SK7396A3 - Electromotive drive - Google Patents

Abstract

To mount the compressive or tensile stress-sensitive magnetic body (2) for an engine speed sensor in an electromotive drive simply and -even with major play due to thermal variation-securely onto the rotor shaft (1), the magnetic body (2) is self-centeringly placed on the rotor shaft (1) without compressive or tensile stress and is pressed against a shoulder (1.1) of the rotor shaft (1) by means of an axially forward contact pressure piece (3) that is fixed on the rotor shaft (1), adjoining the face of the magnetic body (2).

Description

The area -_É £ £ --ίβΣ

The invention relates to an electromotive drive, in particular an automatic washing machine drive, with a magnetic body mounted concentrically on the rotor shaft.

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BACKGROUND OF THE INVENTION

Such drives with a magnetic wheel as a magnetic body mounted on a rotor shaft for producing a signal proportional to the speed with Hall probes on the stator side are used, for example, for speed-controlled or anti-rotationally driven motor vehicle window lift drives or our automatic washing machine drives.

It is known from Japanese Patent A-04 185 145 to be mounted electromotive mounted on a rotor drive on a rotor drive with a magnetic body, a shaft, the bore of which has a corresponding radial tolerance on the shaft, which is held on the rotor shaft and consequently non-axially The recesses on the rotor co-carried by the rotation of the dowel of their one front striker are adapted to the fixed shaft.

From European Patent Specification 0 489 940 a commutator motor is known in which Hall probes are arranged on an electronic connection plate on a stator, which is directly associated with a magnet wheel mounted on a rotor shaft. The mounting of the magnet wheel on the rotor shaft can be carried out, for example, by a corresponding press fit or by glued fit.

From German patent Ul-90 06 935, an electromotive drive is known, in particular for motor vehicles, with a commutator motor and a steering, for speed sensing or arranged on a rotor shaft, with a sensing rotation sleeve, with a magnet.

a wheel cooperating with a Hall sensor mounted on the rotor, whereby a spacer sleeve is fixedly mounted on the rotor shaft first to hold the magnet wheel on the rotor shaft, and then the magnet wheel is concentrically mounted on the outer circumference or pushed on, or pushed on, or fastening by positive fit. For positive fit, the spacer sleeve is provided with a flattening on its outer periphery, and the magnet wheel on its corresponding inner side is also provided with a flattening flat.

For axial securing, with its one end face, the spacer pusher engages the commutator and with its other face with a thin fit that engages in the junction. The magnet forest of plastic is secured by securing the rotor shaft with the shape of a wheel, which may consist of a magnet in which the magnetic particles are connected to the plastic or of a non-magnetic base body in which the permeable magnets are inserted.

Podstata_vynálezu

SUMMARY OF THE INVENTION The object of the present invention is to provide a reliable fastening to the rotor shaft by means of a simple means for a magnetic body of at least a high number of poles at a small construction height and a greater temperature tolerance for longer and demanding operating applications.

This object is achieved according to the invention in that the magnetic body is displaced concentrically in the opening corresponding to the rotor shaft to secure the radial position, but without pressure and tensile stress on the rotor shaft, the magnetic body being axially secured or tangentially rotating with the rotor shaft. by means of a thrust piece fastened to the rotor shaft by means of an axial abutment against the axial stop. Further aspects of the invention are subject to subordinate resilient fronts.

In the electromotive drive according to the invention, irrespective of the porosity of the magnetic body and its proportion of plastic, especially when used in automatic washing machines where the existing heat results in a large tolerance,

ľahlivé fixation this magnetic bodies on ro - t or ov om shaft made of steel . at the same time is behind safe use suitable formulations pr e assembly " at- what all peripheral magnetic surface housing je k disposition for magnetization in the sense thick succession poles and thereby also high number of poles. At mounting magnetic body and the pressure part is expedient magnetic body for rotor hria - split only slid and a press piece from free a horse- .

The rotor shaft must be pressed against the rotor shaft to form a fixed or rotary shaft on the rotor shaft. press fit. According to the development of the invention, a shaft shoulder on the front side of the magnetic body deflected from the pressing part serves as a stop for the axial end securing of the magnetic body of the axially pressed part.

As a resilient pressure member, a pressure disk with a radially inner press fit for the rotor shaft and with axially opposing magnetic fingers protruding axially against the magnetic body is advantageously provided such that normally a rotary drive of the magnetic body is ensured without slipping relative to the rotor shaft. part mounted on the rotor. In order to additionally secure the slip-free rotational drive, snap-in recesses are provided on the magnetic body corresponding to the pressing fingers of the pressing part, so that at the first slip between. with the thrust piece on the one hand and the magnetic body on the other hand, the thrust fingers engage in the latching recesses and thus, for various other operating states, provide additional positive engagement of the rotary entrainment between the magnetic body and the thrust piece.

From the point of view of the preferred method of manufacture and assembly, the pressing part, in particular the pressing disk of plastic, consists of one unit with a radially internal press fit and with pressing fingers formed thereon. The magnetic body consists generally of a comparatively magnetic ring with a plastic bond with an advantageous axially central bearing surface for the rotor shaft only at the time of its axial length.

Prehľad__obrázkov__na__výkrese ^ ..

The invention, as well as other preferred embodiments of the invention according to the features of the subclaims, will be explained in more detail below with reference to the exemplary embodiments shown schematically in the drawings.

In FIG. 1 is a partial cross-sectional view of the rotor shaft with the magnetic body inserted at its free end up to abutting the shaft shoulder and axially pressing the pressure plate.

On the Fig. 2 is a pressure plate according to o'or. 1 in the unfit pre-assembly. On the Fig. 3 is a axial view push disc by Fig. 2 by the magnetic forest • On the Fig. 4 is a The arrangement according to FIG.

in a partial cut-out with the thrust fingers of the thrust disc inserted in the latching recesses on the front of the magnetic body.

In FIG. 5 is an axial front view of a magnetic body made symmetrically on both ends.

Príklady__zhotovenia__vynálezu

Fig. 1 shows a rotor shaft 1 of, for example, an automatic washing machine drive, on which at its free end 12 a radially offset shoulder L.1 is fixed a magnetic body 2, which serves e.g. as speed sensor, resp. as a speed sensor for a measuring device or for a control device. The magnetic body 2 preferably consists of a porous magnetic ring or a ferrite magnetic ring with a plastic binder. Such magnetic bodies are in the case of sintering, i. precipitations from solutions due to their porosity very sensitive to tensile stresses and possibly pressure.

When plastic material is used, tolerance occurs at higher temperatures because the plastic material has a significantly different heat coefficient compared to the rotor shaft.

According to the invention, therefore, the magnetic body 2 is only inserted from the right side onto the free end 2 of the rotor shaft so that it is given a radial centering not. For the slip-free rotating driving of the magnetic body by the rotor shaft 1 made by casting under pressure of the material pressed against the net body 2, which is pushed sideways in its pressure plate 3, in one piece of the artificial right end face mag is its left front end. in its operating position against the shoulder 1.1 of variation of the axial delimitation of the rotor shaft 1. In the mounting of the K1 shaft on an unoccupied rotor shaft 1, a pressure disc similar to a pressure disc on its right side could be pressed onto the front face of the magnetic body 2 on an ice front. but only by an axially flat surface 24 disposed preferably by the end 1.2 of the rotor-abutting bearing axially in the center.

The pressure plate 3 has, according to FIG. 2, according to one preferred embodiment, beside the radial inner press fit 3.4 for the free end 1.2 of the rotor shaft 1, the elastic thrust fingers 3? 1 to 3.3 protruding against the end face of the magnetic body 2 which is subjected to pressure. Suitably, the thrust fingers 5.1 to 3.3 are radially bent at their free ends and press against the magnetic body by the radially bent ends. In this way, axial tolerances can be easily compensated under constant elastic pressure.

Although the rotary drive between the two can be provided with a slip-free pressure disc 5 preferably seated in the forest, and between the elastically biased embodiment on the magnetic temagnetic body 2, according to the present invention shown in FIG. 2 to

4, arranged additionally rotatable by means of a positive fit between the pressure plate 5 on the one hand and the magnetic body 2 on the other, so that the front side of the magnetic body has latching recesses 21 to 25 of the pressing surfaces of the elastic pressing means according to FIG. 2 corresponding to 5.1 to

5.5

If, when the magnetic body is pushed on one side on the other side, there are no dreams in front of the pressure disc 5, the pressure discs engage with the thumb 51.1 to 3.3 and thus force contact for the other axially for the pressure rotation between the magnet. According to a further preferred embodiment, the abutment thrust fingers 3.1 to 3 of the body 2 and the pressing means of the embodiment of the invention are the areas 2, 5 remaining up to 2 _± 7 for the latch-type. The elastic effect of the thrust fingers 3.1 to 3.3 thus compensates for the randomly occurring axial recesses 2 _X 1 to 2.3 provided with a roughened surface 8 of the magnetic tolerance 2 of the magnetic body 2. The radial tolerance of the magnetic body 2 is also possible. 3 deletes. In addition, the oscillations due to friction between the magnetic body 2 and the pressure plate 3 are attenuated. · If the rotational load of the magnetic body 2 exceeds the force contact between the magnetic body 2 and the pressure plate 3, the magnetic body 2 can rotate a slight tangential angle to the rotor shaft. 1, until the pressing fingers 3, 1 to 3, 3 engage in the latching recesses 2.1 to 2.3, thereby ensuring an additional positive fit. The resilience constant of the pressing fingers 31 to 33 and the shape of the latching recesses 2.1 to 2.3 are so coordinated with each other that the increased axial pressing force of the pressing fingers 31 to 33 is greater than zero.

.For manufacturing and assembly. ·. ' an easy way to the axial symmetry of the parts arranged in the locking recess 2 ^ 1-2 _λ 3 and the contact surfaces 2.5 2j.7 to the respective end of the magnetic body of the second In a similar manner, the pressure plate 3 can also be provided with axially protruding resilient springs at the thrust fingers 3 ^ 1 to 3, axially extending axially on both sides of the press fitment 3 ^ 1 to 3, in a modified embodiment.

Claims (10)

PATENT CLAIMS 1. Electromotive drive,. in particular a washing machine drive, with a magnetic housing located concentrically on the rotor shaft, characterized in that the magnetic housing (2) is displaced concentrically, but without pressure and tensile stress, to secure the radial position through the bore corresponding to the rotor shaft (1). the rotor shaft (1), wherein the magnetic position locking or pro (2) body is tangentially axially rotatable with the rotor shaft (1) by a thrust piece (3) »mounted on this rotor shaft (1), axially resilient by facing against the axial stop /1.1/. Electromotive drive according to claim 1, characterized in that the magnetic body (2) is displaceably mounted on the rotor shaft (1). Electromotive drive according to claim 1 or 2, characterized in that the pressing part (3) is fixedly fixed or press-fit on the rotor shaft (1), in particular being pressed from the free shaft end (1.2). Electromotive drive according to one of the preceding claims 1 to 3, characterized in that the shaft axis (1.1) on the front side of the magnetic body (2) which faces away from the pressing part (3) is arranged as soon as possible. . Electric motor drive according to any one of claims 1 to 4, characterized in that a plunger (3) with a radially internal press-in is arranged as a flexible pressing part. by bearing (3.4) for rotor shaft (1) and with flexible thrust fingers (3.1); 3.2 / protruding axially against the magnetic body / 2). 6. The electric motor drive according to claim 5, wherein the pressure fingers (3.1); 3.2; 3 * 3) are obliquely bent radially at their free ends and press flexively against the magnetic body (2) by the bent ends. The electromotive drive according to claim 5 or 6, characterized in that, on the magnetic body (2), an additional form-fitting contact for rotary entrainment is provided on the front side of the snap-in recess (2.1); 2.2; 2.3 / corresponding to thrust fingers /3.1; 3.2; 3.3 /. 8. The electromotive drive according to claim 7, characterized in that the abutment surfaces (2.6); 2.7; 2.8 (on the thrust fingers (3-1 to 3.3)) are provided with a roughened contact surface between the latching recesses (2.1 to 2.3). 9th electromotive propulsion according to any of the following: of the preceding claims 1 to 8; a č u - j ú c i by that the pressure roll / 3 / sa consists in one piece of plastics p radial internal press fit /3.4/ and thrust fingers / 3 * 1 to 3.3 / _P formed on it. Electromotive drive according to one of the preceding claims 1 to 9, characterized in that the magnetic body (2) consists of a porous magnetic ring or a ferrite magnetic ring with a plastic binder, preferably with an axially central bearing surface (2,4) for the rotor shaft only in part of its axial length.