DE122369C - - Google Patents

Description

IMPERIAL

PATENT OFFICE

The subject of the present invention is provided by circuits which can be implemented with cut-open direct current windings in order to obtain two three-phase voltages of different magnitudes than would be possible with the uncut direct current winding. For this purpose any DC winding with s bars and generally parallel circuits can be used, which is divided into 6 a bars by 6 a sections. The rod cells obtained are then to be connected to one another in various ways in order to obtain the two above-mentioned three-phase current voltages.

Before the explanation of these circuits can be dealt with in more detail, it appears necessary, about the execution of the cuts and about the schematic representations to be used, which serve to to indicate the individual circuits, to send the following in advance:

In every DC winding with any number of poles and armature wires (rods or turns), each wire generates an alternating electromotive force, the course of which is generally not a sinusoidal but one that corresponds to the shape of the field. Since the wires (rods or coils) are evenly distributed on the anchor either individually or in groups (e.g. grooves), each rod will have a different phase at a certain time, that is, a different position in relation to the poles. In order to precisely precise this position, it is expedient to imagine a sinusoidal distribution of the field in the air space, in order to then be able to infer its phase immediately from the position of a rod in relation to the sinus field, although such a distribution of the field, with it the circuits to be dealt with later work properly is not necessary. If, as noted, the induced rods are evenly distributed over the circumference of the anchor, it is possible, by dividing the entire circumference of the anchor into six times ρ equal parts - where ρ denotes the number of pole pairs ^; - To form groups of rods in which no wire can have a phase shift greater than 60 ° with respect to the other wires in the same group, and which, taken as a whole (i.e. the sum of the electromotive forces of all the wires in a group) generate electromotive forces which are 60 ° are shifted compared to the electromotive forces of the neighboring groups. By this division there are obtained as many phases as groups, but every sixth group has the same phase of the electromotive force, and hence the number of the actual

Phases are always limited to 6. It is now possible, at each DC winding with generally ia parallel circuits, by cutting the same α in 6 points,

6 a separate traces obtained from rods to so namely, that only wires occur in each such train of the same phase, that is, only wires i on the armature in the routes 4, 7, etc 10 or, in the lines 1 and 4 2 and 5 etc. or, finally, lie in only one line, if one divides the 6p lines into which the anchor. is designated in sequence with 1, 2, 3 to 6p . In all cases, and at each turn, it is not possible to obtain 6 α completely same line trains of rods because it may not That the tie rod number s by 6a is divisible; In this case the division will be carried out in such a way that the individual phases, that is, bar lines, have as many bars as possible, which in reality can always be done quite well without disadvantages for the following circuits.

In Figs. 1 to 4 of the accompanying drawings is now i shown with practical examples, is to take place as such in Aufschneidung 6a points. Fig. 1 shows the circuit diagram of a four-pole machine with series wave winding [a = 1, ie with only 2 parallel circuits), the entire number of wires being chosen so that it can be divided by 6a, here 6. Fig. 2 shows a similar winding with a different number of bars which cannot be divided by 6. Thus, while the winding according to Fig. 1 can be divided into 6 equal bars with 7 bars, one gets with the winding according to 4 sets of bars with 8 and 2 sets of bars with

7 bars. This inequality is not harmful, all the less since in reality there are seldom windings with so few bars, as has been assumed here. In Fig. 3 the division of the direct current winding in 6 a phases of an eight-pole machine is drawn with a = 2, ie with 4 parallel circuits, while Fig. 4 shows the same division for a six-pole (jp = 3) machine with a = 1, ie with 2 parallel circuits, whereby again the individual 6 phases are not exactly the same.

Other examples of the division of the winding with other types of winding, e.g. B. Induction loop or ring wave winding, then drum loop winding, are not necessary here, and may these examples given, how the division is to be made in the case of drum shaft winding are sufficient.

As already said before, by cutting a winding into 6 a points you get 6 a bars, but only always 6 phases, where α bars have the same phase. In the future one will therefore always be able to speak of 6 phases if one assumes that the α identical phases are connected one behind the other or in parallel or partly one behind the other, partly in parallel, and if one always means such a group of identical phases by a phase.

Each phase then generates an ^{electromotive:} force which is shifted by 6o ° with respect to the adjacent phases, as each phase is generated much excitement, it is possible to represent the electromotive forces of the 6 phases by the sides of a regular hexagon, as es.in Fig. 5 is done through the sides of the hexagon inscribed in the circle. The electromotive

The force of a phase now comes from —— wires

6 a

which for their part are equal but not in phase electromotive forces produce. Since now every wire has the same electromotive force and because of the uniform Distribution of the wires on the armature each wire an electromotive force displaced by the same small angle generated, and the sum of all these tensions gives the side of the hexagon, so is It is easy to see that the tension of the individual wires can be increased by tendons, e.g. B. in Fig. 5

of the arc I · ι can represent by, one

equal parts

the arc I 1

in

6-a

and draw the tendons. In FIG. 5 it is assumed that 7 wires together generate the electromotive force of one of the 6 phases, as is the case with the winding diagram shown in FIG. In order to finally be able to cut a DC winding with 2 a parallel circuits correctly into 6 a groups of wires, start at any point I and follow the winding to one side by designating the beginning of the first rod with A ¹ .

After crossing -—- bars one arrives at the second intersection point 1 and let the end of the last bar already crossed with e _x , the beginning of the second phase still to be crossed with a _L.

After crossing further -: bars

. 0 · a

one arrives at the intersection point, etc. The other designations can be seen from FIGS. 1 to 5. If you have now exceeded 6 phases and α is greater than 1, ie if the winding has more than two parallel circuits, you get back to the beginning of a second, first phase, which

denoted by A _1. The other designations can be found in FIG. 3. However, if the machine has separate windings, the second, third, etc. winding must be cut open at the 6 points of the same potential as the first winding.

Now that The above has been provided, it is clear to DAF's from now on the schematic diagram of FIG. 5 will serve to the various circuits to indicate that you can perform with a 6 bar groups.

As has already been mentioned at the beginning, all the circuits forming the subject of the invention have the purpose of obtaining two three-phase voltages of different magnitudes from a direct current winding cut open in 6 a points by switching the 6 α rod trains with one another in different ways.

FIGS. 6 and 7 now show such circuits which are created by connecting two adjacent rod trains to form a double phase, so that one has to deal with the resulting phases A ₁ E ₁ , A ₂ E ₂ and A _S E _S . These 3 double phases are then connected according to FIG. 6 in such a way that E _{3 is} connected to M ₁ , E ₁ to n ₂ and E ₂ to M ₃ , where M ₁ , M ₂ and M _{3 are} three on the 3 phases by the same amount are points of the winding protruding from A ₁ , A ₂ and A _3. It is therefore possible to take three-phase current voltages A ₁ A ₂ and E ₁ E ₂ from a machine 2, their relative magnitudes by selecting the points M ₁ , M ₂

and M ₃ on the corresponding arcs A ₁ E ₁ ,

A ₂ E ₂ and A ₃ E ₃ can be changed. The smaller voltage can e.g. B. for light, the larger ones are used for engine operation.

In Fig. 7 a circuit similar to Fig. 6 is drawn, only with the difference that here the points E ₁ , E ₂ and E ₃ are connected differently to the points M ₁ , M ₂ and M ₃ than before.

Fig. 8 shows such a circuit, which has arisen from the fact that the connections of the ends of the three double phases have been shifted cyclically. While in the uncut DC winding A ₁ with E ₃ , A ₂ with. E ₁ and A _{3 are} connected to E ₂ , A _{1 is} connected to E ₂ , A ₂ to E ₃ and A ₃ to E _{1 in} this circuit.

In order to get 2 three-phase voltages in this circuit, one assumes 3 symmetrically located points M ₁ , M ₂ and M ₃ on the 3 double phases, between which

one then gets a voltage proportional to the distance M ₁ M _2.

This circuit, like the counter circuit, can be used in three-phase motors by either permanently short-circuiting the points that supply the lower voltage or connecting them with resistors. If only the points M ₁ , M ₂ and M _{3 are} permanently short-circuited with one another, then one obtains torques for one and the same. of the motor one in the ratio AAY ²

- -I. larger hatching. Then to the

M ₁ M ₂ /

To override normal operation, ¹ use the higher voltage by short-circuiting points A ₁ , A ₀ and A ₃ with each other.

In the following circuits according to FIGS. 9 to 15, on the other hand, a double phase is always made from two sets of bars, the phases of which are shifted by 180 °, by being connected in series, so that here, too, only three resulting phases, namely the phases A _Ύ ε _λ E ₂ a ₂ , A ₂ e ₂ E ₃ a ₃ and A ₃ e ₃ Ε _λ α _{λ has} to do. These three phases are then connected in Fig. 9 in such a way that U _{1 is} connected to W ₃ , a ₂ to W ₁ and Λ ₃ to W ₂ , so again M ₁ , M ₂ and M _{3 are} three by an equal amount of JE ₁ , jE ₂

and E "

on the sheet E ₁ a _x , E ₂ a ₂

E ₃ a _{3 are} protruding points of the winding. Two three-phase voltages can also be taken from this winding, namely

a smaller a ₁ a ₂ and a larger a ₁ a ₂ . In Fig. 10 a circuit similar to Fig. 9 is drawn, with the difference that here a _{y is} connected to M ₂ instead of M ₃ , a ₂ to M ₃ instead of M ₁ , and a ₃ to M ₁ instead of M ₂ .

In this case, too, the ratio of the stresses can of course be changed by a suitable choice of the points M ₁ , M ₂ and M _3. If you choose M ₁ , M ₂ and M ₃ no longer

on the arc E ₁ Ci ₁ , E ₂ a ₂ and E ₃ a ₃ , 'but on the arc A ₁ e

_x , A ₂ e ₂ and A ₃ e ₃ A

_{1 x 3}

at equal distances from A ₁ , A ₂ and A ₃ , as shown in FIGS. 11 and 12, again 2 three-phase voltages are obtained

Variables behave like the segments a _x a ₂ to A ₁ A ₂ . The difference in the two circuits is that in Fig. 11 a _{ with M ₁ , a. ₂ with M ₂ and a ₃ with M ₃ , while in Fig. 12 U _{1 is} connected to M ₂ , a _{2 is} connected to M ₃ and a _{3 is} connected to M ₁ .

13 and 14 show two special cases, namely when the points M ₁ , M ₂ and M ₃ are chosen so that they coincide with E ₁ , E ₂ and E ₃ . In FIG. 13, a _{x is} connected to E ₂ , a _{2 is} connected to E ₃ and a _{3 is} connected to E ₁ , while in FIG. 14 a _{1 is} connected to E ₃ , a., With JE ₁ and a _{3 is} connected to E ₂ .

In Fig. 15 the three phases are connected in a triangle, a circuit which arises when the three points M ₁ , M ₂ and M ₃ are chosen so that they coincide with A ₁ , A ₂ and _{A 3} .

In order to be able to take 2 three-phase current voltages from this circuit too, one must select 3 points on the 3 double phases, denoted by H ₁ , n ₂ and η. _Λ (Fig. 15) are designated. This circuit can then be used as a counter circuit for three-phase motors by either short-circuiting the 3 points, which supply the lower voltage, or connecting them with resistors. If the 3 points M ₁ , n ₂ and? Z ₃ , which supply the smaller three-phase voltage, are constantly short-circuited with one another, one obtains one for one and the same torque of the motor

(A AA- in the ratio | - ^l - - | larger hatching.

In order then to go over to normal operation, the greater voltage is used by short-circuiting points A ₁ , A ₂ ' and A _a with one another. Finally, in the last circuits to be discussed, a double phase is always made from two sets of bars, the phases of which are shifted by 180 °, by connecting them in parallel, so that one has to deal with three double phases, as, for example, FIG. 16 shows. If these three double phases are now connected either in star (Fig. 16) or in triangle, one must again ensure that one also gets the smaller three-phase voltage by assuming six points on the six bars. In Fig. 16 it is now indicated how this is to be done

by the distances m η the small and the

Line A ₁ A _{2 represent} the higher voltage. This circuit can also be used in three-phase motors, as can the counter circuit; if you closed the 6 points, which the. should supply smaller three-phase voltage, either short in pairs or connected by resistors, in such a way that one always short-circuits those points which are on a double phase with each other, then one obtains a slip at a certain torque,

which is greater in the ratio I 1

Xm ₁ nJ

than those that you would get if the points A ₁ , A ₂ and Α _{Ά were short-circuited.}

Claims (3)

Patent Claims: i. Connection of the windings of alternators or Inductionsmotoren in such a way, that two three-phase voltages can be removed by means of an in 6 a points cut DC winding with generally parallel circuits of a coil, characterized DAF same from the 6 a or nearly equal rod trains ,, which by the 6 α cuts have been obtained, 6 phases are made by always connecting each α in -phase rod trains either by parallel, series or mixed connection to a single phase, and from two adjacent phases each (Fig. 6 to 8) each resulting phase is made, and the windings corresponding to the resulting phases obtained in this way are connected in such a way that the smaller voltage is always taken from 3 points which are symmetrical on the 3 windings, while the larger voltage is taken from 3 of the 6 ends of the 3 windings is taken while the other 3 ends at symmetrical point e of the windings are connected. 2. Circuit of a winding with the same subdivision as claimed in claim 1. thereby characterized that from two phases each shifted by 180 ° (Fig. 9 to 15) by connecting them in series each made a resulting phase and the the windings corresponding to the resulting phases obtained in this way are connected in such a way that that the smaller voltage is always taken from 3 points which are symmetrical on the 3 windings while the larger one is taken from 3 of the 6 ends of the 3 windings, and the other 3 ends from symmetrical ones Points of the windings are connected. 3. Connection of a winding with the same subdivision as according to claim 1, characterized characterized by the fact that two phases each shifted by 180 ° are connected in parallel each of them made a resulting phase and the resulting phases corresponding to the thus obtained Windings are connected either in a star (Fig. 16) or in a delta, whereby the smaller voltage is taken between points of the same double phase, while the larger voltage is taken from a star connection of the double phases from 3 of the 6 ends of the 3 double phases and with delta connection the double phase is taken from the 6 ends of the 3 double phases. For this purpose ι sheet of drawings.