SU543121A1 - Control method for autonomous asynchronous generator - Google Patents

Claims (2)

(connection to sensor 12 of another output is possible). The block 13 is used to control the inverter 4 when the prime mover 1 is started, when the asynchronous machine 2 acts as a starter. The autonomous generator is controlled as follows. The master oscillator 9 generates pulses that follow at a strictly constant frequency. These pulses through the control system 8 supply the thyristors of the converter 5. The converter 5 is the main source of reactive power required to excite the asynchronous mask 4. By setting the constant switching frequency of its thyristors, they set the constant frequency of the magnetizing currents in the stator, and therefore , the constant frequency of rotation of the magnetic field in the gap and the constant frequency of the stator voltage, which is the output. Thus, the independent frequency signal controls the frequency of the output voltage, and the frequency of the output does not depend on changes in the rotational speed, load, and amplitude of the voltage. As in any voltage inverter, the control signals determine the shape and frequency of the voltage converter 5, and the currents in its circuits depend on the size and nature of the load. On the ac side of the converter 5, the magnitude of the reactive component of the current is determined by the total reactive conductivity of the asynchronous machine 2 and the ac consumers. Due to the reverse diode bridge and the capacitor 7, the converter 5 is capable of generating significant reactive power, but it gives as much as the asynchronous machine 2 and the AC load consume. As the load increases or the spin speed decreases, the generator output voltage decreases. With the sensor 11, a signal is given to reduce the opposite-emf. inverter 4, which leads to an increase in the rotor current of the asynchronous machine 2 and an increase in its active power and, consequently, the output voltage of the generator. The reactive power required for this increase is provided by the converter 5. With an opposite change in load or speed, the control is adjusted in the opposite direction. Since the converter 5 has a constant transmission coefficient over voltage, then the emf. DC output varies in proportion to the emf. AC output. The adjustment setpoint is chosen such that over the entire operating range of speeds and loads emf. DC output would be greater than the emf. batteries, which ensures their charge. The current to the charge of the batteries and to the consumers of direct current flows through the diodes of the reverse bridge. Thus, the proposed method makes it possible to reduce to almost zero error in frequency, both in statics and in dynamics. This error is only determined by the instability of the frequency adjuster. By eliminating the effect of frequency variation on voltage, the static and dynamic voltage stabilization error is reduced by about half, and the control speed is increased. Claims The method of controlling an autonomous asynchronous generator with a valve converter in a stator circuit and a rectifier-inverter converter in a rotor chain, consisting in acting on the output voltage of the generator to one of the converters, characterized in that, in order to improve the accuracy and speed of adjustment By this signal, the inverter is controlled in the rotor circuit, and the switching frequency of the converter valves in the stator circuit is set constant. Sources of information taken into account in the examination: 1. M. M. Botvinnik and Yu. G. Shakar N “Managing a non-transitory current machine” ed. "Science, 1969 2. Automated electric drive in the national economy, vol. 1 “Energie, 1971, ed. NG Chilikina, pp. 155-157. s