PL219991B1 - Current stabilization system of the electron thermionic emission and the acceleration voltage of the electrons, especially for high-energy electrons - Google Patents

Description

Description of the invention

The subject of the invention is a system for stabilizing the intensity of the electron thermo-emission current and the electron accelerating voltage, especially for high electron energies.

Thermoelectron beams are known to be used, among others, in the process of gas ionization in ionization vacuum meters and mass spectrometers, in the generation of X-rays in X-ray lamps, in ion pumps, and in electron microscopes. In order to improve the technical parameters of the above-mentioned devices, it is desirable to stabilize both the electron thermo-emission current and the electron kinetic energy.

In the stabilization systems known in the art to date, the detection of the electron thermo-emission current as a negative feedback signal is carried out in the anode circuit or in the cathode heating circuit. For stabilization systems using detection in the anode circuit, a relatively low electron energy range is optimal, while the stabilization systems with thermo-emission current detection in the cathode circuit enable the generation of a beam with significantly higher electron energies.

An example of the use of anodic detection is the method of obtaining an independent regulation of the stabilized intensity and kinetic energy of a thermionic ionizing beam in a mass spectrometer, known from the Polish patent specification No. 189106, which is characterized by the fact that the directly proportional dependence of the intensity of the ionizing thermocouple beam on the first reference voltage is used and the linear characteristic of the voltage supplying the anode circuit is used from the sum of the first reference and the second reference voltages, and then simultaneously the first input of the electron beam intensity stabilization system is controlled with the first reference voltage and the second input of the voltage stabilization system supplying the anode circuit is controlled with a voltage directly proportional to the sum of the reference voltages the first and the exemplary second. The above method does not stabilize the electron accelerating voltage because it depends on the cathode voltage, which in turn is a non-linear function of the filament currents and electron thermoemission.

There are known from Polish patents No. 73 594, No. 155147, No. 174650 systems for stabilizing the current of electron thermoemission using the detection of the current of electron thermoemission in the anode circuit. The above systems require the use of a negative feedback branch that connects the anode circuit to the cathode circuit. This limits the range of high anode voltages to the acceptable voltages for the elements making up the negative feedback circuit. There are attempts to use galvanically isolated circuits in the negative feedback circuit, but their use introduces a relatively high level of noise in the stabilizer output signal and additional non-linear distortions.

An example of a system for stabilizing the intensity of the thermo-emission current using the detection of the thermo-emission current in the cathode circuit is the system known from the Polish patent description No. 210947, containing measuring amplifiers, standard resistors with the same values, a source of high anode voltage, a reference voltage source, anode, cathode and a power amplifier. characterized in that the output of the power amplifier is connected to the first standard resistor and the non-inverting input of the first measuring amplifier, the second terminal of the first standard resistor is connected to the first cathode terminal and the inverting input of the first measuring amplifier and the second cathode terminal is connected to the second standard resistor and the input non-inverting of the second measuring amplifier, the second terminal of the second standard resistor and the inverting input of the second measuring amplifier are connected to the ground of the stabilization circuit, and the output of the first amplifier is The measuring amplifier is connected to the inverting input of the third measuring amplifier and the output of the second measuring amplifier is connected to the non-inverting input of the third measuring amplifier whose output is connected to the inverting power amplifier input and the non-inverting input of the power amplifier is connected to a reference voltage source whose second terminal is connected to the ground of the stabilization system, the anode being connected to the positive pole of the anode high voltage source, the negative terminal of which is connected to the ground of the stabilization system. The above system ensures the stabilization of the electron thermo-emission current, but it does not allow the stabilization of the electron accelerating voltage, defined as the difference between the anode voltage and the voltage assigned to the geometric center of the cathode, because the voltage at the cathode is a function of the filament current intensity, which in turn depends on the set value of the intensity.

Electron thermoemission current as well as, inter alia, from ambient temperature, surface phenomena at the cathode which may locally alter the operation of the electron output.

The essence of the system for stabilizing the intensity of the electron thermo-emission current and the electron accelerating voltage, especially for high electron energies, having the first and second reference voltage sources, power amplifier, standard resistors, measuring amplifiers, analog adder, high-voltage amplifier, cathode and anode placed in the vacuum area, where the resistor the first reference amplifier is connected in parallel to the inputs of the first measuring amplifier, the second reference resistor is connected parallel to the inputs of the second measuring amplifier, the values of the first and the second reference resistors being the same, and the output of the first measuring amplifier is connected to the inverting input of the third measuring amplifier, and the output of the amplifier measuring amplifier of the second is connected to the non-inverting input of the measuring amplifier of the third, and the output of the measuring amplifier of the third is connected to the inverting input of the power amplifier, and the input the non-inverting power amplifier is connected to the reference voltage source of the first, the second terminal of the reference voltage source of the first is connected to the inverting input of the second measuring amplifier and to the ground of the circuit, while the output of the power amplifier is connected to the non-inverting input of the first measuring amplifier, and the inverting input of the first measuring amplifier is connected to the cathode terminal, and the second cathode terminal is connected to the non-inverting input of the second measuring amplifier, and the anode, is connected to the output of the high-voltage amplifier, the input of which is connected to the output of the third analog adder, the first input of which is connected to the reference voltage source of the second, at where the second terminal of the second reference voltage source is connected to the ground of the system, it is that the third reference resistor is connected to the non-inverting input of the first measuring amplifier, the second terminal of the resistor of the third signal amplifier is connected to the fourth reference resistor and to the second input of the analog adder, and the second terminal of the fourth reference resistor is connected to the inverting input of the second measuring amplifier, the values of the third and fourth reference resistors being the same.

The advantageous effect resulting from the use of the electronic thermo-emission current stabilization system and the electron accelerating voltage, especially for high electron energies, according to the invention, is the precise and mutually independent selection of the thermoelectron beam parameters, i.e. the electron thermoemission current intensity and the electron acceleration voltage, and broadening in relation to the existing technical possibilities, range of obtained, stabilized electron energies.

The system is presented in the example in the drawing, which shows the schematic diagram of the stabilization system of the electron thermo-emission current and the electron accelerating voltage, especially for high electron energies.

The system of stabilization of the electron thermo-emission current and electron accelerating voltage, especially for high electron energies, has the sources U _ref1 , U _ref2 of the first and second reference voltages, power WM amplifier, RW1, RW2, RW3, RW4 model resistors, measuring amplifiers WP1, WP2, WP3, analog AS combiner, high voltage HV amplifier and K cathode and A anode placed in the vacuum area. The first reference resistor RW1 is connected in parallel to the inputs of the first measuring amplifier WP1, the second reference resistor RW2 is connected in parallel to the inputs of the second measuring amplifier WP2, and the values of the first and second reference resistors RW1, RW2 are the same. The output of the first measuring amplifier WP1 is connected to the inverting input of the third measuring amplifier WP3, and the output of the second measuring amplifier WP2 is connected to the non-inverting input of the third measuring amplifier WP3. The output of the third measuring amplifier WP3 is connected to the inverting input of the power WM amplifier, and the non-inverting input of the power WM amplifier is connected to the source Ure _f and the reference voltage of the first, while the second terminal of the source Ure _f1 of the reference voltage of the first is connected to the inverting input of the measuring amplifier WP2 of the second and with the mass of the system. The output of the power amplifier WM is connected to the non-inverting input of the measuring amplifier WP1 of the first, and the inverting input of the measuring amplifier WP1 of the first measuring is connected to the cathode terminal K, the second cathode terminal K is connected to the non-inverting input of the measuring amplifier WP2 of the second. Anode A is connected to the output of the HV high voltage amplifier, the input of which is connected to the output 3 of the analog AS adder. Analog su4 input 1

_{The second reference voltage source U ref2} is connected to the second reference voltage source U ref2, the second terminal of the _{second reference voltage source U ref2} is connected to ground. The third reference resistor RW3 is connected with the non-inverting input of the first measuring amplifier WP1, the second terminal of the third reference resistor RW3 is connected with the fourth reference resistor RW4 and with the input 2 of the analog adder AS, and the second terminal of the fourth model resistor RW4 is connected with the inverting input of the second measuring amplifier WP2, the values of the third and fourth reference resistors RW3, RW4 are the same.

The selection of the value of the electron thermo-emission current is carried out using the source U _ref and the first reference voltage. Voltage on the second model resistor RW2 is directly proportional to the sum of the heat and heat emission currents, while the voltage on the first model resistor RW1 is directly proportional to the cathode glow current intensity. The voltage at the output of the measuring amplifier of the third is directly proportional to the intensity of the electron thermo-emission current and as a negative feedback signal from the cathode circuit it is fed to the inverting input of the power amplifier WM, which controls the cathode heating K. Thanks to the use of the reference resistors RW3, RW4 of the third and fourth reference resistors of the same values of the analog adder AS and the source Ure _f2 of the second reference voltage, the anode voltage A is directly proportional to the sum of the voltage associated with the geometric center of the cathode K and the source voltage Ure _f2 of the second reference voltage. The proportionality factor is the gain of the HV high voltage amplifier. As a result, the electron accelerating voltage, as the difference between the anode voltage A and the voltage assigned to the geometric center of the cathode K, is directly proportional to the source voltage Ure _f2 of the second reference voltage and does not depend on the selected intensity of the stabilized electron thermal emission current.

Claims (1)

Patent claim The system of stabilization of the intensity of the electron thermo-emission current and the voltage accelerating the electrons, especially for high electron energies, with the reference voltage sources of the first and second, power amplifier, standard resistors, measuring amplifiers, analog adder, high-voltage amplifier, cathode and anode placed in the vacuum area, in which the reference resistor the first is connected in parallel to the inputs of the first measuring amplifier, the second standard resistor is connected in parallel to the inputs of the second measuring amplifier, the values of the first and the second standard resistors being the same, and the output of the first measuring amplifier is connected to the inverting input of the third measuring amplifier, and the output of the measuring amplifier the second is connected to the non-inverting input of the third measuring amplifier, and the output of the third measuring amplifier is connected to the inverting input of the power amplifier, and the input is not inverted The output of the power amplifier is connected to the reference voltage source of the first, the second terminal of the reference voltage source of the first is connected to the inverting input of the second measuring amplifier and to the ground of the circuit, while the input of the power amplifier is connected to the non-inverting input of the first measuring amplifier, and the inverting input of the measuring amplifier of the first is connected to the cathode terminal, and the second cathode terminal is connected to the non-inverting input of the second measuring amplifier, and the anode, is connected to the output of the high-voltage amplifier, the input of which is connected to the output of the third analog adder, the first input of which is connected to the reference voltage source of the second, the second terminal of the second reference voltage source is connected to the ground of the system, characterized in that the reference resistor (RW3) is connected to the non-inverting input of the first measuring amplifier (WP1) and the resistor terminal (RW3) of the reference resistor is connected to the reference resistor (RW4) and to the second input of the analog adder (AS) and the terminal of the reference resistor (RW4) is connected to the inverting input of the measuring amplifier (WP2), while the values of the reference resistors (RW3) and (RW4) are the same.