Abstract:
In an adjuster ( 101 ) for a vehicle seat, in particular a hinged fitting functioning as an inclination adjuster for a motor vehicle rear seat bank, having a first adjuster part ( 105 ), a second adjuster part ( 108 ) mounted such that it can move relative to the first adjuster part ( 105 ), and a pawl which is pivotably mounted on the first adjuster part ( 105 ) and interacts with the second adjuster part ( 108 ) in order to lock the adjuster ( 101 ), the bearing device ( 113 ) of the pawl is supported on the bearing device ( 110 ) of the second adjuster part ( 108 ).

Description:
CROSS-REFERENCE TO RELATED APPLICATION  
         [0001]    This is a continuation of International Application No. PCT/EP01/12000, which was filed Oct. 17, 2001, was published in German on May 5, 2002, designates the U.S., and is incorporated herein by reference.  
         BACKGROUND OF THE INVENTION  
         [0002]    The present invention relates to an adjuster for a vehicle seat.  
           [0003]    With a known adjuster for a vehicle seat, which is designed as a hinged fitting, the inclination of the backrest of a vehicle seat in the rear passenger compartment of a motor vehicle can be adjusted. In the event of a crash, forces are introduced by the backrest into the structure of the seat part via the hinged fitting. The pawl and the further locking elements are subjected to these higher forces and therefore have to be dimensioned strongly.  
         BRIEF SUMMARY OF THE INVENTION  
         [0004]    The present invention is based on the object of improving vehicle seat adjusters. According to one aspect of the invention, an adjuster for a vehicle seat includes first and second adjuster parts, with the second adjuster part mounted by a bearing device for moving relative to the first adjuster part. The adjuster further includes a pawl pivotably mounted on the first adjuster part by a bearing device, for interacting with the second adjuster part to lock the adjuster. In addition, a support is mounted to both the bearing device of the second adjuster part and the bearing device of the pawl, with the support functioning so that the bearing device of the pawl is supported by the bearing device of the second adjuster part.  
           [0005]    The fact that the bearing device of the pawl is supported on the bearing device of the second adjuster part means that in the event of a crash, the bearing device of the pawl is not loaded differently from the bearing device of the second adjuster part. The interaction between the pawl and the second adjuster part, for example a tooth engagement, is maintained unchanged. Given the same level of safety, the components of the bearing device, in particular the actual bearing, can be dimensioned to a lower level. This reduces the weight of the adjuster and simplifies and cheapens production, in particular of the first adjuster part. For example, the first adjuster part can be produced from thin sheet metal with a constant thickness. If the adjuster is constructed as a hinged fitting, that is to say as a backrest adjuster, the support is preferably provided between a backrest pin forming the backrest axis of rotation and a ratchet pin which carries the pawl, as a result of which the bearing of the ratchet pin is relieved of load.  
           [0006]    In a preferred embodiment, the support is designed as a lug, which is seated both on the backrest pin and on the ratchet pin. Such a lug can be produced and mounted simply and cost-effectively. In order to be able better to absorb and pass on the forces which occur, the lug is preferably produced from high-strength steel. For symmetrical transmission of the force to the backrest pins, two lugs are preferably provided, which each have to absorb at most half of the forces occurring. In particular, if the lower part of the fitting is designed as a hollow profile, in whose interior the pawl is arranged, one lug can be arranged on each of the outer sides of the lower part of the fitting, so that no installation space has to be created in the interior of the lower part of the fitting. In addition, the lugs then support the end sections of the ratchet pin, so that the forces that occur act with the smallest possible lever arm. When the lower part of the fitting is designed as a hollow profile, it has an at least partly closed form with an internal space to accommodate the locking and securing elements.  
           [0007]    The adjuster according to the invention is preferably used as a hinged fitting in a rear seat bank in the rear passenger compartment of a motor vehicle, for example a van, but the hinged fitting could also be used in a front passenger seat or in further rows of seats. Such a hinged fitting can additionally be provided with a control cam which interacts with the pawl in order to be able to control the possible sitting positions and a table position. Furthermore, there may be play-cancelling means. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWING  
       [0008]    In the following text, the invention is explained in more detail with reference to an exemplary embodiment which is illustrated in the drawing, in which:  
         [0009]    [0009]FIG. 1 shows a perspective view of the exemplary embodiment,  
         [0010]    [0010]FIG. 2 shows a schematic side view of a vehicle seat,  
         [0011]    [0011]FIG. 3 shows a section along the line III-III in FIG. 1, and  
         [0012]    [0012]FIG. 4 shows a partly sectioned illustration of the exemplary embodiment, corresponding to FIG. 1.  
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0013]    The exemplary embodiment relates to a hinged fitting  101  for a rear seat bank  103  belonging to a motor vehicle, whose arrangement in the motor vehicle and whose normal direction of travel define the following directional statements. The hinged fitting  101  is an inclination adjuster for the backrest  104 , and it is designed as a latching fitting. On both sides of the rear seat bank  103  or, in the case of a design with a 1/3-2/3 backrest, on the outer sides or on both sides of the corresponding parts of the backrest  104 , a hinged fitting  101  is provided in each case. By way of the hinged fitting  101 , the backrest  104  can assume a plurality of different seating positions and a table position. Each hinged fitting  101  has a lower fitting part  105 , which is permanently fitted to the seat-part structure of the rear seat bank  103 , and an upper fitting part  108 , which is permanently fixed to the structure of the backrest  104 . The lower fitting part  105  is designed in two parts, the two parts being joined by the overlapping edge region to form a hollow profile. The upper fitting part  108  is rotatably mounted in the lower fitting part  105  by way of a backrest pin  110  that defines an axis of rotation aligned in the y direction (that is to say horizontally and transversely with respect to the direction of travel), as a result of which the backrest  104  of the rear seat bank  103  can be pivoted relative to the seat part of the rear seat bank  103 .  
         [0014]    At its lower end, facing away from the backrest  104 , the upper fitting part  108  bears a toothed ring  112  concentric with the backrest pin  110 . On the lower fitting part  105 , a pawl  115  is pivotably mounted on a ratchet pin  113  fixed to the lower part. The pawl  115  has a toothing system  115 ′, which is aligned approximately with the backrest pin  110  and which can interact with the toothed ring  112  located in the same plane. If the rear seat bank  103  is in a seating position, then the toothed ring  112  is within the pivoting range of the pawl  115 . At this inclination of the backrest  104 , the toothing system of the spring-loaded pawl  115  engages in the toothed ring  112  and, as a result, locks the hinged fitting  101 . The toothed ring  112  extends over a large angular range so that there are a plurality of lockable seating positions. That is, a plurality of inclinations of the backrest  104  are possible.  
         [0015]    For the event of a crash, the pawl  115  is secured by a cam-like catching piece  117  pivotably mounted on the lower fitting part  105 . The catching piece  117  is biased in the direction of the pawl  115  by a catching-piece spring  119  and rests as a stop on a ratchet arm  115 ″ that projects radially. There are two of each of the upper fitting part  108 , the pawl  115  and the catching piece  117 . That is, two identically designed halves of these components arranged in the x-z plane are arranged beside each other in the y direction and between the two walls of the hollow profiled lower fitting part  105 , in order to be able to absorb and pass on the forces that occur.  
         [0016]    In the y direction, on one side of the pawl  115 , a control piece  121  is firmly fixed to the pawl  115  so as to rotate with it. A clamping piece  129 , which is pivotably mounted in the same plane as the control piece  121 , is on the same bearing pin  131  as the catching piece  117 , and is biased by a bent helical spring  133  belonging to the control piece  121  of the pawl  115 . The clamping piece  129  is biased towards the side of the control piece  121  facing away from the toothing system  115 ′. Via an eccentrically curved clamping surface, the clamping piece  129  presses against the control piece  121 , which is flat at this point, as a result of which the toothing system  115 ′ of the pawl  115  is forced without play into the toothed ring  112 .  
         [0017]    Fitted off-center to the catching piece  117  is an unlocking pin  145  which projects in the y-direction through a slotted guide  147  in one wall of the lower fitting part  105  and is guided by the slotted guide within the x-z plane. In order to unlock the hinged fitting  101 , the unlocking pin  145  is pulled suitably, whereupon the catching piece  117  is pivoted away from the pawl  115  and, after a short pivoting angle, carries the clamping piece  129  along with it via a driver (not illustrated). As a result, the pawl  115  is released and, by way its weight, by way of pressure on the backrest  104  or by way of a driver arm of the catching piece  117 , the pawl is forced or lifted out of the toothed ring  112 , so that the hinged fitting  101  is unlocked. Locking is carried out via the various spring loadings.  
         [0018]    On both sides of the hinged fitting  101 , in each case on the outer side of the lower fitting part  105 , a pulling lug  149  is provided, which is produced from high-strength steel, for example 25CrMoY. Each of the two pulling lugs  149  is mounted on both the backrest pin  110  and the ratchet pin  113 , so that the ratchet pin  113  is supported on the backrest pin  110 . The flat, elongated pulling lug  149  tapers slightly from the end mounted on the backrest pin  110  towards the end mounted on the ratchet pin  113 .  
         [0019]    In the event of a crash, for example in the event of a front crash, the forces arising on the backrest  104  are introduced into the hinged fitting  101  via the upper fitting part  108 . Some of the crash forces are passed on to the pawl  115  via the toothed ring  112  as an opening moment. The catching piece  117 , now bearing in the opening direction, prevents the pawl  115  from pivoting about the ratchet pin  113 . Without the pulling lugs  149 , the level of toothing overlap between the toothing system  115 ′ and the toothed ring  112  would become smaller and smaller at a rolling point which, on account of the catching piece  117 , lies in the region of engagement of the teeth of the toothing system  115 ′ located furthest from the ratchet pin  113  and in the corresponding teeth of the toothed ring  112 . This is because, without the pulling lugs  149 , the pawl  115  would be forced backwards on account of its loading, so that a corresponding slot-like deformation in the lower fitting part  105  would be produced, while at the same time another part of the crash forces would pull the backrest pin  110  forwards via the upper fitting part  108  loaded forwards by a torque, so that another, in particular differently oriented, slot-like deformation in the lower fitting part  105  would be produced. Without the pulling lugs  149 , therefore, starting from the end remote from the rolling point and going in the direction of the rolling point, the teeth of the toothing system  115 ′ and of the toothed ring  112  would be moved away from one another, reducing the level of overlap.  
         [0020]    By way of the pulling lugs  149 , the ratchet pin  113  is held at a constant distance from the backrest pin  110 , so that in the event of a crash the ratchet pin  113  is pulled upwards behind the backrest pin  110 , and therefore the tooth engagement between the toothing system  115 ′ and the toothed ring  112  is maintained not only in the region of the rolling point but completely or virtually completely. Then, in the region of the bearing of the ratchet pin  113  and of the backrest pin  110 , the lower fitting part  105  does not have to be specially reinforced in order to avoid the slot-like deformations in the event of a crash. Instead, the lower fitting part  105  can be formed from sheet steel with a constant, low thickness, for example from QStE460. The crash forces are ultimately introduced via a common, equally large and synchronous deformation in the same direction of the lower fitting part  105 , through the backrest pin  110  and the ratchet pin  113  into the lower fitting part  105 , onward into the seat part structure and finally into the vehicle structure.