RU226584U1 - Direct Charge Radiation Detector - Google Patents

Abstract

The utility model relates to the technique of measuring ionizing radiation and can be used in direct charge detectors, used primarily for in-reactor measurements of neutron flux density. According to the utility model, a direct charge radiation detector contains a collector made of a material with a small cross section for interaction with neutrons, in the internal cavity of which there is a cylindrical insulating element plugged on one side, in the internal cavity of which there is an emitter made in the form of an electrically conductive rod made of a material with high cross section for interaction with neutrons. The detector also includes: a cylindrical insulating sleeve, a twisted cable with mineral insulation, a sealed lead-in containing a centering and insulation unit, an electrical insulating sleeve and electrical leads.

Description

The utility model relates to the technique of measuring ionizing radiation and can be used in direct charge radiation detectors, used primarily for in-reactor measurements of neutron flux density.

A direct-charge neutron detector is known, containing a collector made in the form of a metal tube plugged at one end, made of a material with a small cross-section for interaction with neutrons, in which an emitter is placed, made in the form of an elongated electrically conductive cylinder made of a material with a high cross-section for interaction with neutrons , a cylindrical insulating element located between the emitter and the collector, a two-core cable, one core of which is a signal and is connected to the emitter, the other is a background one, the metal sheath of the cable is hermetically connected around the perimeter to the metal tube of the collector, and a sealed lead-in installed at the end of the cable, having electrical leads , connected to the signal and background cores (RF patent No. 2138833 C1, G01T3/00, 02/08/1999).

The disadvantage of the known direct-charge neutron detector is that it is not very ergonomic and does not have high measurement accuracy due to the difference in series resistance of the signal and background wires of the cable.

The closest in technical essence and the achieved technical result is a direct charge neutron detector containing a collector made in the form of a thin-walled metal tube, plugged at one end, made of a material with a small cross section for interaction with neutrons, in which an emitter made in the form of an elongated electrically conductive cylinder is placed , made of a material with a high cross section for interaction with neutrons, a cylindrical insulating element located between the emitter and the collector, a two-core cable, one core of which is a signal and is connected to the emitter, the other is a background one, the metal sheath of the cable is hermetically connected around the perimeter to the metal tube of the collector, a sealed lead-in installed at the end of the cable, having electrical leads connected to the signal and background conductors (RF patent No. 143784 U1, G01T3/00, 12/25/2013).

The disadvantages of the known direct-charge neutron detector are insufficiently high ergonomics and low measurement accuracy due to possible contact of the signal and background wires of the cable when the insulator spills out of the cable, as well as the displacement of the position of the emitter from the central axis due to the lack of centering of the signal wire of the cable.

The technical result of the utility model is to increase the ergonomics, reliability and accuracy of measurements.

The specified technical result is achieved by the fact that a direct charge neutron detector containing a collector made of a material with a small cross section for interaction with neutrons, made in the form of a hollow metal cylinder plugged at one end, in which an emitter is placed, made in the form of an electrically conductive rod made of the material with a high cross section for interaction with neutrons, an insulating element in the form of a capillary tube, plugged on one side, with walls located between the collector and the emitter, a twisted cable with mineral insulation, the current-carrying core of which is connected to the emitter, and the second is isolated from the rest of the detector parts (background ), a metal shell is hermetically connected along the perimeter to the collector, an insulating cylindrical sleeve placed at one end into the cable shell, the other into the unplugged end of the insulating element, centering the signal core of the cable with the emitter attached to it and preventing the mineral insulation of the cable from escaping into the internal volume between the emitter and an insulator, and a sealed lead-in installed at the end of the cable, which has a centering and insulation unit, excluding the possibility of contact of non-insulated parts of the cable cores with each other, as well as with the cable sheath, preventing the mineral insulation of the cable from escaping into the internal volume of the sealed lead-in, and electrical terminals connected to the signal and background conductors of the detector, the sealed lead-in is made in the form of a block, the outer sleeve of which is hermetically connected along the perimeter to the cable sheath, while the electrical outlet fixed along the internal electrical insulating sleeve is made in the form of a metal tube through which the current-carrying core of the cable passes, hermetically connected to the end of this tube.

It is advisable that the inner diameter of the insulating cylindrical sleeve differs from the outer diameter of the cable core by an amount less than the grain size of the mineral insulation of the cable and prevents the mineral insulation of the cable from escaping into the internal volume of the collector; the insulating element can be made in the form of an unplugged capillary tube; it is allowed that the rod is made in the form of a piece of wire made primarily of rhodium, vanadium, or silver, or cobalt, with a maximum wire diameter of no more than 1.6 mm, the electrical resistance of the signal and background wires of the cable differs by less than 3%, the sealed lead-in may have one electrical conclusion, the internal cavity of the detector is dehydrated and filled with inert gas, it is advisable that the internal cavity of the detector is filled with helium.

The claimed design of the neutron sensor improves its ergonomics by increasing signal reliability and measurement accuracy by centering the position of the signal core, eliminating contact of the emitter, due to its thermal expansion, with the collector through the use of a plugged insulating element and eliminating short circuits of the background and signal wires between itself and onto the cable sheath.

The analysis of the level of technology showed that the claimed set of essential features set out in the formula of the utility model is unknown. This allows us to conclude that it meets the “novelty” criterion.

The essence of the utility model is illustrated by a drawing, a description of the design and an example of practical implementation.

In fig. Figure 1 shows a longitudinal section of the detector.

The neutron detector (Fig. 1) includes an emitter 1, made in the form of a rod made of rhodium, vanadium, or silver; insulating element 2, made in the form of a capillary tube, plugged on one side; collector 3, made in the form of a metal tube with a plug 14 at one end, made of stainless steel alloyed with nickel, chromium and titanium, for example 08Х18Н10Т, or an alloy of the ХН78Т type (Inconel); two-core cable 4 with a sheath 5, mineral insulation 6 and two conductors: a signal 7, connected to the emitter 1, and a background 8. The background conductor 8 is an element for controlling the background current, located along the signal conductor and isolated from it. An insulating cylindrical sleeve 12, placed with one end in the cable and the other in the unplugged end of the insulating element, centers the signal 7 core of the cable and the emitter 1 relative to the insulating element 2. The sealed lead-in 9 contains an electrical insulating sleeve 16 and the electrical terminals of the signal 10 and background 11 wires passing through it. , while pin 10 of the signal wire is longer than pin 11 of the background wire. Inside the housing of the sealed lead-in 9 there is a centering and insulation unit 15, which eliminates the possibility of contact of non-insulated parts of the cable cores with each other, as well as with the cable sheath, preventing the mineral insulation of the cable from spilling into the internal volume of the sealed lead-in, electrical terminals 10 and 11, connected to the signal and background conductors via connecting conductors 13 passing through the cavities of the leads and hermetically connected to the ends of the leads 14, and an electrical insulating sleeve 16.

Example of practical implementation

Currently, direct charge neutron detectors are manufactured according to ShPIS.418240.001 TU, having an emitter with a diameter of 0.5 mm, or 0.8 mm, or 1.0 mm made of the material: rhodium, or silver, or vanadium with a plugged or unplugged insulating element made of material: quartz, or ceramics, or high-purity magnesium oxide and a collector made of a metal tube, the material of which is stainless steel grade 08Х18Н10Т, or alloy type ХН78Т (Inconel), the communication line from the emitter is made of a two-core cable with a sheath of stainless steel grade 08Х18Н10Т , or alloy type XN78T (Inconel) and insulating material: magnesium oxide or aluminum oxide with twisted conductors (twisting), a sealed lead-in is installed at the end of the cable, having current leads connected to the cable conductors, while the internal cavities of the collector, cable and sealed lead-in are dehydrated and filled inert gas - helium.

Based on the above, we can conclude that the claimed direct charge neutron detector can be implemented in practice with the achievement of the stated technical result, i.e. they meet the criterion of “industrial applicability”.

Claims (8)

1. A direct charge radiation detector containing a collector made of a material with a small cross section for interaction with neutrons, made in the form of a hollow metal cylinder plugged at one end, which houses an emitter made in the form of an electrically conductive rod made of a material with a high cross section for interaction with neutrons, an insulating element in the form of a capillary tube, plugged on one side, with walls located between the collector and the emitter, a twisted cable with mineral insulation, the current-carrying core of which is connected to the emitter, and the second is isolated from the rest of the detector parts (background), the metal shell is hermetically sealed connected along the perimeter to the collector, an insulating cylindrical sleeve placed with one end inside the cable sheath, the other - in the unplugged end of the insulating element, centering the signal core of the cable with the emitter attached to it and preventing the mineral insulation of the cable from escaping into the internal volume between the emitter and the insulator, and installed at the end of the cable there is a sealed lead-in, which has a centering and insulation unit, eliminating the possibility of contact of non-insulated parts of the cable cores with each other, as well as with the cable sheath, preventing the mineral insulation of the cable from escaping into the internal volume of the sealed lead-in, and electrical leads connected to the signal and background conductors of the detector, sealed lead-in made in the form of a block, the outer sleeve of which is hermetically connected along the perimeter to the cable sheath, while the electrical leads fixed along the internal electrical insulating sleeve are made in the form of metal tubes through which the current-carrying conductors of the cable pass, hermetically and electrically connected to the end of this tube. 2. The detector according to claim 1, characterized in that the inner diameter of the insulating cylindrical sleeve differs from the outer diameter of the cable core by an amount less than the grain size of the mineral insulation of the cable, and prevents the mineral insulation of the cable from escaping into the internal volume of the collector. 3. The detector according to claim 1, characterized in that the insulating element can be made in the form of an uncapped capillary tube. 4. The detector according to claim 1, characterized in that the rod is made in the form of a piece of wire made primarily of rhodium, vanadium, or silver, or cobalt, or hafnium, with a maximum wire diameter of no more than 1.6 mm. 5. The detector according to claim 1, characterized in that the electrical resistance of the signal and background wires of the cable differ by less than 3%. 6. The detector according to claim 1, characterized in that the sealed lead-in may have one electrical outlet. 7. The detector according to claim 1, characterized in that the internal cavity of the detector is dehydrated and filled with an inert gas. 8. The detector according to claim 7, characterized in that the internal cavity of the detector is filled with helium.