SU18839A1 - Automatic mercury release rectifier - Google Patents

Description

The ignition of a mercury high-voltage rectifier is usually achieved by swinging the bulb, which is produced either by hand, or by using a solenoid, or in general an electromagnet. In a power-voltage installation, such ignition is a big inconvenience, in view of the need to isolate both the oscillating drive and the relays included in the automatic start system. Finally, with a large number of flasks, the start-up in ko takes some time when starting the flasks separately, or causes a bulky device, when all flasks are started at once. . .

The present invention relates to an automatic start-up mercury rectifier and has the goal of eliminating the aforementioned disadvantages.

In FIG. 1 depicts a mercury rectifier incorporation circuit; FIG. 2, 3, 4, 5-modification of it.

The flask of mercury rectifier is supplied, for the purpose of igniting the pilot arc, or the main circuit arc, with an internal or external auxiliary electrode 1 (Fig. 1 and 2), which in the first case may be mercury, or from some other metal, for example iron or, finally, from graphite or other suitable material. This electrode is located near the cathode so that you can have enough

a large potential gradient at the cathode when the potential electrode is in communication. The auxiliary electrode 1 (Fig. 1) is connected, by means of a capacitor 2, to the winding 3 of a high voltage transformer having a common magnetic circuit with an ignition transformer 4. The capacitor 2. has a capacitance superior to that of the auxiliary electrode 1 so that there is a sufficient voltage drop between electrodes 1 and 5. However, this capacitor should not be so large that through the auxiliary electrode 1 could pass a large current causing a greater load on the transformer 4.

Such a device is also possible when the high-voltage winding 3 will have a common magnetic circuit with the main transformer 7 (Fig. 3). In this case, the ignition standby may be completely absent. Finally, the winding 3 may belong to a separate starting transformer, fed from the same current source as the main transformer, or from a separate current source, which may have a completely different frequency (Fig. 5). In the event that the voltage of the main transformer is sufficiently high, the auxiliary electrode can be driven to one or several main anodes 8 by means of a capacitor 2 (Fig. 4).

The voltage increase at the electrode 1 to the limits necessary for imparting to the electrons the speed required to ionize the space near the electrodes can also be produced by adjusting the circuit (Fig. 5) consisting of the capacitance formed by the electrode 1 and the cathode 5 , the capacitance of the capacitor 2 and the reaction of the transformer dissipation, and, if necessary, the reactive coil 9 included in the auxiliary electrode circuit 1. Moreover, after ignition of the rectifier between electrodes 1 and 5, the voltage drops to a very small value, and the resonance condition in deterioration.

A mercury rectifier is put into operation by simultaneously switching on the duty ignition circuit and auxiliary electrode 1. It is also possible to turn on the main transformer simultaneously with the auxiliary electrode 1. After the current detection in the duty ignition or main current circuit, the auxiliary electrode can be turned off by means of a direct current relay 6, which may be included in the standby or rectified current circuit, as shown in FIG. five.

With regard to the voltage that must be applied to the electrode 1 to create a sufficient electron velocity, this voltage can be reduced by using as the cathode instead of pure mercury, a cathode of oxide immersed in mercury, or an oxide in the form of powder added to mercury.

The subject of the patent.

1. A mercury rectifier with an automatic start-up, characterized by the fact that, in order to ignite the pilot arc or the main circuit arc located near the cathode inside the bulb or outside the bulb, the auxiliary electrode 1 is connected through a capacitor 2 to the winding of a high-voltage transformer, Iyush, its common magnetic circuit with a stand-by ignition transformer (Fig. 1 and 2).

2. Alteration described in p, 1 mercury rectifier, characterized in that the auxiliary electrode 1 is connected through a capacitor 2 to the high voltage winding of the main transformer 7 (Fig. 3),

3. Variation described in paragraph 1 of a mercury rectifier, characterized in that the auxiliary electrode 1 is connected through a capacitor 2 to a transformer 4 connected to the same AC source as the main transformer, or to another AC source (Fig. 5 ).

4. Alteration of the mercury rectifier described in paragraph 1, characterized in that the auxiliary electrode 1 is connected through a capacitor 2 to one or more main anodes 8 (Fig. 4).

5. Modification described in paragraphs 1-4 of a mercury rectifier, characterized in that, in order to obtain the necessary voltage on the auxiliary electrode 1, the latter is connected to a circuit consisting of a capacitor 2, a reactive coil 9 and a transformer 4 and tuned to resonance with oscillations of the current feeding the transformer 4 (Fig. 5).

6. Application of the constant-tone relay with the winding connected in series with the purpose of the rectified current, which is intended for switching off the auxiliary electrode 1 circuit after the occurrence of the arc.

7. Application of mercury cathode rectifier consisting of mercury and oxide of alkaline-earth or other metals, as described in pp.

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