DE4224628A1 - Fractional horsepower miniature electromotor - has lobes which bend over return ring after it is pushed onto pole housing to fix ring in place - Google Patents

Abstract

The motor has a pole housing (10) of magnetically conductive sheet metal, which carries magnet poles. It also has a magnet return ring (11), also made of magnetic conductive sheet material, closely surrounding the housing (10) to increase the magnet return cross-section. The return ring (11) projects beyond the housing (10) at both ends (102-103). In the extending regions (12, 13), several lobes (14, 15) are cut out of the return ring (11) at angles, staggered around the circumference. The lobes (14, 16) are bent over in a radially inwards direction onto the housing (10), after the ring (11) is pushed onto the housing (10) so that they overlap the ends (102, 103) without any play in the axial direction. ADVANTAGE - Simple and inexpensive to mfr. offering greater mfg. flexibility.

Description

State of the art

The invention is based on a small electric motor in Preamble of claim 1 defined genus.

In such small electric motors, the pole housing preferably made of corrosion-protected sheet metal, e.g. B. sendzimir galvanized iron sheet with a thickness of up to 3 mm bent. Due to the cathodic remote protection effect the cut edges are also protected against corrosion. At required greater engine power becomes the Magnetic flux line through larger iron cross section the additional surrounding the pole housing Return ring provided. The yoke ring is made of the same corrosion-protected sheet metal produced. By dividing this for the magnetic flux required iron cross section on the two thin Sheets of pole housing and yoke ring can Reaching the required iron cross section  surface-protected sheets with usual sheet thicknesses be used, which is easy in its workability are manageable and not very powerful Processing machines require. Because of the low Sheet thickness is also a good protection against corrosion given the cut edges, so that a subsequent galvanizing - like this with a one-piece Component with a sum of the sheet cross sections appropriate iron cross section for corrosion protection would be indispensable - not applicable.

In a known small motor of this type (DE 28 10 215 C1) the yoke ring is immediately around that as a rolling mandrel serving pole housing bent around and in this position fixed. The yoke ring is tight around that Pole housing placed and sits completely without play, by pure force fit firmly and immovably on the Outer surface of the pole housing.

Advantages of the invention

The small electric motor according to the invention with the characterizing features of claim 1 has the advantage a much simpler in terms of production technology and cost-saving manufacturing with large Manufacturing flexibility. The yoke ring becomes easy tightly pushed onto the pole housing and by bending the rag is fixed on the front of the pole housing. The Sliding on the return ring is only at the end of Production line necessary, so that in the production line Uniform workpiece carrier for all small motors both can be used with or without an additional pole ring can. Any welding or gluing of the yoke ring, what would cause additional costs is eliminated. By simple additional measures are also an anti-twist device  and a radial lock of the return ring on the Pole housing possible.

By the measures listed in the other claims are advantageous further developments and improvements in Claim 1 specified small electric motor possible.

In a preferred embodiment of the invention, the Rags in at least one protruding area in the tip Cut the angle to the ring axis so that the on the Lobe edges are supported on the end face of the pole housing when the flaps taper from the flap base to the flap tip run obliquely. Through this constructive measure high manufacturing reliability is achieved. The Tapering of the inner edges of the flaps ensures when folded over always an axial one on the end face of the pole housing The yoke ring is firmly seated on the pole housing. This can to a tolerance refinement and thus to reduce costs used in manufacturing, d. H. the tolerances for the axial lengths of the pole housing and yoke ring and also for the axial distance between the lobes in the two Protruding areas of the return ring do not need to be narrow to be measured.

According to a preferred embodiment of the invention the tabs in the other protruding area perpendicular to Ring axis cut free. The facing this rag Front side of the pole housing is with radial flanks having axial recesses, and the tabs have turned so far that they are each on one of the Radial flanks of the recesses in the circumferential direction without play issue. So that the yoke ring is simple secured against rotation on the pole housing.  

In addition, the free ends of the on the radial flanks rag by about 90 ° on the inner wall of the Pole housing bent, so is also one Radial locking for the yoke ring realized.

drawing

The invention is illustrated in the drawing Exemplary embodiments in the description below explained in more detail. Show it:

Fig. 1 is a plan view of a pole housing with a yoke ring of a small electric motor,

Fig. 2 is a view of the small electric motor in the direction of arrow II in Fig. 1,

Fig. 3 shows the same representation as in Fig. 2 of a modified small electric motor.

Description of the embodiments

Of the small electric motor, only its pole housing 10 is shown in FIGS . 1 and 2, on the inner wall 101 of which the magnetic poles, preferably permanent magnet poles, are offset from one another by the same circumferential angle. The magnetic poles, like the rotor with armature winding and commutator, which is rotatably mounted in the interior of the pole housing 10, are not shown. The pole housing 10 is open on the two annular end faces 102 , 103 and can be closed with lids, also not shown. The covers are usually designed as a bearing plate for the rotary mounting of the rotor. The pole housing 10 , which also forms the magnetic yoke for the magnetic flux passing through the magnetic poles, is made of corrosion-protected sheet metal, for. B. Sendzimir galvanized iron sheet, with a thickness of up to 3 mm.

On the pole housing 10 this tightly enclosing yoke ring 11 is pushed, which is also made of a magnetically conductive, corrosion-protected sheet metal, for. B. Sendzimir galvanized iron sheet, is made up to a sheet thickness of 3 mm. The yoke ring 11 has a somewhat greater axial length than the pole housing 10 , so that it protrudes somewhat above the pole housing 10 on the two end faces 102 , 103 thereof. In the two protruding areas 12 , 13 , several, here three (see FIG. 2), cut out from the yoke ring 11 , tabs 14 and 15 offset by the same circumferential angle. While the flaps 15 are cut free in the over standing portion 13 at right angles to the ring axis, the tabs 14 are cut in the over standing portion 12 at an acute angle to the axis of the ring so that its the front side 102 of the yoke 10 respectively facing cloth edge 141 with tapering of the tabs 14 of the lobe reason for flap tip runs obliquely. After the yoke ring 11 has been pushed onto the pole housing 10 , the tabs 14 , 15 are bent inwards in the direction of the radial, whereby they overlap the end faces 102 , 103 of the pole housing 10 . The flaps 15 are first bent inward and then the flaps 14 . Due to the inclined position of the inner flap edge 141 of the flaps 14 , the pole housing 10 is pushed against the inner flap edges 151 of the flaps 15 when the flaps 14 are bent in, so that the yoke ring 11 is held on the pole housing 10 axially without play. By bending the flaps 14 to a greater or lesser extent in the radial direction, both relatively large tolerance ranges in the axial lengths of the pole housing 10 and the yoke ring 11 and tolerance ranges in the distance between the flaps 14 , 15 can be compensated for.

In a modified embodiment of the small electric motor outlined in FIG. 3, axial recesses 16 with radial flanks 17 , 18 are introduced in the end face 102 of the pole housing 10 ′ which is assigned to the protruding area 13 with the tabs 15 cut free at right angles to the ring axis. These recesses 16 are offset from one another by the same circumferential angle as the tabs 15 . After pushing back the yoke ring 11 , these tabs 15 are now bent so far that they rest against a radial flank 17 of the recesses 16 without play. So that the yoke ring 11 is secured against rotation on the pole housing 10 '. In addition, the free ends of the tab 15 can be bent by about 90 ° to the inner wall 101 of the pole housing 10 ', whereby the yoke ring 11 is also firmly pulled in the radial direction on the pole housing 10 '.

Claims (5)

1. Small electric motor with a magnetic pole bearing pole housing made of a magnetically conductive sheet and with a to enlarge the magnetic yoke cross section closely surrounding the pole housing yoke ring made of a magnetically conductive sheet, characterized in that the yoke ring ( 11 ) on both end faces ( 102 , 103 ) of pole housing (10; 10 ') protrudes about this and that (12, 13) has a plurality of circumferential angle mutually offset tabs (14, 15) cut free from the yoke ring (11) and by sliding the yoke ring (11) in the two About standing areas the pole housing ( 10 ) towards the radial inwards, the end faces ( 102 , 103 ) of the pole housing ( 10 ; 10 ') are bent over axially without play. 2. Motor according to claim 1, characterized in that the tabs ( 14 ) in at least one protruding area ( 14 ) are cut out at an acute angle to the ring axis so that each on the end face ( 102 ) of the pole housing ( 10 ; 10 ') itself supporting flap edge ( 141 ) when the flap ( 14 ) tapers obliquely from the flap base to the flap tip. 3. Motor according to claim 2, characterized in that in the other protruding area ( 13 ) the tabs ( 15 ) are cut perpendicular to the ring axis. 4. Motor according to claim 3, characterized in that the right-angled cut tab ( 15 ) associated end face ( 103 ) of the pole housing ( 10 ') has axial recesses ( 16 ) with at least one radial flank ( 17 ) and that the tabs ( 15 ) are bent so far that they bear against the radial flanks ( 17 ) of the recesses ( 16 ) in the circumferential direction without play. 5. Motor according to claim 4, characterized in that the free ends of the on the radial flanks ( 17 ) of the recesses ( 16 ) adjacent tabs ( 15 ) by about 90 ° on the inner wall ( 101 ) of the pole housing ( 10 ') are bent.