RU60295U1 - PULSE SOURCE OF PASSING RADIATION - Google Patents

Abstract

A pulsed source of penetrating radiation relates to devices for generating neutron beams, in particular, to generators of single pulses of neutron and x-ray radiation and can be used for nuclear physics research, studying radiation resistance, for example, elements of electronic equipment, and calibrating ionizing radiation detectors.

The utility model solves the problem of creating a source of pulsed penetrating radiation capable of repeatedly emitting pulses of neutron and x-ray radiation with an intensity an order of magnitude higher than those generated in similar known devices with the possibility of using it autonomously.

To solve this problem in a pulsed source of penetrating radiation, made in the form of one or more modules, each of which contains a capacitive storage 2 connected to a high-voltage power supply 3 and connected through a high-current high-voltage switch 4 and a cable line 5 with a load block 6, a discharge chamber 7, in which a plasma focus type discharge is formed, the cable line 5 is made of coaxial wires of equal length uniformly distributed around the circumference of the current-carrying flanges of the switch 4 and the load unit 6, the interelectrode electric insulation 8 is made of a multilayer stack of spacers of dielectric material, the switch 4 is designed as a vacuum managed arrester, the current collector plate are electrically connected through the throttle 9, the discharge chamber 7 is made in the form of sealed gas-filled device. The pulse source contains an electrical safety system consisting of a high-voltage vacuum relay 10 and discharge resistors 11 connected to the positive bus of the capacitive storage 2 and providing discharge of the capacitive storage after turning off the power source 3. To fill the discharge chamber, deuterium or tritium, or a mixture of deuterium with tritium. A pulsed source of penetrating radiation is enclosed in a sealed moisture-proof housing 16, equipped with wheels, the power of the electronic units is carried out from an autonomous power source with a voltage of +24 V, which allows you to use the source of penetrating radiation autonomously.

Description

The utility model relates to devices for generating neutron beams, in particular, to generators of single pulses of neutron and x-ray radiation and can be used to conduct nuclear physics research, study radiation resistance, for example, elements of electronic equipment, and calibrate ionizing radiation detectors.

A device is known for producing pulses of neutron and x-ray radiation (see, for example, RF patent No. 768376, class N 05 N 1/06, published March 27, 1997), containing an energy source, an energy transmission line, a switch and a plasma reactor formed coaxially located by the anode and cathode, separated by an insulator, an additionally installed high-frequency generator for preliminary formation of a uniform plasma shell, connected to the electrodes of the plasma reactor in parallel with the energy source, and a synchronization device start-up of the high-frequency generator and switch.

The specified device has a low level of neutron radiation intensity.

Known pulsed source of penetrating radiation (see, for example, Collection of scientific papers edited by Makeev N.G. "Physics and technology of pulsed sources of ionizing radiation for the study of fast processes" No. 5, Sarov, 1996), containing as a source the current is an explosive magnetic current source (VMG), an energy transmission line, a discharge chamber, a VMG power supply system from an initial energy source, and a start-up system.

This device is intended for one-time use and requires the protection of the studied objects and equipment from the explosive effects of the VMG.

As a prototype for the largest number of matching design features adopted a pulsed source of penetrating radiation (see RF patent No. 2257020, CL N 05 N 1/06, 2003), which is one or more modules, each of which contains a capacitive storage, connected to a pulsed thyratron commuting a capacitive storage discharge through a cable line to a load unit (current collector), and a discharge chamber installed in it, in which a plasma focus discharge is formed, a charger, a charge source ala thyratron, thyratron start-up system, pulse generator, starting thyratron start-up system, control and monitoring system for generator operation and capacitive storage discharge; diagnostic and recording equipment, the cable line is made of coaxial wires of equal length, evenly distributed around the circumference of the current-carrying flanges of the thyratron and the load unit; electrical isolation of the anode space of the load block is made in the form of a multilayer package of gaskets made of dielectric material; the capacitive storage and the load block are galvanically isolated from the mounting plate, the anode and cathode of the load block are galvanically connected to each other through the resistor block, the cathode of the load block is galvanically connected to the “mass” of the mounting plate, the device elements are compactly mounted and secured by power elements to the mounting plate.

The known pulsed penetrating radiation source has a collector connection to the “mass” of the mounting plate, which when triggered leads to the appearance of “jumping” potentials on the capacitor banks of capacitive storage devices, cable lines, thyratron cases and in thyratron launch systems (the potentials of almost all parts of the device are practically unstable) , which requires careful mutual high-voltage isolation of all parts of the electrical circuit.

For used filament thyratrons, a thyratron filament block is required, which leads to additional energy consumption and the need for careful

adjusting the glow circuit, both during commissioning and during operation.

The use of a block of resistors between the anode and the cathode of the load causes a significant heat generation on the block of resistors when charging a capacitive storage in accordance with the ratio

R · I ² _zar * T _zar

where R is the resistance of the resistor block,

I _zar - charge current of the capacitive storage,

T _zar - charge time.

In addition, when a penetrating radiation source is triggered, a large thermal power is released on the resistor block.

The proposed utility model solves the problem of creating a source of pulsed penetrating radiation capable of repeatedly emitting pulses of neutron and x-ray radiation with an intensity an order of magnitude higher than those generated in similar known devices with the possibility of using it autonomously in the field.

To solve this problem in a pulsed source of penetrating radiation, made in the form of one or more modules, each of which contains a capacitive storage connected to a high-voltage power source and connected through a high-current high-voltage switch and cable line to the load unit, which is a current collector, and installed in It has a discharge chamber, in which a discharge of the “plasma focus” type is formed, a switch start-up system, a cable line made of coaxial wires of equal length Uniformly distributed over the circumference of the live load and flanges switch unit; the interelectrode electrical insulation of the load block is made of a multilayer package of gaskets made of dielectric material, the high-current high-voltage switch is made in the form of a vacuum controlled arrester, the cathode of which is galvanically connected to the zero potential bus, the plates of the current collector are galvanically connected to each other through a choke, the discharge chamber is made in the form of a gas-filled sealed device, a pulsed source of penetrating radiation contains an electrical safety system consisting of and a high-voltage vacuum relay and discharge resistors connected to the positive bus storage capacitor and providing discharge storage capacitor after switching off the power source, wherein the discharge chamber is filled with deuterium or tritium or a mixture of

deuterium with tritium. A pulsed source of penetrating radiation is enclosed in a sealed moisture-proof casing equipped with wheels, the electronic units are powered by an autonomous power supply, with a voltage of +24 V.

The utility model is illustrated in the drawing.

A pulsed penetrating radiation source contains (see drawing) one or more modules 1, each of which consists of a capacitive storage 2 connected to a high-voltage power supply 3, a high-current high-voltage switch 4, a cable line 5, a load unit, which is a current collector 6, installed there is a discharge chamber 7, a multilayer package of gaskets 8 made of dielectric material, a choke 9 connecting the plates of the current collector 6, an electrical safety system consisting of a high-voltage vacuum relay 1 0 and discharge resistors 11 connected to the positive bus of the capacitive storage 2, the start-up system of the switches 12, the control module 13, the control panel 14, an autonomous power source 15, a moisture-proof housing 16.

The device operates as follows:

After applying a supply voltage of +24 V from an autonomous power source 15, a pulse source of penetrating radiation is turned on, which is subsequently controlled by the control module 13 or by the operator from the control panel 14, while the high-voltage vacuum relay 10 opens. When the high-voltage power supply 3 is turned on, the capacitors of the capacitive storage 2 are charged. When the voltage on the capacitors reaches the set value, the high-voltage power supply 3 is turned off, and the energy from the charged capacitors 2 is transmitted via cable lines 5 through the high-voltage high-voltage switches 4 through cable lines 5 through current collector 6 into the discharge chamber 7, which generates a pulse of neutron and x-ray radiation. At the end of the work, the supply voltage from the autonomous power source 15 is disconnected, the high-voltage vacuum relay 10 is closed, and all the high-voltage parts of the pulsed penetrating radiation source are grounded via a discharge resistor 11.

The implementation of the discharge chamber 7 in the form of a gas-filled sealed device allows you to adjust the neutron yield and their spectrum by filling the discharge chamber with an appropriate gas or gas mixture.

The discharge chamber 7, after being filled with working gas, is sealed off (sealed) and is a stand-alone electric vacuum device with a long shelf life (~ 10 years or more).

The proposed pulsed penetrating radiation source makes it possible to generate 2.5 MeV neutron pulses when the discharge chamber is filled with deuterium, when the chamber is filled with a mixture of deuterium with tritium, 14.5 MeV neutrons are generated, and when the chamber is filled with tritium, neutrons of a wide energy spectrum 0-10 MeV.

The discharge chamber 7 has an anode and a cathode that determine the direction of current flow through the chamber. It should be connected to the load block 6 (current collector) accordingly: the anode to the positive collector plate, the cathode to the negative plate.

To ensure trouble-free operation, a pulsed source of penetrating radiation is enclosed in a sealed moisture-proof housing 16 A sealed moisture-proof housing 16 provides operation of a pulsed source of penetrating radiation in conditions of high humidity.

The installation of the housing on wheels (not shown in the drawing) allows you to move the pulse source without the use of additional mechanisms.

In addition, the power supply of electronic units is carried out from an autonomous power supply with a voltage of +24 V, which allows the use of a source of penetrating radiation autonomously.

Claims (7)

1. A pulsed source of penetrating radiation, made in the form of one or more modules, each of which contains a capacitive storage connected to a high-voltage power source and connected through a high-current high-voltage switch and a cable line to the load unit, which is a current collector, and a discharge chamber installed in it in which a plasma focus type discharge is formed, the switch start-up system, the cable line is made of coaxial wires of equal length, uniformly distributed the circumference of the current-carrying flanges of the switchboard and the load unit, the interelectrode electrical insulation of the load unit is made of a multilayer package of gaskets made of dielectric material, characterized in that the high-current high-voltage switch is made in the form of a vacuum controlled arrester, the cathode of which is galvanically connected to the zero potential bus, the plates of the current collector are galvanically connected between each other through the throttle, the discharge chamber is made in the form of a gas-filled sealed device, pulse The penetrating radiation source contains an electrical safety system consisting of a high-voltage vacuum relay and discharge resistors connected to the positive bus of the capacitive storage and providing discharge of the capacitive storage after switching off the pulse source. 2. A pulsed source of penetrating radiation according to claim 1, characterized in that the discharge chamber is filled with deuterium. 3. The pulse source of penetrating radiation according to claim 1, characterized in that the discharge chamber is filled with a mixture of deuterium with tritium. 4. The pulse source of penetrating radiation according to claim 1, characterized in that the discharge chamber is filled with tritium. 5. The pulse source of penetrating radiation according to claim 1, characterized in that it is enclosed in a sealed moisture-proof housing. 6. The pulse source of penetrating radiation according to claim 5, characterized in that the sealed moisture-proof housing is equipped with wheels that allow you to move the source without involving additional mechanisms. 7. The pulse source of penetrating radiation according to claim 1, characterized in that the power supply of the electronic units is carried out from an autonomous source with a voltage of +24 V.