DE935076C - Arrangement for half-wave doubling in electrical controls, especially for resistance welding machines - Google Patents

Description

Arrangement for half-wave doubling in electrical controls, especially for resistance welding machines For welding with periods or whole Control processes are required for multiples of periods, «-which control the welding current control switching vessels. The control vessels (mostly grid-controlled steam or Gas discharge paths) for the switching vessel (mostly ignition-pin-controlled discharge vessel) receive their control impulses from an impulse source. This impulse duel is from a certain Gefä lianordnutig switched on and off, something either arbitrarily or closed by a timer.

1? It is known to avoid DC bias In the welding transformation (-) r it is absolutely necessary to ensure full switching periods to force through the fact that a Zeitgeher is used, which is only half-waves the same Pol @ tritiit ahg-i13t. A so-called sequential circuit is set up for this purpose. the example works in such a way that it is ready to ignite when current flows through a control vessel or a switching vessel for the control or switching vessel of the other half-wave is produced. Such Arrangement is not the subject of the invention, rather the engagement is used to secure full switching periods between the pulse source and control vessels. this has the advantage that the function of the circuit is completely independent of the cos (f the load will. According to the invention is for half-wave doubling in the transmission circuit A discharge path is provided between the pulse source and the control vessel. In the steering committee This discharge path has a capacitor and a parallel resistor. This one Parallel resistance are supplied from the timer with half-waves of the same polarity, and the parallel resistance is dimensioned so that in the event of a charging of the capacitor while one half-wave the discharge during the next half-wave opposite polarity occurs completely.

The drawing shows an embodiment of the invention, namely FIG. 1 explains the mode of operation of the circuit according to FIG. 2 or 3. In FIG. 2 i is a grid-controlled discharge path, which comes from an alternating voltage source 2 is fed via a full wave rectifier 3 and an anode burden 4.

A device is available in the grid circle of the discharge path i Generation of a negative bias voltage 5, a capacitor 6 and a resistor 7. The at d. Tapped voltage is fed to the grid of a vessel 8, which is fed on the anode side from a pulse source 9 and thus the transmission of this Pulses via io and i i to the control vessels of the switching vessels for the welding current controls. Half-waves of the same polarity are now fed to the resistor 7 charge the capacitor 6. Fig. I shows the voltage across the capacitor or the resistor. After such a positive half-wave, a discharge takes place via the resistor 7 of the capacitor. This must have practically subsided at least when the next burst of charging, i.e. the next positive half-wave occurs. The alternating voltage from source 2 is synchronous with the half-waves that are at 6 and 7. Will the If capacitor 6 is charged by a positive half-wave, ignition takes place immediately of the vessel i. The anode circle of i is dimensioned so that the feeding, pulsating DC voltage becomes zero after every half cycle and i goes out. With tension N zero crossing, d. i.e. if both the positive half-wave supplied and the corresponding anode half-cycle at i have become zero, is the charge on the capacitor 6 still so great (time t 1) that the anode voltage rises again immediately the grid still has a sufficiently high, positive potential against the cathode, so that the vessel i ignites.

`` 'ground the resistor 7 or the capacitor through a timer 6, for example, three positive half-waves are supplied, this will certainly lead Vessel i current for three full periods and generates one at the resistor 4th correspondingly long lasting pulsating DC voltage drop. While exactly the At the same time, the vessel 8 can conduct electricity and thus conducts the pulse voltage from the pulse source 9 through transmitters io and i i to the control vessels.

In tube technology, such vessels are known in which a The grid divides the vessel into three spaces, a cathode, an anode and a second grid included. The second grid is in the space between the cathode and the anode compartment. They allow a significant simplification of the circuit according to the invention.

Then the function of the vessels i and 8 can be combined in one tube, as shown in FIG. The vessel 1 8 in FIG. 3 has grid G i G2, the grating G i divided and the vessel in the above three areas. The AC voltage 2 is applied to the grid G 2 via the rectifier 3 and a burden .I. The capacitor voltage is applied to the grid G i, and the anode voltage of the vessel 18 comes from the pulse source 9. If the grid G i receives a positive voltage against the cathode as a result of the voltage on the capacitor 6, an auxiliary exciter arc is ignited by the grid G2, which is positive against the cathode. can be kept sufficiently small. As a result of this current, the grid G i and G 2 is in any case positive towards the cathode when an anode voltage pulse occurs from the pulse source 9, which is then allowed to pass and is transmitted directly via io and ii. If there is no positive voltage on the capacitor or if no positive half-waves are supplied from the timer, no auxiliary excitation arc is ignited in the vessel 18 and no anode current flows either, so that the vessel 18 remains blocked for the pulses.

The invention is not only suitable in the control circuit of welding machines to be switched, but can be used for any control process, where a precise adherence to the switching of full periods is important.

Claims (3)

PATENT CLAIMS: i. Arrangement for half-wave doubling in electronic Controls, especially for resistance welding machines, with one preferably gas-filled discharge tube, the anode voltage of which comes from a full-wave rectifier is removed, characterized in that the discharge path in the control circuit a capacitor and a parallel resistor are provided, which half-waves are more constant Polarity are supplied, the resistance being such that when charging of the capacitor during a half cycle the discharge during the subsequent Half-wave is practically complete, but the capacitor is charged at the beginning the subsequent half-wave is so large that an ignition of the discharge path also takes place during this subsequent voltage half-wave. 2. Arrangement according to Claim i, characterized in that the anode current of the discharge path on a discharge vessel acts, which transmits pulses to a control device controls. 3. Arrangement according to claim i and 2. characterized in that the two Discharge vessels are combined in a multi-lattice tube, with a lattice the capacitor voltage, on the other grid the feeding, pulsating direct voltage and the pulse voltage is applied to the anode.