DE527043C - Asynchronous rotating single or multi-phase machine acting as a motor or generator - Google Patents

Description

German Empire

ISSUED AH JUNE 13, 1931

REICH PATENT OFFICE

PATENT LETTERING

M 527043 CLASS 21 d ² GROUP

A 54788 VHIbisid ² Day of the announcement of the grant of the patent:

General Electricity Society in Berlin *)

Asynchronous machines are known to be tied to the proximity of the synchronous speed insofar as they only work there with a favorable degree of efficiency and satisfactory operating characteristics. The synchronous peripheral speed V ₀ is given by the pole pitch P and the number of periods / of the supplied alternating current, namely it is

^V o = ² f 'P-

This synchronous speed is in for normal machines and for 50 periods of the order of iom / sec., since the Execution of the winding does not allow a smaller PoI division, or m. A. W., the construction a 5operiod asynchronous machine for a significantly lower synchronous speed encounters very great constructive difficulties. In the known arrangements, the winding is housed in slots, the number of which per phase and pole pitch is at least one, d. H. a three-phase motor has three per pole pitch Grooves when using the so-called single-hole winding, d. H. just per pole pitch and phase arranges a hole or a groove. It is easy to understand from this that it is very difficult to achieve small pole pitches.

The invention solves the problem of arbitrarily small in asynchronous induction machines Achieve pole pitches by changing the magnetic flux of each phase for several Pole pitches together in one or more of these pole pitches, concentrated and primary coils not distributed over the pole pitches and generated by the pole pitch defining grooves or the like Arrangement of periodically alternating magnetic reluctance in a spatially wavy distribution of the Induction can act on the secondary winding distributed in a known manner. There the induction at a certain point in time according to its spatial distribution does not alternate is positive and negative, but can only vary between a maximum and a minimum given the same sign the curve of induction can be replaced by a normal sinusoidal distribution with a superimposed spatial mean value that is the same for all pole pitches, which is, however temporally as well as the amplitude of the spatial distribution varies according to the sine law. This superimposed alternating flux is in certain cases., with a rotationally symmetrical self-contained arrangement or in the case of a special type of secondary winding, ineffective, but in many cases causes harmful secondary currents, According to the invention, even with a single-phase arrangement by the action of a

*) The patent seeker stated as the inventor:

Dr.-Ing. Wilhelm Stäblein in Berlin-Hermsdorf.

527 04B

second such wave-shaped induction distribution with opposite sign and spatial offset by a pole pitch or half a slot pitch can be avoided. Act in a three-phase arrangement according to the invention side by side the three wave-shaped distributed phase flows on the Secondary winding one, the slots of the various phases each by a third of the ίο the groove spacing are offset.

In the drawings, embodiments of the invention are illustrated, for example, and the essence of the invention is explained with the help of diagrams, ig Fig the windings i, i 'are traversed by the current in such a way that the current flows in the slots 4 and 6 from back to front and in the slot 5 from front to back, as shown under α . This current flow results in magnetic force flows, as shown in dotted lines, which penetrate the air space in the pole pitch P ₁ from bottom to top and in the pole pitch P ₂ from top to bottom. The fundamental wave of the induction distribution is important for the behavior of the motor, as it is recorded under b . The hatched area represents the flux with which the coil 2 of the secondary winding is linked. Since only the generation of the magnetic flux is of interest here, the known creation of a force effect on the moving secondary winding does not need to be discussed in more detail. Instead of a distributed winding like the one shown above under α, the field distribution shown can also be generated by pronounced poles, as shown under d . In fact, the development of the induction motor also started from a type with pronounced poles. As shown under ¹ c , the pole pitch P ₁ at the relevant point in time is in the area of a south pole S and the pole pitch P ₂ in the area of a north pole is JV (Fig. Ic).

Fig. 2 then explains the essence of the invention. Under α a part of the armature circumference is shown following Fig. 1c with the secondary coils 2 and 3 and the current south poles .S ¹ and the north poles JV, which, however, in contrast to Fig two rows are arranged, one of which contains only north poles and the other only contains south poles. Under b the induction distribution is shown, namely 6 "is the induction distribution, as it is caused by the south poles, and N that of the north pole. Here, too, only the fundamental wave is drawn. In contrast to the previous figure, the center line is not included the zero line, but is increased or decreased by the value S ₀ or n _0. The mean induction over the entire anchor length is then ^{proportional to the sum of the ordinates of 6 1} and JV; Secondary winding 2 given by * / ₂ (s '-j- n') taking into account the different signs. The curve for the double mean value is plotted under c . As you can easily see, this curve is with the curve i ^{6 is} identical, ie the flux linked to coil 2 is shown again by the hatched area, so the effect for the arrangement according to Fig. 2 must be completely analogous to that of Fig. 1. One recognizes It is also easy, however, that it is now possible to excite the poles of a plurality of pole pitches according to the invention by means of a winding that encompasses all poles in common.

Fig. 3 shows, for example, such an arrangement according to the invention for single-phase alternating current, which is able to work as an asynchronous motor or generator and with a pole pitch of about 0.5 cm, i.e. at 50 periods with a synchronous armature speed of 50 cm / sec., that is, with values that are based on the known Embodiments could never be achieved. The fixed iron body 7 is excited by the coil 8, the magnetic alternating flux penetrates the movable secondary part 9, which is not in a is performed in more detail, so z. B. by a perpendicular to the right of the figure ioo to be thought of shaft is rotatably mounted. The iron body 7 has grooves in the cause a wave-shaped induction distribution in the manner described above, namely teeth 10 and 11 are half a pitch offset. In an imaginary moment, when the magnetic flux is directed from top to bottom, the teeth 10 act as the north pole, teeth 11 as the south pole. The movable secondary part 9 carries a secondary winding, z. B. a cage winding 12. The bars 13 lie in small grooves of the Part 9 almost completely around this and are all through the webs 14 and 15 with each other tied together. What was said about Fig. 2 applies to this arrangement, it acts as a single-phase Asynchronous machine with the double pole pitch defined by the slot pitch 2 P.

Fig. 4 explains the relationships of the invention with a three-phase arrangement. U, V ₁ W are the poles of the three phases, each for itself

lie in a row as shown under «. The secondary winding, which is intended as a cage, is drawn in dashed lines above it. Under b , the spatial distribution of the induction is shown again only showing the fundamental wave for the three phase flows. The instantaneous value of the maximum induction results from the vector diagram drawn on the left for the phase fluxes U ₁ V, W. So

ίο the induction distribution for U is given by a sine curve, the spatial mean value of which is U ₀ . The same applies to the curves ν and w with the spatial mean values V ₀ and W ₀ . Again, the mean induction along an armature conductor is equal to the sum of the ordinates of the three curves at this point. The course of these values is shown under c . A sinusoidal distribution is shown, the center line of which coincides with the Xu line, the mean values M ₀ , V ₀ , W ₀ thus result in the sum zero. If one examines the relationships for different time moments of a period, one always finds the same spatial distribution, but it moves to the right with constant speed, i.e. a rotating or traveling field is generated by the arrangement of the pole rows α , just like by a distributed three-phase winding .

Fig. 5 shows an embodiment of an arrangement according to the invention for three-phase current. The windings 19, 20 and 21 of the phases U, V and W are applied to the legs 16, 17 and 18 of an iron body. The magnetic fluxes of the three phases close via a movable secondary part 22, which is forcibly guided in a manner not shown in detail, for example, can be rotated about a perpendicular axis that can be thought of as right. In a manner similar to that in FIG. 3, the surfaces opposite the secondary part 22 are grooved: leg 16 has teeth 23, leg 17 has teeth 24, and leg 18 has teeth 25. The division is the same for the three legs, but the teeth of the different phases are each offset by a third of the division, as the section through the arrangement through AB and shown on the right shows.

The secondary cage winding, the bars of which lie in grooves on the three sides through which the force flows, lies around the secondary part 22 in a manner similar to that used previously. On the right-hand side, the cage is closed by the webs 27 and 28. As can be easily seen, the flux and winding conditions in the figure are identical to those in Fig. 4, the arrangement acts as a three-phase asynchronous machine. Of course, the arrangement can be carried out symmetrically with respect to the axis of rotation, so that the one-sided magnetic pull occurring in the direction of the leg V is canceled by the same counterforces.

The mode of operation of the arrangement according to the invention is evident from the exemplary embodiments referred to, but it should be emphasized that the invention is not bound to these embodiments, but allows many others. So it is, as already mentioned, in certain cases not necessary to calculate the mean value of the power flow, as it is z. B. is shown in Fig. 2 by the distance s " to compensate by the action of an opposite flux n ₀ in the effect on the secondary winding, as was previously assumed in all embodiments. In the case of a rotationally symmetrical arrangement, in which the power flow is uniformly transferred to the secondary part along the entire circumference, this is not necessary regardless of the type of secondary winding. This is also not necessary if the secondary winding according to Fig. 2 consists only of self-contained short-circuit rings 2, 3, etc., which are not connected to one another in a conductive manner. With this type of winding, you can only get by with a row of alternating poles with the same name at every moment, so in 2 a you can imagine the pole row N without, although you only get half the effect, since you can only use curve 6 "in Fig. 2 b may calculate, which has half the amplitude of curve c .

The secondary winding can, taking into account what has just been said, as normal, distributed alternating current winding, designed as short-circuit and cage winding be. The field shape can be sinusoidal as desired by suitable dimensioning of the teeth can be made so that the influence of a small number of slots per pitch in the secondary winding also recedes.

Like any asynchronous machine, the arrangement according to the invention can be used as a motor how to work as a generator. The conditions for this are the well-known: When the secondary winding has no electrical power is supplied, the machine works in sub-synchronous operation as a motor, in oversynchronous operation Run as a generator. According to the invention, it can therefore also be operated as a generator for high frequency, with the possibility of small pole pitches is particularly useful. The excitement can in this case with leading reactive currents generated by a capacitor from the Primary side take place, the generated frequency must be such that the run is oversynchronous, otherwise no service can be delivered.

527 04β

As with all asynchronous machines, it is of course also possible with the arrangement according to the invention the role of the primary and secondary windings are reversed, d. H. it can be used for certain purposes as well the distributed winding as the primary winding are connected to a network without being in the principal A difference occurs.

Claims (8)

Patent claims: 1. Asynchronous, rotating inputs or outputs acting as a motor or generator Multi-phase machine, in particular with a small pole pitch, characterized in that that the primary coils have several pole pitches in common, which are determined by teeth and grooves or by pronounced poles include and the alternating magnetic flux acting on the secondary winding together for these pole pitches produce. 2. Induction machine according to claim ι, characterized in that the same flow or the fluxes of different phases act on the secondary winding in such a way that that the inducing effects of the poles extending over more than one pole division Cancel each other's flow shares. 3. Single-phase induction machine according to claim 1 and 2, characterized in that that the flow of the secondary winding so ι interspersed that the points of maximum induction at the entry point and at the exit point of the flux with respect to the secondary winding are offset from one another by a single pole pitch. 4. Multi-phase induction machine according to claim 1 and 2, characterized in that the η phase fluxes of the M-phase system, the secondary winding with mutual displacement of the slot pitches of the different phases by each enforce the division. 5. Induction machine according to claim 1 to 4, characterized in that the Secondary winding is a short-circuit or cage winding. 6. Induction machine according to claim 1 to 5, characterized in that the Arrangement of the fixed primary iron body with respect to the axis of rotation is so symmetrical that on the secondary part no unilateral magnetic pull is exerted. 7. Induction machine according to claim 1 to 6, characterized in that the primary iron body the secondary part on the full circumference without interruption encloses. 8. Induction machine according to claim 1 to 7, characterized in that the shape of the Täkmz is designed such that the wave of the induction distribution as close as possible to the sinusoidal shape For this purpose ι sheet of drawings