RU23686U1 - POWER SUPPLY FOR ARC WELDING - Google Patents

Abstract

A power source for arc welding, containing an AC converter into a constant and main winding of the inductor, connected by one output to one of the poles of the converter, and the other to the output terminal of the power source, the second terminal of which is connected to another pole of the converter, characterized in that the diode and the inductor winding, connected to each other in series and parallel to the output poles of the converter, with respect to which the diode is connected in the locking polarity, and an additional winding The fabric is connected in series and in accordance with the main winding.

Description

The utility model relates to electrical engineering and can be used in power sources for arc welding.

Known rectifier devices for arc welding, containing an AC to DC converter and a inductor winding connected to one of the poles of the converter and connected in series in the welding circuit 1.

The use of a inductor allows you to limit the slew rate of the current during short circuits, at a certain level, which is determined by the welding mode, and also allows you to ensure the continuity of the welding current in the presence of significant ripple voltage at the output of the rectifier. The fulfillment of these conditions is especially important for arc welding with a constant wire feed speed at which frequent short circuits are possible and a wide range of current regulation is required. The disadvantage of such power sources is the difficulty of obtaining a stable arc in low current mode, and hence the quality of welding, since for this it is necessary to increase the inductance of the inductor, and this contradicts the condition for ensuring the required current rise rate (1, p. 142).

The closest analogue of the proposed utility model is the industrial rectifier NDG-201 2, containing an AC to DC converter with a choke in the welding circuit. The rectifier of the prototype has the same drawback as the above analogue.

The problem, the solution of which the claimed utility model is aimed at, is to eliminate the indicated disadvantage of the prototype and create a power source with a wider range of welding currents, while maintaining arc stability, and with the required current rise rate in the short circuit mode.

poles of the converter and connected in series to the welding circuit. An additional diode and a second inductor winding are connected to the proposed power supply, connected to each other in series and parallel to the output poles of the converter, with respect to which the diode is connected in the locking polarity and the additional winding is connected in series and in accordance with the main winding.

The essence of the utility model is illustrated in the drawing.

The power source for arc welding contains an AC to DC converter 1 and inductor winding 2 connected to one of the transmitter poles and connected in series to the welding circuit, as well as a second winding 3 and diode 4 connected to each other in series and parallel to the output nojnocaM converter, in relation to to which the diode is connected in the locking polarity, and the additional winding is connected in series and in accordance with the main winding.

The power source operates as follows. In the presence of a supply alternating voltage, a unipolar pulsating voltage is generated at the output of the converter, which is applied to the winding of the inductor 2 and the welding circuit and creates a pulsating current. When the instantaneous voltage value of the converter becomes less than the voltage on the arc, the inductor begins to transfer stored energy to the arc circuit, while the polarity of the voltage on its windings changes. If the inductor current is interrupted before the next voltage ripple arrives, the arc will go out, which will negatively affect the welding process. As the instantaneous voltage of the converter decreases, the total voltage of the series-connected windings 2 and 3 increases and when it becomes more than the voltage on the arc, diode 4 opens and the welding circuit current closes through diode 4 and the series-connected windings of inductor 2 and 3. the arc current, according to the law of the total current for transformers, will decrease in proportion to the increase in the number of turns under current, but the inductance of the welding circuit will increase in proportion to the square of the increase I am the number of turns under current.

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Thus, with the same inductance of the inductor winding 2, which provides the required rate of rise of the short circuit current, the proposed model allows for a longer time to maintain the current in the welding circuit when the voltage drops of the converter, and thus reduces the voltage of the latter and the welding current, while maintaining the stability of the arc burning , and, as a result, improve the quality of welding.

The proposed utility model is advisable to use in arc welding power sources with a wide range of welding currents and high stability of the welding process.

Sources of information.

1.Potapievsky A.G. Shielding gas welding with a consumable electrode. M., "Engineering, 1974, 240p.

2. Semi-automatic welding PDG-201 UHL. Passport.

Claims (1)

A power source for arc welding, containing an AC converter into a constant and main winding of the inductor, connected by one output to one of the poles of the converter, and the other to the output terminal of the power source, the second terminal of which is connected to another pole of the converter, characterized in that the diode and the inductor winding, connected to each other in series and parallel to the output poles of the converter, with respect to which the diode is connected in the locking polarity, and an additional winding The fabric is connected in series and in accordance with the main winding.