CS218142B1 - Disconnection circuit of spark gap - Google Patents

Abstract

The invention relates to the connection of a spark gap discharge circuit for spark generators, which are intended in particular for spectrochemical analysis devices. The spark gap discharge circuit is designed in such a way that between the first and second connection nodes there is connected a series arrangement of the first, second, third resistors and an induction coil, the first and second resistances of which are bridged by a second diode, and in parallel to the first resistance there is connected a series arrangement of a capacitor with a first diode. The said discharge circuit is connected via the first connection node to the first output of charging pulses from the power supply and via the second connection node to the output of ignition pulses from the same power supply and at the same time to the second electrode of the spark gap, the first electrode of which is connected to the connection of the capacitor with the first diode.

Description

FIELD OF THE INVENTION The present invention relates to the connection of a spark gap discharge circuit for spark generators, particularly for spectrochemical analysis instruments.

The spark discharging circuit is designed such that a series shifting of the first, second, third resistors and an inductor is connected between the first and second junction nodes, the first and second resistors of which are bridged by the second diode, and a series shifting of the capacitor with the first diode. Said discharge circuit is connected via a first junction node to a first charge pulse output from the power supply and through a second junction node to an ignition pulse output from the same power supply and also to a second spark gap electrode, the first electrode of which is connected to the capacitor junction of the first diode.

FIELD OF THE INVENTION The invention relates to the connection of a spark gap discharge circuit for spark generators, particularly for spectrochemical analysis instruments.

The hitherto known discharging circuits of said spark gaps have the disadvantage that the space between the two electrodes is contaminated by the material of the electrode which is not the sample to be tested, resulting in a deterioration in the accuracy and reproducibility of the spectrochemical analysis results. The pollution is caused by the discharge circuits not sufficiently suppressing currents in the opposite direction.

These shortcomings are eliminated by wiring. a spark discharge circuit for spark generators designed especially for spectrochemical analysis instruments. SUMMARY OF THE INVENTION A series of first, second, third resistors and an inductor whose first and second resistors are bridged by a second diode are connected between the first and second junction nodes, and a series sequencer of the first capacitor is connected in parallel to the first resistor. diode. The spark gap discharge circuit thus formed is connected via a first junction node to the output of charging pulses from the power supply and through a second junction node to the output of ignition pulses from the same source and also to the second spark gap electrode, the first electrode being connected to the first diode capacitor.

The connection of the spark gap discharge circuit according to the invention is simple and achieves that the current wave in the spark generator is attenuated in the shortest possible time interval and the current flow in the opposite direction is eliminated. This avoids contamination of the space between the spark gap electrodes, which increases the accuracy and speed of the performance of spectrochemical analyzes.

The drawing shows an example of a spark gap discharging circuit according to the invention, which is connected between the power supply and the spark gap. The power supply with the spark gap discharge circuit constitutes a spark generator.

The discharge circuit 2 of the spark gap 3 is configured such that a series shifting of the first, second, third resistors 4, 5, 6 and the inductor 7 is connected between the first and second connecting nodes 21, 22. The capacitor 10 and the first diode 8 are connected in parallel to the first resistor 4. The discharge circuit 2 of the spark gap 3 thus formed is connected via a first connecting node 21 to a charging pulse output 11 from the power supply 1 and via a second connecting node 22 s. by outputting 12 ignition pulses from the same power supply 1 and simultaneously with the second electrode 32 of the spark gap 3, the first electrode 31 of which is connected to the junction between the capacitor 10 and the first diode 8. The power supply 1 and the first electrode 31 of the spark gap 3 are grounded.

The polarity of the two spark gap electrodes 31, 32 is dependent on the polarity of the two diodes 8, 9. In this example, the first spark gap electrode 31 is a cathode and the second spark gap electrode 32 is an anode.

Since the circuit formed by the inductor 7, the capacitor 10 and the third resistor 6 is subcritical, the discharge current pulse is shaped by non-linear elements, the first and second diodes 8, 9. When the capacitor 10 is charged with a charging pulse and impulse causes the discharge to ignite. The current pulse begins to pass in a circuit consisting of a capacitor 10, a second diode 9, a first, a second and a third resistor 4, 5, 8, respectively. The first diode 8 is polarized in the reverse direction at the start of the discharge current pulse. During the discharge pulse, the voltage at the capacitor 10 gradually decreases to zero and further changes to a voltage of opposite polarity. At this stage of the discharge pulse, the current passing through the spark gap 3 begins to decrease and at the same time the first diode 8 opens. When all the current passing through the spark gap 3 flows in the circuit of the first diode 8, second, third resistors 5, 6 and induction coil 7 the diode 9 is polarized in the reverse direction before the discharge current wave ends. Therefore, the commutation phenomena of this second diode 9 do not result in an undesired current passage in the spark gap 3 in the opposite sense. The current in the spark gap 3 remains in its original sense, and after the current gradually decreases below the critical limit, the discharge is extinguished. The voltage at the capacitor 19 is in this phase still in the opposite polarity and current in the circuit formed by the capacitor 10, the first diode 8 and the first resistor 4 returns the voltage at the capacitor 10 to zero until the next charging and ignition pulse period. .

Claims (1)

SUBJECT Spark generator discharge circuit connection, especially for spectrochemical analysis instruments, characterized in that a series shifting of the first, second, third resistors (4, 5, 6) is connected between the first and second coupling nodes (21, 22). and an inductor (7) whose first and second resistors (4, 5) are spanned by the second diode (9), and parallel to the first resistor (4) is connected a series sequencing of the capacitor (10) with the first diode (8), OF THE INVENTION the discharge circuit (2) thus formed is connected via a first junction node (21) to one output (11) of the charging pulses from the power supply (1) and through a second junction node (22) to the second output (1). 12) ignition pulses from the same power supply (1) together with the second spark gap electrode (32), the first electrode (31) of which is connected to the capacitor (10) to the first diode (8).