DE127168C - - Google Patents

Description

% ΰΛ'Μ

IMPERIAL

PATENT OFFICE.

With rotating field induction motors, the rotating field should be as constant as possible rotate, and its strength should change as little as possible. It is well known that both requirements are met in practice not to. The magnetic field fluctuates in strength and speed of rotation, namely, As far as the engines that have been designed up to now are taken into account, this is by no means insignificant. the The result is an uneven torque, the dead point of which makes starting difficult while secondary currents in the coils and in the iron cause energy losses.

All of this is intended to be avoided by the present invention.

The task itself is not new, but as old as the polyphase induction motor in general; but the means which are set out and described in the following, have not yet been proposed to solve them. Rather, it is theirs Applying a complete deviation from what was previously considered necessary by the constructor and of course appeared.

Marriage now on the differences from the previously usual and proposed facilities and arrangements are made, the following is the new winding of the motor to be discribed.

In the drawings, the winding is compared with the previously known ones.

It shows Fig. 1 a Tesla motor of the old type, Fig. 2 the AC motor according to of the present invention. For the sake of clarity, the wire windings are drawn radially, while in practice they are attached lengthwise, as in the ordinary Drum type. Fig. 3 is the relative position and direction of the effective magnetic Field corresponding to Fig. 1 show. In contrast, FIG. 4 is the illustration corresponding to FIG. In both cases the dotted lines indicate the second phase shifted by 90 °. Figures 5, 6 and 7 also show how 11 to 14 the magnetic processes in the old Tesla machine, Figs. 8, 9, 10, 15, 16 to 18 the in the new.

Hitherto, when arranging the winding for the primary part of the three-phase motor, each coil has been made to encompass that part of the full circumference which results from dividing the entire circumference into as many parts as there are poles. In a four-pole motor that is, the coils 90 ⁰ umfafsten, in a six-pole motor 6o ° etc.

This old type of winding is shown in FIG. 1, in which abcd correspond to one phase and a ^l b ¹ c ¹ d ^l correspond to the other phase. In order to avoid confusion, the arrows which indicate the direction of the current when the second phase of the current has any value other than zero have been omitted.

In the. The following description is the. For ease of use, the anchor part denotes in which the currents are induced, and the field magnet that which receives the currents from without, and further

the armature is assumed to be stationary, the field magnets are assumed to be rotating, what ratios as is well known, can also be reversed.

In each of FIGS. 5 to 10, the surface of the drum field magnet is indicated by a straight line yy. The vertical lines efg h of these figures give with the sections of the line y the points which correspond to the points in FIGS. 1 to 4 which are also designated. In Fig. 5 z. B. the hatched part signifies the different field strengths at successive points of the field magnet when the currents of phase abcd are positive and at a maximum, and the currents of phase a ^x b ¹ c ¹ d ^{1 are} consequently zero. One sees immediately that the greatest field strength can only be found at one point, and that the wave has a pointed shape. Of course, this may not be the exact shape for every particular machine; but the general principle is aptly represented in these figures. 6 shows the distribution of magnetism when the currents a ¹ b ¹ c ¹ d ^{1 are} at their maximum and the corresponding abcd are zero. Here too, of course, the same shape is obtained. The composition of the two components is drawn in Fig. 7, which shows the virtual wave of the distribution of the magnetic point at the moment when the two currents are equal. It can be seen immediately that this wave has a flat head, and that its height is equal to that of the two components. Since the two waves are equal at 45 ^0, so it is easy to show mathematically, that the height of the two componirenden waves, as drawn in Fig. 7, about _^3/4 of the basic wave of Fig. Is 5, it ie equal to the maximum value multiplied by the sine of 45 °.

11 to 14 show another type of representation of the magnetic relationships, which were illustrated by de in FIGS. 5, 6 and 7, the relationships of FIG. 5 in FIG. 11 and of FIG. 6 in FIG. 13 are reproduced. The curves terminate in peaks, while in Figs. 12 and 14, which correspond to Fig. 7, the curves appear flattened, so that the same field strength exists over a considerable part of the surface of the field magnet. The diameters of the dotted circles in Figs. 11 and 13 on the one hand and Figs. 12 and 14 on the other hand indicate the different limits of the field strengths for both cases. It can be seen that in the old form of the motor the strength of the poles not only changes during the revolution, but also that this change suddenly takes place over a different surface (the wave crest) when the maximum is reached. Both kinds of fluctuation produce secondary induced currents which are harmful. If, on the other hand, that of FIG. 2 is chosen instead of the distribution according to FIG. 1, these disadvantages no longer occur. Here each coil comprises an arc larger or smaller than that which results from dividing the whole surface by the number of coils, and the magnetic effects of the various coils overlap one another, so to speak, in the same way as the coils. In this way there is an interference effect which amounts to the fact that the maximum spreads over an enlarged surface and is reduced in its magnitude. When arranging the coils so, each defining a sheet of _^3/4 DAF to _^8/10 of the theoretical arc embraces which extends it follows by parts of the periphery by the number of poles, or when vergröfsert the arc of the coils by the same amount, so one can almost achieve a rotating field of constant strength without changing the space over which the maximum extends.

The present invention, however, is not limited to any particular degree of deviation from the old shape of the winding. A four pole machine with the new shape of the windings is drawn in Fig. 2 and 4, wherein, as can be seen, each coil approximately _^3/4 embraces of 90 °. Comparing FIGS. 8 and 10 with the corresponding FIGS. 5 and 7, it can be seen that when one of the excited currents in the improved winding is at its maximum, the magnetic wave is flat at the apex and its height is only about ³ / _{4 of} the tapered shaft of FIGS. 5 to 7 is. The relationship between the two forms of wave distribution becomes even clearer by comparing FIGS. 1, 2, 3 and 4. In the arrangement according to FIGS. 1 and 2, the conductors are accommodated in the different slots so that the different magnetic effects of their currents four groups occur, with eight slots for each group. The magnetic effects of each group thus combine to form a pole which gradually grows in strength from h and / to g and e.

In the form illustrated by Figures 2 and 4, the two currents in each of the slots 1 and 8 are opposite to one another and, for this reason, nothing is added to the magnetic field by this current. The arrangement and number of these conductors and slots with respect to the other conductors and slots of the relevant group is a .Such, that the height of the magnetic Vertheilungswellen _^3/4 of height which would be achieved if the magnetic effect in the

Coils 1 and 8 would not be neutralized. It can of course also be the number of slots and leaders in each group are chosen so that the proportion of the flattened and the sharp-edged wave different from the one obtained in the assumed example, fails. It can also be seen that the magnetism of the other phase is shifted, as 6 and 9, and that the interfering, ineffective currents of this phase in the conductors housed in slots 4 and 5 are located. The resulting Shaft, which is shown in Fig. 10 corresponding to Fig. 7 of the old construction, is higher than each of the components, but has approximately their shape. If you have this Figure compares how Figures 5 to 7 were compared with 11 to 14, so you can see that with each successive position of the magnetic distribution waves their shape remains approximately the same, and that in all of them essentially the same height for the maximum is available.

Of course, the present invention can also be used on machines with any other number of poles apply, and it is in no way intended to be limited in this regard.

If one compares the device shown with others of alternating current technology, it is clear that it differs sharply from those which strive for spatial constancy of the field for a certain period of time. As can clearly be seen from FIGS. 15 to 18, this is not intended. According to the space, the field changes a lot; from the flattened, at least only moderately expanding wave peaks, the field falls fairly gradually to zero. Rather, what is sought is that the spatial distribution of the lines of force changes in time only insofar as the field is rotated, so that any distortion in the passage of time is avoided. This is the difference compared to what patent specification 95933, among others, aims at. Since the field is strongest next to the wire turns of a coil and decreases towards the middle, it is suggested that the individual windings be distributed in unequal turns over the available space in order to make the field spatially constant. From the device described above, that of the cited patent already differs externally in that the means of the effective coils in it comprises the arc which results from the division, in that one part of the walls is made just as much larger than the other smaller . The essential means of the present invention consists in choosing the angle, i.e. the arc of the periphery, which each coil embraces, smaller or larger than that which the division of the circumference by the number of poles gives, and at the same time for the phase angle of the currents to maintain the usual sizes, i.e. 90 ⁰ , 120 °. for two-phase current, three-phase current

U. S. W.

The American patent 497110 pursues the same aim as the present invention. The coil is not, as with the old Teslaring anchors, with two-phase current only via one Quarter of the circumference extended so that it overlaps with the second coil, whereby the arrangement is such that the magnetic effect on the nucleus is in the center of the coil is largest, but decreases towards the extreme ends of the coils. Even here the mean of the turns of the wire coincides with the division, for here too becomes as much removed on the one hand as added on the other. Fig. 2 and 3 of the cited patent clearly show that the action of the coils should be such that the one decreases in the effective number of turns just as much as the other increases. Incidentally, this American institution belongs in another Class in which the present invention cannot be used at all, namely in the class of the ring armature, while conversely the covering of the coils in the sense patent specification 49711 ο does not relate to drum armatures transferring. One recognizes the characteristic difference between the present ones Establish others instantly when you put the related wires into a single one summarizes, while the ideal resultant, i.e. the mean of the wire windings in all hitherto known arrangements corresponds to FIG. 19, where the division is the same as the resulting one Arch of the spanning wire winding is. For the sake of clarity, the difference is shown in FIGS. 19 and 20, of which the first corresponds to the old, the second to the new arrangement. the Device according to the American patent specification 49711 ο finally shows in a similar representation, thus settled, Fig. 21.

Windings in which the effective wires are shifted every time they are dealt with are carried out, the direct current motors by Hermann Müller and Fritsche became known. Such windings have also been used for alternating current machines, specifically for generators (see, for example, Kapp, DC and AC dynamo machines, 3rd edition, Page 308). For asynchronous three-phase motors, however, is that in the above description Separate arrangement new and gives advantages which three-phase motors

so far missing, namely a uniformly rotating and constant magnetic field.

Claims (1)

Patent claim:
An AC induction motor in which the coils of the continuously connected winding overlap each other, characterized in that each coil (measured from center to center of the wires of the coil lying next to each other and through which flow flows in the same sense) includes a peripheral arc which is either larger or smaller as the arc which results from dividing the periphery by the number of poles, so that magnetic interference of the various coils occurs, and a field is produced which is almost constant over time and rotates at the same speed. For this purpose ι sheet of drawings.