DE3011127A1 - Igniter pulse generator for AC or DC arc welding plant - contains thyristor and transistors used to discharge capacitor into prim. of transformer - Google Patents

Abstract

A capacitor is discharged through the prim. winding of a transformer, so an ignition pulse is created in the sec. winding; and this pulse is superimposed on the welding voltage. The capacitor is charged by DC from a rectifier and fed to the capacitor via a controllable resistor circuit and a thyristor. The thyristor is triggered by a circuit in the welding power supply. The controllable resistor circuit includes a resistor and a capacitor employed to block the controllable resistor for a specified time. The controllable resistor is pref. a transistor, which has its emitter-collector path as a series resistor in the charging circuit of the capacitor providing the ignition pulse. An inexpensive generator, where the thyristor is released immediately the igniter pulse has been generated.

Description

Circuit arrangement for generating ignition pulses for

AC or DC welding arcs The invention relates to a circuit arrangement for generating ignition pulses for alternating current or direct current welding arcs, in which the ignition pulses are formed by the discharge of an ignition capacitor and the welding voltage are superimposed at which the charging current source of the ignition capacitor designed as a direct current source and the discharge of the ignition capacitor by means of controllable semiconductor is executable, the discharge current through the primary winding a pulse transformer is passed, whose secondary winding with the two-pole Welding output of the welding device is coupled and wherein the control inputs of the controllable semiconductor by means of trigger pulses in the conductive switching state controllable are.

Such a circuit arrangement is known from DE-PS 24 49 557. One difficulty with this circuit arrangement lies in that the controllable semiconductors after their triggering and the discharge of the ignition capacitor not always again with sufficient certainty in the non-conductive switching state to return. The known circuit arrangement sees this in the charging circuit of the Ignition capacitor has an inductance with a series-connected resistor. These However, the arrangement is not only complex in terms of costs and space requirements, but also not always sufficient, since over the one with the welding output Impulse transmitters coupled to the welding machine can have repercussions, which can prevent the controllable semiconductors from being released.

It is the object of the invention to provide a circuit arrangement of the Einaangs to create the type mentioned, in which after the discharge of the ignition capacitor, the release of the triggered controllable semiconductor clearly. occurs even if the circuit of the pulse transmitter is influenced by the effects of the welding output. The space requirement and the costs for the circuit arrangement should also be taken into account can be reduced to a minimum.

This object is achieved in that in the charging circuit of the ignition capacitor a controllable resistor is included, to which an RC element is assigned and that the charging voltage or the charging current of the capacitor of this RC element during triggering the bew. the controllable semiconductor changeable and to block the controllable Resistance is used for a predetermined time by the RC element.

With the circuit arrangement designed in this way, the controllable Resistance of the charging process of the ignition capacitor after triggering of the controllable semiconductor (s) and the associated discharge of the ignition capacitor be prevented for a defined period of time. This period of time can be used with with sufficient security so - determine that the release time for the triggered controllable semiconductors even in the most unfavorable operating condition without affecting the subsequent charging process of the ignition capacitor. The triggered controllable semiconductor is therefore safely free.

The bulky and expensive inductance of the known circuit arrangement is avoided in the circuit arrangement according to the invention. Only a few are in favor of it cheap electrical components required.

An embodiment of the circuit arrangement in which the charging voltage or the charging current from the discharge circuit of the ignition capacitor changes and is used to block the controllable resistor is characterized by that the controllable resistor is a transistor, the emitter-collector path of which is switched on as a series resistor in the charging circuit of the ignition capacitor and its base-emitter path is fed by the charging voltage via a series resistor is that the emitter-collector path of this transistor - a series circuit connected in parallel to the RC element and the base-emitter path of a control transistor and that the collector of the control transistor is connected to the base of the transistor is. The voltage jump required to control the control transistor in the According to a further development, the discharge of the ignition capacitor can thereby be increased that the series connection of the RC element and the base-emitter path of the Control transistor of a series circuit from the collector-emitter path of the Transistor and a collector resistor is connected in parallel.

The controllable resistor in the charging circuit of the ignition capacitor can according to a further embodiment in a simple manner thereby for keeping constant of the charging current are used that the emitter-collector path of the control transistor the series connection of a Zener diode and a resistor is connected in parallel is and that this resistor is switched into the charging circuit of the ignition capacitor is.

Instead of the Zener diode, another constant voltage source can also be used can be used.

The blocking of the controllable semiconductor or the controllable semiconductor can after a further Design can be made independent of the charge state of the ignition capacitor, that the controllable resistor is a transistor, the emitter-collector path of which is switched on as a series resistor in the charging circuit of the ignition capacitor and its base-emitter path via the series connection of a Zener diode and the resistor of the RC element is fed by the charging voltage that the capacitor of the RC element with the emitter of the transistor and the connection point between the. Zener diode and the resistor of the RC element is connected to that of the capacitor of the RC element, the phototransistor of an optocoupler is connected in parallel and that the light-emitting diode of this optocoupler in the trigger circuit of the controllable Semiconductor is switched on. The influence of the charging voltage or the charging current of the capacitor of the RC element assigned to the controllable resistor takes place thereby synchronous with the generation of the trigger pulses for the controllable Semiconductor in the discharge circuit of the ignition capacitor.

The invention is based on the exemplary embodiments shown in the drawings explained in more detail. It shows: FIG. 1, a circuit arrangement with a single one controllable semiconductor in the discharge circuit of the ignition capacitor, in which the controllable Resistance in the charging circuit can be controlled as a series resistance from the discharge circuit is, Figure 2 is a circuit arrangement with two controllable semiconductors and one push-pull operated pulse transformer in the discharge circuit of the ignition capacitor, where the controllable resistor in the charging circuit becomes a constant current source is supplemented and is controlled from the discharge circuit, and FIG. 3 shows a circuit arrangement with a single controllable semiconductor in the discharge circuit of the ignition capacitor, in which the controllable resistor in the charging circuit is synchronized with an optocoupler the generated trigger pulses of the trigger circuit can be controlled.

In the embodiment of Figure 1, a rectifier circuit GR fed by an alternating voltage, which is preferably from the mains or the primary side of the welding transformer is derived. The DC output of the Rectifier circuit GR is smoothed by means of the smoothing capacitor Cs. The DC power source thus obtained feeds the ignition capacitor C as charging voltage via a resistor circuit W1. The charging current flows through the primary winding I of the pulse transformer IUe. The controllable semiconductor Ty for discharging is the series connection from the primary winding I of the pulse transmitter IUe and the ignition capacitor C are connected in parallel. The control input of the controllable semiconductor Ty, which can e.g. be a thyristor, are the trigger pulses TR of a trigger circuit, which e.g.

can be derived from the welding alternating voltage of the welding device. The trigger pulse TR controls the controllable semiconductor Ty in the conductive state. The series connection is made up of the primary winding I of the pulse transformer IUe and the ignition capacitor C short-circuited and the discharge of the ignition capacitor C causes. The discharge current surge generates a high-voltage ignition pulse via the pulse transformer IUe, the welding voltage via the secondary winding II of the pulse transmitter IUe is superimposed.

The resistance circuit W1 in the charging circuit of the ignition capacitor C contains a controllable resistor, which is designed as a transistor T1. This With its emitter-collector path, transistor T1 is connected to the series resistor as a series resistor Charging circuit switched on. The base-emitter path of this transistor T1 becomes fed by the charging voltage via the resistor R1 and in the conductive state brought so that charging current can flow.

The transistor T1 is a collector resistor R2 and an RC element from the resistor Ro and the capacitor Co assigned. The base-emitter route of transistor T1 is the Emitter-collector path of a control transistor T2 connected in parallel. The base-emitter path of the control transistor T2 is from the charging current of the capacitor Co controlled time-dependently via the resistor Ro, if by Äussteuerung of the controllable semiconductor Ty the control voltage for the The transistor T1 used as a controllable resistor is omitted.

The transistor T1 is non-conductive and the capacitor Co can charge. The control transistor T2 is turned on and closes with it its emitter-collector path is the emitter-collector path of transistor T1 short. The time constant of the RC element from the resistor Ro and the capacitor Co determines the duration for which the control transistor T2 is turned on. The transistor T1 therefore remains independent of the state of the charging circuit non-conductive for this predetermined period of time. This period of time is so great that the controllable semiconductor is safely free after triggering and the discharge circuit of the ignition capacitor C interrupts. Then the charging process of the ignition capacitor can be started C take place again unaffected. So that the charging current of the capacitor Co the control transistor T2 can drive, is designed as a series circuit RC element from the resistor Ro and the capacitor Co of the emitter-collector path of the transistor T1 are connected in parallel.

The collector resistor R2 of transistor T1 are included.

In the embodiment of Figure 2 is the controllable resistor included in a constant current source KS. The basic structure is different differs only slightly from the resistance circuit W1 according to FIG. 1. The emitter-collector path of the control transistor T2 is the series connection of a Zener diode D1 and the Resistor R2 connected in parallel tet, where the resistance is called the emitter resistance of the transistor T1 in the charging circuit of the ignition capacitor C is switched on. The zener diode D1 and the resistor R2 are the elements that allow the flow of a determine constant charging current. This constant charging current flows until the ignition capacitor C - is fully charged. Then the charging current and thus also the emitter-collector voltage of transistor T1 zero. If the controllable semiconductor Ty1 or Ty2 conductive, then a appears at the emitter-collector path of the transistor T1 Voltage jump that charges the capacitor Co. The charging current of the capacitor As in the exemplary embodiment according to FIG. 1, Co controls the control transistor T2 in the conductive state according to the time constant of the RC element Ro, Co for a predetermined period of time. The emitter-collector path of the control transistor T2 short-circuits the base-emitter path of transistor T1 so that it is non-conductive and this predetermined period of time is also independent of the state of the discharge circuit of the ignition capacitor C does not remain conductive. So the charging circuit becomes safe interrupted for this predetermined period of time. The triggered controllable semiconductor Tyl or

Ty2 can therefore certainly become free during this time, so that he is available for a further control by means of a trigger pulse TR is ready. This blocking period can easily be made longer than the release time of the controllable semiconductor, without noticeably impairing the subsequent charging process of the ignition capacitor C.

In the embodiment of Figure 2, a pulse transmitter IUe used, which corresponds to the polarity of the welding half-waves of an AC welding voltage Emits high-voltage ignition pulses of assigned polarity. The trigger pulses TR1 and TR2 are generated in a known manner from the two welding half-waves of the welding alternating voltage derived. The ignition capacitor C is connected directly to the output of the constant current source KS switched on. The center tap is at one pole of the ignition capacitor C. connected to the two-part primary winding Ia, Ib of the pulse transformer IUe. The ends of the two primary windings Ia and Ib lead over the controllable semiconductors Tyl and Ty2 to the second pole of the ignition capacitor C. -The primary windings Ia and Ib the resistors R5 and R6 are connected in parallel in order to attenuate the back EMF.

In the secondary winding II of the pulse transformer IUe arise accordingly High-voltage ignition pulses of the same polarity assigned to the welding half-waves, the ignition capacitor C via the controllable semiconductor Tyl and the primary winding Ia or via the controllable semiconductor Tyl and the primary winding Ib is discharged.

In the embodiment of Figure 3, the controllable resistor in the resistance circuit W2 not from the discharge circuit of the ignition capacitor C, but controlled from the trigger circuit synchronously with the triggered trigger pulses. In the exemplary embodiment, the thyristor Ty is used to discharge the ignition capacitor C controlled in each welding half-wave. In the trigger circuit there is a charging capacitor Cl charged via a charging resistor Rl. Via a bilateral semiconductor switch BS, which can be a trigger diode, for example, is set when a Charging voltage initiated the discharge of the charging capacitor Cl. The discharge surge flows over the LED OKd of an optocoupler and controls the controllable semiconductor Ty executive. This process is repeated in every welding half-wave. The controllable one Semiconductor Ty is only used in the welding half-wave conductively controlled, in which the polarity of the discharge current surge for modulation and not for blocking of the controllable semiconductor Ty leads. Of course, the trigger circuit can also control a pulse transmitter circuit according to Figure 2, if both trigger inputs the controllable semiconductors Tyl and Ty2 are connected in parallel.

The two semiconductors Tyl and Ty2 can then be used alternately Control conductive, with the superimposed high-voltage ignition pulses having the same polarity like the welding half-waves of the welding alternating voltage.

The resistance circuit W2 again contains the transistor TI as controllable Resistance in the charging circuit. The base-emitter path of the transistor T1 becomes Via a series connection of a Zener diode D2 and the resistor Ro of the RC element Ro, Co fed by the charging voltage. The capacitor Co is connected to the emitter of the Transistor T1 and the connection point between the Zener diode D2 and the resistor Ro connected.

The capacitor Co is the phototransistor OKt of an optocoupler connected in parallel. When the ignition capacitor C is charged, the capacitor Co charged to the Zener voltage of the Zener diode D2 (voltage drop at the base Emitter path of transistor T1 neglected). Will the.

LED OKd of the optocoupler when generating a trigger pulse conductive in the trigger circuit, then the phototransistor OKt of this optocoupler is also activated conductive. The capacitor Co is discharged and then charges through the resistor Ro on. The transistor T1 remains blocked until the charging voltage decreases Zener voltage of diode D2 reached. The charging time constant of the RC element Ro, Co also determines the blocking time for the controllable in this circuit arrangement Resistance forming transistor T1.

Claims (6)

Claims: Circuit arrangement for generating ignition pulses for AC or DC welding arcs in which the ignition pulses are Discharge of an ignition capacitor is formed and the welding voltage is superimposed, in which the charging current source of the ignition capacitor is designed as a direct current source and the discharge of the ignition capacitor can be carried out by means of controllable semiconductors is, the discharge current passed through the primary winding of a pulse transformer whose secondary winding is connected to the two-pole welding output of the welding machine is coupled and wherein the control inputs of the controllable semiconductor by means of trigger pulses are controllable in the conductive switching state, characterized in that in the The charging circuit of the ignition capacitor (C) includes a controllable resistor, to which an RC element (Ro, Co) is assigned, and that the charging voltage or the charging current of the capacitor (Co) of this RC element (Ro, Co) when triggering the or the controllable semiconductor (Ty or Tyl, Ty2) changeable and to block the controllable resistance is used for a predetermined time by the RC element (Ro, Co). 2. Circuit arrangement according to claim 1, characterized in that the controllable resistor is a transistor (T1) whose emitter-collector path switched on as a series resistor in the charging circuit of the ignition capacitor (C) and its base-emitter path is over a series resistor (R13 from the charging voltage is fed that the emitter-collector path of this transistor lv. a series connection of the RC element (Ro, Co) and del sis emitter path a control transistor (T2) is connected in parallel and that the collector of the control transistor (T2) is connected to the base of the transistor (T1) (Figure 1). 3. Circuit arrangement according to claim 2, characterized in that the series connection of the RC element (Ro, Co) and the base-emitter path of the Control transistor (T2) of a series circuit from the collector-emitter path of the Transistor (T1) and a collector resistor (R2) is connected in parallel. 4. Circuit arrangement according to claim 2, characterized in that the emitter-collector path of the Steuertransist.e-rs (T2) the series connection a Zener diode (D1) and a resistor (R2) is connected in parallel and that this Resistor (R2) is switched on in the charging circuit of the ignition capacitor (C) (Figure 2). 5. Circuit arrangement according to claim 4, characterized in that a constant voltage source is used instead of the Zener diode (D1). 6. Circuit arrangement according to claim 1, characterized in that that the controllable resistor is a transistor (T1) whose emitter-collector path switched on as a series resistor in the charging circuit of the ignition capacitor (C) and its base-emitter path via the series connection of a Zener diode (D2) and the resistor (Ro) of the RC element (Ro, Co) are fed by the charging voltage is that the capacitor (Co) of the RC element (Ro, Co) with the emitter of the translator (T1) and the connection point between the Zener diode (D2) and the resistor (Ro) of the RC element (Ro, Co) is connected, that the capacitor (Co) of the RC element (Ro, Co) the phototransistor (OKt) of an optocoupler is connected in parallel and that the light-emitting diode (OKd) of this optocoupler in the trigger circuit of the controllable Semiconductor (Ty or Tyl, Ty2) is switched on (Figure 3).