RU2537683C1 - Welding transformer for manual arc welding - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device comprises a rod-type transformer with half-windings at each rod, thyristors control unit, thyristors with pick-off diodes between which common connection points there is a commutating capacitor. The thyristors with pick-off diodes and the primary winding of the transformer are connected to clamps of the supply mains and the secondary winding is connected to the load clamps. A pulse transformer is coupled between the primary winding with the same electrodes of the thyristors and the centre tap of the primary winding of the rod-type transformer while its secondary windings are connected in opposition and shunted and through additional thyristors connected to the load clamps and the centre tap of the secondary winding of the rod-type transformer.

EFFECT: welding of metal structures and goods of different thickness during production of installation and repair operations in construction, in household use and other industries of the national economy.

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Description

The invention relates to the field of arc welding of metals by consumable electrodes, in particular to electric welding with alternating current.

The invention can be used for welding metal structures and products of various thicknesses during installation and repair work in construction, in public utilities, in everyday life and in other areas of the national economy.

A known power source for manual arc welding with metal electrodes, selected as an analogue (see, for example, Equipment for arc welding. Reference manual. / Ed. By V.V. Smirnov. - L .: EAID986, p.378, Fig. 8.16, f, g) containing a power transformer, the primary winding of which is connected through a half-wave thyristor switch to the mains, and the secondary winding is connected in parallel with the secondary winding of the pulse transformer through a series capacitor and connected to the load.

The disadvantages of this device are the instability of the amplitude of the exciting pulse initiating the arc, depending on the angle of regulation of the thyristors of the key, and the difficulty of setting the parameters of the stabilizing pulse when the load current changes.

Also known is a power source for arc welding (see, for example, patent No. 2066606 (RF), B23K 9/067, bull. No. 26, 1996), containing a transformer with a primary winding connected through counter-parallel connected thyristors to an AC mains , and a two-winding inductor, one winding of which is connected in parallel to the thyristors through a series-connected capacitor, and its second winding is connected in series with the secondary winding of the transformer and is connected to the load.

The disadvantages of this power source are overestimated weight and dimensions due to the presence of an inductor, the complexity of tuning the oscillatory circuit and the dependence of the locking properties of the thyristors on its natural frequency.

The closest in technical essence to the achieved positive effect is a thyristor transformer for arc welding, selected as a prototype (patent No. 2441733 (RF), B23K 9/06, bull. No. 4, 2012). A thyristor transformer contains a control unit, a pulse transformer, thyristors with cut-off diodes, a capacitor and a rod-type transformer (TST). Semi-windings TST are placed on each core. The TST is connected to the terminals of the supply network by the primary winding through a half-wave thyristor switch, and by the secondary winding to the load terminals. The primary winding of a pulse transformer shunted by a reverse diode is connected between the thyristor electrodes of the same name and the middle terminal of the primary winding of a rod-type transformer. Thyristors with cut-off diodes, between the common connection points of which a capacitor is installed, are connected to the terminals of the supply network, and counter-connected secondary windings of the pulse transformer are connected via diodes to the load terminals. Their common point is connected with the middle terminal of the secondary winding of the rod-type transformer. Due to the transfer of the power transmitted through the transformer to the load and the power of the pulses, the excitation reliability and stability of the arc burning are increased, and losses in the transformer elements are reduced.

The disadvantages of the prototype are: the dependence of the control range on the angle of regulation and on the parameters of the active-inductive load, low energy performance.

The aim of the invention is to ensure the independence of the control range from the parameters of the active-inductive load, increase energy performance, simplify the circuit, increase the reliability of excitation and stabilize the burning of the arc, reduce power loss.

This goal is achieved by the fact that in the welding transformer for manual arc welding, containing a rod-type transformer with semi-windings on each rod, a control unit, thyristors with cut-off diodes, between the common points of which a switching capacitor is installed, and thyristors with cut-off diodes and the primary winding of the transformer are connected to the terminals of the supply network, the secondary winding to the load terminals, and a pulse transformer, the primary winding of which is connected between the same electrodes ristors and the middle terminal of the primary winding of the rod-type transformer, and the oppositely connected secondary windings of the pulse transformer with a common point are connected to the middle terminal of the secondary winding of the rod-type transformer, thyristors and capacitors are introduced, shunting the secondary windings of the pulse transformer, connected through the thyristors to the load terminals and the middle terminal secondary semi-windings of a rod-type transformer.

Analysis of the known technical solutions in the field of power sources for arc welding allows us to conclude that there are no signs similar to the essential features in the claimed thyristor power source for arc welding, and to recognize the claimed solution meets the criterion of "Significant differences".

The essence of the invention lies in the fact that in one half-cycle the switching capacitor is charged to the amplitude value of the supply voltage, storing electrical energy, and when the thyristor with the cut-off diode is unlocked in the same half-cycle, it is recharged by current through the primary half-winding of the rod-type transformer and the primary winding of the pulse transformer, in this case, the total voltage of the switching capacitor pulse is applied to the secondary winding of the rod-type transformer ary poluobmotku stick-type transformer torus and the constant amplitude voltage pulse and the long duration of the pulse transformer with a secondary winding. Each thyristor with cut-off diodes during a half-cycle opens once, providing a power consumption circuit with a load, and is re-unlocked, forming a circuit for recovering electromagnetic energy into the supply network.

Figure 1 shows a circuit diagram of a welding transformer for manual arc welding, and figure 2 is a timing diagram explaining the principle of its operation.

The welding transformer for manual arc welding contains a rod-type transformer 1 with primary semi-windings 2.1 and 2.2 with an average terminal connected to the terminals of the power supply 4, and with secondary semi-windings 3.1 and 3.2 connected to the load 5. Thyristors 6 are connected to the terminals of the power supply 4 7 with cut-off diodes 8 and 9, between the connection points of which a switching capacitor is installed 10. The thyristor electrodes of the same name 6 and 7 are connected through the primary winding 11 of the pulse transformer 12 to the middle terminal of the primary half-cells current of 2.1, 2.2 stick-type transformer. The secondary windings 13, 14 of the pulse transformer 12, shunted by the capacitors 15 and 16, are connected through the thyristors 17 and 18 to the load clamps and the middle terminal of the secondary half-windings of the rod-type transformer. The control unit 19 with a pulse-width modulator of the vertical construction principle is connected to the control inputs of the thyristors 6, 7, 17 and 18.

In the initial state, the capacitor 10 is charged with reverse polarity (in brackets) shown for the polarity of the supply network 4 (without brackets).

The principle of operation of the rod-type welding transformer 1 is as follows: in a positive half-cycle of voltage 20 of the supply network 4 (without brackets), at the moment α = 0 (FIG. 2), the polarity of the supply network 4 opens, thyristor 6. A short-circuited primary semi-winding circuit 2.1 is formed, namely: 2.1 - diode 8 - thyristor 6 - winding 11 - 2.1, in which the current 21 decreases exponentially, scattering on the active resistances of the circuit. At the switching angle α = α _K, thyristor 7 is re-enabled, closing thyristor 6. Switching capacitor 10, discharging along the circuit: +10 - thyristor 7 - winding 11 - winding 2.1 - ± of the network 4 - diode 8 - minus 10, is recharged by the transformed current 21 load 5 reverse polarity in brackets (figure 2, b), while the thyristor 6 is instantly locked.

The capacitor 15, charged from the secondary winding 13 of the pulse transformer 12, when the thyristor 17 is unlocked, discharges to load 5 in the same polarity of the supply voltage 4 and, together with the pulse of the switching capacitor 10, is applied to the load 5. The arc ignition pulse 22 with a duration of 250-500 μs or more is added from the sum of two pulses: a switching capacitor 10 and a discharge capacitor 15 or 16. The thick lines in Fig. 2, b show the moments of switching of the total pulses 22 of the capacitors 10, 15 (16), and the thin lines show the moment nt switching 23 switching capacitor 10.

At the moment α = φ of the current 21 passing through zero, the thyristor 6 is unlocked and the reverse voltage of the switching capacitor 10 closes the thyristor 7. A current 21 flows through the primary winding 11 and the primary half-winding 2.2.

As a result, a power is applied to the load 5, determined by the sum of the transmitted power from the supply network 4 and the power of the total arc ignition pulse 22

, $$P=ui+\frac{C{U}_3^2}{2t_p}\left(\mathrm{AT}t\right)$$

,

where u, i are the instantaneous voltage and current values of the primary semi-windings of the rod-type transformer; C and U _З - the total capacity of the switching and discharge capacitor and the voltage of their charge; t _p - discharge time of capacitors 10 and 16 (15).

When the thyristor 6 is opened, the capacitor 10 is recharged along the circuit: (+) 10-6-11-2.2-9 - (-) 10 with the polarity shown without brackets (Figs. 1 and 2, b).

With a high potential difference between the electrode and the load product 5, the air, being ionized, becomes a current conductor, as a result of which the arc ignites and continues to burn.

After ignition of the arc, the voltage across the arc gap of the load 5 decreases to a voltage of 24 arc burning U _D = 20 + 0.04 · I _D , where U _D , I _D is the voltage and current of the arc. Until the moment α = π + α _{K, the} voltage across the plates of the capacitor 10 remains stable.

Figure 2, c, d gives the operation algorithms of thyristors 6 and 7, indicated by 25 and 26, the range of formation of short-circuited circuits is indicated by the numbers 27 and 28, and by the numbers 29, 30 - the re-inclusion of the thyristors.

In the negative half-period of the voltage of the network 4 (the polarity is indicated in brackets) in the interval π≤α≤π + α _K, after unlocking the thyristor 7 and locking the thyristor 6, a short-circuited load circuit 5 is formed: semi-winding 2.2-9-7-11-11.2. At the switching angle α = π + α _K, thyristor 6 is re-enabled (see the thyristor 6 and 7 operation algorithm - Fig. 2, c and d) and excess electromagnetic energy is recovered to network 4 through: 8-6-11-2.2. The current 21 drops to zero at the time α = φ + π, and the thyristor 6 closes. When the capacitors 15 and 16 are discharged to the load 5, the thyristors 17 and 18 are locked. In the interval φ + π≤α≤2π, the current 21 flows through the diode 9, the thyristor 7, the winding 11 of the pulse transformer 12 and the half-winding 2.1. At this time, the plates of the switching capacitor 10 are charged with the polarity shown without brackets (Fig.2, b). At the moment α = 2π, thyristor 7 reopens, forming a short-circuited load circuit 5, while the current 21 continues to support the burning of the arc. The application of load 5 at the moment of unlocking of thyristors with cut-off diodes of pulses of stable amplitude of 200-250 V for a duration of up to 0.5 ms increases the conditions of ignition and burning of the arc, which reduces the effective voltage of the secondary half-windings of the rod-type transformer to 28-32 V, reducing the minimum 2-2.5 times the number of turns.

In Fig. 1, the shaded oblique lines show the power consumption zone (voltage, load), and in the cell, the recovery zone. With a relative change in these zones, the shape of the output voltage curve does not change.

The use of two thyristors with cut-off diodes with forced switching allows not only to regulate the output voltage during the entire period of the mains voltage, but also to ensure continuous current flow, as a result of which the arc ignites and burns for half a period. As a result of this, energy indicators increase - power factor, efficiency. Due to the presence of a pulse transformer, the voltage source is converted into a current source having a steeply dipping external characteristic. In addition, since the half-windings are coaxially placed on both rods and connected in series, the leakage inductances of each rod are summed up and the total leakage inductance will be almost half that when placing the windings on different rods.

Improved conditions for the excitation and stabilization of the arc burning can improve the reliability of the welding transformer and at a higher level to carry out welding work.

The power of the welding transformer can be several tens of kilowatts with a minimum weight and dimensions.

Claims (1)

A welding transformer for manual arc welding, comprising a rod-type transformer with semi-windings on each rod, a control unit, a pulse transformer, thyristors with cut-off diodes, between which common points are connected a switching capacitor, while thyristors with cut-off diodes and the primary winding of the rod-type transformer are connected to the terminals of the supply network, and its secondary winding to the load terminals, the primary winding of the pulse transformer is connected between the same name by the types of thyristors and the middle terminal of the primary winding of a rod-type transformer, and the counter-connected secondary windings of a pulse transformer by a common point are connected with the middle terminal of the secondary winding of a rod-type transformer, characterized in that it is equipped with additional thyristors and capacitors shunting the secondary windings of a pulse transformer said thyristors are connected to load terminals and to the middle terminal of the secondary winding of a rod-type transformer.

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