DE346466C - Self-exciting DC shaded-pole generator with main and auxiliary brushes flanking the half-poles, the voltage of which can be regulated within wide limits - Google Patents

Description

Self-exciting DC shaded pole generator with the half poles flanking main and auxiliary brushes, the tension of which can be regulated within wide limits is. A need for self-exciting direct current generators with within wide limits adjustable voltage is often available in practice. The invention has one such a generator, so a machine to the subject, whose voltage either from a given negative value or from zero or from a certain positive Smallest values up to a likewise prescribed positive maximum value in can be regulated in a similar manner, as is the case with any shunt generator.

Self-exciting generators must work above the knee of the no-load characteristic in order to enable stable voltage conditions. Your iron must therefore have a certain saturation at some point in the circuit. At the same time, however, the resulting (dynamic) field, from which the useful voltage of the machine originates, must be changeable according to the required voltage range. Both of these contradicting conditions for normal machines can be met by splitting the poles and arranging certain windings. One only needs to cause the first half-pole to generate a flux Z, which is either constant or only changeable within moderate limits and which can be found in iron, e.g. B. causes the desired saturation in the thighs or in the teeth or in both parts at the same time. Thereby, the voltage characteristic for two brushes (B1 and bi or B2 and b2) including this flux is curved as required. The second half pole then has to generate a flux that can be varied between a positive and a negative maximum. It is not necessary that the poles are split in the middle. going on; so if one half of the pole is mentioned in the following, it is not meant to imply that the poles are necessarily thought to be divided into two equal halves.

The way in which the intended voltage regulation comes about can be clearly explained with the aid of Fig. Z, which shows a two-pole machine with equally large gap poles. As can be seen from the various pole diagrams a to e in Fig. Z, the flux of the first half-pole Z1 should be constant or approximately constant. The flux of the second half-pole Z2, on the other hand, is variable from a positive maximum (Fig. Za) to a negative maximum (Fig. Ze). For the EMF between the two main brushes B1 and B2 separated by one pole pitch, the flux Z = Z, + Z ?, comes into consideration. This is greatest in the pole diagram, equal to Z1 in the pole diagram c and zero in the pole diagram e. The resulting flow Z is negative in the case of the pole diagram f, which was achieved by further increasing Z2 in the nagative sense and reducing Z1. All pole diagrams are drawn for the case of idling or a compensated machine.

Between the main brush B1 and the secondary brush b1, however, a Voltage can be taken off, which is proportional to the flux Z1 and with this essentially is constant. Exactly the same tension is also between the brushes B2 and b2 available.

If you want to change the voltage between the limits - ¢ -E and -E, then it is best to commutate the current and then the voltage at the moment when E- = o (pole diagram e in Fig. I) to increase again, ie to move on to diagrams d, c, b and a . In this case, commutation does not present any difficulties, because it can take place without interrupting both the armature and the external circuit.

Another between equally high positive and negative values A variable voltage could also be obtained from the brushes bi and B, or b, and Bi decrease without having to resort to commutation. In such a case, however the generator may not be fully utilized. It is noteworthy that the tension between the two secondary brushes Ei-EJ is when those between the main brushes with Ei + E2 is called. This circumstance can in certain cases feed two independent circuits can be used to advantage. It can now be shown that the described voltage or field change by simply setting a shunt resistor is possible without an external power source for the supply of the shunt current to need: As with every DC machine, reversible poles and also arrange compensation windings, both for the main and for the auxiliary brushes, so that the generator does not have any sparking differs from normal.

In Fig. 2 such a two-pole machine is shown, which also is still provided with main and secondary poles. Wear the half-poles of the same size the shunt windings Ni and N, and the series windings Ri and R2. It is important to note that the series windings, their axes here not perpendicular to the axis of the main brushes B1, B2, not pure excitation windings but also have the character of compensation windings. Instead of Series windings or in addition to these could therefore also compensate windings are arranged, but are not shown in Fig. 2.

In the present case, in which the split poles are the same size, close the axes of the He. energizing windings R and N with the armature winding of the axis of the main brushes at an angle of 45 'as shown in Fig. 3. In this In the figure and also in the following, the windings Ri, R ,, Ni and N2 are only j e drawn once to make the circuit diagram as clear as possible; against it could draw the reversible pole windings twice without any disadvantage for the clarity will. Should the secondary brushes bi and b2 only serve to deliver the excitation current, then their Iffendepole are probably dispensable. For this reason, Fig. 4 to 6 omitted the auxiliary poles.

As said above, the first half pole should be approximately constant River Z, lead. This is the case when the resulting excitation of this half pole is independent of the load current. To achieve this, the first half pole is to be provided with a series winding R, matching number of turns and this winding to switch against the armature winding. Assume that there is a positive current in the armature is directed from B2 to Bi and results in an armature field that, like the armature current is directed (cf. the arrows in Figs. 2 and 3), the series winding must R, as indicated in "of Fig. 3, are switched. Then the flows, which originate from the armature current or from the current in R, directed against each other. the Shunt winding Ni is either on the brushes Bi and bi or on the brushes B2 and b2 to be created. Ni can be switched so that either the series winding Rl or the armature winding is supported. Generators are obtained in both cases of the same properties, so that here only one case, namely that in which the shunt winding Ni supports the series winding R1, treated too needs to be.

Assuming this circuit of the excitation windings of the first half-pole shown in Fig. 3, the resulting number of ampere-turns F of the first half-pole is given by the equation given if one denotes finite w, .i the number of turns of the series winding Ri, w, the number of turns of the armature winding, w l the number of turns of the shunt winding Ni, J the armature current and il the shunt current in N1. So, by choosing can be made completely independent of J, if one does not prefer wri something larger than Select au to keep the excitation voltage as constant as possible.

While the circuit of the excitation windings of the first half pole in all Fig. 4 to 6 recurs, the circuit of the excitation windings of the second Half poles, depending on the desired goal, turn out different. want two cases differ, depending on the series winding R2 the armature winding is supported or connected to the armature winding. The circuit of the shunt winding N2 is then clearly determined by the tension that you create want.

A. Series winding R2 and armature winding connected against each other (Fig.q.).

If the current i2 in the shunt winding of the second half-pole is considered to be positive if it is as shown in Fig. Q. is drawn, supports the anchor field, that is, strives to produce a flow that is in the same direction as Z1; so the resulting ampere turns of the second half pole are through y given. The two shunt windings are placed on different pairs of brushes, but this is not necessary.

F2 and with it the flux Z2 become larger the larger i2 is, so that the resulting -for Flux Z = Zi Z2 increases and decreases with i2. The characteristic behavior of the machine also depends on the sign of the resulting ampere-turns resulting from + W ") 1 + wn #! I, load current J. Here we have to distinguish three cases, namely depending on the situation larger, pale, or smaller than zv, -z.

If w, .2, then the case of a compound generator lies before. If you want to get smaller voltage values, you have to make F2 negative, which can be done by commutating the excitation current i2. In this case, the manufacturer from the main stream of machine voltage touching mperewindungen and the shunt-ampere-turns are connected to each other, such that F2 (ab-. Solut taken) with increasing J decreases. The decrease in F now causes an increase in voltage (see pole diagram d in Fig. Z), s so that the generator retains its character as a compound generator. If i is chosen so large in the negative sense that the resulting flux Z and with it also the current j become negative, then the same-circuit ampere-turns and the ampere-turns resulting from the load current have the same sign, so that the generator also in this operating state ( Pole diagram f the ompoundbb. R) retains its character as a generator. The number of turns can also be chosen to be equal to zero, that is to say that there is no serial connection whatsoever. On the other hand, you do the same then we have to do with a pure bypass generator. The regulation takes place here as well by changing i3 from a positive to a negative maximum value.

On the other hand, if ze 2 is greater than then the machine picks up because is negative, indicates the character of a counter-compounded generator. The counter-compounding can, if necessary, also be carried out to such an extent that the generator can be short-circuited without damage at any voltage. Here, too, regulation takes place by changing i2 between the corresponding negative and positive limits.

If "one wants to get larger negative values, it is best to commute the armature current as soon as the armature voltage has reached zero.

B. Series winding R supports armature winding (Figs. 5 and 6). In the case shown in Fig. 5, the resulting ampere-turns are through the second half pole given when the shunt winding is connected so that it supports the other windings. The machine takes on the character of a heavily compounded generator. In order to generate lower voltages one must commutate i2, ie switch the shunt winding in such a way that it tries to weaken the field of the other windings. This circuit is shown in Fig. 6. There is also a compound generator in this circuit, because the (ie F2) increases with J. If one wants to get even smaller voltages, one must make F2 negative, ie choose a large negative value for i. In this operating state (field diagram d in Fig. R) the shunt ampere turns are switched against the series shunt and armature amp turns, so that F2, taken in absolute terms, decreases with increasing f. A decrease in FZ is associated with an increase in the machine voltage, so that the machine retains its character as a compound generator. The same thing happens if the negative shunt ampere-turns are increased so much that the voltage becomes negative (pole diagram f in Fig. Z). This circuit is particularly advantageous if it is a matter of feeding a circuit with a constant or at least not greatly variable resistance (e.g. feeding the excitation winding of a machine), because it is then possible to change the ratio; Nisse must be chosen so that i2 does not need to be commutated during the entire control range. One only has to choose the exciting ampere-turns so large that they alone are already sufficient to generate the maximum field Z2. Then i always remains negative, that is, as directed as in Fig. 6. To reach the voltage zero, one only needs to make the shunt ampere-turns wn2 - i2 = wnl - il, because then F1 = F2 after J = o is. If you increase i2 further, F2 becomes greater than F, and E and, j negative. The machine retains its compound character, as all ampere turns now support each other.

In addition to the advantage that i2 does not commute over the entire voltage range needs to be, this circuit has the further that the ampere-turns to generate the maximum field are fully exploited, so that one can excite Can save ampere turns.

Regarding the ampere-turns to be expended is at all the shaded pole machine described here has an advantage over normal machines, because the transverse amp turns under a pole are only half as large as at of the machine with undivided poles, so that one can work with a relatively small Ampere-turns for air and teeth gets by without the field distortion exceeds permissible level.

If you want to change the voltage in the "limits + E to - E continuously, so it is best to then switch the armature current through a changeover switch without interruption to turn when the voltage is zero. In fig. Q. to 6 is for this purpose the switch indicated.

To bend the magnetic characteristic of the first half pole or in order to make the maximum value of Z2 greater than that of Z1, one can use the leg of the first half-pole give a smaller cross-section than that of the second half-pole. This measure can be useful if you simply adjust the bypass regulator from N2, i.e. without adjusting the regulator from Ni and without switching the armature current, wants to achieve smaller negative values in addition to high positive voltage values.

It is assumed up to now that the regulation by mere adjustment of a shunt regulator, i.e. by changing the shunt current i2 go yourself. Of course, this does not exclude the possibility of this regulation any longer or less by a circuit resistance to the series winding of the second Can support half poles. Named by the circuit resistance is namely the Number of turns ze "2 reduced virtually. In individual cases it can also happen that the desired regulation can only be achieved by actuating the mentioned loop resistance want to perform.

Claims (3)

PATENT CLAIMS: i. Self-exciting DC shaded pole generator with the main and auxiliary brushes flanking the half-poles, whose tension is wide Limits can be regulated, characterized in that the first half pole by one of the Armature winding counteracting series winding an approximately constant or little variable flux to be transferred from the brushes that enclose this half-pole, to gain a voltage suitable for feeding the shunt winding while the flow of the associated second half-pole by regulating the excitation current of its Shunt winding or its series winding changed within wide limits will. 2. Embodiment according to claim z, characterized in that the second Partial pole _ provided with a series winding supporting the armature winding is, to the voltage regulation without, switching of the excitation current in its shunt winding to manage and get by with the least possible amount of material. 3rd embodiment according to claim i, characterized in that the second half pole with a counter the armature winding connected series winding is provided to as desired to obtain a compound or shunt or counter compound machine. ¢. Embodiment according to claim i, characterized in that the first half pole has a smaller leg cross section or a smaller pole arc or generally smaller than the second one is either for the purpose of stabilizing the excitation voltage for the shunt windings or to get larger negative voltage values without switching.