SU1254847A1 - Photometer for measuring transparency of materials - Google Patents

Abstract

A PHOTOMETER FOR MEASURING THE TRANSPARENCY OF MATERIALS containing a main fiber in which a light source is placed, two photodetectors mounted on its ends and connected to recording units, characterized in that, in order to improve the measurement accuracy by taking into account radio luminescence, registration of a radioluminescent, the input connected to the main fiber at the location of the side surface of the sample, and the output to the photodetector connected to the registration units.

Description

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The invention relates to the field of optical instrumentation and can be used to measure the transparency of materials under the influence of pulsed ionizing radiation.

The aim of the invention is to improve the accuracy of measurement by. taking into account radioluminescence when exposed to ionizing radiation.

The drawing shows a structural diagram of one of the variants of the photometer.

The photometer consists of a pulsed light source 1 placed inside the main LED 2, in which mirrors 3 and 4 and the sample 5 are also placed.

At the location of the side surface of sample 5, an additional optical fiber 6 is connected to the main light-emitting diode 2. Photo detectors 7–9 with wedge-shaped compensators 10–12 are connected to the ends of optical fibers 2 and 6. Photodetectors 7-9 are connected to recording units, in this case consisting of a differential amplifier 13 and an oscilloscope 14 with a differential input. The part of the device where the simulated sample 5 is placed is located behind the biological protection 15 in the zone of pulsed ionizing radiation emitted by the source 16.

The device works as follows.

Light from a pulsed light source 1, synchronized with an ionizing radiation source 16, and to the light guide 2, through the mirror 3, hits the sample 5 and, having passed it, with

using mirror 4, it is directed to the photodetector 7. The sample 5’s radioluminescence, which is caused by the sample 5 being irradiated by ionizing radiation from the source 16, enters here. The additional photodetector 9 through the light guide 6 hits only the sample 5 radio-luminescence light, and the photodetector 8 - the light from source 1 The difference in the transmittance of the optical fibers 2 and 6 and the sensitivity of the photodetectors 7-9 is compensated by wedge compensators 10-1 (when calibrating the photometer), Next. signals from photodetectors 7–9 are fed to recording units — an amplifier 13 and an oscilloscope 14; The signal from the photoreceiver 8 is subtracted from the signal of the photoreceiver 7 using a differential amplifier 13 and fed to one of the differential inputs of the oscilloscope 14, to the second input of which the signal of the photodetector 9 is fed. The measurement accuracy in the proposed photometer is increased by directly taking into account the radio luminescence of the sample 5 when simultaneously irradiating it from source 1 and 16. This eliminates errors caused by the accumulation of defects in materials and the mismatch of the conditions of irradiation from impulse to impulse. Su. Compared to the prototype, the time taken to measure the transparency of materials is also reduced by at least 2 times. The proposed photometer makes it possible to increase the accuracy of transparency measurements by 20–25% and can be used in radiation and radioluminescence studies.