SU1539970A1 - Generator of pulses for supply of accelerator deflecting plates - Google Patents

Abstract

The invention relates to high voltage pulsed technology and can be used in pulsed accelerators of charged particles. The purpose of the invention is to simplify the generator and reduce the duration of the edges of the accelerator current pulse. The pulse generator contains a charging resistor 2 through which the deflection plates of the accelerator 6 and the storage capacitor 8 are charged from the high-voltage source 1. With the charged deflection plates of the accelerator 6, the particles will be deflected to the side and will not get into the acceleration process. When the thyratron switch 5 is turned on, the deflection plates of the accelerator 6 are quickly discharged, and the charged particles do not deviate from their trajectory and fall into the acceleration process. When the thyratron switch 9 is turned on, the storage capacitor 8 quickly recharges the deflection plates of the accelerator 6 through the switch 5 which is not yet closed and the particles will be deflected in the opposite direction, which prolongs the service life of the target. 1 il.

Description

Phys. 1

The invention relates to high voltage pulsed technology and can be used in pulsed accelerators of charged particles to produce a current pulse of adjustable duration with a short front and fall.

The purpose of the invention is to simplify and reduce the duration of the accelerator current pulse fronts.

FIG. 1 shows a schematic diagram of the generator; Fig. 2 shows oscillograms of its operation: a, b are control pulses on thyratron switches; c is the voltage pulses on the deflection plates of the accelerator; gfg is the form of the accelerator current to the deflection plates and after their passage, respectively.

The pulse generator for powering the accelerator deflection plates contains a high-frequency voltage source 1, to the positive terminal of which a charging resistor 2 is connected, the second terminal of which is connected to the anodes of diodes 3 and 4. The anode of the first thyratron switch 5 is connected to the cathode of diode 3 and one of the deviations of the accelerator plate 6. In this case, the cathode of the first thyratron switch 5 is connected to the anode of diode 7 and the output of the storage capacitor 8, the second terminal of which is connected to the anode of the second thyratron switch 9 and ohm diode 4 "negative high-voltage source 1 output voltage, a second deflection plate accelerator 6, a diode 7 cathode and cathode thyratron switch 9 are connected to the common bus.

The pulse generator for feeding the accelerator deflection plates works as follows.

In the initial state, the deflection plates of the accelerator 6 and the storage capacitor 8 are charged through the charging resistor 2 to the voltage of the high-voltage source 1, and the charging current of the storage capacitor 8 passes through two diodes 4 and 7. As the deflection plates of the accelerator 6 is charged, the particles deflect to the side after passing the plates and do not enter the acceleration process.

For (Normalization of the front of the accelerator current pulse at time t1 (Fig. 2, a) by the firing pulse

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The first thyratron switch 5 opens. In this case, the deflection plates of the accelerator 6 are discharged through it and the diode 7 (Fig. 2c). Consequently, the particles do not deviate from their path, pass through the discharged deflecting plates of the accelerator 6, and enter the acceleration process. When a current pulse decays at a given time point C (figure 2, c), determined by the required duration of the accelerator's current pulse, a second thyratron switch 9 opens with a firing pulse. This charge of the deflector plates of the accelerator 6 occurs along the circuit of a positively charged lining the storage capacitor 8 - the second thyratron switch 9 - the deflection plates of the accelerator 6 - the first thyratron switch 5, in which the deionization process has not yet finished, - the negative charge of the storage capacitor the capacitor 8. After charging the deflection plates of the accelerator 6, the tirztron switches are locked. In this case, the deflection plates of the accelerator 6 begin to recharge the JOT of the high voltage source 1 voltage through the charging resistor 2, however, its magnitude is large, therefore, the reverse polarity is maintained on the deflecting plates for a long time (longer than the accelerator current duration). Consequently, the particles are deflected in the opposite direction with respect to the particles deflected during the formation of the current pulse front, which lengthens the TERM of the target service. The storage capacitor 8 is charged between the pulse and the accelerator current through the circuit. The positive lead of the high voltage source 1 is voltage - charging resistor 2 - diode 4 - the storage capacitor 8 - diode 7 - negative lead of high voltage source 1. The pulse shape up to the deflecting plates and after them is shown in FIG. 2 (g, d).

Claims (1)

Invention Formula A pulse generator for accelerator deflection plates, containing a high-voltage source, the negative terminal of which is connected to a common bus and a positive one to a single terminal of a charging resistor, is a storage capacitor, characterized in that, in order to simplify and reduce the length of the current pulse front the accelerator, two thyratron switches and three diodes are inserted, the anodes of the first and second diodes are connected to the second output of the charging resistor, the cathode of the first diode is connected to one of the deflection plates astin and anode the first thyratron switch, the cathode of the first thyratron switch is connected to the anode of the third diode and one of the terminals of the storage capacitor, the second output of which is connected to the cathode of the second diode and the anode of the second thyratron switch, the cathode of the second diode of the accelerator and the cathode of the third diode are connected to a common by bus. H