SU756330A1 - Device for signalling ionizing radiation level - Google Patents

Description

<p> 756330A1_1-2.png "style =" width: 94pt; height: 20pt; "/> <p> 1 </ p> <p> The device relates to the field of ionizing radiation measurement, in particular, to individual dosimetry monitoring devices. </ p> <p> Conducting individual dosimetry monitoring is a prerequisite for working with ionizing radiation. For this purpose, small-sized dosimeters-signaling devices are used, which, in the presence of ionizing radiation, are signaled with sound or light signals with a frequency proportional to the level of ionizing radiation. </ P> <p> Known dosimeters-signaling devices contain a detector, a shaper, and a signaling device {1]. The signals from the detector are sent to the driver, which converts them into pulses with a duration convenient for perception by the service personnel. The generated pulses go to the detector. 25 </ p> <p> The maximum level of ionizing radiation, which can be assessed using well-known dosimeters, is determined by the maximum frequency of the signals, which </ p> <p> 2 </ p> <p> can be counted by ear or visually by service personnel. </ p> <p> Known dosimeters-signaling devices do not allow to estimate the dose. </ p> <p> Closest to the proposed signaling device is a dosimeter-signaling device containing a series-connected detector, driver, and signaling device [2]. The known dosimeter-signaling device allows to estimate the level of ionizing radiation by the frequency of signals. </ P> <p> However, the maximum level of ionizing radiation, which can be estimated using a known device, is negligible due to limitations due to the insignificant zelichina of the maximum frequency of the signals, above which such an assessment is visual and audible. This circumstance does not allow using the device at all necessary (permissible for human stay} intensity range of ionizing radiation. In addition, when working with ionizing radiation, it is necessary to know the dose received by the operating personnel. The known device does not comply with 756330 </ p> <p> evolves to make an estimate of the dose. These drawbacks limit the use of dosimeters-signaling devices. </ P> <p> Thus, the known device has the following main disadvantages: a small dynamic display range and the inability to estimate the dose of ionizing radiation. </ p> <p> The purpose of this device is to increase the display range of the -level while simultaneously estimating the dose of ionizing radiation. </ p> <p> This goal is achieved by inserting recalculation, control, and power supply devices to the device, the input of the recalculation unit being connected to the detector, and the output to the input of the control unit, the output of which is connected to the signaling device through the node. < / p> <p> The block diagram of the described device for signaling the level of ionizing radiation is shown in the drawing. </ p> <p> The device contains detector 1, driver 2, alarm 3,. </ p> <p> Recalculation node 4, control node 5, a signaling device supply node. </ p> <p> The device’s operation is as follows. </ p> <p> The pulses from detector 1 are fed to the imaging unit 2 and to the conversion unit 4. The pulses generated by the duration and amplitude of the output of the former 2 are fed to the signaling device 3. The conversion unit 4 has a conversion factor Ν. At the output of the conversion unit, after receipt of each m / 2 pulses, alternating voltages of a logical zero and a logical unit occur, by means of which the node 5 controls the operation of the node. </ P> <p> 6 power signaling device. If there is a logical unit at the output of the voltage recalculation node, the control node generates a voltage at the output of the signaling device supply node and the voltage applied to the alarm device. <p> If a logic zero voltage appears at the output of the recalculation node, then the voltage applied to the alarm 3 changes to K. times. </ p> <p> As a result, the power dissipated by the signaling device changes in K <sup> r </ sup> times, and, consequently, the strength of the sound or the brightness of the signal element changes. Both series, containing the And / Ί pulses, it is easy to distinguish by the strength of the sound or the brightness of the glow. </ P> <p> By determining the duration of the T series using a stopwatch, you can determine the frequency of the signals π in N / 1Ύ and, knowing the sensitivity of the detector,. You can find the dose rate of ionizing radiation. The frequency of arrival of the series is much less than the frequency </ p> <p> the arrival of signals from detector 1 and depends on the magnitude of the conversion factor N of the conversion node. The larger the Ν value, the higher the frequency of the signals can be counted by the service personnel and, </ p> <p> 5 therefore, the wider the range of indication of ionizing radiation. </ p> <p> For example, if you take the value of Ν equal to 1000 for a large load, considering not the individual signals, but the number of batches containing 1000 signals each, you can determine the maximum level of ionizing radiation corresponding to the repetition rate of batches up to 2 Hz. </ p > <p> 15 Therefore, the maximum frequency of the signals that can be determined using this device is η = 2000 pulses / s, i.e. The range of indication of the level of ionizing radiation is increased by three decimal orders. The value of K can be selected based on the convenience of perception of each series of signals, for example, you can put </ p> <p> <a name="caption1"> </a> 25 <sup> to </ sup> ~ <sup> 2 < / sup> · </ p> <p> The set of N pulses corresponds; a certain dose, which is also determined by the sensitivity of detector 1 and the coefficient of recalculation of node 4 of recalculation. Considering the number of batches (and not individual pulses, as in a known device), it is possible to determine the dialed dose. </ p> <p> In some cases, it may be more convenient to end each series only with one signal, different from the rest in terms of volume or brightness. For this purpose, the proposed device between the conversion unit and the control unit can be '</ p> <p> 40 make the second driver, input </ p> <p> which is connected to the output of the conversion unit, and the output to the inputs of the detector 3 and the control node, forming at the end of each series </ p> <p> 45 signals pulse of greater duration than the other pulses, series. The specified pulse through the control node and the power node of the detector controls the duration and </ p> <p> __ The intensity of the signal supplied by the signaling device 3. As a result, the signal indicating the end of each series of pulses can be easily distinguished from all other signals of the series, and therefore it is possible <p> 55 to determine the level and dose of ionizing radiation. . </ p> <p> The proposed device makes it possible not only to increase the indication range of the level of ionizing radiation 1000 times, but also to determine the dose of ionizing radiation. Both of these factors are important for estimating the radial stop, for example, for determining the time for the operator to continue working </ p> <p> 5 </ p> <p> 756330 </ p> <p> 6 </ p> <p> (location. A more precise definition of the residence time allows for improved work planning, increases safety, has a positive psychological effect, which increases productivity. </ p>

Claims (1)

Claim A device for signaling the level of ionizing radiation, containing a series-connected detector, driver, and a signaling device, characterized in that, in order to increase the range of the level indication while simultaneously estimating the dose of ionizing · radiation, nodes are entered into it counting, control and power supply of the alarm device, the input of the node is recalculated to the detector, and the output to the input of the control unit, the output of which is connected to the alarm device through the power supply node of the alarm device. ten