DE2658724A1 - Welding transformer current source - has current controller connected by switches to inverter control inputs for different load current directions - Google Patents

Abstract

The current source has a transformer whose secondary winding is connected to a rectifier followd by an SC invertor whose SC components are in series with the load. They are switched by control pulses with variable keying ratio. A current controller generates pulses with the keying ratio proportional to the load current. It is connected to a switch controlled by output pulses of a frequency regulating unit whose frequency is low in comparison with that of current controller pulses. In its first position it connects the current controller to a first invertor control unit for the first load current direction, and in its second position connects a second invertor control input for the opposite load current direction.

Description

Power source, in particular welding power source

The invention relates to a power source, in particular a welding power source with a transformer with a rectifier connected to its secondary winding which is followed by an inverter consisting of semiconductor components, which are in series with the load and variable by a control unit with pulses Pulse-pause ratio are switched.

From DT-OS 21 10 028 there is a circuit arrangement for generating an alternating voltage of variable amplitude and frequency known, the one from the network fed rectifier, a first inverter connected to this for generating a direct voltage of variable magnitude and one with this direct voltage powered second inverter for generating the AC voltage of variable frequency having. Such a circuit that can also be used in a power source can has the disadvantage that both inverters contain power components must, as the load current flows through them.

The present invention is based on the object of providing a power source, in particular to create a welding power source, which is characterized by a simple Construction and favorable operating characteristics.

According to the invention, this object is achieved in that a current regulator is provided, the pulses with a pulse-pause ratio proportional to the load current generated and to which a changeover switch is connected, that of the output pulses a frequency controller whose frequency compared to the frequency of the pulses of the current regulator is small, is controlled and in one position the output of the current controller with an inverter control input for one load current direction and in the other position a second inverter control input for the opposite one Load current direction connects. In such a circuit there is only one inverter contain. Its semiconductor components are connected with a square-wave voltage; they therefore work with a high degree of efficiency. The new circuit arrangement there an alternating current of controllable medium strength and selectable in a wide range Frequency.

The current intensity is determined by the pulse-pause ratio of the current regulator certainly. The frequency of the mean amperage is equal to that of the output pulses of the frequency controller. The mark-to-space ratio is used to regulate the current or voltage the impulses of the current controller depending on the deviation of the load current or the voltage changed from a setpoint value, so that with increasing load current or as the output voltage increases, the mark-to-space ratio becomes smaller and vice versa.

The dead times are so short that if the new arrangement is used for electric welding, the gas ions cannot recombine and so there are still enough charge carriers to ignite after the power breaks. An additional high-frequency current can therefore be dispensed with.

If the new circuit arrangement is used as a welding power source, the frequency and the pulse-pause ratio of the frequency controller are useful variable. In electric welding, the anode heats up when the Electrons much stronger than the cathode.

When direct current welding, e.g. B. in tungsten inert gas welding, therefore, the electrode is placed on the negative pole and the workpiece to be welded the positive pole. When AC welding, move with a sinusoidal alternating current the ions move during a period, e.g. B. at an AC frequency of 50 Hz, 10 msec long from the electrode to the workpiece and also 10 msec long from the Workpiece to electrode, with the electrode as much heat as the workpiece is fed. Therefore, only a low level of efficiency is achieved. When welding of aluminum cannot do without the direction of current from the workpiece to the electrode because it tears open the oxide layer of the aluminum and thereby the surface is cleaned. You do not need a full one to tear open the oxide layer Half cycle of the alternating current, as is the case with conventional alternating current welding is, but only about 10 X, so that another 40 z of the energy that leads to unnecessary electrode heating are consumed, can be fed to the workpiece.

This is the case with a pulse-pause ratio of 9: 1, the can be set with the frequency adjuster.

A pulse-pause ratio of 9: 1 means that z. B. at a Frequency of 50 Hz the current from the electrode to the workpiece 18 msec and in opposite Direction 2 msec flows. Should it turn out that this 2 msec is too short for the Cleaning the surface is what you want with the advantageous pulse-pause ratio remain at 9: 1, then the frequency can be changed. At a frequency of 10 Hz and the same mark-space ratio of 9: 1 flows the Ion current for 10 msec from the workpiece to the electrode. This does not become unnecessary heated up and maintains its shape, what z. B. in automated welding for Igniting the arc is advantageous.

Can the pulse-pause ratio of the frequency controller be up to Change borderline cases 0 and 1, so the welding power source can be used very versatile Then you can not only use an alternating current of any desired pulse-pause ratio and adjustable amperage, but also pulsating direct currents in both directions.

Based on the drawing in which as an embodiment of the invention the circuit diagram of a welding current device is shown, in the following the Invention and further advantages and additions are described and explained in more detail.

In order to maintain clarity, those skilled in the art are familiar Direct current feeds to amplifiers, luminescent diodes, etc. only hinted at.

A transformer TR sets the one supplied to its primary winding W1 Mains voltage down.-A rectifier GL is connected to its secondary winding W2, to which a charging capacitor C1 is connected. The rectifier GL has a Choke DS and a current measuring resistor B1 followed by an inverter, the essentially made up of four bridge-connected power transistors T1, T2, T3 and T4 exists. At the connection point 1 of the emitter of the transistor T1 with the A workpiece WS is connected to the collector of the transistor T3 and is welded shall be.

The welding electrode EL is at connection point 2 of the emitter of the Transistor T2 to the collector of transistor T4.

The resistance RM, that of the welding current, serves to measure the welding current is flowed through and at which therefore a voltage drops that is proportional to the size of the welding current is. A current regulator, shown in dashed lines, is connected to the resistor RM SR connected. This contains a smoothing capacitor C2 at the input, which the Resistor RM and the inputs of a differential amplifier V1 bridged. Whose The output is via a resistor R1 to the inverting input 3 of a control amplifier V2 connected. A negative feedback resistor R2 is determined in conjunction with the resistor R1 the gain. The non-inverting input 4 of the control amplifier V2 is connected to the tap of a potentiometer P1, with which the setpoint of the Current is set. The output voltage of the control amplifier V2 is therefore a measure of the system deviation. This voltage is applied to the inverting input 5 of a comparator K1. Its non-inverting input 6 becomes a triangle voltage with a frequency of about 10 kHz, the amplitude of which corresponds to the possible output voltages of the amplifier V2 is adapted.

The triangle voltage is generated in an oscillator with two amplifiers V3 and V4 generated. The amplifier V3 works as a comparator. He compares them triangular voltage, which is fed to the inverting input 10, with his in a voltage divider with the resistors R4 and R5 reduced and the non-inverting Output voltage fed to input 11. With the output of the amplifier V3 is connected to the non-inverting input 8 of the amplifier V4, whose output 9 Connected to the inverting input 7 via an integration capacitor C3 which is connected to ground via an integration resistor R3. The amplifier V3 shows tilting behavior; its output voltage can therefore only two Accept values. Assume that its output voltage is at the lower value may be. The output voltage of the amplifier V4 therefore falls linearly over time. Achieved it is the voltage fed to the non-inverting input 11 of amplifier V3, the amplifier V3 flips over, its output voltage assumes the upper value and the output voltage of amplifier V4 rises until it returns to that of the non-inverting one Input 11 of the amplifier V3 supplied voltage value reached. It is created like this a triangular voltage that depends on the slope and thus the frequency on the size of the resistor R3 and that of the capacitor C3, their amplitude on the division ratio of the voltage divider with the resistors R4 and R5.

The comparator K1 compares the size of its non-inverting Input 6 supplied triangular voltage with the value of the inverting input 5 supplied output voltage of the amplifier V2. Its output voltage increases the two states log. "O" and "1" a. Is the triangle voltage greater than that The output voltage of the amplifier V2, if its output signal is "1", is the triangle voltage smaller, the output signal is "O". So the higher the output voltage of the amplifier V2 is, i.e. That is, the more the welding current exceeds the setpoint value by the smaller the pulse-pause ratio of the output signal of the comparator K1. As the welding current decreases, the pulse-pause ratio increases.

The output pulses of the comparator K1 are the two inputs of AND gates U1 and U2 supplied. The other input of the AND element U2 is direct, that of the AND gate U1 via an inverter J at the output of a dashed line Frequency controller FSQ This contains a triangular voltage generator, the corresponding the one in the current regulator SR contained from two amplifiers V5, V6, an integrating capacitor C4, an integrating resistor R9 and a feedback potentiometer with resistors R6 and R7. With the resistor R9 the frequency, z. B. can be set between 1 and 250 Hz.

The triangular voltage generated is in a comparator K2 with the compared voltage set in a potentiometer P2. With the potentiometer P2 can therefore be the mark-to-space ratio of the output signal of the comparator K2 can be set. The frequency adjuster FS can thus produce pulses of variable frequency and deliver any pulse-pause ratio. With these impulses, it turns off the AND gates U1 and U2 and the inverter I controlled existing switch. There the pulses emitted by the comparator K1 have a much higher frequency than the have generated in the frequency controller FS are at the outputs of the AND gates U1 and U2 pulse follow received from the kind, as they are drawn there. Possibly the frequency of the frequency controller can be greater than that contained in the current controller SR Oscillator V3, V4.

The control electrode of a transistor is connected to the output of the AND element U1 T9 connected, in whose collector circuit there are two luminescent diodes LD2 and LD3, the components of optocouplers are the receivers of which are contained in the inverter Photo transistors PT2 and PT3 are. For the purpose of a clear presentation the luminescent diodes drawn outside the inverter and next to the phototransistors entered again in dashed lines. With the output of the AND gate U2 the control electrode of a transistor T10 is connected in its collector circuit two light emitting diodes LD1 and LD4 are located. she are components of optocouplers whose receivers are photo transistors PT1 and PT4. Is the transistor T10 switched through, the luminescence diodes LD1 and LD4 light up, the collector-emitter stretch the phototransistors PT1 and PT4 become low-resistance and the inverter transistors T1 and T4 are switched through by auxiliary voltage sources Q1 and Q2 or Q3. In order to A current flows from the rectifier GL via the choke DS and the transistor T1 to the workpiece WS to be welded, from there via the arc to the electrode EL and via the collector-emitter path of the transistor T4 and the current measuring resistor RM back to rectifier GL. The electrode EL is on the negative pole, so it will especially the workpiece WS is heated.

During the pulse pauses of the output signal of the comparator K2 is the transistor T9 is switched on, and the luminescent diodes LD2 and light up LD3 on, so that the transistor T2 from an auxiliary voltage source Q3 and the transistor T3 is controlled by the auxiliary voltage source. In this case the electrode is EL placed on the positive pole. It therefore flows between the workpiece WS and the electrode EL an alternating current. The ratio of positive to negative phase is with the Potentiometer P2 of the frequency controller FS adjustable. During the two phases a pulsating direct current flows, whose mark-space ratio is determined by the current regulator SR is given. In the borderline case - the setting of the potentiometer P2, in which the Output signal of the comparator K2 log. Is "1", a pulsating direct current flows from the workpiece WS to the electrode EL, in the other borderline case, in which the output signal of the comparator K2 log. "O" is a pulsating direct current from the electrode EL to workpiece WS. The mean values of the direct currents are obtained with the help of the current regulator SR regulated.

With the circuit arrangement shown, pulsating direct currents can therefore be achieved regulated, medium strength and opposite polarity as well Alternating currents generated with any ratio of positive to negative phase so that the welding machine can be used universally.

Claims

Claims (7)

Claims 1. Power source, in particular welding power source, with a transformer with a rectifier connected to its secondary winding which is followed by an inverter consisting of semiconductor components, which are in series with the load and variable by a control unit with pulses Pulse-pause ratio are switched, characterized in that a current regulator (SR) is provided, the pulses with a pulse-pause ratio proportional to the load current generated and to which a changeover switch (U1, U2, J) is connected, that of the output pulses a frequency controller (FS) whose frequency compared to the frequency of the pulses of the current regulator (SR) is small, is controlled and in one position the Output of the current controller (SR) with a first inverter control input (LD1, LD4) for one load current direction and in the second position a second inverter control input (LD2, LD3) connects for the opposite load current direction. 2. Power source according to claim 1, characterized # that for current control the current controller CSR) pulses with a deviation of the load current resp. the output voltage depends on a setpoint-dependent pulse-pause ratio generated in such a way that the load current or the output voltage in the sense of a constant hold to be influenced. 3. Power source according to claim 1 or 2, characterized in that the frequency of the output pulses of the frequency controller (FS) can be changed. 4. Power source according to one of claims 1 to 3, characterized in that that the pulse-pause ratio of the output pulses of the frequency controller (FS) can be changed is. 5. Power source according to one of claims 1 to 4, characterized in that that the current regulator (SR) contains a differential amplifier (V2), one input of which (3) the falling on a current measuring resistor (RM) connected in the load circuit Voltage or the output voltage and its other input (4) is a reference voltage is fed, and at the output of one input (5) of a comparator (K1) is connected, the other input (6) with the output (9) of a current regulator oscillator (V3, V4) is connected, the one with the frequency of the output pulses of the current regulator periodically time-varying voltage, preferably a triangular or sawtooth voltage generated. 6. Power source according to one of claims 1 to 5, characterized in that that the frequency controller (FS) contains an oscillator (VS, V6) of controllable frequency, of a periodically time-varying voltage, preferably a triangular or Sawtooth voltage generated and connected to the one input of a comparator (K2) whose other input is connected to the tap of a potentiometer (P2) is. 7. Power source according to one of claims 1 to 6, characterized in that that the inverter is a bridge circuit made up of four transistors (T1, T2, T3, T4), one diagonal of which is connected to the rectifier (GL) and in the other diagonal (1,2) of which the load (WS, EL) lies and that the transistors (T1, T2, T3, T4) are controlled by optocouplers (LD1, .PT1; LD2, PT2 ...) whose Inputs the control inputs of the inverter connected to the changeover switch (U1, U2, J) are.