SU1135286A1 - Electronic densimeter - Google Patents

Abstract

ELECTRONIC PLOTNOMER, containing an electron source, a channel for conducting electrons, an electron detector, made fl as an aggregate of children’s sections, intersection screens and summation nodes of the output signals of the detecting sections, a meter for the difference of the summation nodes of the summation of the output sections of the detecting sections, and the number of objects that are summed by the detecting sections; the accuracy of the density measurement, the detecting sections are divided into two groups, the detecting sections of the first group are connected to the first summation node of the output signals sections, and the detecting sections of the second group are connected to the second node of the sum of output sections, before the input apertures of the detecting sections of the first group there are electron absorbers, and before the i input apertures of the detecting sec (electrons, with the possibility of moving beyond the input apertures of the second group, and the outputs of the summation nodes are connected to the inputs of the difference meter. Od ate INS oo O5

Description

The invention relates to the field of measuring the density of materials by radiation methods, in particular, to devices for monitoring the density of materials by backscattering: / electrons.

A known electron density meter containing an electron source, a collimator, has a channel for conducting electrons from the source and an internal recording channel bounded by conical surfaces coaxial with the channel for conducting electrons from the source and crossing its surface, the electron detectors located along the source one side of the end face of the collimator, which has a radius of intersection with the outer surface of the collimator, chosen for the object being monitored, depending on the electron energy The detector and the object to be monitored, one of the detectors located in the internal registration channel of the collimator, has a solid registration angle limited by the internal registration channel, and the second detector - on the external surface of the collimator - has a solid registration angle limited by the external surface of the collimator, ratio meter, inputs which is connected to the detectors.

The output signals of the detectors of this densitometer, each of which are sensitive to changes in the density of the object due to the detection of back scattered electrons, have components corresponding to the registration of bremsstrahlung from the electron source from the channel of the collimator for conducting electrons from the source and occurring in the object, the intensity of which is determined both the material of the object and its thickness, especially if it does not exceed the electron path in the material of the object. Due to the practical insensitivity of the components of the signals, corresponding to the bremsstrahlung from the object, to its density and the different sensitivity of different detectors to changes in thickness only due to the different solid angles of detection of the detectors, this electron density meter has a limited accuracy due to the error due to thickness fluctuations

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controlled objects, and the sensitivity of the detector signals depending on the thickness of the object to density changes.

5 Of the known technical designs, the closest to the invention in its technical essence is an electron density meter containing a source of electrons, a channel for conducting electrons, a detector of electrons, implemented as a combination of detection sections, intersection screens and two summation nodes of the output signals of the detection sections.

However, due to the smaller difference in the corners of the registration of the detector sections located opposite the notches and the detector section, 20 located between the notches of the collimator, the sensitivity of the components of the detector signals, the corresponding registration of bremsstrahlung radiation to changes in the object's mass, 5 do not differ in sensitivity. In general, the variations are very different because the signal component corresponding to the detection of the Q bremsstrahlung for the detector sections is located against cuts, it is a much smaller proportion of the signal than for the detector sections arranged between the notches. Therefore, the presence of signal components of the detector sections, corresponding to bremsstrahlung detection, with less sensitivity to density changes due to practical insensitivity to them of sections located against the notches, determines the low accuracy of the known densitometer.

The aim of the invention is to improve the accuracy of the density measurement.

The goal is achieved by the fact that in an electronic densitometer containing a source of electrons, a channel for conducting electrons, an electron detector made as a set of detecting sections, intersection screens and two summation nodes of the output signals of the detecting sections also contain a difference meter that detects 5 sections first the groups are connected to the first summation node of the output signals of the sections, and the detecting sections of the group are connected to the second

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the summation node of the output signals of the sections, in front of the input apertures of the detecting sections of the first group are electron absorbers, and in front of the input apertures of the detecting sections of the second group are electron absorbers configured to move outside the input apertures of the specified second group, and the outputs of the summation nodes are connected to the inputs of the meter the difference.

The output signals of the sections of the first group, in front of the entrance apertures of which electron absorbers are located, correspond to the registration of bremsstrahlung. The output signals of the sections of the second group, in front of the entrance apertures of which are absorbers of electrons, are moved outside the entrance apertures of the sections, in the position of the absorber outside the apertures of the sections corresponding to the registration of both backscattered electrons and bremsstrahlung, and in the position of the absorber in front of the entrance apertures of the sections the output signals of the sections are equal to the components of the output signals of these sections, corresponding to the registration of bremsstrahlung in the absorber position outside the apertures. The output of the summing device of the output signals of the sections of the first group by changing the transfer coefficients of the sections or the summing device is set to the output signal of the slm device. The output signals of the sections of the second group when the movable absorbers are located in front of the apertures of the sections of the second group correspond to the zero output signal of the difference meter. The output signal of the difference meter in the position of the moving absorber outside the apertures of sections of the second group, at which the density is monitored, in this case due to the alternation of sections of different groups is proportional to the zymmar component of the output signals of the sections of the second group corresponding to recording only backscattered electrons regardless of the object of control electron source, etc.

The sensitivity of the output signal of the difference meter to changes

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density is equal to the sensitivity of the component of the detector signal, the corresponding registration of only backscattered electrons, i.e. 5 is higher than the output sensitivity of the detector of a known density meter.

The independence of the output signal of the difference meter from the intensity

0 bremsstrahlung also ensures the absence of an error due to the dependence of the intensity of bremsstrahlung on the thickness of the object. This achieves higher

5 ka density control accuracy.

FIG. 1 shows a diagram of a density meter; in fig. 2 - sections A-A, BB, B-B, GG in FIG. one; in fig. 3 is a plot of the sensitivity of

0, the output signal of the difference meter to changes in the density of the object being monitored against the ratio between the output signal of the summation device, the output signals of the sections of

5 and a component of the output signal of the device for summing the output signals of sections of the second group, corresponding to the registration of bremsstrahlung; in fig. 4 - grades

0 Fiction of output signal dependency of the summing device of the output signals of the sections of the second group and from the difference meter at the output signal of the summing device of the sections of the first group equal to the component of the output signal of the device of summing the output signals of the sections of the second group corresponding to the registration of bremsstrahlung.

The proposed electronic densitometer contains (Fig. 1 and 2) a collimator with channel 1 with a diameter of 2 rd for conducting electrons from source 2 to a controlled object 3 mounted on the end of collimator 4 having an end radius Eg. The detector, covering the collimator, is made of twelve sections 5, which are sectors of an annular plastic scintilla -

 Torah. The sections are separated by absorbing electrons by screens 6. The odd sections of the detector, which constitute the first group, are optically connected to the output summation device.

5 signals of sections of the first group, made in the form of an annular light guide 7 - with a photomultiplier optically connected to it 8. Even sections

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The detector components that make up the second group are optically connected to a device for summing the output signals of sections of the second group, made in the form of an annular light 9 with optically connected to a photomultiplier 10. The outputs of photomultipliers 8 and 10 are connected to the meter 11 of the difference between the output signals of the devices summation. In front of the entrance apertures of the sections of the second group there are absorbers of 12 electrons, made in the form of plates of a material with a low atomic number, for example, of graphite, with a thickness exceeding the mileage of the back scattering of electrons in the absorber material. The same absorbers 13, but moved beyond the limits of the entrance apertures of the sections, are located in front of the entrance apertures of the sections of the first group

The detector in the internal channel and registration of the collimator is made similar to the described detector, covering the collimator.

The outputs of the difference meters corresponding to the detector enclosing the collimator and the detector in the internal recording channel are connected to the inputs of the ratio meter, the output of which is a measure of the density of the object.

Before carrying out the inspection of the density of objects, the movable absorbers of the sections of the first group are positioned in front of the apertures of the sections.

The electron beam from source 2 passes through channel 1 to conduct electrons from source 2 to controlled object 3. Three electrons are backscattered by the object being monitored, bremsstrahlung arising in the object, as well as bremsstrahlung transmitted through the elements of the densitometer from channel 1 to conduct electrons from source 2 to the controlled object 3 and directly from source 2 fall on the absorbers in front of the apertures of the sections of both groups. At the same time, due to the low atomic number of the material, the absorbers are backscattered. electrons are completely absorbed by absorbers in front of the apertures with practically no generation of bremsstrahlung in it, and the bremsstrahlung

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the radiation passes through the absorbers with little or no absorption.

The light emission from the sections, proportional to the intensity of the bremsstrahlung incident on them, comes from the sections of the first group to the ring light guide 7, and from the sections of the second group to the ring light guide 9. The output signals of the photomultiplier

The bodies 8 and photomultiplier 10, proportional to the intensity of bremsstrahlung, recorded by the sections of the first and second groups, respectively, go to the meter

15 and by selecting the photomultiplier transfer coefficients at the output of the difference meter, the operator sets the zero signal. Thanks to the alternation of sections of the first and second

In the case of a group of groups, a change in the intensity of the bremsstrahlung from the object, the channel of the collimator and from the source practically does not change the zero output signal of the difference meter.

After that, the absorbers in front of (and the perforations of the sections of the first group are moved to a position outside the entrance aperture of the sections, and in this position of the moving absorbers, the density of objects is monitored. At the same time, sections of the first group are irradiated with both bremsstrahlung and backscattered electrons, and the difference meter, the signal is proportional to the result of registering only the back scattered electrons by the sections of the first group, since the component of the output signal of the photomultiplier 8, the corresponding registration and bremsstrahlung and, equal to the output signal of the photomultiplier 10 U, (U, / U 2 1) This corresponds to Tfig. 3) the highest sensitivity value 5

output signal to the difference meter. When the U-f2 component is incompletely compensated by the photomultiplier signal lOU, (u,) due to a decrease in the transfer coefficient of the photomultiplier U, which corresponds to the simulation of a known densitometer, the sensitivity of the signal to the ratio of the signal to density changes decreases depending on 3–20 times, which means that the sensitivity of the proposed density meter to density changes exceeds the sensitivity of the known density meter, respectively, more than 3–20 times. The output signal of the difference meter I 1 (Fig. 1) Uj-U, with the object thicknesses greater than the control depth d, does not depend on the thickness of the objects cm, curve 15, fig. A) and, therefore, the proposed density meter has no error. due to the change in thickness. The output signal of the NIN summation device of the output signals of sections of the first group, which are similar to the detector of a known densitometer, depends on the component U on the thickness of the objects at all thicknesses (see curve 1 b) and, therefore, the known density has an error due to fluctuations thickness of objects at all thicknesses of objects. Less error due to fluctuations of uncontrolled properties of objects, and higher sensitivity to changes in control

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The phage / 68 of the rotated parameter, density, determines the higher accuracy of the proposed densitometer compared to the known ones. The proposed densitometer provides high-performance non-destructive. The control of density distribution in powder metallurgy materials, for example, in powder rolled products with an accuracy not worse than the accuracy of hydrostatic weighing used in powder metallurgy, the use of which for these purposes does not, however, require the destruction of a controlled object. Estimation of the expected economic effect without taking into account the qualitatively new possibilities of the proposed densitometer when replacing the hydrostatic weighing, which is taken as the basic object, gives more than 100 thousand rubles. for a laboratory making 40,000 measurements per year.

Claims (1)

ELECTRON DENSITY METER containing an electron source, channel for conducting electrons, an electron detector made in the form of a set of detecting sections, intersection screens and two nodes for summing the output signals of the detecting sections, a meter for the difference of the nodes for summing the output signals of the detecting sections, characterized in that, with in order to increase the accuracy of density measurement, the detecting sections are divided into two groups, the detecting sections of the first group are connected to the first node for summing the output signals in sections, and the detecting sections of the second group are connected to the second node for summing the output signals of the sections, electron absorbers are located in front of the input apertures of the detecting sections of the first group, and electron absorbers are located in front of the input apertures of the detecting sections of the second group, which can move beyond the input apertures the specified second group, and the outputs of the nodes of the summation are connected to the inputs of the difference meter.