DE1206067B - Multipole electric rotating machine - Google Patents

Description

Multipole Electric Rotating Machine The invention relates to to a multi-pole electric rotating machine with a stator and a rotor in the form of disk-shaped, an approximately annular, axially extending planes Air gap enclosing elements, at least one of the disc-shaped Elements contains means for generating a magnetic field and at least one of the disc-shaped elements have a continuous winding with inside of the magnetically active area approximately radially lying conductor sections and themselves adjoining it on both sides in the same plane, according to type and course Winding resulting connecting conductors carries.

An electrical machine of this type is from the early days of electrical engineering known. It consists of two concentric commutator rings, between which are free bearing copper rods in two layers at a relatively large angle to the radial direction are stretched, with the inclinations of the copper rods in the two Positions are opposite. The outer commutator ring is exclusive borne by the copper rods. The copper rods are cantilevered in the ring-shaped, plane air gap of the machine and represent the active winding conductors. The whole The arrangement has the structure of a spoked wheel of a bicycle, but with the difference is that the copper bars forming the "spokes" are in the two layers limit axially parallel planes and not, as with a bicycle, after converge outside.

The inclination of the copper rods is not due to mechanical aspects, but determined by the electrical winding step of the machine. At a eight-pole machine, the copper bars are almost tangential to the inner commutator ring. This means that the radially directed centrifugal forces occurring during operation cause very large tensile forces in the copper rods, which are greater by a factor of cos a than the radial forces are. Because copper is relatively soft and ductile If it is metal, such a construction is out of the question for reasons of strength.

The disc armature of this known machine is in the lateral direction completely unstable. The outer commutator ring is only made by the flexural strength the copper rods held in a sideways direction. Since the whole arrangement as a result the elasticity of the copper rods is a vibratory structure, so can Movements in the lateral direction are practically not prevented during operation. However, even with a small amount of these movements, the copper rods strike nicely on the pole faces of the exciter.

Finally, there are practically insoluble difficulties Construction of the commutator rings from individual, electrically isolated commutator blocks.

This machine is just as unfavorable as it is from a mechanical point of view in electrical terms. As the copper rods for reasons of mechanical strength and to achieve a reasonably acceptable electrical resistance, a Must have a relatively large width and also to prevent winding short circuits must be at a sufficient distance from each other and from the pole faces, the magnetic air gap has a very considerable width. In this air gap move winding conductors that are very strongly inclined against the radial direction are. Since only the tangential component of the perpendicular is used to generate the torque contributes to the electromagnetic force standing on the winding conductors, the machine can only emit a very low torque. The conditions become even more unfavorable if the winding conductors incline even more when the number of poles is reduced Need to become.

For these reasons, machines are of this type, as are many others Experiments from the early days of electrical engineering, soon completely abandoned, and the further development moved almost exclusively on apart from the field of radial air gap machines with slot windings and drum anchors of some special designs for special, narrowly limited applications. To this Special designs include, for example, axial air gap small direct current motors with self-supporting or glued onto a thin, disk-shaped insulating material carrier Flat coils that move in the air gap between two permanent magnet rings. One such device works on the principle of electromagnetic attraction and Repulsion of coils and therefore cannot rotate uniformly. Further torque and power are very low. Above all, however, can according to this principle DC or AC machines with any winding shape are not manufactured will.

In other known axial air gap machines, a disk-shaped Rotor without windings is used, while the stator is made from ordinary solenoid coils exists, the end faces of which face the rotor disk. This version is suitable however only for certain types of machines, for example asynchronous motors and Hysteresis motors. They can be produced easily and cheaply, but it is the efficiency achieved is low.

Axial air gap machines have also been designed in which to improve efficiency the windings of the shape of the flat, axial Air gap are adapted. For this purpose the coils became flat sectors wound and in sector-shaped cutouts of the disc-shaped rotor or stator used. However, this makes the production of the machines much more expensive. They are also limited to relatively small torques and powers have therefore only been able to assert themselves where the flat shape of the engine of is crucial.

In contrast, radial air gap machines with slot windings can be used manufactured for practically all conceivable applications and operating conditions will. There are motors and generators for direct current as well as following this principle Single-phase and multi-phase alternating current from very small to very large powers, and there are numerous winding forms to meet the most diverse requirements has been developed.

Nevertheless, some stick to the radial air gap machines with slot windings significant disadvantages. In particular, the individual Conductor bars or previously formed coils individually inserted into the grooves and accordingly connected, isolated and fixed. This production requires skilled workers and is complicated and expensive; nor is it suitable for a fully automated one Mass production. The operating behavior of the machines is due to the well-known groove effect impaired. In addition, there is also the heat dissipation from the ones inserted in the grooves Winding conductors inhibited by the required insulation, so that the machine performance out of consideration of the permissible heating for a given machine weight and given size is relatively limited.

The aim of the invention is to create an electrical Machine at least for smaller performances with the same versatility and adaptability like the well-known radial air gap machines with slot windings, but in a much simpler and especially for automated production suitable processes can be produced.

Starting from a machine of the type specified at the outset, this will be the case according to the invention achieved in that by printing thin flat conductors directly on the insulating surfaces of a flat annular support according to the known Technique of printed circuits the continuous winding is formed which either homogeneously coherent on the same side of the disk-shaped carrier runs or through conductive connections between conductor sections printed on both sides arises that the conductor defines the air gap of the disk-shaped surface Elements predominantly cover and over the entire magnetic air gap of the machine are exposed and that power take-off and power supply devices directly with it are connected to the flat conductors.

The machines according to the invention can be according to the known methods, which are used for the production of printed circuits, very cheap and rational mass-produce, with extensive automation possible. The efficiency is very good because the field profile is more favorable than with classic slot windings is. Another advantage is the improved heat dissipation from the flat conductors to the Winding support compared to the insulated conductors lying in grooves in the conventional machines. This makes it possible for the same performance with reduced Get along with copper weight.

The extraordinary versatility of the view machines according to the invention. It can be practically in the manner indicated manufacture all types of DC and AC machines. By application of the printed circuits it is possible all with the classic machines known radial air gap. To simulate winding processes and for machines with axial, air gap to be used. The advantages of simple manufacture are particularly evident then in appearance when it comes to multi-pole machines, which according to the conventional processes are generally difficult to implement, and their efficiency therefore is low. In the case of the machines according to the invention, the shorter the longer the longer Number of poles the length of the connecting conductor, which even reduces the total resistance of the armature and the copper weight is achieved.

Finally, there is no need to specialize on the machine's rotor To attach commutators or collector rings because the power supply or. Current collection devices attack the printed flat conductors directly.

It should be noted that after the advent of the technology of the printed Circuits already the suggestion was known, this technique also for the production of the windings of electrical machines. But it was only about it thought, the slot guide of a machine adapted to one of the shape of the slots to print insulating carriers and with this about in the grooves one Insert drum anchor or disc anchor. However, this solution essentially has still have all the disadvantages of radial air gap machines with grooved windings.

A preferred embodiment of the invention is that the Flat conductors on both sides of the ring-shaped carrier in two mirror images Sows of identically shaped coil side conductors are arranged, which are attached to the approximately radially extending active conductor sections adjoining connecting conductors are inclined or curved so that their ends in a winding step determining angular distance from each other, and that the on both sides of the annular support opposite ends of these connecting conductors in pairs are electrically connected to one another in such a way that the coil seldom conductors are continuous are connected in series.

In this way, for example, the rotor windings of Manufacture DC and AC machines. Receives the desired winding course by the way in which the sinks on both sides of the support are connected, Rare. The connections can be formed by recesses in the insulating material be or consist of conductive bridges over the edges of the insulating material go away.

For using the printed winding as a rotor winding in the machine there is a possibility that the only from the annular carrier and the Imprinted flat conductors formed disc as a rotor in the annular air gap is arranged, which is limited at least on one side by exciter poles. Through this this results in a particularly small moment of inertia for the rotor.

Another possibility is that of the annular Support and the pressed flat conductors formed on an annular disc Part attached and arranged with this as a rotor in the annular air gap which is limited on at least one side by exciter poles. The ring-shaped Toll can in this case consist of magnetizable material and a yoke to the Closing the magnetic flux form the exciter poles, or it can be made from an electrical one conductive material that allows the formation of eddy currents to dampen the rotor exist.

The stator windings of such machines can be done in the same way be executed. In this case is on both sides of the disc-shaped rotor one of the windings formed from printed flat conductors on the stature of the machine appropriate. The winding carrier is then either an insulating or with an insulating Covered ring made of magnetizable material, or the flat conductors formed on a very thin winding carrier and with this isolated on one ring-shaped magnetizable wreath attached.

In the case of DC machines, however, it is also possible to use each of the exciter poles by forming a permanent magnet. According to a particular embodiment of the According to the invention, a change in the excitation is also possible in such machines, by an axially displaceable magnetizable ring coaxial with the rim of the Exciter bead forming permanent magnets are attached to regulate the excitation of the machine is. Embodiments of the invention are shown in the drawings. In this shows Fig. 1 shows a section through an alternating current machine, FIG. 2 and 3 half Side views of the stator halves of the machine of FIG. 1, from the cutting line from F i g. 1 seen to the left or right, FIG. 4 is a half side view of a executed differently. Stator half, FIG. 5 is a partial front view of one with a rotor provided with a winding, FIG. 6 is a partial sectional view of a machine with the rotor of FIG. 5, Fig. 7 is a view similar to FIG. 6 with another Execution, F i g. 8 shows an axial section through a complete machine the rotor of FIG. 5 and FIG. 9 is a partial view of another embodiment the machine of FIG. 8th.

The simplest embodiment is a multi-pole alternating current machine, in which only the stator carries windings, while the rotor takes the form of a thin one Disc has. An example of this is shown in FIG. 1 to 3 a sixteen-pole two-phase machine shown. The rotor disk 1 is mounted at 2 on a shaft 3, and the stator consists of two greats, which are carried by two half-shells 4 and 5. The half-shells furthermore contain the bearings 6 fit the shaft 3.

The stator has two ring-shaped rings 7 and 8, respectively, made of a magnetizable one Material that are attached to the two half-shells 4 and 5, respectively.

The magnetizable parts of the stator can be made from sintered iron powder or the like. Manufactured with appropriate permeability and resistance properties be. A band of magnetic sheet can be wrapped around each magnetic core in such a way that that it forms a toroidal core laminated parallel to the lines of flux.

The winding conductors are on the magnetizable rings 7 and 8 9 applied in the form of bare flat conductors. This is done according to one of the numerous Processes used to manufacture printed circuits. In F i G. 2 and 3, the winding courses are only indicated by simple lines; in reality they can be coils with many fine conductors. It is known that it is possible to create networks of very fine conductors with very small Print intervals. The active parts of the ladder. lie radial and are through Circular arc-shaped sections connected to each other, which the winding heads are more common Machines correspond.

Since it is in the exemplary embodiment of FIG. 1 to 3 by one Is a two-phase machine, the two stator windings are mutually around one shifted half a step, as is the usual rule for the two windings of one Corresponds to two-phase machine. This is shown in the half-views of FIG. 2 and 3 to recognize.

Each winding is shown in the form of a simple meander. IDles corresponds to the simplest case, because all guides are located on the same area. The application possibility of this version is limited because. it is only suitable for windings where no conductors cross. Flat coils can now also be manufactured using the usual printed circuitry method, whereby the connections crossing the coil conductors (power supply and current discharge) run on the back of the carrier and are connected to the coil conductors by metallized conductive bridges through the carrier. It can then without difficulty windings in FIG. 4 produce the type indicated schematically.

The air gaps must be used to achieve the greatest possible efficiency be as small as possible. Therefore it is advantageous by molding or machining to provide the parts that carry the coils with grooves in which the conductors are formed so that smooth air-gap surfaces are obtained. This is with windings with relatively large winding pitch possible. For coils with a tight winding pitch the same effect can be achieved in that first the coils z. B. by a light printing process can be imprinted, creating the winding in relief form the magnetic surface of the carrier is formed, and that then the spaces between the conductors are filled with a magnetizable material in such a way that that a smooth surface is obtained. This order can initially cover the ladder, which are then exposed by grinding the entire surface. The order can e.g. B. be formed from a colloidal solution of iron powder. Possibly finally, an insulating film can be made by any method known per se on the surface of the magnetic material of the annular rims and that on them formed winding conductors are formed. If the winding carrier consists of an electrical Conductive material is made of course before the winding is printed on insulating coating applied.

The rotor in many types of AC machines consists of one Disc with no winding. This disc can be made of soft iron (im Case of asynchronous motors) or from a hysteresis steel (hysteresis motors), or it can be a composite disc which e.g. B. contains copper and iron.

In numerous applications, especially audio frequency generators, DC machines and universal machines, the rotor must have at least one winding and still stay completely flat. You then make this winding as in the previous one described case the stator windings on the type of printed circuits. These Windings are preferably made by printing the carrier on both sides, because it is possible to have any winding course, for example a To simulate series wave winding.

An example of such machines is shown in FIG. 5 to 9 a DC machine shown. The rotor in this version consists of an insulating thin one Plate 11, the thickness of which is, for example, of the order of a millimeter. On the plate 11, a double-sided winding 12 is formed, which a plurality contains of spatially overlapping turns and z. B. closed in itself is. Looking at the partial view of FIG. 5, in which only a few turns are shown you can see the winding pitch of the turns and their actual shape. They consist of radial parts 13, which form a ring, the ring-shaped Wreath of the magnetic poles 16 of the stator is opposite. The radial part of each turn is extended at one end by a curved section 14, which the winding head forms for this turn, while the other end is curved by another Part 15 is extended, which here contributes to the formation of the collector. The connections between the conductors of the two disks are each over the edges of the carrier disk 11 manufactured. However, they can also be formed by having conductors through Openings in the insulating support 11 are passed.

The winding can be formed, for example, by light printing from two copper foils which have previously been glued to the two sides of an insulating plate which has previously been cut into a circular ring of the desired dimensions. The following procedure can then be used to form the numerous required connections from one side to the other side of the windings: Each foil is galvanoplastically coated with two rings made of indium or a similar material, the inner diameter of one ring being equal to the outer diameter of the insulating support and the outside diameter of the other ring is equal to the inside diameter of the carrier. The foils coated in this way are attached to the carrier - in such a way that the rings are opposite each other. - Then the conductors and also tongues protruding at each end of the conductor are formed on both sides using the photographic printing process. To make the connections, it is then sufficient to press the opposing pairs of tongues together, since the applied material, indium being a typical example, has been selected in such a way that it can be cold-welded by simple pressure applications.

The stator may be provided with windings similar to those of F i g. 1 to 4 correspond. In the case of smaller DC machines, however, it is common a permanent magnet excitation is preferable. This case is when running from F i g. 5 to 9 accepted. The magnetic poles 16 of the machine are small Permanent magnets formed with alternating polarity on an annular magnet yoke 18 are arranged and each wear a pole piece 17. All permanent magnets are arranged on the same side of the rotor. To close the magnetic flux a ring made of magnetizable material is attached to the other side of the rotor. There are two possibilities for this, which are shown in FIG. 6 and 7 are shown.

In the example of FIG. 6, the annular yoke 18 is fixed to the stator appropriate. The rotor rotates between the two stator elements, and there is an air gap on each side of the rotor.

In performing FIG. 7 there is only one air gap because here the annular yoke 19 is mounted on the rotor and rotates with it. This design results in a larger moment of inertia for the rotor.

The complete machine using the rotor of FIG. 5 and the yoke arrangement of FIG. 7 is in FIG. S shown. The rotor is mounted on a hub 20 fixedly connected to the shaft 3. The shaft is mounted in slide bearings 21 which are held in carriers 22 and 23 by means of clamping rings 24. The stator is screwed onto a base plate 25. The base plate 25 carries a support ring 26 for the resiliently mounted current collector brushes 27. It can be seen that the coals of these brushes rest on the parts 15 (FIG. 5) of the windings of the rotor.

In Fig. 8 is also a measure to change the arousal shown when using permanent magnets. For this purpose is a magnetic Shunt ring 28 mounted on pins 29 which are carried by a plate 30. This plate is fixed to the base plate by means of a threaded rod 31 25 connected disc 32 attached. A knurled wheel 33 enables the setting the axial position of the plate 30 and thus the axial position of the magnetic shunt ring 28.

To achieve a damping effect, the winding of the rotor be formed on a disc that is not insulating, but made of a conductor, such as copper, aluminum or even iron or a combination of these metals. The eddy currents that then arise in this conductor material generate in a known manner Way a braking torque, which is proportional to the speed, because the conductive disc acts like a short-circuited secondary winding of the rotating part. In the Production can easily regulate the size of the braking torque, as this is known is inversely proportional to the electrical resistance of the disc, this being Resistance from such factors, e.g. B. the thickness and the specific resistance depends on which can be changed as desired when building the engine.

In Fig. 9 is one of the embodiment according to FIG. 8 different Type of power supply to the rotor winding shown. The brushes of the motor are arranged on a ring 35. They are regularly distributed around the circumference of the wreath and since electrical terminals 36 connected. Each brush has a conductive pair Leaf springs 37, each of which carries a holder 38 for a roller 39. Each The pair of rollers is therefore pressed elastically onto the circumference of the rotor disk of the motor. The roles are z. B. made of silver or other suitable material. The brushes thus grip the conductor sections 14 which form the end windings at.

The invention is in the entirety of the main claim characterizing Features seen.

Claims (25)

Claims: 1. Multi-pole electric rotating machine with a stator and a rotor in the form of disk-shaped, an approximately ring-shaped, axially extending planar air gap enclosing elements, wherein at least one of the disk-shaped elements contains means for generating a magnetic field and at least one of the disk-shaped elements is a contiguous, continuous one Winding with conductor sections lying approximately radially within the magnetically active area and adjoining it on both sides on the same level, according to type and course the winding resulting connecting conductors, characterized in that Printing thin flat conductors directly onto the insulating surfaces of a flat annular support according to the known technology of printed circuits the continuous Winding is formed that is either homogeneously contiguous on the same side of the disk-shaped carrier runs or through conductive connections between Conductor sections printed on both sides results in the conductors forming the air gap Bounding area of the disk-shaped element predominantly cover and over the entire magnetic air gap of the machine are exposed and that current consumption and Power supply devices are directly connected to the flat conductors. 2. Machine according to claim 1, characterized in that the flat conductors on both Sides of the annular support in two mirror-inverted sets of identically shaped coil side conductors are arranged, which are approximately radially running active conductor sections adjoining connecting conductors inclined in this way or are curved so that their ends are angularly spaced at an angular distance which determines the winding pitch are from each other and de each other on both sides of the annular support pairs of opposite ends of these connecting conductors electrically so with each other are connected that the coil side conductors are continuously connected in series. 3. Machine according to claim 2, characterized in that the connections between the ends of the connecting conductors formed by recesses in the insulating material are. 4. Machine according to claim 2, characterized in that the connections between the ends of the connecting conductors consist of conductive bridges, the over the] edges of the insulating material go away. 5. Machine according to one of the claims 1 to 4, characterized in that the only of the annular carrier and the Imprinted flat conductors formed disc as a rotor in the annular air gap is arranged, which is limited at least on one side by exciter poles. 6th Machine according to one of Claims 1 to 4, characterized in that the ring-shaped carrier and the printed flat conductors formed disc on a attached annular part and with this as a rotor in the annular air gap is arranged, which is limited on at least one side by exciter poles. 7th Machine according to claim 6, characterized in that the ring-shaped part is made of magnetizable Material is made and forms a yoke for closing the magnetic flux of the exciter poles. 8: Machine according to claim 6, characterized in that the annular part consists of an electrically conductive, the formation of eddy currents to dampen the rotor permitting material. 9. Machine according to claim 2, characterized in that that the annular carrier is a disk insulated from the printed flat conductors of electrically conductive material between the two sets of coil side conductors contains and is arranged as a rotor in the annular air gap, which is at least one Side is limited by exciter poles. 10. Machine according to one of claims 5 to 9, characterized in that each exciter pole by a sector coil from a Flat conductor winding is formed on a wreath of a magnetizable Material is attached. 11. Machine according to claim 10, characterized in that that the radial conductor sections of the sector coil lie in grooves in the ring made of magnetizable material are attached. 12. Machine according to claim 10 or 11, characterized in that the ring consists of a sintered magnetizable Material. 13. Machine according to one of claims 10 to 12, characterized in that that the wreath made of the magnetizable material from a winding made of magnetic sheet is surrounded. 14. Machine according to one of claims 5 to 9, characterized in that that each of the excitation poles is formed by a permanent magnet. 15. Machine according to claim 14, characterized in that an axially displaceable magnetizable Ring coaxial to the ring of the permanent magnets forming the exciter poles for change the excitation of the machine is appropriate. 16. Machine according to claim 1, characterized characterized in that on both sides of the disc-shaped rotor each one of the Windings formed by printed flat conductors are attached to the stator of the machine is. 17. Machine according to claim 16, characterized in that the flat conductor are arranged in the form of a meander. 18. Machine according to claim 17, characterized in that that the flat conductors are formed into flat coils and that they cross the flat coils Connecting conductors run on the back of the carrier. 19. machine after one of claims 16 to 18, characterized in that the winding carrier is an insulating or is provided with an insulating cover ring made of magnetizable material. 20. Machine according to one of claims 16 to 18, characterized in that the Flat conductor formed on a very thin winding support and insulated with this are mounted on a ring-shaped magnetizable wreath. 21. Machine after one of the preceding claims, characterized in that between the flat conductors on the entire surface of the winding support facing the air gap, an insulating one magnetizable order is attached, which cuts off with the surfaces of the conductors. 22. Machine according to claim 21, characterized in that the order of particles of a magnetic material in a dielectric binder. 23. Machine according to claim 2 and one of claims 5 to 9, characterized in that to at least one pair of brushes belongs to the power take-off and power supply devices, that grinds on the inclined or curved connecting conductors. 24. Machine according to claim 23, characterized in that the brushes are arranged axially and rest on the same side of the winding. 25. Machine according to claim 23, characterized in that the brushes contain rollers with a radial axis, pinching the circumference of the winding between them, and at least one of them is conductive. Publications considered: German Patent Specifications No. 25 012, 43 298, 45 808, 157 152, 217 086, 226 725, 295 047, 295 225, 708 014, 839 062, 912 713, 966 475; German patent application W 6345P21d1 (published 11/25/1954); Swiss Patent No. 311376; British Patent No. 127,488; U.S. Patent No. 2,441,960; "Wireless World" magazine, December 1952, p.488.