DE3835947A1 - Rack gearing, in particular toothed-rack steering gear - Google Patents

Abstract

In a rack gearing, in particular toothed-rack steering gear, for motor vehicles, having a toothed rack which is guided in an axially displaceable fashion in a housing, a rotatably mounted drive pinion and a pressure element which acts on the back of the toothed rack and pretensions the toothed rack against the drive pinion and is displaceably guided in the housing and is held free of play by a spring-pretensioned readjustment element which produces a wedge effect, in order to avoid overstressing and difficulty of movement a second spring is provided as an additional resilient means, the force of which is greater than the pretensioning force exerted by the readjustment element on the toothed rack.

Description

The invention relates to a rack and pinion gear, in particular a tooth rod steering gear for motor vehicles, according to the preamble of Claim 1.

Such a rack and pinion steering gear is in DE-AS 17 80 354 described. As an adjusting element is a radial to the pressure piece ver slidable wedge provided, which with an inclined surface supports an inclined surface of the pressure piece. By one on the Wedge acting spring, the thrust piece is free of play in the housing hold and thus the rack reliably against the drive pinion biased. To dampen shocks or shocks is additional Lich to the adjusting element a resilient means, for example as a disc made of microven provided.

This arrangement provides freedom of play in the area of printing piece safe, so that rattling noises are avoided. But it is not to be excluded that by a certain settlement of the plastic due to a retraction of the pressure piece or the rack of manufacturing tolerances, with uneven wear and at Bumps on the rack is no longer guaranteed and therefore Overloads and stiffness occur in the steering gear can.

The object of the invention is to provide the generic steering gear with technical resources in such a way that with unchanged more reliable Free play Overloads and stiffness are avoided.

This object is achieved with the characterizing features of claim 1 solved. Appropriate and advantageous further education Applications of the invention are set out in claims 2 to 5.  

According to the invention, a further spring is in series with the adjusting element switched whose force is greater than that by the adjusting element is pre-tensioning force. Accordingly, the spring only works if reaction forces are exerted on the pressure piece via the rack will. Which exceed the forces acting in the normal operating state and in particular are higher than those formed by the adjusting element practiced preload.

The spring can be of any type and possibly in the preloaded Be arranged state, but is preferred according to claim 2 A disc spring is suggested because this is already a high start Can have power and takes up very little space.

The plate spring or possibly a plate spring assembly can be arranged directly between the pressure piece and the adjusting element in a particularly simple manner. Particularly advantageously, however, the spring can also be tensioned between the two ring parts which are held at a defined distance from one another by at least one holding means (eg screw). This has the advantage that the distance or the play s is precisely adjustable before or during the assembly of the steering gear, so that the rack with the pressure piece can retreat at high reaction forces. In addition to simplifying the assembly, this results in a high level of functional reliability with the lowest operating noise that excludes noise.

The wedge effect adjuster can be of any type. At for example, it is possible to gela rotatable in the steering gear housing Extender or cam provided by one or more Springs receives a torsional preload and thereby the adjustment be works. According to claim 5, however, a type is proposed as it is known per se by the aforementioned DE-AS 17 80 354.

Several embodiments of the invention are in the following with white teren details explained. The schematic drawing shows in:

Figure 1 shows a cross section through a rack and pinion steering gear for motor vehicles, the cutting plane in the drilling means axis for the pressure piece and through the axis of rotation of the drive pinion to.

Figure 2 shows a portion of the same steering gear and the same cutting plane with an adjusting element with integrated second spring. and

Fig. 3 shows a further section of the same steering gear in cross section with arranged between the pressure piece and the adjusting element ring parts with an integrated spring.

Fig. 1 shows a rack and pinion steering gear 10 for motor vehicles with a substantially known type. Here, in the housing 12 of the steering gear 10, a rack 14 with a substantially circular cross section perpendicular to the plane of the drawing is axially displaceable. The rack 14 carries a toothing 24 which is located on a drive shaft 26 located on a drive pinion 28 in engagement. At the drive shaft 26 is via a roller bearing 30 and otherwise in a manner not shown in the housing 12 of the steering gear 10 rotatably gela gert. The drive shaft 26 is connected in a known manner via a steering column to the steering handwheel of the motor vehicle. The rack 14 acts on the steerable wheels of the motor vehicle via tie rods, not shown.

Perpendicular to the central axis of the rack 14 , a bore 18 is machined into the housing 12 , in which a cylindrical pressure piece 16 is slidably guided. On the pressure piece 16 acts as an adjusting element a wedge 32 which is guided in a guide groove 34 with an oblique base 20 of a housing cover 22 radially displaceably. In a bore 36 of the wedge 32 , a helical compression spring 38 is set, which is supported on the wall of the bore 18 and biases the wedge on the drawing to the left.

Between the wedge 32 and the pressure piece 16 , a plate spring 40 is provided as a second spring, which is supported on the one hand in a circular recess 42 of the pressure piece 16 and on the other hand on the base surface 44 of the wedge 32 . The plate spring 40 of the configuration shown has an initial force which is greater than the preload force of the wedge 32 , which results from the force of the helical compression spring 38 and the wedge angle of the wedge 32 in conjunction with the inclined surface 20 .

By the biasing force of the wedge 32 in connection with the screw compression spring 38 , the rack 14 with the drive pinion 28 is held in play-free engagement via the pressure piece 16 . The plate spring 40 is not deformed due to its higher initial force, whereby between the wedge 32 and the pressure piece 16, the distance s is maintained. If a reaction force is exerted via the rack 14 on the pressure element 16 , which increases the initial force of the plate spring 40 , the pressure element 16 can move back by the dimension s and avoid the overloading or stiffness in the steering gear. A reset of the wedge 32 does not take place due to the chosen wedge angle and the friction on the contact surfaces of the wedge.

Fig. 2 shows another embodiment having substantially the same function. The same parts are hen with the same reference numerals. The adjusting element or the wedge is in two parts ausgebil det with a base plate 50 and a wedge plate 52 which are fixed to each other via a molded on the wedge plate 52 pin 54 . The pin 54 can slide in a bore 56 of the base plate 50 , so that the two plates in the direction of displacement of the pressure piece 16 'are mutually displaceable. A circular depression 58 is provided in the wedge plate 52 , in which a plate spring 60 is arranged. The initial force of the plate spring 60 is in turn higher than the biasing force formed by the helical compression spring 38 and wedge angle of the adjusting element or wedge 50 , 52 . Between the base plate 50 and the wedge plate 52 , in turn, a gap s is formed, which at the initial force of the plate spring 60 exceeding reaction forces allows the pressure piece 16 'to go back. It is understood that the plate springs 40 and 60 must be specially made, since the maximum travel only corresponds to the distance s . In the case of a very small operating clearance s , the preferred embodiment below is therefore preferred.

In Fig. 3 finally, in a central bore 70 of the pressure piece 16 '' two ring parts 72 , 74 are arranged, which accommodate two disc springs 76 , 78 between them. The disc springs are supported against each other in a sensible arrangement on their inner circumferential area, while their respective outer circumference is supported in circular depressions 80 , 82 of the ring parts 72 , 74 . A screw 84 extends centrally through the ring parts, the head 86 of which is received in a stepped recess in the upper ring part 74 and the threaded part of which is screwed into the lower ring part 72 . The threads are designed with slightly different pitch angles as self-locking threaded connections. By turning the screw 84 can be set with the gap s between the two ring parts 72 , 74 who the.

If the biasing force of the two plate springs 76 , 78 , which is greater than the biasing force by the helical compression spring 38 in connection with the wedge action of the wedge 32 , is exceeded, the pressure piece 16 '' can withdraw by the defined dimension s , the screw 84 is shifted accordingly relative to the upper ring part 74 .

The invention is not limited to the exemplary embodiments shown. For example, instead of a wedge 32 , an eccentric or cam could also be provided as an adjusting element. Instead of disc springs, other springs, for example a compression spring screw in the preloaded state, can also be used. Furthermore, the wedge bevel could also be provided between the pressure piece 16 and the adjusting element and the second spring could lie between the adjusting element and the housing cover 22 . If necessary, wedge surfaces could also be provided on both sides of the adjusting element.

To simplify assembly, it may be appropriate to push the wedge back against the spring loading it until the cover 22 is installed. For this purpose, a correspondingly aligned bore can be provided in the housing of the steering gear, into which a pin can be inserted. After assembly, the hole can be closed tightly.

Claims (5)

1. Rack and pinion gear, in particular rack and pinion steering gear for motor vehicles, with an axially displaceable GE guided rack, a rotatably mounted drive pinion and acting on the back of the rack, the rack GE biasing the drive pinion thrust piece, which is slidably guided in the housing is and is held by a spring-loaded, wedge-effect adjusting element free of play, with a resilient means is additionally provided between the pressure piece and the housing, characterized in that the means is a spring (disc spring 40; 60; 76, 78 ), the force of which is greater than the pretensioning force exerted by the adjusting element ( 32 ; 50 , 52 ) on the rack ( 14 ). 2. Rack and pinion gear according to claim 1, characterized in that the spring is at least a plate spring. 3. Rack and pinion gear according to claims 1 and 2, characterized in that the plate spring ( 40 ) is arranged directly between the pressure piece ( 16 ) and the adjusting element ( 32 ). 4. Rack and pinion gear according to claims 1 and 2, characterized in that the spring ( 76 , 78 ) between two by at least one holding means ( 84 ) at a defined distance s to each other ring parts ( 72 , 74 ) is clamped. 5. Rack and pinion gear according to one or more of claims 1 to 4, characterized in that the adjusting element is a radially to the pressure piece ( 16 ) displaceable wedge ( 32 ; 50 , 52 ).