DE236854C - - Google Patents

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■■ - M 236854 CLASS 21 d. GROUP

Dr THEODOR LEHMANN in BELFORT.

Procedure for starting synchronous motors. Patented in the German Empire on September 16, 1910.

For this registration, the examination according to the Union Treaty of

March 20, 1883

Recognized on December 14, 1900 on the basis of the registration in France on September 16, 1909.

the priority

Starting synchronous motors generally requires artificial aids. The best known are so-called starting windings on the magnetic poles, which are designed in the manner of damper windings and independent of the DC magnet winding are short-circuited in itself. The latter usually remains open during the entire starting period, so that the auxiliary winding has to supply the entire torque. However, such short-circuit windings have serious disadvantages. First of all, even when the machine is idling, they cause excessive current consumption, which can result in unacceptable network disturbances, particularly in the case of larger machines. In addition, their resistance is given once and for all, and since it has to be relatively large with regard to the first starting period, the auxiliary winding alone does not come close enough to synchronism to be able to switch on reliably. An attempt was made to avoid the latter disadvantage by switching the stator to a lower number of poles. In connection with an ordinary damper winding, the synchronism can be achieved from below or from above by means of pole switching in the stator. Apart from the large starting currents, this method has the disadvantage that the motor easily gets stuck at intermediate speeds. It moves this name from the fact that in machines with salient poles, the magnetic resistance of the cross-field (a in Fig. 1) from that of the main field · (b in Fig. 1) is different. The damper winding therefore does not behave symmetrically with respect to both fields, all the more so since the related stray fields are also significantly different. As a result, the reaction field of the auxiliary winding turns out to be an imperfect rotating field with strongly pronounced alternating fields. It is now known that single-phase closed armatures of asynchronous multiphase motors have the tendency to assume half the synchronous number of revolutions and often develop a considerable torque at this speed. With a small air space and relatively high magnet saturation, the effect of the alternating field caused by asymmetry in the auxiliary winding can become so prevalent that the motor does not go beyond the saddle point of the torque curve and remains far below the synchronism.

Underspeed can also occur with the first-mentioned method, since the Currents induced by transverse and main fields in the damper winding are not phase symmetrical are.

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One could now get the idea by including the magnetic winding (c Fig. i), which is only induced by the main field, the unequal retroactive behavior to compensate for the damper winding in relation to the cross and main field. As a result However, due to its much smaller scatter, the damper winding has a strong shielding effect on the magnet winding, so that

ίο the latter is all the less effective as it would only act as a single-phase winding. If, in addition, pole switching is used in the stator, the magnet winding would not have any effect at all, because the resulting EMF induced in the exciter winding would always be zero due to the different pole numbers on both sides.
. The present invention is based on the idea of using windings when starting synchronous motors which are not induced simultaneously by transverse and main flux, so that the transverse and main reactance can be influenced separately in the most favorable way for starting. The magnet winding is characterized by the fact that it is only induced by the main field; however, it is not readily suitable for occasional purposes for the reasons already mentioned.

However, if you switch the armature winding to half the number of poles when starting, then with respect to the main field, the phase distance between two adjacent magnet coils is no longer 180 °, but only 90 °. If you now connect the odd ones on the one hand and on the other hand, the straight Magnetspuleri with each other so that their E. M. Ke. add up, This gives you two partial windings that are exactly 90 ° out of phase with one another. the DC winding set up in this way now turns out to be a symmetrical two-phase winding and can now, switched to suitable resistances, a much stronger torque to be developed as a single-phase circuit.

In order to utilize the transverse field, 8-shaped winding elements are now used according to the invention, which are axially symmetrical are embedded on the pole circumference towards the center of the pole and are self-contained. While the in induced the two loops of such an 8-shaped winding element from the transverse field E. M. Ke. add up, the E.M. Ke. each other up. These 8-shaped windings do not have any shielding effect on the magnet winding exercised and vice versa; the two windings do not induce one another. It should be noted that if there is only one 8-shaped turn on each pole, the auxiliary winding as a whole forms a symmetrical two-phase winding because as a result of the pole switching in the armature, two turns located on adjacent poles are shifted in phase by 90 °.

8-shaped coils are already known per se. So far, however, they have served one essential other purposes, insofar as they are intended to destroy the cross-field as a matter of principle; for single-phase motors This is intended to eliminate the spark voltage resulting from the cross-field in AC machines the field distortion caused by the cross-field can be corrected. the On the contrary, the present invention seeks to utilize the transverse field. Through the 8-shaped Winding elements should be used, the cross field just to develop torque, which would be impossible from the start if the cross-field were destroyed. Structurally finds this Difference in purpose in their expression that earlier as little resistance as possible, according to the invention but high ohmic loss, i.e. a relatively high resistance, is strived for.

One can be satisfied with the invention with the resistance of the direct current winding Provide only changeable and choose the resistance of the auxiliary winding once and for all so that for the first half of the Tempering period the reactance ratios are the most favorable. Since started with half the number of poles is, by the way, it is enough to go just a little over half the synchronous number of revolutions, to be able to switch on. An essential advantage of this starting device is, finally, that the main field when starting in is not throttled in any way, since initially the two-phase switched direct current winding is also used works with considerable resistance. This reduces the current surge when switching on as well as the constant current consumption many times smaller than with motors that throttle using cross and main fields Damp he windings are started, so that one is usually without artificial aids can leave on. For starting with normal damper or short-circuit windings gen is just the weak field and the high current load characteristic, while here on the contrary not only with a strong field and low current load, but because of the greater resistance of the starting windings is also used with far better cos φ. You can finally with just one of the two windings with not too great a torque start because the DC winding and the auxiliary winding despite their uniaxial Structure with a normal number of poles as a result of the pole switching in the armature with respect to the fields that induce them, two-phase symmetrical behave.

To illustrate, assume a synchronous motor with four p poles, the armature of which is wound for any number of phases. In Fig. 2 the development of part of the circumference of this motor is shown for a specific position of the armature relative to the field magnet. Only one phase of the anchor is shown. For a certain moment the current directions in the various coils are those indicated by arrows. For starting, the armature coils are now connected in such a way that only two p-poles are present, ie that at a certain moment the current in the armature has, for example, the current directions shown in FIG. Then the magnetic poles in this position can be divided into two groups, namely: 1. the poles e, e ', e " and 2. the poles f, f, f". In the former, the transverse force line flux g, g, g closes through the pole heads and is lost to the magnet winding; In contrast, in the second group f, f, f " all lines of force h, h ', h" completely penetrate the nuclei of both poles and close through the pole yoke. These main force line flows generate EM Ke in the magnet winding. and with suitable switching of the same also a useful torque. If now, the mutual position of the armature to the field magnet is electrically shifted by 90 °, the lines of force flows of the poles e, e ', e "are fully utilized and the lines of force of the poles f, f, f" have no effect. It follows that the EM Ke induced in the windings of the poles e, e ', β " is 90 ° in phase with that in the poles f, f', f". are shifted. The magnet coils of the poles e, e ', e " are now connected to one another in such a way that the EM Ke induced therein.

are connected in series (i in Fig. 4), and in the same way the magnetic coils of the poles f, f, f ″ are connected (/ in Fig. 4). The windings i and j are finally connected by adjustable resistors k , which have two phases Of course, both windings can also be connected to a resistor, so that a real asynchronous motor is created during start-up, the rotor of which is wound in two phases, whereby the part of the transverse force line flow that is not used is greatly reduced.

This remainder is now used by an auxiliary winding. The same is designed in the manner shown in FIGS. Each magnetic pole is intended to be divided into two equal parts parallel to the machine axis, each of which is encompassed by a current loop I or m. The two loops I and m of a pole piece are finally connected to one another in the form of an 8, as can be seen from FIG.

Such 8-shaped winding elements make use of the transverse flow without any shielding effect on the main flow. The EMF induced in the loop / by the transverse force line flow g is connected in series with the EMF induced in the circuit m; both loops therefore give rectified torques. The EM Ke induced by the main fluxes h, h ' in both loops of the 8-shaped turns. are opposed to each other. the 8-shaped turns as such are therefore not induced by the main field. 7 and 8 show an embodiment of these auxiliary windings. The conductors η are surrounded by insulation 0 . There is a conductor at each end of the pole piece, while two conductors, insulated from one another, are concentric in the middle. Four flat end connections complete the figure 8 loop. In most cases, the insulation of the two outer conductors can be dispensed with.

In special cases it may be advisable to both form a two-phase Winding by means of the direct current magnet winding and the auxiliary winding each alone to use. The auxiliary windings alone, their structure, are sufficient for smaller torques is as simple as that of damper windings.

Finally, in addition to a single auxiliary turn in the form of an 8, several such Turns per pole are used. In Fig. 9, for example, a magnetic pole is with two such auxiliary windings shown in the form of an 8. With externally excited machines A high excitation voltage is often prescribed, which causes the magnet winding during starting Dangerously high E.M. Ke., up to thousands of volts, can occur. To bring this voltage down to a permissible value, you can to a certain extent the magnet winding into several parallel circuits' split up, however some complication occurs in the connections.

If it is only a matter of no-load starting, an auxiliary winding made of 8-shaped ones is usually sufficient Coils of suitable resistance. When starting, only the armature is switched to half the number of poles, while the magnet winding is left at its normal number of poles. Because of the difference in the number of poles the E.M.K. induced in the DC magnet winding is then the same at all times Zero.

As a result of the reduced number of poles, the synchronism is still slightly exceeded and the engine can be started. Here it has no further concerns,

that the resistance of the auxiliary winding is not adjustable because hardly more than half of the Synchronism must be achieved3.

If the motor is to be connected to the mains, one of the known Tools can be used to reduce power consumption. If the armature winding is connected in parallel several times, the starting reactance can be reduced by partially connecting in series expediently increase and reduce the current surge to the same extent. You can also use an autotransformer or a Use a choke coil with a short-circuit device in one or more stages. In the In most cases, however, special aids are not required because in contrast for other starting processes with damper windings, the main flow initially neither from the auxiliary winding nor from the magnet winding is throttled, as the latter only gradually closes across the resistors will. So you have the full main flow reactance when starting, so that the current consumption can be reduced quite significantly. As for the actual connection, it is easy due to the pole switching, to exceed synchronism. It is then only necessary to decrease the number of revolutions to let and with the help of the known

• 30 devices, such as phase lamps, synchronoscopes, etc. to connect the motor to the mains, if he goes through synchronism.

The auxiliary winding can be designed in different ways structurally. Likewise can the devices for switching the number of armature poles and the solenoids can be any. In particular, pole changers can be used to switch the magnet winding, which are similar in shape to the apparatus commonly used with asynchronous motors and at Series connection only require three slip rings.

If finally the number of poles of the motor is not divisible by 4, then the auxiliary winding can, if is used alone, of course other ratios for pole switching to get voted. But the shared use of the magnet winding is not part of the divisibility the number of poles bound by 4. Is z. B. the number of poles by 3, so also by 2x3 divisible, by pole switching of the armature winding in the ratio 6 ρ to 2 ρ the Magnetic winding can be converted into a three-phase winding in a similar manner to how it was shown for two phases.

Claims (4)

Patent Claims: i. Method for starting synchronous motors, characterized in that After switching the armature to half the number of poles, the main flux is divided into two groups, each with half the number of poles, for starting Magnet winding, which can be switched to one or a common controllable resistor, two in Phase shifted by 90 ° against each other E. M. Ke. be induced and at the same time the transverse flux is used by an auxiliary winding, the conductor of which the magnetic poles in enforce the direction of the motor axis and are connected to one another at the front ends are that 8-shaped closed turns arise. 2. The method according to claim i, characterized in that the magnet winding or the auxiliary winding can be used alone. 3. Apparatus according to claim 1, characterized in that several on each pole 8-shaped auxiliary windings are attached. 4. Apparatus according to claim 1, characterized in that the two inner Head of the auxiliary winding are performed concentrically and isolated from each other. 1 sheet of drawings.