DE917624C - Device for briefly switching on an electrical power consumer - Google Patents

Description

Device for briefly switching on an electrical power consumer The invention relates to a device for briefly switching on an electrical Power consumer and is of particular concern to welding machines that have controllable discharge paths, preferably grid-controlled mercury vapor discharge vessels, are connected to an AC power source. The invention can also be used for other power consumers, for example X-ray tubes, are used in which it comes down to using the consumer during a relatively short period of time the power source and where it is still important to check the size of the during this time the current flowing or, in the case of alternating current supply, the time of the Ignition of the discharge path within the half-wave of the feeding AC voltage to be precisely defined.

The invention assumes that in the control circuit between the power source and the load lying discharge path a control voltage is effective, which is for the purpose of engaging the consumer on such Is brought to a height that the ignition limit of the discharge gap is exceeded, and which are lowered again below the ignition limit after the resulting activation will. Control voltages of this type are known control devices often taken from the charging or discharging circuit of a capacitor.

According to the invention, the known control devices are thereby improved and designed that in the control circuit of the consumer feeding discharge path an additional voltage is introduced, which by the Switched consumer current triggered and directed such that it the The rate of decrease in the control voltage used for ignition is increased. The invention has the advantage that with short-term switching devices in which the Consumers only during a time that is less than a half-wave of the feeding AC voltage to which the power source is to be connected is definitely prevented is that in the following half-wave another ignition occurs. Closer Details of the invention emerge from the description in the drawing illustrated embodiments.

In the circuit of Fig. I, a welding transformer i is on Grid-controlled mercury vapor discharge vessel 2 to an alternating current source 3 connected. In the grid circle, d. H. between the cathode and the control grid of the Discharge vessel, there is a negative reverse voltage .4, an ohmic resistance 5, a grid series resistor 6 and a transformer 7, whose primary winding to the Primary winding of the welding transformer i is connected in parallel. The reverse voltage source 4 is bridged by connecting two resistors 8 and 9 in series. To the Connection point io between these two resistors and the connection point i i of the resistor 5 to the transformer 7 is the series connection of a grid transformer 12, a capacitor 13 and a control switch 14 are connected. The grid transformer 12 is fed from the alternating current network 3 and supplies control voltages sharper Waveform whose phase position can be changed by means known per se. The control switch 14 has two switch positions. In one position the Capacitor 13 over part of the grid transformer as a limiting resistor short-circuited, in the other position the capacitor 13 is in series with the Resistor 5 connected to the voltage of resistor 8. The tension of this Resistance 8 is given by the current, which from the negative reverse voltage source 4. flows through resistors 8 and 9. This tension: can also be another Power source, for example via a dry rectifier, the alternating current network 3 can be taken.

The mode of operation of the short-term switching device described above is as follows: It is assumed that the control switch 14 is in the drawn Position is in which the capacitor 13 is short-circuited and therefore discharged is. The discharge tube 2 is by the voltage of the power source q. kept locked. When the welding transformer i is switched on during a spot weld, for example is to be, the control switch 14 is turned to the right. The condenser 13 is now charged by the voltage of the resistor 8 via the resistor 5. The current flowing in the resistor 5 rises rapidly to its maximum value and then gradually increases again until the capacitor 13 is fully charged away. The voltage drop across the resistor 5 caused by this current acts as the reverse voltage the power source .a. opposite. The exact time of the ignition of the discharge vessel 2 is determined by the voltage spike of the grid transformer 12, which the charging voltage of the capacitor 13 is superimposed.

At the moment the discharge vessel 2 is ignited, a current flows through the transformer 7, the primary winding of which is parallel to the welding transformer i is switched. The secondary winding of this transformer is connected so that the current flows through the grid-cathode discharge path of discharge vessel 2, the resistor 8 and the capacitor 13 closes. The effect of the capacitor The current flowing through consists in that the speed with which the capacitor is charged, is increased. In other words, the speed at which the voltage at the resistor 5 decreases after the ignition has taken place, also increases, because the voltage across this resistor depends on the degree to which the capacitor is charged 13 dependent.

The additional current flowing through the capacitor 13, that of the load current of the consumer i is dependent, can also be done via a separate rectifier, preferably a dry rectifier fed to the capacitor. Advantageous However, the arrangement indicated in the circuit of FIG. i, in which the auxiliary discharge path Grid cathode of the discharge vessel 2 is used to connect the converter 7 to the Capacitor 13 to connect.

In Figure 2, a further embodiment of the invention is shown. Here, too, is a welding transformer over a grid-controlled mercury vapor discharge vessel 2 connected to an alternating current network 3. In the lattice circle of the discharge vessel : 2, as in the circuit according to FIG. 1, there is a transformer 7, a grid transformer 12 and a grid series resistor 6. The difference compared to the circuit of FIG. i lies in the fact that two capacitors C1 and C2 are used as control capacitors in the grid circuit be used. The capacitor C1 is via an ohmic resistor 15 to a Direct current source 16, for example a dry rectifier with a parallel connected Smoothing capacitor 17 connected. The second capacitor C., is with his an assignment connected via a resistor 18 to the negative pole of the direct current source. The control switch 14, which is used to switch on the consumer, is via a resistor ig to the connection point between the two capacitors C and C. In the switch-off position shown is bridged by the control switch 14 the capacitor C2, wherein a resistor 2o is also switched on. In the on position the capacitor Cl is connected in parallel to the resistor i9.

The mode of operation of the control device in FIG. 2 is as follows: As long as the control switch 14 is in the position shown, the full Voltage of direct current source 16 as reverse voltage in the grid circle of the discharge vessel 2. The positive pole is directly connected to the cathode, the negative pole via the Resistor 18, in which, however, no current flows. The capacitor Cl is in this Position charged to the full voltage of the direct current source 16.

When you flip the control switch 14, the voltage on the capacitor Cl gradually decreased and the voltage across capacitor C2 gradually increased. the Reduction in the voltage of the capacitor Cl is due to the fact that this capacitor the resistor i9 is connected in parallel to which because of the series connection with the resistor 15 is only part of the voltage 16. The capacitor C2 is with the voltage at resistor 15 is charged via resistor 18. This voltage change at the two capacitors C1 and C2 has the consequence that the superimposed voltage peaks of the grid transformer 12, the reverse voltage limit after a certain time of the discharge vessel 2 and ignite this discharge vessel. Essential is that the voltage peaks are not proportionate as in the circuit of FIG can be raised quickly above the ignition limit, but that the voltage peaks gradually approached the ignition limit of the discharge vessel and, as it were, pushed into it will. It is achieved that the ignition time of the discharge vessel with extremely high accuracy is determined because the intersection between the voltage peak and the ignition voltage limit in the area of the voltage peak lies, in which this tip is relatively very narrow. It should be noted that this measure of slowly increasing the voltage peaks used for ignition can also be used in switching devices in which none of the Load current-dependent additional voltage applied by the means of the current transformer 7 is used to produce certain effects after ignition.

As soon as the discharge vessel 2 is ignited, flows in a manner similar to that in FIG the circuit according to FIG. i from the transformer 7 a current via the discharge path Grid cathode of the discharge vessel 2 into the two capacitors C1 and C2. This Current has the consequence that immediately after the ignition of the discharge vessel Voltage across capacitor C2 is lowered rapidly. Definitely will be great with Acceleration reached the state in which the except for the voltage spike of the transformer 12 effective voltage again the full value of the reverse voltage of the direct current source 16 reached. The capacitor C is advantageously given a smaller capacitance than the capacitor Cl, so that the current triggered by the consumer current of the Transformer 7 essentially only the state of charge of the capacitor C2 and not that of the capacitor Cl affects.

The advantage of the additional voltage, which is dependent on the consumer current, lies again in the fact that immediately after the ignition of the discharge vessel 2, the control voltage in whose lattice circle is reduced with certainty to a value at which the voltage peaks of the transformer 12 cannot re-ignite the discharge vessel.

When the control switch 14 is returned to the upper position shown is, the capacitor C2 discharges through the two resistors i9 and 2o. Of the Resistor 20 is dimensioned so that the voltages on the two capacitors Cl and .C2 approach the new state practically at the same speed. It will this prevents that shortly after flipping the control switch 14 through the both capacitors C1 and C2 conditional voltage can be raised so far that a misfire occurs due to the transient voltage transients of the transformer 12.

The short-term switching devices shown in FIGS can also be used in such a way that one and the same discharge vessel, So the discharge vessel 2, in the two circuits one after the other for several welding transformers or other power consumers are used for switching on and off. For the purpose are switching devices that can be built as rotating collectors in the connection line between the welding transformers and the discharge vessels to turn on. These switching devices each become that welding transformer connected to the discharge vessel that is about to be switched on. Different Expressed, is with constantly changing connection between the individual welding transformers and the common discharge vessel ensures that the feeding alternating current network can only be loaded with one welding transformer at the same time.

Except for the switching device located in the anode circuit of the discharge vessel a second switching device is expediently switched into the grid circuit, thus also the size of the welding current or the point in time for each welding machine the ignition can be set within the feeding AC half-wave. This switching device can also be designed in the manner of a revolving collector be. In the circuit according to FIG. I, such a switch is between the welding transformer i and the discharge vessel 2 and between the control switch 14 and the connection point i i of the resistor 5.

It should be noted that this type of switching can be used for both the Control circuit as well of the anode circuit for the various Consumers are not limited to the special control circuit circuits of FIGS is, but also in other devices for brief electrical switching on Consumers can be applied to a feeding power source via controllable Discharge paths are connected, in their control circuit for the purpose of switching on of the consumer a control voltage is introduced, which after it is switched on automatically drops to a value that is no longer sufficient for ignition.

In Fig. 3 a particularly useful circuit for the excitation circuits of the transformer 12 of the two circuits of Fig. I and is shown, ie for the grid transformer which generates the voltage of a sharp waveform. This grid transformer has two primary windings in a manner known per se, of which one winding carries a current shifted by 90 ° compared to the anode voltage, while a current flows in the other winding that is in phase with the anode voltage, but its direction and size are arbitrary can be changed. The resultant of these two currents gives an excitation current, the phase position of which can be largely changed, and thus a voltage peak with a phase position that can be changed in the same way. In the circuit of FIG. 3, a and b denote the two excitation windings and c denotes the secondary winding of the grid transformer. Winding b is preceded by a choke coil d so that the current is shifted in phase by 90 °. Before winding a. if there is an ohmic resistance, the phase position is the same between the supply voltage and the current of winding a. By changing the tap on the resistor w, the size and direction of this current are changed.

The essential characteristic of the circuit of FIG. 3 is that that the resistances w for all consumers belonging to the same group, ie for example for six welding transformers, connected in series to the feeding one AC voltage are connected. That has the advantage of being smaller and therefore cheaper resistors can be used for the individual control circuits, and that regardless of the phase angle to be generated for each circuit Voltage sharp waveform can be adjusted.

Claims (7)

PATENT APPLICATIONS: i. Device for briefly switching on a electrical power consumer, preferably a spot welding machine, which at a feeding power source is connected via controllable discharge paths, a control voltage in their control circuit for the purpose of switching on the consumer is introduced, which automatically switches to ignition after being switched on no longer sufficient value drops, characterized in that in the control circuit an additional voltage is introduced, which is generated by the upstream consumer current triggered and directed such that it slows the rate of decrease of the the first-mentioned control voltage increased. 2. Device according to claim i, wherein the the discharge path igniting voltage to the charging circuit at the time of Is taken from a capacitor connected to a direct current source when switching on, characterized in that in the charging circuit one through the consumer current triggered additional voltage is switched on. 3. Device according to claim i, characterized characterized in that one taken from a converter and corresponding to the consumer current Additional voltage via a rectifier, preferably via the discharge path Grid cathode of the discharge path that switches on the consumer in the control circuit is switched. 4. Device according to claim i to 3, characterized in that between the cathode and the grid of the consumer to an alternating current source subsequent grid-controlled gas or vapor discharge path a negative Reverse voltage source, an ohmic resistor, the secondary winding of a primary side The converter connected in parallel with the consumer and, if necessary, a grid series resistor are connected in series, that further to the negative bias voltage source two series resistors are connected in parallel and that to the resistor connected to the voltage source and the resistor in the grid circuit is the series connection of a capacitor and a voltage with a sharp waveform can be switched in parallel via a control switch are. 5. Device according to claim i to 3, characterized in that the voltage A sharp waveform is superimposed on a voltage that gradually increases before it is switched on is, preferably the charging voltage of a capacitor. 6. Device according to claim i to 3, characterized in that between the cathode and the control grid of the Discharge path in series with the voltage of sharp waveform two capacitors are connected, which are connected in series with one another, one pole being one DC power source to one end of the series connection of capacitors, the other Pole on the other hand via a resistor to the other end and a second resistor is connected to the connection point between the two capacitors, and that furthermore by a switch either to the one directly at the direct current source lying capacitor a resistor connected in parallel or the other capacitor is short-circuited via a resistor. 7. Set up after Claim 6, characterized in that it is not directly connected to the direct current source lying capacitor has a smaller capacity than the other. B. Establishment for briefly switching on an electrical power consumer, preferably a spot welding machine that is connected to a feeding power source via controllable discharge paths is connected, in their control circuit for the purpose of switching on the consumer a control voltage is introduced, which automatically switches on after being switched on a value that is no longer sufficient for ignition drops, in particular according to claim i and following, characterized in that both in the lattice crystal and in the anode circle of the discharge vessel switching devices are provided through which the same Discharge vessel can be connected to different consumers one after the other and into the Lattice circle of the discharge vessel different assigned to the individual consumers Control voltages of selectable phase positions can be switched on. Referred publications: German patent specification No. 658 453.