DE232281C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 232281 CLASS 21 d. GROUP

Patented in the German Empire on December 31, 1909.

The invention relates to a multiphase commutator machine that is particularly suitable suitable as exciter for AC induction motors and power generators. Both usual induction motors or power generators, only the primary winding is connected to the network placed and a component of the current to excite the magnetic circuit of the Machine used. The power factor of a

ίο such machine is well below one. In order to improve this power factor or even to achieve phase lead, has it was proposed to use the magnetizing current in the secondary winding of the machine an auxiliary exciter, whose windings are electrically connected to the secondary windings the induction machine are connected. The exciter is mechanically turned into powered of some appropriate type.

Auxiliary excitation machines of the type mentioned have armatures such as direct current generators Commutator. They supply alternating current, the number of periods of which corresponds to the number of periods of their field the number of cycles of the current flowing through it, and obviously equal to the number of periods Must be the slip of the induction motor or generator. ' The easiest way to get there this in that one of the secondary number of phases of the induction machine corresponding Number of emphasis commutator machines used. Then you lay the field winding each machine to a different phase than the associated armature and thus reaches at Appropriate choice of these phases that a leading voltage in the armature of the auxiliary exciter which improves the power factor of the main engine. Instead of this one could also use a multiphase commutator machine whose phase number in turn must correspond to the secondary number of phases of the main machine.

The present invention relates to an auxiliary exciter of the latter type. The armature of the exciter is generally similar in construction to a DC armature. He has a commutator to which a winding "is placed," which in slits on the circumference of the iron core. In contrast to known arrangements, but here a so-called open armature winding is used. It consists of a number of Coils, of which one end of each coil is always placed at a common point, that is forms a star connection, while the other ends with a commutator segment are connected. ,

The field magnet system of the machine has field coils, the number of which is either equal to the Number of secondary phase circles of the induction machine or equal to a multiple this number is. The number of pantograph brushes is equal to the number of field coils.

The field windings of the machine are connected in series with the armature brushes. aside from that can also accommodate compensation windings in slots in the pole faces to compensate for the anchor reaction.

The drawing shows an execution

form of such an exciter in Fig. ι shown, and that is a three-phase machine chosen, that is, to an induction motor, the secondary part of which is three-phase winding can be connected.

Fig. 2 shows how the induction machine and the excitation machine are useful with one another can be connected.

The armature of the machine ι (Fig. I) is the same

ίο an armature of a DC machine, made of peeled iron and with slots in its circumference to accommodate the armature windings. The armature windings 2, 3, 4, 5, etc. encompass an arc of about 120 ⁰ ; if z. B. the armature has 36 circumferential grooves, the two sides of a single armature coil lie in grooves which are separated from one another by 12 slots. The inner ends of all these coils lead to the common point 32, but their outer ends to one of the commutator bars 6, 7 etc. The commutator has three brushes 8, 9, 10, and the field magnets have three poles n, 12, 13, their Axes are shifted from one another by 120 ^0.

The field poles 11, 12, 13 are made by field windings 14, 15, 16 aroused, they have, as well Grooves 17 in the pole face to accommodate the compensation windings 18, 19, 20.

probably these compensation windings 18, 19, 20 actually in the grooves 17 in the pole faces are accommodated, as indicated in the figure, it is a representation for the sake of clarity selected with simple field coils 18, 19,

20, which are between the poles 11, 12, 13.

The current collector brushes 8, 9, 10 are wide enough to cover all current collector segments, which lie under a pole (see the figure). They are connected in series with the corresponding compensation windings and the field magnet winding. The current curve in one phase of the machine is therefore the following: ■ From point 32 it goes through the armature coil 2, 3, whose conductor is under the poles 13, 11

lie; further through the pantograph seg-. ment 6, the brush 8, the compensation winding 18 and the. Series field winding 14 to one of the terminals of machine 21. The circuits for the other phases can be

go then without further ado.

The terminals 21 of the machine are connected to slip rings or other terminals of the three-phase winding of the secondary part of the induction motor or power generator to which the

machine serves as the pathogen.

To the current in the rotor of the induction motor to which the exciter is connected is to lead to the tension generated by the slip, must take into account the sequence of the phases of the motor circuits and also the direction of tension exerted by the armature of the exciter at a certain level of excitation is generated. In Fig. 1 it is assumed that the order ■ of the phases is such that the poles are energized sequentially in the order 14, 15, 16. Next is for the direction of rotation of the armature, which the arrow indicates, chosen so that the Direction of the voltages generated in the coils 3 and 5, at the moment after is directed outwards, where the current goes from the star point 32 to the outside.

If only one of the machine's phase circuits is taken into account, it must Field generated by the currents flowing through the series field windings 14, bring about a flux through the field pole 11 and thus an electromotive force in the Create conductors under the pole, i.e. 3 and 5 etc. of the armature winding. An electromotive Force is similar in conductors 2,4 that of magnetic flow are subject to the field pole 13 is generated. The conductors 2, 4 are so with the Conductors 3, 6 connected that the resulting tension created by the flow from the Poles 11 and 13 are produced from one such Phase has that it has leading currents in the phase circuit of the secondary winding of the Brings induction machine, which is connected to the brush 8. The voltage, which is generated in each phase circuit of the exciter is therefore the resultant the voltages generated by the fields that are generated by currents in two phase circuits It can be seen that this voltage has the required phases necessary that the connections of the. Conductor 2, 4 etc. reversed with respect to 3, 5 so that while the voltage generated in the conductors 3, 5 with the Current through brush 8 is in phase, the voltage created by conductors 2, 4, is shifted in phase by 180 ° with respect to the current through brush 10.

It should be emphasized that the brushes 8, 9, ι ο are wide enough to accommodate several commutator bars to cover and therefore a corresponding number of armature circuits in parallel ζιΛιο switch. If a number of armature circuits are connected in this way, it is in usually difficult to get the current that goes through the brushes to go over evenly all of these circuits is distributed as the current in the circuit of those coils is larger, which lie under the rear end of the pole, because here a larger magnetic There is a flow as a result of the anchor reaction. The compensation windings 18, 19, 20 serve to equalize the currents in all the conductors below a single pole, e.g. B.

the current in conductors 4, 5 is less than the current in all current conductors that are under one Pole rush away, so the compensation winding in the slots 17 strengthens the field in which the anchor ladder are about to move towards the position of the ladder 4, 5. In fact, it is always possible to have a suitable current distribution in the compensation windings produce so that an approximately uniform current distribution in the armature windings results under the pole. But this makes commutation easier.

It can e.g. B. the flow through the pole tip can be slightly increased in any case, so that an entering coil quickly comes to the correct voltage.

The commutation works as follows:

The brushes are rotated forward until

the voltage that is generated in the Arrkerspule, and which is about to apply the brushes leave to be so much smaller than the voltage of the coil under the pole that the Current in the coil that leaves the brush drops to zero before the commutator bar separated from the brush. Since the machine is wound in series, so it is Field approximately proportional to the current at any moment, so that theoretically favorable conditions for the current reversal at all loads are to be achieved. When turning counterclockwise, if the armature coil comprises more than the pole pitch, a member of the coil 2 still below the Be pole 13, while the other link 3 has left the pole end of the pole 11, so that the Commutation voltage is proportional to the current in the coil 14 and independent of the Current in coil 16, which has a different phase. The brush is in the under the part located at the pole is preferably made of a mixture of metal and coal, which results in low contact resistance, while the part of the brush on which as a result inaccurate setting sparks could occur which is made up of carbon. With such brushes large width it is possible to use a commutator that is considerably smaller than with the usual use of narrow brushes with high resistance.

In the figure, only one series field winding is shown for each pole, leave it of course but additional coils apply to any of the phase circuits of the machine like this are connected so that the voltage generated in each armature phase is a desired one Phase has.

The voltage that is generated in a single armature coil 2, 3 is the resultant from two tensions. One of the components is a voltage that, as noted, is in Phase is with the current that passes through brush 8, but the other is in Phase shifted voltage by 180 ° with respect to the current which passes through the brush 10. The resulting voltage that arises in this way brings the current that runs the secondary circuit the induction motor or generator to which the machine is connected, flows through, tends to advance in phase, and at the same time causes a decrease in Slip of the rotor of the induction machine; The larger the component that is in Part 3 of the coil is created, d. H. the larger the component that is in phase with the Current of the brush 8, the greater must also be the reduction of the slip. By Enlargement "of this tension component it is apparently possible to the slippage on To bring zero, and the excitation machine would then act as a DC generator, the induction machine but work as a synchronous machine. You only need to interrupt one of the exciter circuits, e.g. B. the from the brush 10 to make the induction motor work as a synchronous motor. The exciter 6 then works as a DC generator with two terminals connected to the Brushes 8 and 9 are fed. If you still have the tension component over this If the value is increased, the slip of the rotor becomes negative, so that the induction motor at a speed that is above the synchronous speed, or the Induction generator with a speed below the synchronous speed lies, works.

If only one coil is used for each pole, as in Fig. 1, the voltage generated in any circuit of the rotor will ^{have a component offset by 90 ° from} the rotor voltage and also a component that supports the rotor voltage. This arrangement is the most suitable for increasing the power factor of induction motors. But it is also possible to attach two or more series coils on each pole, through which currents of different phases flow, so that any desired excitation phase can be produced. Furthermore, this excitation phase can be regulated at will by changing one or the other of the currents that excite the pole it has flowed through the coil 14, pass through another coil at the pole 13, in such a direction that it increases the voltage which is generated in the armature coils 2, 3, 4, 5. The voltage in these coils is with the current in phase. This has the effect that the total voltage,

Claims (3)

which the pathogen produces is almost in phase with the voltage generated in the rotor. At the same time, however, the excitation derived from the coil 16 achieves a considerable lead component which can be made just as large as one wants it to be. This advance component has little effect on the motor's slip, but the motor's power factor is improved. If you change the voltage generated by the exciter, either by changing its speed or by changing the excitation current, you can do that. Regulate motor slip for any load 'and within wide limits. It is not necessary to change the ratio between the 900 component and the direct component for this purpose, although this can be done by suitable means. In systems for balancing the load using an induction motor and flywheel, it is customary to influence the change in speed of the flywheel by changing the resistance in the secondary circuit of the induction motor. The exciter according to the present invention is obviously suitable for such load balancing systems and can serve to reduce or increase the speed of the rotor by changing the amount and value of the electromotive force that is in phase with the voltage in the corresponding rotor circuit in the exciter Induction machine is generated to effect. Such a balancing arrangement is. naturally more economical than the aforementioned arrangements, in which energy is destroyed by the resistors in the rotor circuits. Fig. 2 shows, as mentioned, an arrangement of the circuits of the exciter and the induction motor or generator, which is particularly useful for high-speed machines, e.g. B. turbo generators is suitable. The armature of the exciter is mounted on the same axis 22 as the secondary winding of the induction motor or generator. This has a secondary winding divided into two phase circuits 23, 24, one end of each of these circuits being connected to the axis 22 at 25. The other end of the phase circuits 23, 24 is connected to the insulated slip rings 26, 27 on the axis 22. The contact brushes 28, 29, which slide on the said rings, are connected to the brushes 30, 31 of the exciter machine. In this case the exciter has four field poles; the inner ends of the armature coils are connected to the axle at the common point 32. The operation of the exciter is similar to that of the arrangement according to FIG. • Patent claims: 1. Mefar phase series connection - commutator machine, in particular for exciting induction motors and generators, characterized in that the armature is a has open winding with coils connected in star, for the purpose of the circuits of the machine and the phase relationship between these currents to be able to maintain in a stable manner. 2. Embodiment of the machine according to claim 1, characterized in that each arm of the star armature winding consists of two parts connected in series are offset from one another by one pole pitch, so that the two parts of the effective coils are under different phases associated field poles lie. 3. Exciter machine directly coupled to an induction machine according to claim i, characterized in that the linkage point of its armature winding with the interlinking point of the star-connected rotor winding of the induction machine is connected by the axis common to both machines. For this purpose ι sheet of drawings.