NO115034B - - Google Patents

Description

Device for producing control voltage pulses by means of controllable gas- or steam-filled discharge tubes.

The invention relates to a device for producing control voltage pulses by means of controllable gas- or steam-filled discharge tubes, in particular a control device for resistance welding devices, characterized in that two discharge tubes in toggle connection are fed from a direct current source, which tubes each have an impedance inserted in their anode circuits from which control voltage pulses are taken, that furthermore the discharge tubes' control means are periodically supplied with ignition voltages so that one discharge tube conducts current, while a device is provided to keep the other discharge tube blocked and that the blocking of the other tube is lifted to generate control voltage pulses during a certain time, so that the tubes ignite one after the other periodically, until the other tube is finally blocked, so that an equal number of voltage pulses are always produced.

This achieves the advantage that the first control voltage pulse is always delivered by the second pipe and the last control voltage pulse is always supplied by the first pipe. When controlling two devices, one can therefore cause one device to start and the other to end, despite the fact that the blocking is lifted and made active again at an arbitrary moment (i.e. asynchronously).

When the voltage pulses, e.g. is supplied to an alternating current coupling device from two opposite anti-parallel connected, controllable

gas- or steam-filled discharge tubes, a whole number of half-cycles from the alternating current source are always let through, i.e. that only a whole number of alternating current periods always flow, as is often desired. When

the alternating current connection device, e.g. is connected in series with the primary winding of a resistance welding transformer, the last magnetization of the transformer core as a result of the current passing through the last half period of a wave train is always of the opposite polarity to the first magnetization, as a result of the current passing through the first half period in the next wave train. This is generally necessary to prevent an over-magnetization of the core and consequent connection and irregular welding.

According to a further feature of the invention, the device which keeps the second discharge tube blocked consists of a switch which disables the effect of the control voltage on this tube. This switch can also be an electronic switch, e.g. an out-charge tube.

The invention shall be explained in more detail with reference to the exemplary embodiments shown in the schematic drawing.

In fig. 1, the two gas- or steam-filled discharge tubes 1 and 2 are connected to the direct current source 4 by means of the capacitor 3 in toggle connection. In the anode circuits, impulse transformers 5 and 6 are inserted which can be controlled into the riveting area and where on the secondary side control voltage pulses can be taken . The tubes 1 and 2 have a common cathode resistor 7 and an ignition voltage transformer 8, whose secondary windings 9 and 10 are connected to the control electrodes 11 and 12. The transformer 8 can be designed as a transformer that can be controlled into the saturation range and is fed primarily from an alternating voltage source with an arbitrary control voltage source. Grid resistors 13 and 14 are inserted in the control circuits for pipes 1 and 2. The secondary winding 10 and the grid resistor 14 are shunted with a switch 15, so that the ignition voltage on the control electrode 12 is short-circuited, and only pipe 1 is, as a result, coming from the winding 9 ignition voltage which is sufficiently positive in relation to the negative bias across the resistor 7, continuously ignited under the influence of the anode voltage source 4. In the transformer 5, no control voltage pulses are thus produced.

If the switch 15 is now opened at an arbitrary moment, then at the next positive ignition voltage across the secondary winding 10, tube 2 ignites, whereby tube 1 goes out as a result of the toggle connection of tubes 1 and 2. Hereby

occurs across the secondary winding of the transformer 6 a control voltage pulse which is used as a positive control voltage and across the secondary winding of the transformer 5 a pulse occurs which can be used as a negative control voltage (or vice versa).

At the next positive ignition pulse across the secondary winding 9, the tube 1 ignites and the tube 2 goes out, so that a positive control voltage pulse can be taken from the transformer 5 and a negative control voltage pulse from the transformer 6. This repeats as long as the switch 15 is open. If this now ends in an arbitrary

moment, the tube 2 no longer ignites, so that the last ignition of the tube 1 produces the last positive control voltage pulse across the transformer 5, so that a whole number of positive input voltage pulses are delivered by the transformers 5 and 6, the first positive ignition voltage always occurring across the transformer 6 despite the use of an asynchronous switch.

Fig. 2 shows a variant of the coupling in fig. 1, in which the ignition of the tube 2 is avoided by

disconnection of the secondary winding 10. Tube 2 ignites when the inverter 15 switches to

the winding 10. However, it must be ensured that the grid circuit of the tube 2 is not left open, otherwise an unwanted ignition of the tube can occur at any time. For that purpose, the contacts on the inverter 15 can e.g. are arranged so close to each other that the connection with the center outlet of the transformer first

is broken when the inverter is connected to the winding 10. When, as shown in fig. 3, the secondary windings 9 and 10 are not magnetically connected to each other, the ignition of the tube 2 can also be prevented by short-circuiting the left half of the primary winding with the switch 15. Optionally, two at-separated transformers can also be used.

Fig. 4 shows that ignition of the pipe 2 can be avoided by means of a further negative bias from the resistor 16. If the resistor 16 is short-circuited by means of the switch 15 (or electronically), the blocking of the pipe 2 is lifted.

Finally, fig. 5 a variant of the coupling in fig. 4.

Claims (3)

1. Device with controllable gas- or steam-filled discharge tubes in toggle connection, which tubes are fed from a direct current source and each has an impedance in its anode circuit from which control voltage pulses can be extracted for controlling resistance welding devices by the two discharge tubes being periodically supplied with ignition voltages, characterized by a switch (15) which prevents the ignition of one discharge tube (2) by means of the ignition voltage, so that only the other tube (1) conducts current and that the blocking of one discharge tube (2) is lifted by means of the switch in a specific time for the generation of control voltage Ipulses across the impedances (5, 6), so that the tubes ignite periodically one after the other until one discharge tube (2) is again blocked by the switch, so that an equal number of control voltage pulses are always generated across the impedances (5, 6). 2. Device according to claim 1, characterized in that the influence of the control voltage on the second tube (2) is switched off by means of a negative bias voltage, which can be deactivated with the switch (15). 3. Device according to claim 1 or 2, characterized in that both tubes (1, 2) have a faulty cathode resistance (7).