a bearing edge especially stepped in the longitudinal direction.
The flanges of the belt shaft usually are provided with a tooth profile so as to prevent the belt shaft from co-rotating in the case of tensile force acting on the webbing by the tooth profile engaging in a bearing-side toothing. In order to avoid interruption of the toothing by the hooking silt, the hooking portion may be provided with a toothed edge which completes the circumferential toothing on the flange of the body when the reinforcing member is hooked in.
For achieving better catching in the bearing-side toothing said toothed edge may be bent vis-à-vis a plane defined by the hooking portions.
When viewed in section perpendicularly to the longitudinal axis of the reinforcing member, the toothed edge may also be located approximately on the same radius as the supporting portion in this area, which allows to obtain very uniform load transfer to the body.
For achieving the object a belt shaft is further provided comprising a belt shaft body which in the center has a recess and comprising two flanges in each of which a hooking slit is provided, wherein the belt shaft body includes a supporting surface for the supporting portion adjacent to the recess. Said supporting surface is preferably provided on a land interconnecting the two flanges.
The supporting surface may have at least one first partial surface extending in the circumferential direction with respect to the belt shaft axis en which partial surface the supporting portion rests. Preferably said first partial surface is provided on the radial outer surface of the land interconnecting the two flanges. By the extension in the circumferential direction excellent load transfer to the land can be achieved. In particular, lever forces acting on the reinforcing member can be excellently absorbed by an appropriately wide support.
The supporting surface may also have a second partial surface extending radially with respect to the belt shaft axis. Especially, a combination of the first and second partial surfaces is possible.
In accordance with the invention, furthermore a reinforcing member according to the invention is inserted in the hooking slits so that the hooking portion is located in the hooking slit and the supporting portion contacts the supporting surface.
For achieving the object furthermore an end fitting tensioner for a seat belt is provided comprising such belt shaft.
Further advantages and features will be evident from the following description in connection with the enclosed drawings, wherein:
in
The end fitting tensioner 12 includes a retaining frame 14 having a base plats 16 for mounting the retaining frame 14 fixed to the vehicle as well as two substantially parallel side legs 18 each including a round cutout 20 (see
As is evident from
A tooth profile 38 adapted to interact with the toothing 22 at the side legs 18 of the retaining frame 14 is provided on each of the flanges 30. Moreover, a torque transmission profile 40 projecting in the axial direction in which a drive element of the tensioning drive 24 may engage, for example a pulley, is provided.
As can be inferred from
The reinforcing member 36 shown in
The reinforcing member 36 includes a central portion 46 and two hooking portions 48 provided at the longitudinal ends of the central portion 46.
The central portion 46 has a retaining portion 50 which, as is evident from
In addition, the central portion 46 includes a supporting portion 58 extending in the longitudinal direction L and being spaced from the retaining portion which is connected to the retaining portion 50 by two bent retaining lands 60. A passage window 62 is defined by the retaining lands 60, the supporting portion 58 and the retaining portion 50.
As is visible in
As is visible in
Subsequently the reinforcing member 36 is inserted along with the hooking portions 48 into the hooking slits 42 of the belt shaft body 28 until said hooking portions contact the bottom of the hooking slits 42 (cf.
As is evident from
When the belt shaft 10 then is moved in the direction of rotation D so as to wind the webbing 26 onto the belt shaft 10, the webbing 26 first contacts a contact face 68 opposed to the supporting surface 66 on the land 32 when viewed in cross-section. When a tensile force Z acts on the webbing 28, pressure forces D1 thus act on the contact face 68. At the same time, pressure forces D2 act on the bottom of the hooking silts 42 via the hooking portions 48. In addition, pressure forces D3 act on the supporting surface 68 of the land 32.
In
In this case, merely pressure forces D1′ and D2′ are acting, which causes a strongly irregular load of the belt shaft body 28. Since the reinforcing member 36′ does not rest on the land 32′, it can be bent by the tensile forces acting on the webbing. In addition, the forces act exclusively on the hooking silts 42′ and the contact face 68′, thus causing an asymmetric load of the belt shaft body 28′ when viewed in cross-section. Furthermore, the pressure forces D1′ may cause bending stress of the land 32′.
As is evident from
This more uniform load is achieved by the supporting portion 58 being offset relative to the plane M which is defined by the retaining portion 50. The central portion 50 especially exhibits a substantially e-shaped design, with the supporting portion 58 being provided at the tree end of the “e”. The hooking portions 48 are provided at the opposite inner end of said “e”.
Especially the retaining lands 60 extend from a first side with respect to the plane M over said plane M to the other side, in this way, very uniform load transfer, when viewed in cross-section, to the belt shaft body 28 is achieved.
Moreover, as the reinforcing member 36 can be adapted better to the outer circumference of the belt shaft 10 due to the double-layered design, a rounder cross-section of the belt shaft 10 is obtained (cf.
As is evident from
Opposite to the bearing edges 70 a toothed edge 72 which is bent vis-à-vis a plane E defined by the hooking portions 48 is provided at each of the hooking portions 48 (cf.
As is visible in
A second embodiment of a belt shaft 10 according to the invention isillustrated in
The supporting surface 66 provided on the land 32 of the belt shaft body 28 includes two partial surfaces 74, 76, however. A first partial surface 74 is provided on the circumferential surface of the land 32 and extends in the circumferential direction. A second partial surface 76 extends substantially in the radial direction. The first partial surface 74 is provided in a recess 78.
The reinforcing member 36 of the belt shaft 10 is shown in detail inFIGS. 13 to 16.
As is evident from
The reinforcing member 36 also includes a central portion 46, two hooking portions 48 provided at the longitudinal ends of the central portion 46 and a supporting portion 56. The central portion 46 includes a retaining portion 50 equally formed of two lands 52, 54 which are interconnected by a bending portion 56.
As is especially visible from
The bending portion 56 is bent so that the land 54 is provided on a first side of the land 52, the lands 60 of the supporting portion 58 are bent so that the supporting portion 58 is located on the opposite side of the land 52. Hence, the reinforcing element 36 is s-shaped. when viewed in cross-section. The supporting portion 58 is curved, when viewed in cross-section, in portions substantially along a circular path the radius of which corresponds to the radius of the belt shaft 10.
As can be inferred from
In addition, by the larger contact surface a lever action acting on the reinforcing member 36 is shifted by the pivot point 80 (cf.
The reinforcing member 36 shown in
Number | Date | Country | Kind |
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10 2014 011 966.1 | Aug 2014 | DE | national |
This application corresponds to PCT/EP2015/001524, filed Jul. 23, 2015, which claims the benefit of Gorman Application No. 10 2014 011 966.1, filed Aug. 15, 2014, the subject matter of which are incorporated herein by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/001524 | 7/23/2015 | WO | 00 |