SU1273218A1 - Pulse generator for electric-spark machining - Google Patents

Abstract

The invention relates to the field of electrospark machining of metals and other conductive materials in a dielectric solid. The purpose of the present invention is to increase the efficiency. This goal is achieved by the formation of voltage pulses in idle mode with a frequency twice as high as in the short circuit mode of the operating mode, which contributes to the reduction of time lost during processing. The pulse generator contains a power source 1, charge 2 and discharge 5 thyristors, charge 3 and discharge 4 chokes, load 6, electrode electrode / current 7, storage capacitor 8, diode 9, control unit consisting of a threshold device 10, the distributor 11 pulses, the clock generator 12. An additional thyristor 13 and a time relay 14 are introduced into the pulse generator W. 1 il.

Description

The invention relates to electric spark processing of metals and other conductive materials in a dielectric fluid medium.

The purpose of the invention is to increase the efficiency.

The drawing shows a diagram of a pulse generator for electric spark processing.

The pulse generator for electric spark processing contains a power supply 1 connected in series to a closed circuit, a charging thyristor 2, a charging inductor 3, a discharge inductor 4, a discharge thyristor 5 and a load 6, in parallel with which there is an interelectrode gap 7, a storage capacitor 8, one terminal of which is connected to the connection point of the terminals of the charging 3 and 4 discharge chokes, and 'the other terminal is to the connection point of the load 6 with the power source 1, diode 9 and the control unit, consisting of a threshold device 10, the input of which the second is connected to the connection point of the terminals of charging 3 and 4 of the inductors with a storage capacitor 8, and the output is to the output of the pulse distributor 11, the first output of which is connected to the control electrode of charging thyristor 2, and the second output to the control electrode of discharge thyristor 5, clock 12, the output of which is connected to the second input of the pulse distributor 11, while the discharge 5 and charging 2 thyristors are turned on according to, and the diode is opposite to the power supply 1, additional thyristor 13 and relay 14 times change, and the first electrode of the additional thyristor 13 is connected to the connection point of one of the terminals of the discharge choke 4 with the first electrode of the discharge thyristor 5, the second electrode of the additional thyristor 13 is connected to the first output of the power supply 1, and the control electrode is connected to the output of the time relay 14. An additional 13 and discharge'5 thyristors are connected by the same electrodes, the input of the time relay 14 is connected to the connection point of the terminals of the charging 3 and 4 discharge chokes with the output of the storage capacitor 8, the first electrode of the diode 9 is connected to the first output of the source ^! power supply, and the second electrode of the diode 9 is connected to the connection point of the second electrode of the charging thyristor with one of the terminals of the charging dros5 village 3, the first electrode of the charging thyristor 2 is connected to the second terminal of the power source 1.

The proposed pulse generator for electrospark processing was created 10 on the basis of a generator of the GKI-250 type.

The pulse generator for electric spark processing operates as follows.

The threshold device 10 fixes 15 two states of the storage capacitor 8 — it is charged or discharged and controls the operation of the pulse distributor 11 in such a way that if the capacitor 8 is charged, 20 pulses of the clock generator 12 start the charging thyristor 2, and if the capacitor 8 is discharged - they arrive at thyristor control electrode 5. When a voltage of opposite polarity appears on the capacitor 8 due to its overcharging, the diode 9 opens, through which the charge is recharged and appears on the capacitor posal working 30 polarity.

In idle mode, due to the large value of the load resistance 6, the discharge thyristor 5 opens only for the duration of the start-up pulse and after its end is not kept open. In this case, the capacitor 8 remains non-discharged and all the pulses of the clock generator 12 are supplied '40 to the control electrode of the discharge thyristor 5. Thus, a pulse voltage with a frequency of the clock generator 12 is formed on the interelectrode gap 7. From the moment 45 of the row of the capacitor 8, the relay 14 starts counting. time and, if the capacitor 8 remains charged all the time (idle mode), at the end of the countdown 50, a pulse is issued, unlocking an additional thyristor 13, through which; there is a discharge of the capacitor 8. The next pulse of the clock generator 12 opens the charging thyristor 55 2, through which the capacitor 8 is recharged. If the idle mode is maintained, then the countdown starts again, voltage pulses are formed on the interelectrode gap 7, i.e. the process is repeated.

With each discharge of the capacitor 8, the time relay 14 is reset, so that the additional thyristor 13 is unlocked only in idle mode.

The inclusion of an additional thyristor 13, triggered by the time relay 14, allows to reduce to a minimum of 10 energy loss in idle mode. In this case, the capacitor is recharged with a minimum frequency, which is determined by the parameters of the selected circuit elements. 15 In the proposed generator in idle mode in the interelectrode gap voltage pulses are generated with a frequency that is two times higher compared to the short-circuit mode of 20 rd short circuit or operating mode. This accordingly increases the likelihood of breakdown and helps reduce processing time losses.

Claims (1)

The invention relates to the electric-spark processing of metals and other conductive materials in a medium of a dielectric solid. The purpose of the invention is to increase the efficiency. The drawing shows a diagram of a pulse generator for electrospark processing. The pulse generator for electric-spark processing comprises a power supply source 1, a thyristor 2, a charging choke 3, a discharge choke 4, a discharge thyristor 5, and a load 6, in parallel with which the interelectrode junction 7, connected to a storage capacitor 8, are connected in series into a closed circuit, one pin of which is connected to the point of connection of the charging 3 and bit 4 droplets, and the OTHER pin to the connection point of the load 6 with the power supply 1, the diode 9 and the control unit consisting of the threshold device 10, which input It is connected to the point of connection of the charging 3 and bit 4 chokes with the storage capacitor 8, and the output to the output of the pulse distributor 11, the first output of which is connected to the control electrode of the charge thyristor 2, and the second output to the discharge control electrode one thyristor 5, a clock generator 12, the output of which is connected to the second input of the pulse distributor 11, while the bit 5 and charge 2 thyristors are turned on according to, and the diode is opposed to the power source 1 additional thyristor 13 and relay 14 the first electrode of the additional thyristor 13 is connected to the point of connection of one of the discharge droplet 4 bridges with the first electrode of the discharge thyristor 5, the second electrode of the additional thyristor 13 to the first output of the power supply 1 and the control electrode to the output of the relay 14 Additional time 13 and the discharge thyristors are connected by the same type of elec- trons, the time relay input 14 is connected to the junction point of the charging 3 and bit 4 chokes with the storage capacitor 8, the first electrode of the diode 9 The source of the power supply 182 1 is connected to the first terminal, and the second electrode of diode 9 is connected to the connection point of the second electrode of the thyristor 2 with one of the terminals of charge throttle 3, the first electrode of the charge thyristor 2 is connected to the second output of power supply 1. The proposed pulse generator for the electric-spark treatment was created on the basis of a generator of the type GKI-250. The pulse generator for the electric-spark processing works as follows. The threshold device 10 detects two states of the storage capacitor 8 - charged or discharged and. controls the operation of the pulse distributor 11 in such a way that if the capacitor 8 is charged, the pulses of the clock generator 12 start charge thyristor 2, and if the capacitor 8 is discharged, go to the control electrode of the thyristor 5. When appearing on the capacitor 8 the voltage of the opposite polarity due to its recharging opens diode 9, through which the recharging is performed again and the voltage of the working polarity appears on the capacitor. In idle mode, due to the large value of load resistance 6, discharge thyristor 5 is opened only for the duration of the triggering pulse and after its termination is not kept open. In this case, the capacitor 8 remains unstressed and all the pulses of the clock generator 12 are fed to the control electrode of the discharge thyristor 5. Thus, a pulse voltage with the frequency of the clock generator 12 is formed on the interelectrode gap 7 the time relay 14 and, if the capacitor 8 is still charging all the time (idle mode), at the end of the countdown time, a pulse is released that unlocks the additional thyristor 13, through which; capacitor 8 is discharged. The next pulse of clock generator 12 opens charge thyristor 2, through which capacitor 8 is again charged. If the idle mode is maintained, then the time starts again, and voltage pulses are generated on the interelectrode gap 7, i.e. the process repeats. Each time the capacitor 8 is discharged, the time relay 1A is reset, so that the additional thyristor 13 is opened only in idle mode. Turning on an additional thyristor 13, triggered by time relay 14, minimizes energy losses during idling. The resampling of the capacitor is performed at the minimum frequency, which is determined by the parameters of the selected circuit elements. In the proposed generator, in the mode of idling, in the interelectrode gap, voltage pulses are formed with a frequency twice as large as the short circuit mode 6 or operating mode. This accordingly increases the likelihood of breakdown and contributes to the reduction of time lost during processing. The claims of the Pulse generator for the electrode-spark processing, containing a power source, a charge thyristor, a charging choke, a discharge choke, a discharge thyristor and a load, parallel to which the interelectrode gap is connected, are in series connected to the point of connection of the charge and discharge chokes, and the other pin to the point of connection of the load with the power source, a diode and a control unit consisting of a threshold device a, whose input is connected to the point of connection of the charging and discharging chokes with a storage capacitor, and the output to the input of the pulse distributor, the first output of which is connected to the control electrode of the charging thyristor, and the second output - with the control electrode of the discharge thyristor a clock generator, the output of which is connected to the second input of the pulse distributor, wherein the discharge and charge thyristors are turned on according to, and the diode is opposite in relation to the power source, characterized in that No additional efficiency, an additional thyristor was inserted into it, and a time relay control unit, the first additional thyristor electrode connected to the connection point of one of the discharge throttle outputs with the first discharge thyristor electrode, the second additional thyristor electrode connected to the first output of the power source , and the control electrode to the time relay output, with the additional and discharge thyristors connected by the same electrodes, the time relay input is connected to the junction point The first electrode of the diode is connected to the first output of the power source, and the second electrode of the diode is connected to the point of connection of the second electrode of the charging thyristor with one of the other diodes of the charge thyristor the second output of the power source.