CS196421B2 - Radiation ionization detector of the electrone capture for the gas chromatography - Google Patents

Description

. The invention relates to a radiation ionization electron capture detector for gas chromatography usable for the delegation of gases and vapors of eiektronegative compounds.

A known radiation ionization electron capture detector, also called a beta ionization detector, is provided with two electrodes disposed in an insulator, one of which contains a radioactive source emitting radiation ionizing gas, while the other is a collecting electrode. The radioactive sources used, made from eritium-scandium-bound tritium and nickel-63 preparations, can operate at temperatures of 350 and 400 ° C. Electrode insulators made of porcelain are provided with an additional seal between the porcelain and the material from which the detector is made. Instead, insulators made of Teflon can operate at a temperature not exceeding 150 ° C because they lose mechanical properties at elevated temperatures. In addition, detectors with insulators made of Teflon are designed such that the Teflon Insulating Electrode is located behind the detector heating surface in a special head provided with thermal bodies that lower the temperature of the Teflon during operation of the detector. Such a design causes a high detector volume, which results in an increase in the detector time constant affecting the detection of its operation. In addition, the temperature in the upper part of the detector body, lowered by the heat bodies, causes condensation of the test sample components on the inner surface of said upper part, thereby reducing the insulating property of the Teflon. These constructions are known from Polish Patent Nos. 64,383 and 74,815.

An essential feature of the invention is that the electron capture detector comprises a base shell in which a cylindrical radioactive specimen is mounted by means of a nut and a collecting electrode is coaxially disposed within said radioactive specimen cylinder. The collecting electrode is mounted in a ceramic insulator provided with a sleeve fastened by means of a set of parts connected by a base shell screw between the base shell part and the sleeve. The clamping sleeve is additionally connected by brazing a. In the clamping device of the front part of the base container and the sleeve is a seal whose sealing part is the clamping sleeve material formed by the pressure of the cylindrical clamping part.

The described construction due to the use of a ceramic insulator of the collecting electrode coupled to the collet by means of a brazing solder allows the detector to operate at temperatures up to 400 ° C.

Placing the collector electrode near the active area of the detector included in the volume of the radiation source cylinder allows the detector to be compactly designed, reducing its volume, thereby improving its detection properties. An advantage of the detector according to the invention is also its simplified shape requiring lower costs compared to known detector designs.

The invention will now be described in more detail with reference to the accompanying drawing showing a cross-section of an exemplary embodiment of an electron capture type detector according to the invention.

The detector according to the invention comprises a base casing 1 in which a cylindrical radioactive source 2 is fixed by means of a nut 3, while a coaxial collecting electrode 4 is provided inside the radioactive source cylinder 4, provided with a ceramic insulator 5. The ceramic insulator S is provided The front sleeve part 6 is connected to the ceramic insulator 5 by brazing.

In the clamping device of the base container part 1 with the washer 7 there is a clamping seal, the sealing part of which is the material of the clamping sleeve 6 shaped by the pressure of the cylindrical clamping part 8.

The base housing 1 of the detector is provided with an input 4j.

and the outlet connector tube 10 for the test gases.

Before the detector according to the invention is activated, its inlet connector tube 9 is connected to the outlet of the chromatography column and the connector 11 is connected to a power source and a measuring unit. Gases flowing from the chromatographic column are ionized beta particles transmitted by a radioactive source, resulting in that the ionized current flows between the collecting electrode and ^r radioactive source. When constant temperature conditions are reached at the detector and on the chromatography column, a sample of the gas or liquid to be analyzed is fed to the column. The chromatographic column divides the sample into individual components carried by the carrier gas stream into the interior of the detector base 1.

If the supported component exhibits negative properties (electronegativity), then negative ions are formed inside the ionized gas which, by recombination with the positive ions of the carrier gas, reduce the ionization current value of the detector.

On the basis of changes in the ionization current value of the detector, the concentration and type of the component of the examined sample are evaluated.

Detector equipped with ⁶³ µl activity · 20 mCi source or 400 mCi activity tritium source with detectable ^10-13 and ^10-14 against CCU.

Claims (1)

BEFORE A radiation ionization gas-electron capture detector comprising a base shell in which a cylindrical radioactive source is mounted by means of a nut, a collecting electrode is coaxially positioned within the radioactive source cylinder, characterized in that the collecting electrode (4) is located in a ceramic insulator (5) provided with a set of rings (6) mounted between the front face portion of the ynAlez base sleeve (1j and the sleeve (7) by means of a cylindrical clamping piece (8) connected by a screw to the base sleeve (1j); a ceramic insulator (5) by means of brazing solder and in the clamping device part of the front cover (1) with said washer (7j being a clamping seal from which the ring set material (6) is shaped by the pressure of the cylindrical clamping piece (8j).