DE1014211B - Hand machine tool with an electric drive motor, which is housed in an insulated metallic outer housing - Google Patents

Description

Hand machine tool with an electric drive motor that works in one metallic outer housing is housed insulated The invention relates on a hand machine tool with an electric drive motor in a metallic The outer housing is housed insulated with the help of two centered on the outer housing End shields made of insulating material.

In known hand machine tools of this type, the axial distance is the anchor bearing set by the insulating material, which is when shrinking or Sources within the metallic outer housing of the hand machine tools in their Dimensions can change significantly and thus a strong tension in the armature bearings cause. This can lead to the machines, after a short period of operation, among other things also as a result of the heating of the insulating material parts occurring during operation, show significant storage damage. It has been shown that these difficulties the greater the free length of the insulating material between their Clamping points is. However, in order to achieve protective insulation that is common among all Occurring operating conditions there is sufficient isolation between the in one Damage to live metal parts of the drive motor and the one Ensures contact with the directly accessible metallic outer housing of the machine, Attempts have already been made to install the motor in a tubular insulating material intermediate housing to be arranged that covers the engine including its storage position. With such The insulating material intermediate housing on a significant part of its machines Length of the clamping pressure of a tofl housing to hold the insulating housing in the metal housing serving screw ring exposed. As a result, apart from the changes in length, caused by swelling or shrinking of the insulating material, including the Clamping pressure influences the bearing spacing.

These disadvantages are avoided in an arrangement according to FIG Invention uses the following features known per se in combination: a) that for Achieving as closed an insulating material housing as possible between the Motor and the metallic outer housing of one of the two end shields cup-shaped is formed and enclosing the stator of the motor up to the vicinity of the other End shield is enough, b) that each of the two end shields against axial displacement Is attached to contact surfaces of the outer housing, which is in the plane of the. From the associated Ball bearing encompassed by the end shield run, and c) that the cup-shaped end shield at its bottom zone a collar running in the plane of the ball bearing there has, which is in the parting line between the handle and the cylindrical longitudinal part of the outer housing or between this and the gear housing is clamped.

Two exemplary embodiments of the invention are shown in the drawing.

Fig. 1 shows one in two mutually perpendicular: ndein sectional planes along line I-1 in Fig. 2, longitudinal section through a hand drill; Fig. 2 shows a cross-section along the line II-II in FIG. 1, but without Motor anchor; Fig. 3 shows another hand drill, also in one in two perpendicular to each other cutting planes guided longitudinal section.

The hand drill essentially consists of an electric one Universal motor with an armature 11 and a stator 12, a motor housing 13 Cast aluminum and one arranged on the front face of the motor housing Handle 15. This is also made of metal. It contains a double pole Mains switch 16 and a suppression capacitor 17 and also takes one end of the power cord 18. For complete electrical insulation of the motor and its in the event of damage, metal parts (of the stand 12 and the entire armature 11) is a cup-shaped made of molded insulating material End shield 20 arranged, the inside of the engine except for the one on the transmission side protruding shaft piece 21 completely covers. The cup-shaped end shield is only about the length of its outer circumference, which I screwed into it 22 attached stator 12 including its field winding extends into the cylindrical Bore of the metallic outer housing 13 fitted. By doing by strong ribs 26 stiffened bottom part 27 of the cup-shaped bearing plate is seated the outer ring 28 of a ball bearing arranged in the vicinity of the collector 30. In In the vicinity of the bottom part, there are two on the outer circumference of the cup-shaped end shield 20 diametrically opposite eyes 23 are provided, each of which has a guide bush 24 for receiving a carbon brush 25 included. The guide bushings 24 are outward - Covered by a plug 29 made of insulating material, which has an external thread and is screwed to this in the eyes 23.

The ball bearing arranged at the end of the armature shaft 21 on the transmission side is with its outer ring 31 in an: also serving as a bearing shield insulating piece 32 fitted, in which the metal housing 13 terminates against the gear housing 14 Centered transverse wall 33 and provided with a blind hole 34 on the transmission side which serves as a bearing point for the countershaft 36. Find your second camp this shaft in a blind hole 37 made in the gear housing 14, which a lubrication groove 38 contains. So that there is no tension from the armature shaft 21 on the gearbox housing 14 can be transmitted, is the back gear meshing with the armature shaft pinion 41 42 made of insulating material.

The training and arrangement deserve particular attention of the cup-shaped end shield 20 itself.

This is in the vicinity of the collector-side ball bearing receiving Bottom part. 27 is provided on its circumference with a flange-like edge 52 which into a fitting 51 at the open. Front side of the metal housing 13 pushed in and there by a mating surface 53 cut into the handle housing 15 is braced against axial displacement. The distance D of the clamping surface 53 to the center of the - ball bearing, which is arranged approximately in the plane of the clamping edge, is right dimensioned small and should not be more than 10 mm if possible. Through this way the one-sided clamping of the cup-shaped bearing plate 20 is achieved that its hollow cylindrical longitudinal part expand or shrink as desired in the axial direction can, without three changes in length affecting the bearings of the armature shaft can have harmful effects. Only axial changes in length in the bottom part 27, i. H. Changes to the distance D can have the effect of changing the bearing distance. Since the distance v, as said, is kept very small, any changes in length hardly affect the bearing spacing.

Any changes to the dimensions of the cup-shaped end shield 20 in the radial direction cannot affect operational safety as a result the embodiment of the nested parts shown in FIG. To the cup-shaped To offer end shield 20 also sufficient radial evasive options is for the Stator 12 of the motor uses a sheet metal section, the outer boundary line two diametrically opposed circular arcs extending over approximately 90 ° whose end points are connected by straight lines. The inner surface of the cup-shaped bearing plate 20 surrounding the motor stand 12 touches the motor stand so only on two surfaces (60 and 62), which, taken together, about the Extend half of the circumference. The resulting when the end shield 20 shrinks Changes in shape can easily occur in the gaps compared to the straight ones Boundary surfaces 61 and 63 of the motor stand au; work without it being excessive internal stresses in the insulating material.

If the cup-shaped end shield 20 is, for example, due to swelling of the insulating material expands, recesses can be; 64 and 65, which run along the inner The outer surface of the metal housing 13 extends to accommodate such expansions. These Recesses become the flats 61 and 63 of the motor stand during assembly arranged opposite, so that the cup-shaped housing 20 in these zones neither on Motor stand 12 still rests on the metal housing 13 and the properties of the insulating material can result in changes.

The described and illustrated arrangement and design of the insulating material results in more conceivable for everyone. Operating cases a completely safe protection against Contact voltages, because even if the pot-shaped Should the insulating end shield break, the fragments will only move slightly can, but in any case prevent the possibly under operating voltage standing metal parts of the motor come into direct contact with the outer housing.

The hand tool shown in Figure 3 differs of the machine described above essentially only in that the cup-shaped End shield 80 is attached to the pinion side of the motor armature 71 and at the same time is the partition wall forms between the gear housing 74 and the motor housing 73. In contrast to of the machine according to FIGS. 1 and 2 is here also the second bearing plate, denoted by 82 cup-shaped. Like the front end shield, it is on an annular one Collar 83 held in about the same plane as the balls 78 in the end shield 82 recorded ball bearing runs. The clamping surface also runs on the end shield 80, with which it rests against the motor housing, at least approximately in the plane of the Balls 79 of the ball bearing received there. Even with this arrangement the changes in length that may occur in the cup-shaped end shields practically does not affect the bearing distance at all, since the bearing distance is through the metallic motor housing 73 is fixed, while the wall parts of the cup-shaped End shields when stretching or shrinking along the cylindrical bore 85 of the Motor housing 73 can move as desired. In contrast to Fig. 1 are in this Embodiment, the carbon brushes 95 taken in insulating sockets 93 with the end shields 83 and 80 are not connected, but from the outside into the motor housing 73 are fitted.

Claims (4)

PATENT CLAIMS: 1. Hand machine tool with an electric drive motor, which is housed insulated in a metallic outer housing with the help of two bearing shields made of insulating material centered on the outer housing, characterized by the combination of the following features: a) that to achieve an intermediate insulating housing that is as closed as possible between the motor and the metallic outer housing one (20 or 80) of the two end shields is cup-shaped and encompasses the stator of the motor extends into the vicinity of the other end shield, b) that each of the two end shields is fastened against axial displacement on contact surfaces of the outer housing, which in the plane of the ball bearing encompassed by the associated bearing shield run, and d) there, ß the cup-shaped bearing shield has a collar (52) running in the plane of the ball bearing there on its bottom zone, which is located in the joint between the handle (15) and the cylindrical longitudinal part (13 ) of the outer housing uses or is clamped between this and the gear housing (14). 2. Hand machine tool according to claim 1, characterized in that there is between the stator (12) of the motor and the cylindrical. Longitudinal part of the cup-shaped end shield (20) recesses are provided, the total of about half of the inner circumference of the housing make up and extend in the axial direction at least approximately over the length of the stator core extend. 3. Hand machine tool according to one of claims 1 and. 2, characterized in that that between the metal housing (13) and the wall of the cup-shaped end shield (20) recesses (64) are provided which extend axially at least approximately over the length of the stator core (12) and along the surface line of the housing over extend those zones in which the motor stand is not directly on the Inner wall of the cup-shaped end shield rests. 4. Hand tool according to one of claims 1 to 3, characterized in that eyes for receiving the brushes (25) are arranged on the cup-shaped bearing plate (20) in the vicinity of its bottom part (27), protrude through the outer housing and at their passage point len have a radial air gap of preferably 1 mm with respect to the outer housing. Considered publications: German Patent Specifications Nos. 567 127, 830 208; Belgian Patent No. 498,929; British Patent No. 433 013; French Patent No. 751817; U.S. Patent Nos. 2,456,571, 2,532,823.