RU2356193C1 - Device for charge-particle beam conducting - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: claimed invention relates to accelerating equipment and high-current electronics. Conducting device can be used in design of systems for charged particles beam input into various accelerators working in the mode of single pulses. In the claimed device focusing system is made stepped consisting of at least two magnet lenses and output shaper. In the magnet lenses inner stepped current-conducting screen is located, and output shaper step is made tapered with smooth transition from circular section at input to ellipsoidal section at output. Each of magnet lenses is connected to independent switched power supply.

EFFECT: reduction of current losses during beam transportation and improvement of focusing and generating stable output current pulse of specified shape.

2 cl, 1 dwg

Description

The invention relates to accelerator technology and high-current electronics. The wiring device can be used in the design of input systems for betatrons, synchrotrons and other accelerators operating in the single-pulse mode, and for focusing a high-current beam of charged particles.

It is known "Device for introducing charged particles into a cyclic accelerator", see USSR copyright certificate No. 357892, class. IPC Н05Н 7/08 with a priority dated 10.03.1967, published in BI No. 9 of 1973, A.I. Pavlovsky, G.D. Kuleshov, A.D. Tarasov and V.O. Kuznetsov. The device for wiring a beam of charged particles according to the prototype, without considering the injector, which is a source of particles, contains a metal shielding housing, a focusing system and an external screen. The housing of the wiring device for a beam of charged particles and the outer screen are made of metal with high conductivity, and the generators of the screen profile are in the form of magnetic lines of force at its location. The principle of operation of the outer screen, as well as the shielding case, is based on the relatively low speed of penetration of the magnetic field deep into the metal, which allows one part of the space separated by the screen to be shielded from disturbance of the field in its other part. The disadvantages of the known solutions are the influence of the beam on the magnetic field of the focusing system, the instability and lack of focusing of the beam.

In the famous invention according to the patent of the Russian Federation No. 2281622, class. IPC НО5Н 11/02 with a priority dated 12/14/2004. "Method for maintaining the number of electrons during acceleration in a betatron" L.N. Robkin, V.D. Selemir, the technical result is achieved by the fact that an electron beam with the most flat section shape in the form of an ellipse is formed in the injector or in the device for introducing. The disadvantages of the known invention on the prototype should include restrictions on the optimal focusing of the electron beam in the process of posting it to the accelerator chamber.

When creating this invention, the problem was solved of developing a device for posting a beam of charged particles to obtain a stable and focused beam at the output of the device in order to reliably capture particles in acceleration mode.

The technical result in solving this problem is to reduce current losses during beam transport, improve focusing and the formation of a stable output current pulse of a beam of a given shape.

The specified technical result is achieved in that in comparison with the prototype, which contains a metal shielding body, a focusing system and an external screen, in the inventive device for conducting a beam of charged particles, the focusing system is made stepped, consisting of at least two magnetic lenses and an output shaper, moreover, an internal stepped conductive screen is located in the magnetic lenses, and the step of the output shaper is conical in shape with a smooth transition from a circular section at the entrance to an ellipsoidal section at the exit. Each of the magnetic lenses is connected to an independent source of pulsed power.

Implementation of a three-stage focusing system consisting of at least two magnetic lenses and an output shaper allows the following functions to be sequentially performed: the first magnetic lens conducts a particle beam with minimal losses, the second magnetic lens focuses the beam, and the output shaper generates a beam current pulse given shape. It was possible to reduce losses during the passage of a particle beam, firstly, by reducing the intrinsic inductance of the first magnetic lens by using a two-layer winding lens with a certain pitch in the solenoid and, secondly, by selecting the parameters of the electrical pulse power of the first magnetic lens. A feature of the wiring device is its sharp narrowing at the output, which is necessary to ensure the conditions for capturing an electron beam in a betatron. An internal stepped metal screen in the lenses, which is a thin-walled tube of different diameters made of stainless steel, serves as a return conductor for the transported part of the beam and as an absorber of charged particles of its low-energy part. It also screens the effect of the beam on the magnetic field of the focusing system, which improves beam stability. The thickness of the stepped screen tube is determined from the condition of its transparency for the inverse effect of the magnetic field of the focusing system on the transported beam. The metal step of the output shaper, made in a cone-shaped form with a smooth transition from a circular cross section at the entrance to an ellipsoidal at the exit, allows the ellipsoidal shape of the beam section of the required size to be formed at the device output. The beam sizes, depending on the parameters of the power system of the magnetic lenses of the focusing system, and the shape of the beam were optimized for the output of the radiation generated by the accelerator, in particular the betatron, in a pulse.

Connecting magnetic lenses to independent power sources allows you to more accurately adjust the magnetic field of the focusing system, and hence the shape of the output pulse of the beam current.

The drawing shows the inventive device for wiring a beam of charged particles, where:

1 - metal shielding case;

2 - the first magnetic lens;

3 - internal conductive screen;

4 - dielectric insert;

5 - grid-anode of the injector;

6 - the second magnetic lens;

7 - output driver;

8 - outer screen;

9 - high voltage bushings;

10, 11, 12 - measuring sensors;

13 - adapter with a bellows.

The inventive device for conducting a beam of charged particles contains a metal shielding housing 1, a focusing system and an external screen 8. The focusing system is made stepwise and consists of at least two magnetic lenses 2 and 6 and the output shaper 7. In the magnetic lenses there is an internal stepwise conductive screen 3. The step of the output shaper is made conical in shape with a smooth transition from a circular section at the entrance to an ellipsoidal section at the exit. Magnetic lenses are connected to independent sources of switching power via high-voltage inputs 9.

In an example implementation, the inventive device for conducting a beam of charged particles serves for efficient wiring (transportation) of an electron beam from the anode of a field emission diode to the point of entry of the beam into the betatron. The design of the wiring device is shown in the drawing. The shielding case in the form of a copper pipe (1) ⌀102 mm, 5 mm thick and 470 mm long serves as the mechanical basis of the wiring device. In the housing is the first magnetic lens (2), which is a two-layer solenoid, the frame of which is made of caprolon. The frame has grooves for laying wires with varnish insulation. Inside the lens there is an internal screen, which is a thin-walled tube (3) ⌀64 mm and a wall thickness of 0.2 mm made of stainless steel. The lens is aligned in the housing using a dielectric insert (4). At the entrance of the wiring path there is a grid (5), which serves as the anode of the injector. The housing of the wiring device has a sharply tapering section-step, in which the second magnetic lens (6) of the focusing system is located, which is a single-layer solenoid. The second lens has a smooth caprolon frame, inside of which there is a similar inner screen of a thin-walled tube of smaller diameter. At the output of the wiring device, there is a step of the output shaper (7) made of a copper pipe, which is a cylindrical sleeve on the side of the magnetic lens, and a tapered truncated cone with a tapering ellipsoidal opening at the output side. The boundary of the transition sleeve-cone is made smoothed. Part of the wiring device from the side facing the center of the betatron electromagnet is equipped with an external copper screen (8), which localizes the perturbation of the magnetic field lines of the betatron, since the generatrices of the external screen profile are in the form of magnetic field lines at its location. Magnetic lens solenoids are wound with a ⌀ 2 mm copper wire, the first lens with a certain step in two layers, and the second lens tightly in one layer. The inductances of the first and second lenses placed on the screen are respectively L ₁ = 25.8µH and L ₂ = 9.6µH. The polarity of the supply voltage for magnetic lenses must be such that their magnetic fields add up. The magnetic lenses are fed through special high-voltage bushings (9). In the wide end part of the wiring device from the field emission diode in front of the anode grid, in a special groove shielding from scattered electrons, there is a Rogowski belt (10) that measures the diode current. Behind the grid, in a similar groove, is the Rogowski belt (11), which measures the input current of the electron beam. At the output of the wiring device there is a shell with a groove for the induction sensor (12), which measures the current of the electron beam at the output. An adapter with a bellows (13) serves for the vacuum-tight connection of the device with the accelerating chamber of the betatron.

The claimed device operates as follows. The injected electron beam from the anode of the field emission diode enters the focusing system (FS) of the wiring device. The focusing system of the wiring device is based on the focusing of a cylindrical electron beam by a longitudinal magnetic field. The first magnetic lens of the FS is tuned to provide maximum beam passage along the wiring channel, and the second magnetic lens corrects its divergence at the exit of the wiring device, providing focusing of the electron beam and, together with the output shaper, matching the beam with the aperture of the betatron chamber. The metal shielding housing provides shielding of the beam from the magnetic field of the betatron and shielding of the betatron field from the field of the focusing system of the wiring device. To reduce the distortion introduced by the wiring device into the magnetic field of the betatron, it is equipped with a profiled external screen that corrects the course of the lines of force of the magnetic field of the betatron in the beam exit zone. The inner screen, which is a thin-walled stainless steel pipe, the thickness of which is determined from the condition of its transparency for the magnetic field of the focusing system, shields the FS from the influence of the transported electron beam. The shielding housing of the wiring device provides shielding of the betatron from the magnetic field of the focusing system for the first 30-50 μs. The accelerator cycle in the betatron lasts from hundreds of microseconds to milliseconds and in order to exclude the influence of the FS on the beam in the betatron, the FS is fed from pulsed electrical sources by current pulses of tens of microseconds in duration. To effectively control the parameters of the beam transported in the wiring device, it is equipped with a system of inductive sensors - Rogowski belts.

Thus, in comparison with the prototype, the inventive wiring device transports the electron beam necessary for injection into the betatron, reducing the beam current loss by 20% and providing better stability and focusing of the beam at the output of the wiring device for reliable capture of particles in acceleration mode, without introducing interference, interfering with the normal operation of the betatron. The shape and size of the cross section of the electron beam correspond to the optimal ones and are 8 mm and 4 mm along the axes of the ellipse. With these parameters, the maximum radiation intensity of the betatron was obtained.

Claims (2)

1. A device for conducting a beam of charged particles, comprising a metal shielding body, a focusing system and an external screen, characterized in that the focusing system is made stepwise, consisting of at least two magnetic lenses and an output shaper, and an internal stepwise conductive is located in the magnetic lenses the screen, and the step of the output shaper is conical in shape with a smooth transition from a circular cross section at the entrance to an ellipsoidal cross section at the exit. 2. The device according to claim 1, characterized in that each of the magnetic lenses is connected to an independent switching power supply.