PL411B1 - A method to prevent an unacceptable increase in the number of rotations of asynchronous motors during a negative load. - Google Patents

Description

The following circuit arrangement is intended to prevent an unacceptable increase in the number of rotations of asynchronous motors operating under negative load. First of all, it is to prevent exceeding the synchronous number of revolutions. This type of load ratio occurs in the first row with mine winches and other lifting devices when the weight is suspended. But this system is also applicable in all those other cases in which the weight may rush the motor, for example in railroad traffic on a sloping line or when a machine is running of any kind which itself carries out mechanical work on the shaft. In order to prevent an increase in the number of revolutions according to the invention, the induced part of the motor is excited, i.e. the rotor, before or during the attainment of a synchronous number of revolutions with a constant current, so that the rotor is decelerated by this excitation, or as a synchronous alternator it continues with a synchronous number of revolutions. As long as the motor load is negative, so as long as the energies are multiplied or returned to the grid. Figures 1 and 2 show examples of application of the invention with reference to a mine winch. 1 shows, for example, the drum on which the weight 5 hangs, which is lowered in the direction of the arrow, 3 shows an asynchronous motor connected to the mains 4, 5 its slip rings connected to a control resistor 6. Two further rings the non-slip rotor windings to which a separate DC excited rotor winding is connected are marked with the number 7. 8 shows a DC excitation machine whose positive pole is connected directly to one of the slip rings 7 for DC, while the pole is negative is connected by a switch 9, a direction indicator 10, a switch 11 and a regulating resistor 12 with the second slip ring 7. Switches! it is switched on by a so-called zero voltage switch 13 as soon as the rotor voltage at the slip rings 5 for alternating current becomes zero, i.e., when the rotor runs synchronously. At this point, the DC circuit is closed and the rotor of the asynchronous motor is excited with the DC current, so that it continues to rotate as a synchronous motor without any further increase in speed. Auxiliary switch 9 and a switch 9 connected to it in parallel as well as ¬ Non-directional indicator iO, is used only for reversal movements. The switches 9 and 9r are connected to the control lever of the asynchronous motor in such a way that when the control lever is pivoted in one direction of movement, the switch 9 is closed, and the switch 9 'is open, while in the case of a deviation in the other direction. In the course of the movement, the switch 9f is closed and the switch 9 is opened. If the switch 9 corresponds to the indicated direction of rotation of the machine in the direction of the arrow, the direction indicator 10 switches it into the excitation current circuit; a switch 9 'is provided for the other direction of rotation. If, therefore, during the direction of rotation indicated by the arrows, after activating the machine with a direct current, the control switch returns to the position controlling the direction of rotation in the opposite direction, then switch 9 opens when passing through the zero position, and the excitation itself is turned off The direct current is run so that the motor runs on as an asynchronous motor momentarily. Reactivation of the 'DC excitation by the switch 9' is then not possible at all before changing the direction of rotation of the motor, because the indicator of the direction of rotation must first move to the second position, marked with dashes. Since, after changing the direction of movement of the motor, it was found that the motor, turning in the opposite direction, would obtain a synchronous number of revolutions, the relay 13 closes the DC circuit. Separate slip rings are not necessarily needed. It is possible to excite the motor with a DC current also by using slip rings 5 for alternating current, either only two of them or all three. The resistor 6 is deliberately disconnected in order to avoid unnecessary energy losses. This is also best done automatically depending on the DC switching device, so for example depending on the relay 13. In this case, the rotor is executed in the normal way without a separate DC-excited winding. The switching on of the DC circuit may also take place in some other way, for example by means of a centrifugal regulator or the like, which turns on the switch i when the motor reaches the synchronous number of revolutions. This device can be made on the assumption that the frequency of the network does not change, because the excitation with direct current is activated either at too high or too low speed. Another connection system in which the defect is 2-th is removed, as in Fig. 1, is shown in Fig. 2. In this case two frequency meters 14 and 15 are used, made, for example, as frequency needle meters. In one meter, the needles are marked with the letters a1, a2, and% and td, in the second with the letters b1, b2, 68 and td. The frequency meter 14 is connected to the network 4. The meter 15 gives the number of revolutions of the asynchronous motor, e.g. in that it is powered by an auxiliary alternating current generator connected to the axis of the asynchronous motor. Below the needles there are switches 16, 17 and so on for one frequency meter, 26, 27 and so on - for the other,. For example, each two circuit breakers facing each other are connected in series into the DC induction circuit of an asynchronous motor. If, for example, the needle a1 is deflected, then the switch 16 is turned on, and when the needle b1 is deflected simultaneously, the switch 26 is also turned on simultaneously, so that excitation with a direct current occurs. The device should therefore be designed only in such a way that the opposing needles of the two switches show the frequencies which correspond to each other during synchronous operation. Since each frequency meter contains a series of needles equipped with auxiliary switches in series, the frequency of the network may fluctuate within certain marked limits, with the result that proper activation of the excitation with direct current when synchronism is achieved is not prevented. With steels it is necessary to turn on gradually in order to obtain a safe and smooth entry of the motor into synchronism. The resistor 12 serves for this, which at the moment of turning on the engine is fully turned on, and after turning on the engine it is slowly turned off. This switching off of the resistor is best done automatically, for example by the zero voltage switch 13 discharging the stop part, so that the weight or spring can then shift the sliding contact of the resistor 12 in the right direction. which one is not needed, since a source of current is used, which supplies a low voltage during switching on, and only after switching on it slowly increases its voltage. For this purpose, a series DC generator is used. At the moment of switching on, the voltage is equal to zero, and then when the DC circuit is closed, the machine is self-excited. The series excitation machine can be run separately, but it can also be connected to the asynchronous motor itself, as shown in Fig. 1. ¬ vacuum controller, eg mercury or with zarowe cathodes. PL

Claims (1)

Patent claims. 1. '1. A method to prevent an unacceptable increase in the number of rotations of asynchronous motors during their negative load, the characteristic feature that when there is synchronism between the rotor and the field, the rotor is automatically energized with a constant current switched on in order to obtain a constant number of revolutions. while the engine is still running. 2. ' The method of lugs 1, the significant point is that a series DC generator serves as the source of the excitation current. 3. A safety device for applying the method of claim 1 1, characterized by the fact that the direct current is turned on when two meters - 3 - of frequencies are consensually indicated, one of which gives the frequency of the network, and the other - the amount of rotation of the rotor. 4. A safety device made of claim 1 1-3, it is characteristic that the direct current is switched on by means of a zero voltage relay (U-13) connected to the conductors of the sliding rings (5) of the alternating current of the rotor. 5. A safety device made of claim 1 1-4 for an alternating direction of motion, it is characterized that there is a switch in the DC excitation circuit and that this circuit is opened by the control lever of the asynchronous motor when it is deflected in the opposite direction of rotation. 6. A safety device made according to claim 1-5, characterized by the fact that it includes an indicator of the direction of rotation (10) of the asynchronous motor, which, depending on the direction of rotation, connects the first or second DC switch (9-9 ') in the DC excitation circuit. Siemens-Schuckertwerke G. m. B. H. Deputy: I. Myszczyóski, patent attorney. For the patent description M 411. FigJ Fig.3 k ¦ / z a * j J l a. * Sk * P J l Cli | Jlr / * J t SA S5 l L L _i L L <^ l L of the Kozianski characters in Warsaw PL