RU188749U1 - MOUNTING FRAME FOR ENSURING INSTALLATION, VERIFICATION, TESTING OF RADIO INSULATED TABLE DEPTH - Google Patents

Abstract

The invention relates to the field of verification and testing of radiation density monitoring devices. The essence of the utility model is that the mounting frame for installation, verification, testing of the radioisotope densitometer on the pipeline further comprises a collimation device fixedly mounted on the chassis mounted on the platform of the detecting unit, the screen of the safe area, the radiation correction device of the exposure dose rate -radiation, installed on the platform of the gamma source block, shock absorbers under the base frame installation. The technical result is the expansion of the operational characteristics of the mounting frame. 4 hp f-ly, 4 ill.

Description

The mounting frame for the installation, verification, testing of the radioisotope densitometer on the pipeline refers to the structural elements of the devices necessary for the reliable and safe operation of density radiation monitoring devices in various industries.

The installation bracket for installing the LB444 densitometer from Berthold Technologies GmbH & Co KG '' L1] is known. The density meter is registered in the State Register number 20387-00a. The bracket is rigidly connected to the pipeline - the influence of pipeline vibration on the density meter. There is no possibility to quickly test the density meter without removing it from the pipeline.

A device for controlling the density and the mass fraction of the liquid phase of the slurries in pipelines [L2]. Biological protection has a turning segment and a through hole in which a half-pipe is placed with clamps at the ends, for fastening on a controlled pipeline. The device allows you to simplify the process of installing the sensors in the working and calibration position. The installation of sensors on the carriage, made with the possibility of reciprocating movement perpendicular to the pipeline, along the frame allows you to quickly move the sensors from the monitored pipeline to the calibration position. The device is multifunctional, complex, just as tightly connected to the controlled pipeline.

The closest to the technical essence of the prototype, utility model, is a calibration stand with simulator-holder of density measures [L3].

Calibration stand with simulator-holder of density measures [L3] was implemented by Soyuztsvetmetavtomatika JSC as a mounting frame and plate-simulators of a controlled medium for radioisotope density meters [L4]. The mounting frame and plate-simulators are used to work complete with radioisotope density meters RP-24, RP-25 (with the density measurement program RRP-3P) and their modifications and sources of ionizing radiation Cesium-137 (block gamma source BGI-A) and Sodium-22 (Protective screen).

Mounting frames of this type are designed to provide installation, verification, testing of radioisotope densitometer on the pipeline and are used as structural elements of radioisotope process control devices. Known mounting frames provide a certain degree of technological parameters necessary for the operation of technological control devices.

The technical result of the proposed utility model is to expand the operating characteristics of the mounting frame: adjustment of the measurement base; protection of a part of the crystal detection unit, in order to reduce the impact on the measurement result of radiation background oscillations; limiting the area of the working radiation beam in order to reduce the degree of radiation hazard; ensuring accurate correction of the exposure dose rate of gamma radiation.

The achievement of this result is ensured by the fact that in the utility model [L3] an assembly frame containing an installation bed; rotary shaft with a rotation angle of 90 ° on the axis of rotation in the bed installation; platform for installation of the detection unit and platform for installation of the gamma source unit rigidly mounted on the rotary shaft; locking the working position of the shaft with platforms for the passage of the ionizing radiation beam through a controlled pipeline; check shaft position lock with platforms for passing the ionizing radiation beam through the density plates simulators located in the site for mounting the plate simulators fixed to the installation bed safety zone limit screen; radiation correction device installed on the platform of the gamma source unit; shock absorbers under the bed installation.

Chassis with a collimation device installed with the possibility of reciprocating motion on the platform perpendicular to the pipeline.

The configuration and geometrical dimensions of a collimation device are determined by the design of the detection unit and the requirements of radiation safety.

The screen of the safe zone is designed to be installed on both platforms and reciprocating movement on the platform perpendicular to the pipeline, and the screen configuration must match the profile of the pipeline being monitored.

The radiation correction device is made in the form of a wedge-shaped ionizing radiation absorber with the possibility of controlling and fixing the position relative to the ionizing radiation beam.

The essence of the utility model is illustrated in FIG. 1-4.

FIG. 1 shows the installation frame device: 1 - installation frame; 2 - platform for installation of the gamma source unit; 3 - locking wedge absorber; 4 - device for the correction of radiation exposure dose rate of gamma radiation; 5 - site for the installation of plates-simulators; 6 - density plate simulators; 7 - pipeline area; 8 - swivel shaft; 9 - collimation device; 10 - safeguard stop screen; 11 - platform for installation of the detection unit; 12 - chassis with a collimation device; 13 - locking calibration position of the mounting frame; 14 - locking the working position of the mounting frame; 15 - shock absorber; 16 - the axis of rotation of the rotary shaft; 17 - wedge-shaped ionizing radiation absorber.

FIG. 2 shows the working position of the mounting frame: 18 - BGI-block of gamma source Cesium-137; 19 - controlled pipeline; 20 - DB-unit for detecting radioisotope density meter; 14 - locking the working position of the mounting frame.

FIG. 3 shows the verification position of the mounting frame: 6 - a set of density simulator plates; 18 - BGI-block of gamma source Cesium-137; 19 - controlled pipeline; 20 - DB-unit for detecting radioisotope density meter; 13 - locking calibration position of the mounting frame.

FIG. 4 shows the working position of the mounting frame when working with the Sodium-22 source: 10 — screen-guard of the safe zone; 21 - source container Sodium-22; 22 - source Sodium-22; 19 - controlled pipeline; 20 - DB-unit for detecting radioisotope density meter; 14 - locking the working position of the mounting frame.

Consider working with the mounting frame in the composition of the radioisotope density meter and the source of ionizing radiation. The mounting frame is installed at a controlled technological point with a rigid attachment relative to the object being monitored. The mounting frame has no mechanical contact with the pipeline, which reduces the effect of vibration. If necessary, the installation bed 1 is installed on the shock absorbers 15. The detecting unit 20 and the gamma source unit 18 are installed on the respective platforms 11 and 2. The position of the chassis 12 with the collimation device 9 and the detecting unit 20 installed in it is determined by the diameter of the tested pipeline 19. The collimation device 9 ensures the attenuation of the ambient dose equivalent power level on the external contour of the detecting unit 20, reduces the effect on the measurement result of the fluctuations of radiation she is. The limiting screens of the safe zone 10 form an accessibility zone to the detection unit 20 and the container 21 with a Sodium-22 source in order to ensure radiation safety standards.

FIG. 2 shows the working position of the frame assembly when working with a source of Cesium-137. When working with the BGI block of gamma source 18, a radiation correction device 4 is installed on platform 2 for precise correction of gamma radiation dose, which is provided by mechanical advancement of the wedge-shaped ionizing radiation absorber 17 along the BGI collimation channel axis. Thus, compensation of changes in the radiation dose rate is carried out at: the product of the closing-opening of the shutter of the BGI unit; pipeline overgrowing and abrasion during density meter operation; adjusting the calibration curve of the density meter.

FIG. 4 shows the working position of the mounting frame when working with the Sodium-22 source. The screen-limiter 10 is shifted to the contour of the controlled pipeline 19, in this configuration, direct access to the radiation beam area is excluded, thus the requirement of sanitary norms on dose rate from any available surface point of radioisotope devices is fulfilled.

FIG. 3 shows the verification position of the mounting frame. The rotary shaft 8 and the mounting platforms 2 and 11 are rotated 90 ° along the axis of rotation 16 of the shaft with platforms, secured with a lock of the calibration position 13. In this position in the area of the gamma radiation beam is a set of density simulator plates 6. The density simulator plates 6 are intended to play a controlled environment and are used when checking and monitoring the performance of density meters. Verification of densitometers is carried out according to the method of verification, agreed in the prescribed manner.

The mounting frame proposed as a useful model makes it possible to determine the time constant, calibrate and test density meters directly at the process point without dismantling, in accordance with the calibration procedure approved in the prescribed manner. The introduced structural elements will ensure: the formation of the measurement base, in accordance with the diameter of the pipeline being monitored; exclude the possibility of direct access to the radiation beam area, thus meeting the additional requirements of the radiation safety standards; the possibility of providing precision correction of the exposure dose rate of gamma radiation; reducing the impact on the measurement result of fluctuations of radiation background

Literature

1. "density meter LB444", "Berthold Technologies GmbH & Co KG. Http://rip74.ru/d/374661/d/lb444-rus.pdf

2. Patent of the Russian Federation No. 2082152, G01N 9/24, publication of 06/20/1997.

3. Patent for utility model No. 75756, registered on 20.08.2008.

4. The mounting frame and plate-simulators controlled environment for radioisotope density meters. Moscow, Soyuztsvetmetavtomatika JSC, http://www.scma.ru/ru/ru/products/2-14.html

Claims (9)

1. Mounting frame to provide installation, verification, testing of radioisotope densitometer on the pipeline, containing the installation frame; rotary shaft with a rotation angle of 90 ° on the axis of rotation in the bed installation; platform for installation of the detection unit and platform for installation of the gamma source unit, rigidly mounted on the rotary shaft; locking the working position of the shaft with platforms for the passage of the ionizing radiation beam through a controlled pipeline; the lock of the calibration position of the shaft with platforms for the passage of the ionizing radiation beam through the plates-density simulators, located in the assembly for the installation of the plates-simulators, fixed on the bed of the installation, characterized in that added: - a collimation device fixedly mounted on the chassis mounted on the platform of the detecting unit; - safeguard screen; - a device for correcting radiation of the gamma radiation exposure dose rate installed on the platform of the gamma source unit; - shock absorbers under the bed installation. 2. The mounting frame according to claim. 1, characterized in that the chassis with a collimation device is installed with the possibility of reciprocating movement along the platform perpendicular to the pipeline. 3. The mounting frame according to claim 2, characterized in that the configuration and geometrical dimensions of the collimation device are determined by the design of the detecting unit and the requirements of radiation safety. 4. The mounting frame according to claim 1, characterized in that the screen-limiter of the safe zone is made with the possibility of installation on both platforms and the possibility of reciprocating movement along the platform perpendicular to the pipeline, and the configuration of the screen must correspond to the profile of the pipeline being monitored. 5. The mounting frame according to claim 1, characterized in that the radiation correction device is made in the form of a wedge-shaped ionizing radiation absorber with the ability to control and fix its position relative to the ionizing radiation beam.

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