DE19725693C1 - Unit with electric motor and worm gear for vehicle window, seat, roof - Google Patents

Abstract

The unit has a housing containing an electric motor and a worm gear driven by the motor. At least one shaft is rotatably mounted in the housing by means of two axial bearings. The shaft forms an armature shaft of the electric motor and also forms a worm shaft for the worm gear. One of the axial bearings is adjustable in the direction of the other by means of a starter. The latter can be inserted into an opening in the housing aligned with the shaft and can be moved relative to the shaft. The starter is axially secured in the housing by a fixing mechanism. The fixing mechanism has a first and second saw tooth locking mechanism. The second saw tooth mechanism has a different equal tooth spacing than the first.

Description

The invention is based on an aggregate of the type of the main claim. Such an aggregate is, for example usable in a device for adjusting a Sunroof, a window, a seat, one Vehicle or to move elements like that Windscreen wipers of a vehicle.

DE 195 08 306 A1 is an aggregate known with an electric motor and a subordinate Worm gear, with an axially adjustable thrust bearing a start-up part with claws springing transversely to the worm shaft has, which are in two opposite to each other Must claw the boundary surfaces of a groove, the Groove aligned with the armature shaft. Of the There is a worm shaft seen behind the groove Recess that is wider than the groove, so that the run-up body there without difficulty across to the imaginary Extension of the worm shaft can be used. From there it is pushed into the groove and against the armature shaft.  

A unit is known from DE 37 44 274 A1 with an aggregate housing and therein an electric motor and one of this drivable worm gear, at least one Shaft which is an armature shaft of the motor and on the other hand forms a worm shaft of the worm gear, rotatably supported in the unit housing and thereby by means of two Axial bearing is axially supported, one of which in the direction of another is adjustable and one for this Has thrust body, which is in alignment with the shaft Receiving opening can be inserted into the unit housing and against the Shaft is displaceable and by means of a fixing agent in the Unit housing is axially secured. Here is what Fixing agent from at least one in the direction of insertion Starting body running sequence of essentially sawtooth-like locking means with the same distances between them and associated with each sequence essentially another sawtooth-like locking means, which together with the respective assigned sequence of sawtooth-like locking means can be positively locked. This is the further sawtooth-shaped locking means as a single locking tooth on one each resilient tongue arranged, the tongue of the Starting body runs out. The thrust body, the resilient tongues and the individual locking teeth are, for example, as one piece Component can be manufactured by injection molding. Determine clearly the same distances between the first locking means shortest possible adjustment step when reducing axial play the wave. If you want particularly short adjustment steps, that's it  training tools to be adapted accordingly and disadvantageously difficult to manufacture. Accordingly small recesses in the tool fail, within which later the individual locking teeth are shaped.

So it turned out Task to improve the fixative so that, for example for particularly short adjustment steps with larger locking devices longer intervals can be used.

In the unit according to the invention with the characteristic features of claim 1 are the same distances between themselves in the Sequences of locking means much longer than an adjustment step with the advantage that a tool for the extended distances can be made easier.  

By the measures listed in the subclaims advantageous further developments and improvements of the Main claim specified aggregate possible.

The characterizing features of claim 2 enter practical embodiment, in which a cheaper Way editable element with the locking means the shorter distances.

The characterizing features of claim 3 result ring-like closed locking surfaces with the advantage that adjacent resting areas create protection against the penetration of dirt into the interior of the Unit housing.

The characterizing features of claim 4 result in the Advantage that for inserting and moving the Starting body in the housing of the unit less force is required and less wear on the locking means occurs than in the embodiment according to claim 3. The at least one resilient tongue is sufficient Can be made resilient, for example from metal. A integral design of the thrust body with the at least a tongue made of metal gives the advantage of a good one Dissipation of heat caused by the operation of the unit  starting wave is generated. The characteristic features of claim 5 result in symmetrical arrangements of the first and the second locking means. The characteristic features of the Claim 6 effect in a technically simple manner Securing the starting body against rotation when starting rotating shaft. The characteristic features of the claim 7 result in an exemplary embodiment with, for example, three resilient tongues that are rotated 120 ° relative to each other can be aligned.

In the drawings Fig. 1 assembly according to the invention partly in longitudinal section, FIG. 2 shows a section with the axial bearing of the assembly of FIG. 1 as an enlargement in longitudinal section, Fig. 3 shows a second embodiment of a thrust bearing in longitudinal section and Fig. 4 is an end view of a component of the axial bearing according to FIG. 3.

The unit 10 according to the invention has an electric motor 12 and a worm gear 13 driven by it within a multi-part unit housing 11 . Of the worm gear 13 , only one worm shaft 14 is shown. The electric motor 12 has permanent magnets 15 , an armature 16 and an armature shaft 17 . In the exemplary embodiment, the worm shaft 14 and the armature shaft 17 are combined or formed into an integral integral shaft. For the rotatable mounting of the integral shaft which, as mentioned, the worm shaft 14 and comprises the armature shaft 17, here are two radial bearings 18, 19 arranged in the unit housing. 11 The radial bearings are designed, for example, as so-called sintered bronze bearings and are spherically shaped on the outside for the purpose of the known self-alignability with respect to the mounted shaft. The integral shaft 14 , 17 has shaft ends 20 , 21 , to which axial bearings 22 and 23 are assigned.

The axial bearing 22 consists, for example, of a bottom 24 of a housing cover 25 which receives the radial bearing 19 . The bottom 24 is made of metal and therefore provides a surface facing the shaft end 20 as a plain bearing surface. In the illustrated embodiment, a sliding body is installed between the bottom 24 and the shaft end 20 . This sliding body 26 has, for example, the shape of a so-called mushroom, which is inserted into the shaft end 20 with a stem, not shown, in a manner known per se. Such a sliding body 26 consists for example of thermoplastic material.

Such a sliding body 26 is, for example, also inserted into the shaft end 21 . The thrust bearing 23 includes a thrust body 27 with a thrust surface 28 which is directed against the sliding body 26 and forms a sliding pair with it. The thrust body 27 is designed here as an essentially cup-like deep-drawn part with a bottom 29 which has the mentioned thrust surface 28 . The deep-drawn part can have a circular, oval or polygon-like cross-section, for example. On the circumference, the thrust body 27 has grooves 30 with boundary surfaces inclined to the longitudinal axis of the thrust body 7 , which, viewed in half section, result in sawtooth-like latching means 31 . Coaxial to the thrust body 27 , the unit housing 11 has a receiving opening 32 , into which circumferential grooves 33 with conical inclined boundary surfaces are also machined. Again, such grooves 33 form latching means 34 between them, which in turn look like sawtooth-shaped latching teeth in the lower half of the half-section according to FIG. 2.

The latching means 34 , which are formed in the receiving opening 32 , have first identical distances A between them. The latching means 31 , which are provided on the circumference of the run-up body 27 , have second equally spaced intervals B. In a manner belonging to the essence of the invention the second distances B different, here smaller, selected than the first distances A. For example, you can choose the second distances B in the size of 2/3 of the distances A. This results in the insertion of the thrust body 27 into the receiving opening 32 that each step has a length of 1/3 of the distance A. For example, the distance B can be made half as large as the distance A. On the other hand, there is also the possibility of choosing the distance B to be greater than 2/3 of the distance A. For example, if the distance A is designated 100%, the distance B can be 95% of A, for example. If you then choose a dimension of 2 mm for the distance A, you get locking steps with a length of 0.1 mm. The designer is therefore free to choose a locking step length and then to determine the distances A and B.

In deviation from FIG. 2, the selected distances B can also be chosen larger than the distances A between the locking means of the receiving opening for the locking means located on the run-up body.

Because, as already described, the locking means are created by circumferential grooves, one will choose a sufficiently elastic active ingredient for the unit housing 11 and / or the thrust body 27 , so that for each locking step, for example, a radial expansion of the unit housing in the region of the receiving opening 32 and subsequently one radial contraction will take place. This applies mutatis mutandis to the thrust body 27 if it is made, for example, from a relatively compliant material such as thermoplastic.

In Figs. 1 and 2, the thrust bearing essential to the invention the worm shaft 14 is associated. The designer is free to design the axial bearing assigned to the armature shaft in the manner described and then to assign an axially non-adjustable axial bearing to the worm shaft 14 .

The second exemplary embodiment of a thrust bearing 23 a according to FIGS. 3 and 4 has a thrust body 27 a, for example made of metal, the bottom 29 a of which forms a thrust surface 28 a on the one hand and is a base on the other hand, of which in this example the shaft 14 going away four spring tongues 40 , 41 , 42 , 43 go out, on which first locking means 31 a are arranged. As shown in FIG. 3, a result each succession of first latching means 31 by inclined to a longitudinal axis of the starting body 27 a oriented boundary faces 44 and further substantially aligned transversely to the longitudinal axis of boundary surfaces 45, a substantially sawtooth-like course of the alternating boundary surfaces. As can be seen from FIG. 4, seen on an end face of the run-up body 27 a, the spring tongues 40 , 41 and 42 , 43 are arranged in pairs opposite one another and relative to the longitudinal axis of the run-up body 27 a, and are essentially flat.

Each spring tongue is aligned to the neighboring spring tongue rotated by 90 °, so that here the spring tongues lie in an imaginary rectangle. The first locking means 31 a functional and thereby the first embodiment similarly designed second locking means 34 a are in registry with the spring tongues 40, 41, 42, 43 turn, in a receiving opening 32, the a is located in axial alignment with the shaft 14 in the assembly housing 11 a, , incorporated. Fig. 4 shows the spring tongues 40 to 43 in orientations which they take after installation in the receiving opening 32 a. Before installation, free ends, which are far from the floor 29 a, have larger distances than is shown for the spring tongues 40 , 41 in FIG. 3, so that in the installed state the first locking means 31 a with the second locking means 34 a can be locked securely.

The alignment of the spring tongues 40 to 43 on the above-mentioned imaginary rectangle and the alignment of the second latching means 34 a which is adapted to it, in particular with the use of the bottom 29 a which is likewise delimited by an imaginary rectangle, provides security against rotation of the startup body, in particular if its startup surface is separated from the rotating shaft end 21 is loaded.

In addition, it is mentioned that less or more than the four spring tongues 40 to 43 shown can also be arranged on a thrust body with first latching means. For example, three spring tongues can be arranged in a rotationally aligned manner by 120 ° relative to one another.

As already mentioned in the introduction to the description, the spring tongues 40 to 43 starting from the bottom 29 a act as heat-conducting bodies for carrying away frictional heat from the bottom 29 a to the second latching means 34 a and thus into the unit housing 11 a. Another heat flow originates from inwardly facing surfaces of the spring tongues 40 to 43 , to which ambient air has access.

Claims (7)

1. aggregate with an aggregate housing and therein an electric motor and a worm gear that can be driven by it, at least one shaft, which on the one hand forms an armature shaft of the electric motor and on the other hand a worm gear of the worm gear, is rotatably mounted in the aggregate housing and is axially supported by means of two axial bearings, One of which is adjustable in the direction of the other and has a thrust body for this purpose, which can be inserted into a receiving opening aligned with the shaft in the unit housing and displaceable against the shaft and is axially secured in the unit housing by means of a fixing means, the fixing means in the direction of insertion of the starting body consists of at least a sequence of first substantially sawtooth-like locking means with equal intervals between them in the receiving opening and at least a second, directed against the first latching means sawtooth-like locking means, characterized characterized in that the second sawtooth-like latching means is further developed to form a further sequence of essentially sawtooth-like latching means ( 34 , 34 a) with second spacings (B) which are the same among themselves on the starting body ( 27 , 27 a) and that the second spacings (B) are not equal to the (first) distances (A) of the sequence from the first sawtooth-like locking means ( 31 , 31 a). 2. Unit according to claim 1, characterized in that the second distances (B) shorter than the first distances (A) are. 3. Unit according to claim 1 or 2, characterized in that the latching means ( 34 , 31 ) from around the longitudinal axis of the receiving opening ( 32 ) and / and the thrust body ( 27 ) extending grooves ( 33 , 30 ) are formed. 4. Unit according to claim 1 or 2, characterized in that the thrust body ( 27 a) a transverse to the shaft ( 14 , 17 ) aligned bottom ( 29 a) with a shaft end ( 21 ) directed contact surface ( 28 a) and at least one from the bottom ( 29 a), pointing away from the shaft end ( 21 ) and thereby extending along the receiving opening ( 32 a) and pressing against it spring tongue ( 40 , 41 , 42 , 43 ) that on the at least one spring tongue ( 40 , 41 , 42 , 43 ) a sequence of first locking means ( 31 a) is arranged and that the receiving opening ( 32 a) has the second locking means ( 34 a) opposite the first locking means ( 31 a). 5. Unit according to claim 4, characterized in that two pairs of spring tongues ( 40 , 41 and 42 , 43 ) extend from the bottom ( 29 a), a pair of spring tongues ( 40 , 41 ) and the bottom ( 29 a) in are essentially connected in the manner of a U. 6. Unit according to claim 5, characterized in that the receiving opening ( 32 a) has a rectangular cross section and adapted to the rectangular cross section, the four spring tongues ( 40 , 41 , 42 , 43 ) enclose right angles between them. 7. Unit according to claim 4, characterized in that the unit has an odd number of spring tongues ( 40 , 41 , 42 ).