RU71468U1 - SEALED NEUTRON PIPE - Google Patents

Abstract

The utility model relates to small sealed neutron tubes, and can be used in the development of neutron generators for the study of geophysical and field wells. The technical result of the utility model is to increase the neutron yield without increasing the dimensions of the tube, increase the diameter of the anode and the magnetic field near the surface of the anode, increase the lifetime of electrons in the discharge in crossed magnetic and electric fields, increase the ion current and, accordingly, increase the neutron flux of a sealed neutron tube. The technical result is achieved by the fact that in a sealed neutron tube, the anode is made in the form of a grounded metal body, and the cathode and anticathode are isolated from it. 1 s.p.f. 1 ill.

Description

The utility model relates to small sealed neutron tubes, and can be used in the development of neutron generators for the study of geophysical and field wells.

Known sealed neutron tube containing a hollow cylindrical insulator, at one end of which a target is hermetically fixed, at the other end is a metal case hermetically placed with a cathode, anticathode, anode and cylindrical permanent magnet that creates an axial magnetic field between the cathodes. Bespalov D.F. Small accelerator tube UNG-1 for downhole neutron generators. Geophysical equipment, N 30, 1966, pp. 97-108. US patent N 3546512, NKI: 313-61. IPC: G21G 4/02, 1970.

The disadvantage is the low magnitude of the ion current on the target, the low magnitude of the neutron flux, the loss of the properties of a permanent magnet due to overheating.

Known sealed neutron tube containing a hollow cylindrical insulator, at one end of which a target is hermetically fixed, and a metal case with a cathode, anticathode and anode located in it is sealed in a cavity of a cylindrical permanent magnet. US patent No. 4282440, IPC: G21G 4/02, 1981. Prototype.

The disadvantage of the prototype is the low efficiency of gas ionization in the ion source and low neutron flux due to the small magnitude of the magnetic induction on the inner surface of the anode, due to the fact that the anode is located at a distance from the surface of the magnet.

The technical result of the invention is to increase the neutron yield without increasing the dimensions of the tube, increase the diameter of the anode and the magnetic field near the surface of the anode, increase the lifetime of electrons in the discharge in crossed magnetic and electric fields, increase the ion current and, accordingly, increase the neutron flux of a sealed neutron tube.

The technical result is achieved by the fact that in a sealed neutron tube containing the anode, a hollow cylindrical insulator at one end of which the target is hermetically fixed, at the other end hermetically fixed, located in the cavity of the cylindrical magnet, a metal case with the cathode and anticathode located in it, the anode is made in in the form of a grounded metal case, and the cathode and anticathode are isolated from the grounded metal case.

The essence of the utility model is illustrated by the drawing, which schematically shows a sealed neutron tube, where:

1 — a hollow cylindrical insulator, 2 — a target hermetically fixed at the end of the resonator, 3 — an anode made in the form of a grounded metal case, 4 — a cathode isolated from the case, 5 — an anti-cathode, 6 — a cylindrical permanent magnet.

The neutron yield depends on the ion current. The ion current depends on the efficiency of gas ionization in the discharge. The ionization efficiency for discharges in crossed electric and magnetic fields increases with increasing magnetic field strength on the inner surface of the anode and anode diameter. The permanent magnet in the prototype is placed at a distance from the anode since they are under different potentials. This does not allow increasing the magnetic field strength on the surface of the anode. In addition, the prototype is excluded

the possibility of increasing the diameter of the anode without increasing the size of the entire sealed neutron tube.

A sealed neutron tube operates as follows.

In the volume between the cathode 4, the anti-cathode 5 and the anode 3, a discharge is ignited in crossed electric and magnetic fields. For this, anode 3 is supplied with voltage relative to the cathode 4 and anticathode 5.

Deuterium ions are accelerated to target 2 of a sealed neutron tube. Accelerated ions interact with tritium atoms located in target 2. As a result of the ³ H (d, n) ⁴ reaction, neutrons are not formed.

The diameter of the anode 3, due to the exclusion of the gap between the anode 3 and the casing, is increased to the diameter of the casing.

In addition, in this design, the magnetic field on the surface of the anode 3 is increased due to the fact that the surface of the anode is in direct contact with the inner surface of the cylindrical permanent magnet 6. Moreover, the diameter of the neutron tube does not increase and it is not necessary to increase the size of the permanent magnet 6.

Claims (1)

A sealed neutron tube containing an anode, a hollow cylindrical insulator at one end of which the target is hermetically fixed, a metal case located in the cavity of the cylindrical magnet with a cathode and anticathode placed in it, hermetically fixed in the form of a grounded metal case, and the cathode and anticathode are isolated from a grounded metal casing.