DE4416353A1 - Arc welding appts. with a transformerless power supply unit - Google Patents

Abstract

The arc welding appts. is provided with a preferably transformerless power supply unit (11) producing direct current, an inverse rectifier (12), a step-down voltage transformer (13), and a rectifier (14) supplying direct current to a welding circuit (17) including the welding electrode (15). A control unit (22) operates the inverse rectifier (12) so that alternatingly positive and negative pulse sequences are produced at a frequency which is significantly above the working frequency of the transformer (13). The preferably rectangular pulses are width modulated at a frequency which is significantly below the pulse generation frequency, so that the input windings of the transformer are fed with an alternating voltage at the modulation frequency.

Description

The invention relates to an arc welding device according to the Preamble of claim 1.

The chopping of a direct current supplied by the power supply generally makes sense by choosing one accordingly high AC voltage frequency the structural dimensions of the required to step down the DC voltage substantial transformer. The higher the AC frequency is the lighter and the space-saving transformer can be used be formed. The electro provided in the inverter African circuit breakers are such. B. switching transistors, Thyristors, IGBT's (Insulated Gate Bipolar Transistor) or the like. Usually is between two on top of each other following positive and negative impulses of the used A short dead time is provided for the pulse AC voltage an overlap of the leading phases from to differ circuit breakers of the Should safely prevent the inverter.

For very high switching frequencies, e.g. 10-20 kHz, transformers with ferrite cores are required, so the frequency-dependent inductive resistance is not like that is high that the efficiency of the transformer in not is more acceptable degraded.

However, ferrite core transformers are comparatively expensive and are often not available for certain applications. The much cheaper and in an abundance of Variations on available cutting tape core trans however, formers can only be comparatively low alternating voltage frequencies of, for example, 5 kHz be used.

In principle, the frequency of the inverter could  to one with the inductance of a cutting tape core trans formators compatible value can be reduced; one with Circuit breakers working inverter is however not to control or only with great effort so that he one required to power a transformer provides at least sinusoidal voltage. Even if this is but with great effort would be with such Circuit arrangement a power control in a large Area not possible or also only with great effort.

The aim of the invention is an arc welding to create device of the type mentioned, in which at the same time with only for dispensing Rectangular pulses suitable inverter and a Input voltage an at least sinusoidal voltage required transformer can be worked. A Another object of the invention is to provide a Arc welding device, in which despite using only one suitable for comparatively low frequencies, with an at least sine-like voltage to be controlled Transformers, in particular cut core transformers simple and effective power control is possible.

To solve this problem, the characteristics of the characteristic ning part of claim 1 provided.

The idea of the invention can therefore be seen in the fact that with alternating positive and negative impulse follow worked whose frequency is so high that within a Single pulse causes the input voltage at the transformer due to the relatively high inductance of the primary winding only moderate and at least not up to the theoretical possible maximum value increases. After completing a The collapsing magnetic field then tries the pulse Input winding to maintain the current so that it only drops slowly until the next pulse comes on again further moderate increase in the input voltage brings, the extent of the pulse increase at each  single pulse by its width to a predetermined Value can be set. Overall, one can periodic increase and decrease in the width of the individual pulses and the cyclic sign reversal of the pulse trains at the input of the transformer is at least sinusoidal Input voltage are generated, the frequency of which is clear and is preferably an order of magnitude less than that Frequency of the pulses of the pulse trains.

The invention has the advantage that a for delivery only of rectangular pulses of suitable inverters can be, but nevertheless the transformer one at least sine-like voltage can be supplied, the also in terms of frequency for processing in one only for relatively low frequencies suitable transformer in Question is coming.

Advantageous further developments of the invention are provided by Subclaims marked.

Since the mean width of the individual pulses with simple electronic means easily to a desired value can be adjusted and the amplitude of the input of the Transformer generated sine voltage from the middle Pulse width depends on that in the transformer brought in or delivered by him on special simple and economical way to a desired one Value can be set. The output voltage of the The power supply can remain unchanged just like the Amplitude of the output from the inverter preferably rectangular single pulses.

The pulse width modulation is preferably sinusoidal, because this ensures optimal efficiency when down transformation of the input voltage generated in this way in the Transfor mator is achieved.

Advantageous frequencies can be found in claims 5 and 6.  

The arc welding device according to the invention is suitable especially for the use of cutting tape core trans formers according to claim 7.

The invention is of particular advantage in the implementation examples according to claims 8 and 9. Since three-phase Ferrite core transformers are not available or can be very expensive, one with a three phase Inverter and transformer working arc welding machine only with cutting core transformers realized, which in turn with an acceptable Efficiency can only work when the relatively high Frequency of the pulses according to the invention clearly and is preferably reduced to about 1/10.

The inverter according to the invention is according to claim 10 preferably fully controlled.

When using a three-phase inverter also three individual single-phase cutting core transformers be used according to claim 11.

The invention is described below, for example, with the aid of Drawing described; in this shows

Fig. 1 is a block diagram of an arc welding machine according to the invention,

Fig. 2 is a voltage or current-time diagram of the control voltage U for one phase of the inverter of FIG. 1 and the resulting current I in the associated input winding of the three-phase transformer according to FIG. 1 as a function of Time, for the sake of clarity the actual square pulse frequency, ie the number of square pulses per period of the sine voltage to be generated is significantly reduced, and

Fig. 3 is a Fig. 2 corresponding voltage-current-time diagram with a clearly reduced average amplitude of the pulse width modulation to generate a lower output power.

According to Fig. 1, a power supply unit 11 is connected to a power supply by means of a plug 18, which may be single or three phase. There is a rectifier in the power supply 11 , which converts the mains voltage into a DC voltage. Preferably, there is no transformer in the power supply 11 that transforms the voltage up or down.

The two output lines 20 , 21 of the power supply 11 , between which a smoothing capacitor 19 is connected, are connected to the input of a three-phase inverter 12 which, in three-phase bridge circuit, six electronic circuit breakers T₁, T₂, T₃, T₄, T₅ and T₆ contains, which may be transistors, thyristors or the like, the emitter and collector are each connected by a freewheeling diode D₁, D₂, D₃, D₄, D₅ or D₅ and which are controlled by a control stage 22 via a line 33 are that the DC voltage applied via lines 20 , 21 is converted into alternating positive and negative rectangular pulse trains 34 , 35 . The frequency of the pulse trains 34 , 35 is the same and constant, while the pulse widths are modulated sinusoidally in the manner shown in FIGS . 2 and 3.

The input of a three-phase cutting core transformer 13 is connected to the three-phase output of the inverter 12 . The freewheeling diodes D₁ to D₆ ensure an inductive partial discharge of the input windings of the three-phase transformer 13 in the pulse pauses. The output of the three-phase cutting core transformer 13 feeds the leads 25 , 26 of a welding circuit 17 via a three-phase rectifier bridge 14 , in which a welding electrode 15 protruding from a welding electrode holder 23 and a workpiece 16 are located. The arc formed between welding electrode 15 and workpiece 16 is indicated by dashed lines at 24 . The supply lines 25 , 26 are connected by a freewheeling diode 27 so that the welding current choke 28 can be fully effective.

Before the welding electrode holder 23 , a welding current choke 28 is turned on in the welding circuit 17 .

From the supply line 26 carrying the positive output voltage leads to the independent welding voltage or welding current control, a line 29 to a setting device 30 , which contains a setpoint setting potentiometer 31 and a comparison circuit, not shown, and acts on the control stage 22 via a control line 32 .

The frequency of the rectangular pulse trains 34 , 35 ( FIG. 2) fed from the control stage 22 to the inverter 12 via the line 33 is z. B. 1 to 2 kHz. In particular, the control of the inverter 12 is carried out by means of the control stage 22 in such a way that a sequence of positive pulses 34 is first generated, the width of which starts from the zero point of the coordinate system according to FIG. 2, sinusoidally up to a maximum and then again decreases to zero. The pauses between the individual rectangular pulses decrease accordingly and increase again after reaching a minimum at the maximum pulse width. The pulse frequency therefore remains constant despite the sinusoidally changing pulse width. The sequence of positive pulses 34 is followed by a sequence 35 of negative pulses of the same amplitude, the width of which increases from approximately zero to a negative maximum and then decreases again to zero. A sequence 34 of positive impulses then follows again, whereupon the work cycle continues cyclically in the same way.

Overall, this results in a sinusoidal pulse width modulation of the positive and negative pulse trains 34 , 35 . The arithmetic mean of the voltage generated by the pulses and the pulse pauses is shown in solid lines in FIG. 2. With suitably high inductance, as z. B. has a cutting core transformer, the current in the or the input windings of the transformer 13, the z. B. do not follow a frequency of 20 kHz pulses, so that the resulting current in the input winding (s) corresponds to the arithmetic mean of the individual pulse periods consisting of pulses and pulse pauses. The current in the input windings of the transformer 13 thus essentially follows the sine curve shown in FIG. 2.

The actual voltage curve in the input windings of the transformer 13 is not exactly sinusoidal, as is shown in solid lines in FIG. 2. In fact, the voltage curve at the beginning and end of each pulse undergoes a sudden change, which, however, amounts to the sine function shown in solid lines in FIG. 2.

The average width of the square-wave pulses can be set by suitably adjusting the potentiometer 31 , as can be seen from the comparison of FIG. 2 (maximum pulse width) and FIG. 3 (minimum pulse width). Due to the smaller pulse widths according to FIG. 3 and the correspondingly larger pulse pauses, the arithmetic mean value shown as a solid line decreases, and a correspondingly lower quasi-sinusoidal voltage appears at the input of the transformer 13 .

After the potentiometer 31 a certain mean pulse width has been set, an automatic control is performed due to the shown in Fig. 1 the control circuit 29, 30, 32, 22, 33 to a constant DC voltage at the output of the rectifier bridge 14 by the over line 29 Setting device 30, the actual voltage at the output of the rectifier bridge 14 is reported. This is compared with the setpoint set on the potentiometer 31 . If the actual and target values match, the control of the control stage 22 remains unchanged. If the setting device 30 detects an excessively high actual voltage, the maximum pulse width emitted by the control stage 22 is reduced until the output voltage on the line 29 corresponds to the set value.

The operation of the arc welding device according to the invention is explained below with reference to FIGS . 1 to 3.

From Fig. 2 it can be seen that while driving a pair of circuit breakers of the inverter 12 , for example the pair T₁ / T₅ ( Fig. 1), first a sequence 34 of positive square-wave voltage pulses of a fixed frequency and with a positive sine half-wave modulated pulse width and then by driving a further pair of circuit breakers of the inverter 12 , for example the pair T₄ / T₂, a sequence 35 of negative square-wave voltage pulses of the same frequency and width modulation is generated, which are applied to one of the input windings of the transformer 13 . After the sequence 35 of negative square-wave voltage pulses, another sequence 34 of positive square-wave voltage pulses follows.

Because of the comparatively high inductance of the primary windings, the current generated there can only gradually follow the voltage, so that the current at the end of each pulse has not yet approximately reached the theoretically possible maximum value. During the subsequent pause in the pulse, the collapsing magnetic field induces a voltage in the primary winding, which slowly drops the current until the next pulse occurs, which causes the voltage to rise again. Due to the sinusoidal pulse width modulation according to the invention, the current assumes an initially zigzag rising and then decreasing shape, which on average gives the sinusoidal curve I shown in FIG. 2, which represents the smoothed arithmetic mean of the pulsed voltage.

If, by adjusting the potentiometer 31, the mean pulse width is reduced while maintaining the sinusoidal pulse width modulation, a quasi-sinusoidal input current I 1 can be generated for the transformer 13 with a correspondingly reduced amplitude as shown in FIG. 3.

The input current of the transformer 13 (sine curve I of Fig. 2, 3) is transformed up in the manner required for the welding process and then rectified in the rectifier terbrücke 14 and supplied to the welding circuit 17 in this form.

Via the control circuit 29 , 30 , 32 , 22 , 33 , the average width of the pulses of the pulse trains 34 , 35 is adjusted to such a value that a predetermined welding voltage or a predetermined welding current is maintained at the output of the rectifier bridge 14 .

The essence of the invention thus lies in a device for converting a relatively high-frequency square-wave voltage into a low-frequency sinusoidal voltage or a low-frequency current, which is then used by a transformer or current transformer 13 for potential isolation and reduction of the mains input voltage to welding-approved voltages or Increasing the input current to welding currents required is processed.

The advantage of the arrangement according to the invention is that the frequency for the circuit breaker in the inverter 12 z. B. 5, 10, 20 or 50 kHz, while the input frequency for the transformer 13 or current transformer is 1 kHz. The most economical area for e.g. B. Cutting band cores is 1 to 2 kHz, since cutting band cores for higher frequencies and high powers are very expensive. Well-usable ferrite cores for high frequencies are not available for high performance or are too expensive.

The transformer losses are made up of the Iron core losses that occur in the core and the copper losses in the windings. The iron losses in the kernel The core of the ribbon consists of the three components ten: magnetic reversal (hysteresis) losses, eddy current (Foucault) losses and small residual losses.

The hysteresis losses are primarily of the type and Depending on the nature of the sheets, the surface area the hysteresis loop is a measure of the magnitude of this loss partly is. The eddy current losses are proportional to the Frequency and sheet thickness as well as the square of the magnetic Induction, but inversely proportional to the specific Resistance of the material.

Because of the arrangement according to the invention, the high control frequency of the circuit breakers T 1 to T 4 is converted into a low-frequency voltage or a low-frequency current for the transformer or current transformer 13 . So that the iron losses are kept small, a sinusoidal voltage is provided as the input voltage for the transformer or current transformer 13 .

Reference list

11 power supply
12 inverters
13 transformer
14 rectifier bridge
15 welding electrode
16 workpiece
17 welding circuit
18 plugs
19 smoothing capacitor
20 output line
21 output line
22 control level
23 welding electrode holder
24 arcs
25 supply line
26 supply line
27 freewheeling diode
28 welding current choke
29 line
30 setting device
31 setting potentiometers
32 control line
33 control line
34 Sequence of positive rectangular pulses
35 Sequence of negative rectangular pulses.

Claims (11)

1. Arc welding device with a preferably transformer-free, connectable to a power grid, a direct current output power supply ( 11 ) to which an electrical circuit breaker (T₁, T₂, T₃, T₄, T₅, T₆) containing the inverter ( 12 ) is connected, the output is applied to a transformer ( 13 ) which transforms the AC voltage down to a lower voltage and which is followed by a rectifier arrangement, in particular a rectifier bridge ( 14 ), which supplies a welding circuit ( 17 ) containing the welding electrode ( 15 ) with direct current, characterized in that in that the inverter (12) is driven by a control stage (22) so that from the direct current alternately positive and negative pulse trains (34, 35) are generated with a significantly higher frequency permits than the transformer (13) to be processed, and that the pulse sequences ( 34 , 35 ) each consist of preferably quite angular individual consist of pulses that are width modulated at a frequency that is significantly lower than the pulse frequency, such that at the input winding (s) of the transformer ( 13 ) an AC input voltage with the frequency of the pulse width modulation is present. 2. Arc welding device according to claim 1, characterized, that the pulse width modulation frequency by one Order of magnitude less than the pulse frequency.   3. Arc welding device according to claim 1 or 2, characterized, that the mean pulse width is changeable and to one certain value is adjustable. 4. Arc welding device according to one of the preceding claims, characterized in that the pulse width modulation is sinusoidal, such that an essentially the pulse width modulation quasi-sinusoidal voltage is applied to the input windings of the transformer ( 13 ). 5. Arc welding device according to one of the preceding Expectations, characterized, that the pulse frequency 5-50 kHz, especially about 20 kHz is. 6. Arc welding device according to one of the preceding Expectations, characterized, that the pulse width modulation frequency 1 to 2, is in particular about 1.5 kHz. 7. Arc welding device according to one of the preceding claims, characterized in that the transformer ( 13 ) is a cutting band core transformer. 8. Arc welding device according to one of the preceding claims, characterized in that the inverter ( 12 ), the transformer ( 13 ) and the rectifier ( 14 ) are three-phase. 9. Arc welding device according to claim 8, characterized in that a three-phase rectifier bridge ( 14 ) is connected to the three-phase output of the transformer ( 13 ). 10. Arc welding device according to one of the preceding claims, characterized in that the inverter ( 12 ) is fully controlled. 11. Arc welding device according to one of claims 8 to 10, characterized, that the three-phase transformer by three individual Single-phase cutting core transformers is realized.