SU705750A1 - Power source for impulsed arc welding - Google Patents

Description

(54) POWER SUPPLY FOR WELDING PULSE ARC

control topics, the anode of which is associated with the common point of the cathode group of the core circuit, and the cathode with the control Electrodes of the contact thyristors.

The proposed invention is shown in the drawing.

The power source for pulsed arc welding contains a thyristor contactor consisting of anti-parallel tic 1 and 2, resistance 3, which is connected in parallel with the thyristors connected in series with the primary

welding transformer winding 4. The control of the contactor operation is carried out by a control system, which consists of the following blocks: amplifier — shaper 5 control pulses, multivibrator 6 and generator 7 pulses synchronized with the mains voltage. The power supply of all three blocks of the control system of the oscillator is through a bridge rectifier circuit assembled on diodes 8.9, 10 and 11, the voltage that drops my resistance 3 in the interval of the corresponding closed state of thyristors 1 and 2.

The control pulse shaper amplifier consists of a thyristor 12 connected by an anode to the common point of diodes 8 and 9 of a rectifying bridge, and a cathode is connected through diodes 13 and 14 to the control electrodes of the contactor thyristors. The synchronized pulse generator consists of a pulse transformer 15 with windings 16 and 17. Primary winding 16 is connected in series with capacitor 18 with variable resistance 19 and variable resistance 20 (as alternating potentials, other devices, such as transistors ) The value of the variable resistance 19 is usually chosen close to zero.

Parallel to the winding of the pulse transformer 16 and the capacitor 18 is switched on a switching device, for example, a dynistor 21, and parallel to the transducer. The valuable resistance 20 is switched on by a controlled switching device 22 (for example, a thyristor or a transistor). The secondary winding 17 of the pulse transformer 15 through the diode 23 is connected to the control transition of the thyristor 12 of the pulse shaping amplifier.

The control electrode of the thyristor 22 is galvanically connected to one arm of the multivibrator 6. Multivibrator 6 is made on two dynistors 24 and 25, the anodes of which include the switching capacitor 2.

Andyny dynistorov connected to by

Residual power supply pole via variable resistances

21 and 28 and constant resistances 29 and 30. The power of the multivibrator is realized through an AC voltage rectifier selected at iodines 8–11; To increase the stability of its operation, the power of the multivibrator is supplied through the add-on. A capacitive peak capacitive filter, which consists of a diode 34 and a capacitor 31. A diode 32 is connected to one arm of the multivibrator to facilitate the switching conditions of the dynistor 24.

The diode 33 is designed to prevent the supply of a negative voltage to the control electrode of the thyristor 22 at the time when dynistor 24 is cohled by the discharge current of the capacitor 26 along the circuit: capacitor 26, distor 25, diode 32, dynistor 24, capacitor 26. In the absence of diode 33 at the moment switching to the control electrode of the thyristor 22 is supplied with the reverse voltage equal to the direct voltage drop across the diode 32.

The scheme works as follows. Let the polarity of the alternating voltage be such that (., Plus +) above. . The thyristors of contactor 1 and 2 are turned on and the current in the primary circuit of the welding transformer is limited by resistance 3. Then in the first half period the capacitor 31 is charged through diodes 8.34 and 11 and that multivibrator dioder (25, 24) / is turned on which is less than the trigger voltage Let us suppose that the operation of the transistor is 1istor 25. Then through the diode 8, the primary winding 16 of the pulse transformer 15, the resistance 19 and 20 and the diode 11 the capacitor 8 starts to charge. As soon as the voltage of the capacitor 18 exceeds the threshold voltage of the threshold element ( 21), the threshold element is triggered, and a pulse is formed on the secondary winding of the pulse transformer 17 which turns on the thyristor 12 of the amplifier-former 5. After turning on the thyristor 12, the supply voltage is applied through diode 8, thyristor 12, diode 13 to the control switch 1 1 to the electrode of the thyristor 1 of the contactor that causes it to fire.

. As a result, the ballast resistance 3 is shunted by a thyristor contactor. If the resistance 20 i is chosen to be large (for example, equal to infinity), the capacitor 18 does not charge and the control pulse does not form and, therefore, the cooking current will be limited by resistance 3. In a similar way, the circuit works with a negative voltage half-wave With the only difference that the capacitors 31 and 1.8 are going through diodes 9 and 10. The modulator's operation mode does not change until the switching of the dynistors 24 and 25 of the multivibrator occurs. PV, switching of the dynistor occurs at the moment when the switching capacitor 26 is charged before the trigger voltage of the dynistor 24. When the distor 24 is turned on, the capacitor 26 closes and the switching device (thyristor 22) that shunts the resistance 20 and the capacitor charge 18 is implemented through resistance 19 which is very small. As a result, the triggering of the threshold element occurs already at the beginning of the half-wave of the supply voltage and for almost the entire half-period the resistance 3 is shunted by a thyristor contactor. Thus, the time, pause and pulse are controlled by variable resistances 27 and 28, and the voltage during the pause and pulse is controlled by ballast resistance 3 and variable resistances 20 and 19.

The introduction of the proposed power source for pulsed arc welding will improve the quality of the weld, mainly when welding ceiling and vertical welds, as well as for arc welding of thin sheet metal parts.

Claims (2)

1. Author's certificate of the USSR; 315531, class 23 K 9/00, 1972. 2. Sidoruk V.S. et al. Attachment to the welding transformer for modulating the welding current. M., Welding production, 1975, No. 9, p. 48.