RU2142644C1 - Method for detection of ionizing radiation source in mobile object - Google Patents

Abstract

FIELD: radiation monitoring on state and customs checkpoints. SUBSTANCE: radiation is measured, while mobile object passes checkpoint region, by means of detection units, which are arranged along and above monitored region on both sides of mobile object. Said method involves detection of duration starting from appearance of mobile object in monitored region till detection of ionizing radiation source (Tn), till end of ionizing radiation source detection (Te), till moment, when object leaves monitored region (Tin), calculation of sum of samples for all detection units (∑ Si), for detection units which are located in upper part of monitored region

, for detection units, which are located on one side of mobile object

. Then method involves calculation of equations

Description

 The invention relates to radiation technology and can be used in radiation monitoring at checkpoints, customs control to detect sources of ionizing radiation (III). In particular, the invention can be used to control the unauthorized movement of III, for example, uranium-235, plutonium-239, by road and rail.

 A known method of controlling the unauthorized movement of a small amount of fissile and other radioactive materials using a radiation monitor containing detecting modules, and the processing of information and the operation of the functional blocks is carried out by a microprocessor [1]. The specified method does not allow to determine the probable location of ionizing radiation sources in a moving object. To determine the location of the III, an additional examination of the object is necessary, which requires time and special radiation equipment.

 The closest technical solution of the present invention is a method for detecting a source of ionizing radiation in a moving object, which consists in measuring the background radiation in the controlled zone by detection modules, generating a threshold value, measuring radiation when there is a moving object in the controlled zone, comparing it with a threshold value, detecting III in case of exceeding the threshold value [2].

 However, this method does not allow to determine the probable location of the ionizing radiation source in a moving object, which is its drawback.

 The invention is aimed at solving the problem of determining the likely location of III in a moving object.

, от детектирующих модулей, расположенных с одной из сторон движущегося объекта,

, вычисляют отношения

по значениям которых судят о вероятном расположении ИИИ в объекте по высоте (H), по ширине (LR), по длине (FB). Например, при значении отношения больше 2/3 определяют ИИИ в верхней левой задней трети объекта, менее 1/3 - в нижней правой передней трети объекта, в интервале 1/3 - 2/3 - в средней трети движущегося объекта.The essence of the invention lies in the fact that in a method for detecting a source of ionizing radiation in a moving object, which consists in measuring the background radiation in the controlled area by the detecting modules, generating a threshold value, measuring radiation when there is a moving object in the controlled area, comparing it with a threshold value, detecting detection III in case of exceeding the threshold value, measure the ionizing radiation by detecting modules sequentially distributed along the length and height of the cont of the controlled area on both sides of the moving object, the time is recorded from the moment the moving object appears in the controlled area until the detection of III (Tn) until the detection of III (Te) ceases until the object leaves the controlled zone (Tin), the account amount from III from all detecting modules (∑ Si), from detecting modules located in the upper part of the controlled zone,

, from detecting modules located on one of the sides of a moving object,

calculate relationships

the values of which judge the likely location of III in the object by height (H), by width (LR), by length (FB). For example, if the ratio value is more than 2/3, the III is determined in the upper left rear third of the object, less than 1/3 in the lower right front third of the object, in the interval 1/3 - 2/3 in the middle third of the moving object.

 The method can be implemented, for example, using a portal monitor. A diagram of one of the variants of the portal radiation transport monitor designed to control the presence of special nuclear materials and alarms in case of their detection is presented in the drawing. The radiation monitor consists of two measuring columns 1, an electronics unit 2 with a microprocessor and a remote control 3 with nine LEDs illuminating the stylized image of the car (mimic diagram) and indicating the probable location of the detected III in a moving object in height (above, in the middle, from below), along the length of the car (front, middle, rear), on the sides (left side, center, right side). In each measuring column in the upper and lower parts there are detecting modules (photon and neutron radiation meters). In the absence of a moving object, the monitor automatically monitors the change in background and the formation of a threshold value. From the moment a moving object appears in the controlled area, background tracking stops and the measurement process begins as described above. In case of detecting an III in a moving object, a sound signal is automatically generated, the message "Detection" appears on the operator panel of the LED backlight and a likely location of the III in a moving object is displayed on the mimic diagram.

 Using a barium-133 source - 200 kBq (equivalent to 3.3 g of plutonium-239), the vehicle was driven through a stationary radiation monitor at an average speed of 6 km / h at a distance of 1.5 - 2 m from the measuring column at various locations of these sources inside a car. The table shows the results of experimental verification of the above method with a quantitative measurement of all necessary data.

 The table shows that according to the experimentally measured data, the calculated values of H, LR, FB, which are used to judge the location of the III in the vehicle, are in good agreement with the coordinates of the real location of the III.

 Verification of the determination of the probable location of sources inside the car showed that the readings on the mimic diagram of the stationary radiation monitor correspond to the location of these sources in the car.

 Thus, the implementation of the invention allows to identify and determine the likely location of the sources of ionizing radiation in a moving object.

Sources of information:
1. Kositsyn V.F., Shumakov A.V. Improving the reliability of control of unauthorized movement of a small amount of fissile and other radioactive materials. “Atomic Energy,” vol. 75, no. 2, August 1993, p. 103.

 2. RF patent N 2094821, G 01 T 1/167, priority from 09/07/94 (prototype).

Claims (1)

A method for identifying a source of ionizing radiation (III) in a moving object, which consists in measuring the background radiation in the controlled zone with detection modules, generating a threshold value, measuring radiation when there is a moving object in the controlled zone, comparing it with a threshold value, registering detecting III in case the threshold is exceeded values, fixing the total amount from all detecting modules (∑ Si), characterized in that the ionizing radiation is measured by detecting modules, followed by tionary distributed along the length and height of the controlled area on both sides of a moving object from the fixed amount of the bill detection modules arranged on top of the controlled area

, from detecting modules located in one of the sides of a moving object

, measure the time from the moment a moving object appears in the controlled area until the start of detection of III (Tn), until the stop of detection of III (Te), until the object leaves the controlled zone (Tin), calculate the ratio

the values of which judge the likely location of III in a moving object by height (N), by width (LR), by length (FB).

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