SU854141A1 - Radioisotope device - Google Patents

Abstract

RADIPIZOTOPNIP PRIGOR, containing a source of ionizing radiation, a detecting unit, a differential average frequency meter connected to a source of reference signal, characterized in that, in order to improve the measurement accuracy, by measuring the dynamic component, the first measurement error is entered into it the average frequency of direct radiation, a controlled pulse generator and a device for summing pulsed streams, with the output of the detecting unit connected to the input of the average frequency meter radiation, the input of which is connected to the in-year. controlled oscillator and pulses, the output of the controlled pulse generator is connected to one input of the pulse flow summer, the second input of which is connected to the output of the detecting unit, and the output of the pulse flow summing device is connected to the signal input differential: average frequency meter . X ate 4

Description

The invention relates to a measurement technique, in particular, to radio isotope measuring means, and can be used in the control and automation of technological processes in various industries of the people. Radioisotope devices are known, for example, radioisotope thickness gauges containing an ionizing source, radiation source, detection unit and average frequency meter l. A disadvantage of the known devices is that they have a non-linear calibration characteristic. Of the known radioisotope devices, the closest in technical essence is a radioisotope instrument, which contains a source of ionizing radiation, a detecting unit, a differential meter of average frequency, connected to the source of the reference signal 2. The disadvantage of such radioisotope devices is the appearance of an additional Ia component in terms of | The intensity of the controlled parameter during the measurement cycle due to the nonlinear dependence of the output signal of the detector unit on the value of con. Controlled Parameter, i.e. nonlinearity of the calibration characteristic of the primary measuring converter of the radioisotope device. The aim of the invention is to improve the accuracy of the measurement by reducing the dynamic component of the measurement error. The goal is achieved by those. that a radioisotope device containing an ionizing radiation source, a detecting unit, a differential average frequency meter connected to a source of a reference signal were inserted into a direct frequency average frequency meter, a controlled pulse generator and a summation device and continuous fluxes, and the output of the detecting unit is connected to the input of the additional meter of the direct frequency average meter, the output of which is connected to the input of the controlled pulse generator, the output of the controlled pulse generator sov connected to one summing device consist: pulse flows, a second input coupled to an output detection unit, and the output of summing device is connected to the pulsed flow signal input differentsionnogo measurable s-bodies medium frequency. Figure 1 shows the block diagram of a radioisotope device; Fig. 2 is a graph showing the EN the formation of an additional component of the dynamic measurement error; Fig. 3 is an example of the dependence of the frequency of the controlled oscillator on the average frequency of the detecting unit. The radioisotope device contains an ionizing radiation source 1, a detecting unit 2, a medium frequency meter 3 for direct radiation, a controlled pulse generator 4, a device 5 for summing pulsed streams, a differential meter for medium frequency 6, and a source generator 7 for the reference signal. Between the source. 1 and the detection unit 2 placed the first object 8 under control. The device operates as follows. The controlled object 8 is irradiated with a stream of ionizing radiation generated by the source of 1 ionizing radiation. After the interaction of ionizing radiation with the controlled object 8, it is registered by the unit of ionizing radiation, in which it is converted into a stream of electrical pulses. This stream of electrical pulses through the summation device 5 is fed to the input of a differential meter b of medium frequency. The other input of the differential meter 6 receives the reference signal (pulsed flow) from the source 7 of the reference signal. The magnitude of the reference signal is usually chosen such that its magnitude corresponds to the magnitude of the signal coming from block 2 at a nominal value of a measurable quantity, such as thickness. At the same time, setting the required steepness of the static characteristic of the differential meter b of the average frequency, at its output we get a signal proportional to the deviation of the monitored parameter. This is true if the dependence of the value of the informative parameter (average frequency) of the output signal of the detecting unit 2 on the value of the monitored parameter of the object 8 is linear in the operating range. However, in most practical cases, this dependence, also called the calibration characteristic, is non-linear. The principle of operation of such radioisotope devices is mainly cyclical, i.e. the averaged value of the monitored parameter over a certain time — the measurement cycle. Therefore, when the value of the monitored parameter changes during a measurement cycle, an additional component of the dynamic measurement error is observed. The essence of the appearance of this component can be clarified with the help of FIG. 2. We assume that during the first half of the cycle we have the value of the parameter f of thickness) (J2 S is the second half of the cycle d. If we have a nonlinear characteristic of the form of 9, then a simple graphic design shows that the average value of the output signal does not correspond to ho which was the new value, therefore the dynamic error of the ho-ho was formed. The reduction of this second common error in the proposed device is carried out in the following way. The current average frequency meter 3. Direct radiation is measured by the output signal of the detecting unit 2 HK and, depending on its value, using a controlled pulse generator 4, an additional impulse flow h is generated, which is summed with the IC with the help of the 5 cm device. the average frequency of the flow H from the medium; 1 the frequency hj (- is chosen so that the dependence of the average frequency of the total flow hg on the value of the monitored parameter is linear. An example of the dependence of their i-i (fl ") is shown in figure 3 Essentially, a new linear calibration characteristic has been obtained for it. It is necessary to adjust the differential meter 6. Thus, the dynamic component of the error is reduced, and, consequently, the increase is 1; There is a measurement accuracy. Reducing the dynamic component of Y1; 1y error will improve the quality of products, the control of which is produced at. the help of radioisotopic devices, as well as reducing the waste caused by inaccuracy in the regulation of technological processes due to the presence of an additional component of the dynamic error. The paper industry is particularly effective in controlling the weight of 1 m of paper web, where there is a large unevenness of the paper web, and averaging the weight of 1 m to make a control decision occurs over the total web length of about 10 or more meters. In addition, this invention will allow real radioisotope devices to be brought into conformity with the requirements of GOST 9895-76 on the linearity of nominal static characteristics.

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Claims (1)

A RADIOISOTOPE DEVICE containing an ionizing radiation source, a detection unit, a medium-frequency differential meter connected to a reference signal source, characterized in that in order to increase the measurement accuracy by reducing the dynamic component of the measurement error, a direct-frequency average frequency meter is introduced into it radiation, a controlled pulse generator and a device for summing pulse flows, and the output of the detecting unit is connected to the input of the average frequency meter direct from exercises, the output of which is connected to the input of the controlled pulse generator, the output of the controlled pulse generator is connected to one input of the device for summing pulse flows, the second, -, - swarm input of which is connected to the output <3 of the detection unit, and the output of the device for summing pulse streams connected to the signal input of a differential meter of average frequency <4 frequencies. · □ about Cn U