SU582708A1 - Device for guiding-out electron beam - Google Patents

Abstract

1. A DEVICE FOR OUTPUTING THE ELECTRON BEAM from the accelerator formation area, containing a metal foil and a mesh base in contact with it, characterized in that, in order to expand its functionality, the foil has a different thickness at different lines. The device according to claim 1; characterized in that the foil is vacuum tightly connected to all the edges of the mesh base .00 "- ^ o00

Description

The invention relates to electronic engineering and can be used in installations in which an elec- tron beam is emitted into the atmosphere or another gaseous medium, for example in installations for electron-beam welding, for medical, biological, and chemical research, in electro-ionization laser, in a number of modern accelerators. .

A device is known for outputting a beam into a gaseous medium, which is a thin metal foil of duralumin. The disadvantage of such a device is that it operates at low pressures of the gaseous medium. In order to increase the pressure of the gaseous medium, it is necessary to fix the foil on supporting supports. .

The closest to the proposed is a device for removing the electron beam from the region of the formation of the accelerator containing metal ;. foil and mesh base in contact with it. In this device, the foil has the same thickness, lies freely on the mesh base, and for vacuum sealing it is c. The device body uses a rubber gasket.

The disadvantage of such a device is the difficulty of producing electrons with different energies at the output. This leads to the need to create special means for modulating an electron beam transmitted through a foil or complex electron-optical systems to form a different-energy electron beam.

In addition, in the known device poor contact of the foil with the mesh base and the use of rubber vacuum seals leads to inefficient heat dissipation, to increased gas separation, which ultimately significantly reduces the efficiency of the device.

 The aim of the invention is to expand the functionality of the device.

This goal is achieved by the fact that the foil has a different thickness at different

plots. In addition, the foil is vacuum tightly connected to each edge of the set4aTofo base. At the same time, a beam directed to a section of a foil with “one thickness,” has one energy at the outlet, and a directional to another section — another energy.

The vacuum tightly bonding of the foil with each rib-mesh base, carried out, for example, by diffusion welding, provides a significant improvement in the heat removal from the working section of the foil and thereby increases the durability of the device.

FIG. 1 shows a device for withdrawing electronic in FIG. 2 is view A in FIG.

The device contains a mesh base 1, made, for example, by electrospark processing and metal foil 2 with a variable thickness {for example, from titanium, aluminum,). The connection of the foil with the base by diffusion welding provides good thermal contact between the foil and the base. The heat sink from the base to the cooled anode 3 is carried out through the weld 4, made, for example, by fusion welding (electron beam or pulsed argon-arc welding).

The device works as follows.

Depending on the required energy of the electron beam, it is directed to different parts of the foil. Having passed through the foil, he loses some of the energy in it and hits a target located in the working area. The energy released on the working area of the foil is discharged along the edges of the base and further transferred to the cooled anode.

If it is necessary to produce a beam with a different energy, it is directed to another part of the foil, and if it is necessary to obtain a certain energy spectrum, it is possible to scan the beam along the foil using an appropriate program.

The work carried out on the technology of manufacturing and testing the device confirmed its effectiveness.

Claims (2)

1. A DEVICE FOR WITHDRAWING AN ELECTRON BEAM from the region of accelerator formation, containing a metal foil and a mesh base in contact with it, characterized in that, in order to expand its functional capabilities, the foil has a different thickness in different areas. 2. The device according to claim 1, characterized in that the foil is vacuum tightly connected to all the ribs of the mesh base. (L s Word □ about to m about □ about plots. In addition, the foil is vacuum tightly connected to each edge of the retinal base. At the same time, the yoke directed to the foil section with one thickness has one energy at the output, and the other energy directed to the other section. The vacuum tight connection of the foil with each edge of the mesh base, carried out, for example, by diffusion welding, provides a significant improvement in heat removal from the working section of the foil and thereby increases the durability of the device. In FIG. 1 shows a device for. the output of the electron beam ^ ·, in FIG. 2 — view A in FIG. 1. The device comprises a mesh base 1, made, for example, by electric spark processing and metal foil 2 with a variable thickness (for example, titanium, aluminum, beryllium). The connection of the foil to the base by diffusion welding provides good thermal contact between the foil and the base. The heat removal from the base to the cooled anode 3 is carried out through a weld 4, made, for example, by fusion welding (electron beam or pulsed arc welding). The device operates as follows. Depending on the required energy of the electron beam, it is directed to various sections of the foil. After passing _ ._ ._., He loses part of the energy in it and falls on a target located in the work area. The energy released in the working portion of the foil is removed along the edges of the base and transferred further to the cooled anode. If it is necessary to obtain a beam with a different energy, it is sent to another portion of the foil, and if it is necessary to obtain a certain energy spectrum, it is possible to scan the beam through the foil according to the corresponding program. / The work on the manufacturing technology and testing of the device confirmed its effectiveness. ·