DE1538715B1 - ELECTRIC MACHINE WITH SPHERICAL AIR GAP - Google Patents

Description

The invention relates to an electric machine with permanent-magnetic and / or soft revolving pole ring with permanent or induced poles and a soft-magnetic, a rotary field generating pole ring with rotating magnetic poles and between the Polrin- gen extending air gap, which runs on an imaginary sphere, so that a pole ring with its concave side and the other pole ring with its convex side faces the air gap.

Dynamo-electric clutches of such a design are known (US Pat. No. 1,568,304). There are also motors with a spherical air gap and wobble mounted rotor are known (British Patent 259,133), in which the rotor is annular and is mounted at only one support point. These motors are either provided with a weight, which is arranged below the bearing point and holds the bearing shaft vertically, or they are mounted in an unstable manner.

The invention has for its object to avoid the disadvantages of increased weight or an unstable storage of electric motors of the known type mentioned above. It achieves this in that the centers of the magnetic poles of the convex pole ring are on a first level, that the centers of the rotating magnetic poles of the concave pole ring are on a second level and that the convex pole ring is supported against the concave pole ring via a spherical bearing gap, wherein the plane of the magnetic centers of the convex pole ring lies between the plane of the poles of the concave pole ring and the center of the sphere of the spherical sliding surface. In the inventive assignment of the magnetic poles and the spherical center to one another, the magnetic poles of the driving pole ring on the one hand and the driven rotor on the other hand lie on spherical shells, which preferably run radially to the spherical center of the spherical bearing. This gives the rotor a stable position on its geometric axis, from which it can be swiveled temporarily due to disturbing torques, but to which it returns again precessing. The precession movement does not cause any stressing forces on the plain bearing. Axial fixation of the rotor can also be achieved by additional axial magnetic fields that do not generate any rotational moment. This type of magnetic fields allows the use of e.g. B. identically polarized permanent magnet pairs. in which one partner is stationary and the other is mounted rotating, and is particularly advantageous for electrical machines whose rotor would no longer be axially held when the current was switched off.

The principle according to the invention is used with advantage in flow machine construction. A partition in the spherical air gap between the two Polrinoes allows the hermetic separation between two media. The partition is made of magnetically permeable material which has no or only a relatively low electrical conductivity. The rotor, which at the same time carries the blades of the turbomachine, is supported by a bearing column. which is attached to the partition or is formed from a part of the partition . The partition itself can also be designed as a spherical bearing surface: it can also form a unit with the housing wall of the turbo machine on the motor side.

With machines. operatively working with a horizontal axis of rotation, the influence of the gravity field of the earth can be eliminated on the position of the rotor is effected by a weight balance, the opposite through a mass magnification at which the magnetically active hemisphere side of the rotor. In flow machines the gap formed between the rotor and the suction nozzle can extend concentrically with the center of the spherical bearing on a spherical surface.

The magnetically active hemisphere of the rotor of the electric machine can be constructed so that the current environmentally pole ring of soft magnetic material and is provided with a cap of electrically highly conductive material. The driving pole ring of the electric machine can be designed as a laminated core with dynamo laminations either parallel or perpendicular to the plane of rotation.

The invention is to be described in more detail below with reference to figures will.

Fig. La shows an electric machine according to the invention schematically.

F i g. 1 b shows a bearing detail.

F i g. 2 shows a rotor support according to the invention.

F i g. 3 shows a motor with a ring iron core. F i g. 4 shows one Motor with a horseshoe core.

F i '-. 5 shows a pole ring of a four-pole motor according to the invention.

Fig. 6 shows a rotor with blades.

Fig. 7 shows a pump runner of the same type in a mass-equilibrated design.

FIG . 1 a schematically shows, in section, the rotating pole ring 1 and the rotating field generating = pole ring 2 of an electric motor according to the invention. The air gap between the two pole rings runs on a spherical surface. In it, a partition 3 made of magnetically permeable material is arranged, which hermetically separates the space of the rotating pole ring 1 from the space of the rotating field generating pole ring 2. The design of the pole rings is such that the centers 4 and 5 of the isodyne names lie on conical shells, so that the plane 6 assigned to the centers 4 of the unilateral pole ring 1 is at a smaller distance from the center of the sphere 7 than the plane 8 on which the centers are located 5 of the rotating field generating pole ring 2 lie. In the center of the sphere 7, the rotating pole ring 1 is supported by the bearing column 9.

F i g. 1b shows enlarged the formation of the support surface in the center of the sphere 7, which consists of a convex sliding surface 10 and a socket 11 with a concave sliding surface 12, the boundary 13 of which does not extend into the plane of rotation 14 passing through the center of the sphere 7.

Through the described assignment of the centers 4 and 5 of the isodyne names the rotating field generating pole ring 2 not only applies a torque to the rotating one Pole ring 1 transferred, but at the same time the pole ring 1 is also due to the magnetic forces held in its position and. if he is brought out of this position by a disturbance was moved back into this position.

F l g. 2 schematically shows a rotating pole ring 1 and a pole ring 2 generating a rotating field, a bearing column 9 and, arranged in the inner area of the pole ring 1 , a permanent magnet, the outer ring area 20 of which forms one pole and the inner circular surface area 21 forms the second pole. To fix the pole ring 1 in its position, a second stationary permanent magnet is arranged at a distance and on the side opposite the bearing column 9, which magnet is magnetized in the same direction. The repulsive forces acting as a result between the pole regions 20, 20 'and 21, 21' of the same polarity press the rotating pole ring 1 firmly onto its bearing seat 10.

In Fig. 3 shows a motor with a ring iron core. the Iron sheets 31 form the rotating field generating pole ring 2. One leg 32 is of a coil 33 surrounded by a bobbin 34, while the parallel to it Leg 35 has a hemispherical cavity 36. A bearing bracket 37 from Non-magnetic material carries a bearing column 9, the top of which with the center 7 of the cavity 36 coincides. Short-circuit rings are used to generate a rotating field 38 and 38 'are provided. The rotating pole ring 1 consists of a soft magnetic one Core and serving as a short-circuit winding cap 39 made of a good electrical conductor Material, such as copper. The soft magnetic core is penetrated by the magnetic flux, Eddy currents are formed in the cap 39, which induce magnetic poles, as a result of which the pole ring 1 is set in rotation.

Fi g. 4 shows a similar electrical machine with a horseshoe-shaped one Iron package of the rotating field generating pole ring 2. The sheets 41 are parallel here designed to the plane of rotation. which leads to a very flat embodiment.

F i g. 5 shows schematically a rotating field generating section Pole ring 2 of a 4-pole motor. The sheets 50 also run parallel to the Plane of rotation. Two main poles 51 and 51 'are wound with coils, of which in the figure shows only the coil 52, while the secondary poles 53 have no winding wear. Both of the main poles and the minor poles are split poles 54 and 54 'split off and provided with short-circuit rings 55 and 55'.

F i g. 6 shows a rotating pole ring 1 which forms a unit with a pump rotor 60. The cover plate 61 of the pump rotor 60 forms a spherical gap 63 with a stationary suction connection piece 62 so that the rotor 1, 60, 61 can perform wobbling movements without the cover plate 61 touching the suction connection piece 62.

F i g. 7 shows a similar rotating pole ring 1, which forms a pump rotor, with pump blades 60 and a cover plate 61, the weight of the cover plate being kept so great that the rotor 2, 60, 61 is equilibrated with the center 7 of the sphere. This prevents the pump rotor 1, 60, 61 from pivoting when the axis is horizontal.

Claims (14)

Claims: 1. Electric machine with permanent magnetic and / or soft magnetic revolving pole ring with permanent or induced poles and a soft magnetic, a rotating field generating pole ring with revolving magnetic poles and an air gap running between the pole rings, which runs on an imaginary sphere, so that a pole ring with its concave side and the other pole ring with its convex side facing the air gap, characterized in that the centers of the magnetic poles of the convex pole ring (1 ) lie on a first plane (6). that the centers (5) of the rotating magnetic poles of the concave pole ring (2) lie on a second plane (8) and that the convex pole ring (1) is supported against the concave pole ring (2) via a spherical bearing gap (10, 12), wherein the plane of the magnetic centers (6) of the convex pole ring (1) lies between the plane (8) of the poles of the concave pole ring (2) and the center of the sphere (7) of the spherical sliding surface (10, 12). 2. Electrical machine according to claim 1, characterized in that the circumferential pole ring (1) has a recess (15) which extends at least to the center (7) of the imaginary ball and that a bearing column (9) fixed to the pole ring (2) is connected and has concave or convex spherical sliding surfaces (10) which forms a sliding bearing with a corresponding sliding surface (12) of the rotating pole ring (1). 3. Electric machine according to claim 1 or 2, characterized in that in the spherical air gap a Hermetically sealing wall (3) runs. 4. Electric machine according to claim 3, characterized characterized in that the partition (3) consists of a magnetically permeable and electrically poorly conductive material. 5. Electric machine according to claim 1 or 2, characterized in that the rotating pole ring (1) is pressed by stationary magnetic forces against a support surface (10) which is firmly connected to the pole ring (2). 6. Electrical machine according to claim 5, characterized characterized in that the stationary magnetic forces magnetized by homopolar Permanent magnets are formed. 7. Electrical machine according to claim 1 or 2, data carried in that the pole ring (2) is formed from par- allel extending perpendicular to the plane of rotation plates (41). B. Electric machine according to claim I or 2, by DA in that the pole ring is formed (1) perpendicular to the plane of rotation plates (32). 9. Electric machine according to claim 1 or 2, characterized in that the rotating pole ring (1) made of soft magnetic Material consists and with a cap (39) made of electrically good conductive material is provided. 10. Electrical machine according to claim 1, characterized in that the Center of gravity of the rotating pole ring (1, 60, 61) approximately with the center of the sphere (7) coincides. 11. Electrical machine according to claim 1, characterized. that the rotating pole ring (1) with a turbo-engine rotor (60, 61) a Unity forms. 12. Electrical machine according to claim 4 and 11, characterized in that that the partition (3) with the motor-side housing wall of the flow machine housing forms a unit. 13. Electrical machine according to claim 1, characterized in that that the gap (63) formed between the rotor and the suction port (62) on a Spherical surface runs concentrically with the center (7) of the spherical bearing. 14. Electrical machine according to claim 2, characterized in that the convex spherical Area is formed by a sphere.