DE1538180A1 - Single-phase synchronous motor with permanent magnet rotor - Google Patents

Description

Single-phase synchronous motor with permanent magnet rotor The invention aims A single-phase synchronous motor with permanent magnet rotor, which has a strong torque has to be designed as small as possible and in a compact, circular-cylindrical shape. It is intended in particular as a drive for control devices, counters and the like Find use.

It is characteristic of the motor according to the invention that two are magnetic claw pole systems connected in series are provided and the rotor has two pole wheels has, between which a permanent magnet magnetized in the axial direction is arranged is and that each claw pole system is assigned a pole wheel, the pole widths are dimensioned so that a rotor pole is approximately flush with two adjacent claw poles is.

The stator magnet system consists of a cylindrical inner wall, a concentric, cylindrical outer wall and two side walls, so that an annulus is formed which contains the winding. Preferably they are Claw pole systems on the inner wall of the magnet designed in such a way that the Inner wall has two serpentine wound openings and is thereby divided into three claw-like interlocking tooth crowns. The rotor lies inside the magnet system and is coaxial with it, so that the rotor poles stand vertically on the claw poles. The rotor can by means of two bearing caps be stored, which are fitted on the front sides in the magnet system.

Another embodiment results when the claw poles on the one hand on the edges of the inner wall and, on the other hand, on the inner edges of the side walls are formed, the poles of opposite polarity perpendicular to each other stand. In this case, the rotor's pole wheels move further apart and the The rotor poles are partly directly opposite the claw poles and partly perpendicular to them.

The following is an embodiment of the invention in greater detail explained. The same parts are given the same reference numbers in the various figures Mistake.

1 shows a longitudinal section through the motor according to the invention.

FIGS. 2 and 35 show a line section according to the section lines AB and CD in FIG. 1.

FIG. 4 is a perspective illustration of the cut-open magnet system without bearings, and FIG. 5 is a corresponding illustration of the rotor.

FIGS. 6 to 9 show fragments of the development of the inner wall of the magnet system, two rotor pole surfaces each being shown hatched. The four representations illustrate the migration of the rotor poles in the course of an alternating current period. According to FIGS. 1 to 1, the outer wall of the magnet system is denoted by 1. Side walls 2 and 3 are provided with inwardly facing tooth crowns and thus form parts of the inner wall. The double-sided toothed middle piece 4 of the inner wall forms with the where their distance and mutual angular position are adjusted, the winding is wound onto the resulting coil - optionally with the interposition of insulating material. The winding is now impregnated with a hardenable potting compound, generally a casting resin. After hardening, the winding, insulation material and the three individual parts of the coil are consolidated into a block. Finally, the outer wall 1 is attached. A modification of this process consists in coating the inside of the coil with plastic, for example in an injection molding process. As a result, the coil is already solidified before winding and can be removed from the 15orn. The serpentine gaps 6 and 7 are also always filled with the potting compound or the plastic. In this respect, the term air gap is not applicable. The operation of the motor is not affected by this filling. In the manner of a diagram, FIGS. 6 to 9 show the migration of the rotor poles in four different phase positions. The same part of the development of the two claw systems is considered in each case. The rotor poles move relative to this development. The hatched illustration shows the pole faces 16a and 17a (compare FIG. 5) each of a pole of the two pole wheels 16 and 17 . As can also be seen from FIG. 2, the rotor poles are approximately flush with two adjacent claw poles, ie. H. the pole faces cover two adjacent claw poles and the air gap between them. Fig. 6 shows the rest position in which the winding is not energized. Die.Rotorpole occupy the position in the * I can close the flux of the permanent magnet on the path of least resistance-Nazi to gne. This is the position shown. One part of the permanent magnet lumbar goes the short way over the middle piece 4 and the other part the 19 ffl ren way over toothed crown 2a, side wall 2, outer wall 1, side wall 3 ed toothed cranes 3a. It is assumed that the permanent magnet has a north pole on the side facing the pinion. The permanent magnetic flux therefore exits at pole face 16a (north pole) and re-enters at pole face 17a (south pole).

If the winding is now excited, according to FIG. 7 , north poles may be formed on tooth crown 2a and south poles on tooth crown 3a. Accordingly, the claw poles represent 4 south poles on the left side of the middle section and 4 south poles on the right side, as shown. Since poles of the same name repel and unlike poles attract, the rotor poles start moving in the direction of arrows 23 and 24 (FIG. 6) and take the position shown in FIG. 7 at the stroke maximum.

While the magnetic flux originating from the field winding is subsequently reduced, the rotor poles migrate beyond the position shown in FIG. 7 as a result of the inertia of the rotor mass. The Krart of the permanent magnet becomes more and more apparent until the poles according to FIG. 8 have been set at the zero crossing of the excitation current.

The mechanism of action now continues with the opposite sign. In Fig. 9, the negative current maximum is shown in which the polarity of the claw pole with respect to FIG. 7 has umgekphrt. The rotor has now moved on by two claw pole teeth and a gap. At the next zero crossing of the excitation current, the position of the rotor will be shifted by one pole pitch compared to FIG. 6.

Claims (1)

Claims single-phase synchronous motor with Dauerwagnetläufer, gekennzeit2hnet characterized .. that two magnetically Series-connected claw pole systems are provided, and the rotor has two pole wheels (16, 17), between which is disposed an axially magnetized permanent magnet (15), and that each Klauenpolsystem a pole wheel is assigned, the pole widths being dimensioned so that a rotor pole (13) is approximately flush with two adjacent claw poles. 2. Motor according to claim 1, characterized in that the stator magnet system consists of a cylindrical inner wall (# -, a, --a, 4) of a concentric, cylindrical outer wall (1) and two side walls, so that an annular space is formed , which contains the winding (5) . Blotor according to claims 1 and 2, characterized in that the claw pole systems are designed on the inner wall in such a way that it is divided into three claw-like interlocking tooth crowns by two serpentine openings (6, 7). 4. Motor according to claim 1 to 3, characterized in that the middle, double-sided toothed crown (4) is attached to the winding by means of a hardenable casting compound which also impregnates the winding. 51 Motor according to Claims 1 to 4, characterized in that the pole wheels are flat circular disks on which tooth-shaped poles are formed by notches in the edge. j6. Motor according to Claims 1 to 5, characterized in that a backstop (20, 21) is provided which allows the rotor to rotate in only one direction.