SU1139505A1 - Device for monitoring quality of coal on conveyer belt - Google Patents

Abstract

COAL QUALITY CONTROL DEVICE ON CONVEYOR TAPE, containing a relationship meter, successively located gamma-radiation source with a collimator, tape, screen and detector installed above the angle layer perpendicular to its surface, and the control unit, the first output of which is connected to an electromagnetic drive characterized in that, in order to increase the accuracy of the control, it is equipped with an electronic switch. a frequency divider, a counter, a reversible counter, the detector being made in the form of a ts1-shinra inserted into the pipe with axisymmetric peripheral slots in which gas-discharge counters are inserted, the pipe is made of a material with a low atomic number, such as fiberglass, filters are filled in longitudinal inserts into the pipe, which are located opposite the cylinder slots, the pipe drive shaft is connected to an electromagnetic drive, the second output of the control unit is connected to the control input of the electronic switch, to the input gas-discharge counters are connected to the outputs (I have connected the inputs of the frequency divider, the counter and the reversible counter, respectively, to the summing input of which the output of the frequency divider is connected, and the output is connected to the first input of the meter, the second input is connected to the output of the counter, while the filter is made of a material whose energy of a k-jump with EJ satisfies the condition

Description

The invention relates to a mining conveyor transport, and more specifically to devices for automatic automatic quality control of minerals on belt conveyors of mines, quarries, mines, and processing plants, and can be used, for example, to control the ash content of coal mines and coal preparation plants for automation. production or enrichment of coal. A device for analyzing coal quality on a conveyor belt is known, which contains two limited arms and an articulated hanger with counterweights and equalizer installed at opposite ends and a coal quality sensor, in which, to improve the accuracy of the analysis, I have a computationally connected sensor of the angle of inclination of the hanger. the block, the extreme regulator and shafts perpendicular to the edges of the conveyor belt with the drives to which the bounding flanges are attached. Each bounding bead is made in the form of a direct helicoid, the axis of which is the side of the bead adjacent to the surface of the bead. These drawbacks prevent the use of the device for controlling the ash content of coal,. A coal quality control device on a conveyor belt is known, containing a ratio meter, a gamma radiation source with a collimator, a tape, a screen and a detector mounted above the coal layer perpendicular to its surface, and a control unit, the first output of which is connected to an electromagnetic pr | 1vodom. The device may also contain a power supply stabilizer and a digital printing device. In the known device, the detector output is connected to the input of the pulse generator, and the electromagnetic drive is connected to a shutter blocking the radiation flux from the additional control source to the detector U. However, the known device has a low accuracy, which is determined on the one hand by the impossibility of obtaining invariance to density fluctuations and the moisture content of coal in a wide range, but on the other hand is due to the strong influence of the change in the chemical composition of ash coal on the measurement result. The purpose of the invention is to increase the accuracy of control Ka4ectBa ang. The goal is achieved by the fact that the coal quality control device on a conveyor belt, containing a ratio meter, successively located gamma radiation source with a collimator, a tape, a screen and a detector mounted above the carbon layer perpendicular to its surface, and the control unit, the first output of which is connected Electromagnetic drive equipped with an electronic switch, frequency divider, counter, reversible counter, and the detector is made in the form of a cylinder inserted into the -tube with ocecHMMeTpH4HbiNoi In the grooves in which gas-discharge counters are inserted, the pipe is made of a material with a low atomic number, for example fiberglass, the filters are made in the form of longitudinal inserts into the pipe, which are opposed to the cylinder pae, the drive shaft of the pipe is connected to the electromagnetic drive, from the control input of the electronic switch, to the input of which the gas-discharge counters are connected, and to the outputs are connected the inputs of the frequency divider, the counter and the reversive counter-: tick, to the sums ruyuschemu entry whose output is connected frequency divider, and the output is connected to a first input of the meter, a second input coupled to an output of the counter, wherein the filter vtolnen of a material whose energy E K satisfies a condition of discontinuity. 0.9Ei, Kj, E, where E (; (is the gamma radiation energy of the source. Such a constructive implementation makes it possible to compensate the effect of coal density and moisture fluctuations over a wide range and at the same time eliminate the effect of changes in the chemical composition of coal ash and its ash content, which significantly improves the accuracy. The presence of the indicator and the recorder does not affect the accuracy increase.

Fig. 1 shows schematically a quality control device for coal on a conveyor belt (with a sectional image of a tape and a gamma radiation source with a collimator POMJJ container in fig 12 - section A-A in Fig. 1 (detector with filter / in Fig. 3: mass attenuation coefficient gamma radiation / li (in CNr / r by a filter from thuli,

The device for monitoring the quality of the coal | On the pipeline the conveyor consists of a gamma-radiation source 1 mounted in the container collimator 2. On the conveyor belt 3 there is a layer of coal 4. The continuous detector consists of a cylinder 5, in its slots gas-discharge counters 6 are installed, A screen 7 of a material with a high atomic number, such as lead or tungsten, is attached to the detector at the bottom. The pipe 8 is equipped with an axis 9 driven to rotate the pipe.

The control unit (control unit} 10 by the first output is connected to the input of the actuator 9 for rotating the pipe 8, the second output of the control unit 10 is connected to the control input of the electronic switch II. The information input of the electronic switch 11 is connected to the outputs of the gas discharge meters 6, and to the first output of the electronic switch the switch is connected to the input of the frequency divider 12, to the second - summations the input of the reversible pulse counter 13, to the third - the input of the counter and terminal 14, the output of the frequency divider 12 is connected to the subtractive input reversing th counter 13, the output of which is connected to the counter 14 and the ratio meter 15.,

The detector is installed perpendicular to the base of the tape 3 and, therefore, perpendicular to the layer of coal 4, on the axis of the detector, only on the other side of the layer of coal 4, is the source of gamma radiation from americium 241 installed in the container collimator 2, Mezhl, at the source 1, and the detector 7 houses a screen 7, which almost completely overlaps the direct gamma ray beam from the source to the detector.

The tube 8 is made of a material with a low atomic number, for example, of fiberglass, has filters from thuli, which are made from thuli

Longitudinal inserts into the tube 8. The dimensions, the number and the location of the filters are chosen because the gamma quanta paths (scattered forward in the controlled coal 4 layer) are blocked for gas-discharge counters 6 (when the tube 8 is rotated appropriately), the device works as follows.

When turned on by a signal from the control unit 10 by means of an electronic switch 11, the output of the gas-discharge counters 6 is connected to the input of the pulse counter 14 and connected through the frequency divider 1 2 to the summing input of the reverse pulse counter 13, the signals from the control unit 10 turn 9 pipe 8 in such a way that the filters 16 are installed in front of the projections of the cylinder 5, the collimated beam of gamma rays from the source 1 falls on the layer of coal 4, the gamma rays scattered in the forward direction through the thin wall t Uba 8 fall on the gas discharge 6 meters (solid line on soistrelkami fyg, 1). The pulse frequency from counters Ij is proportional to the flux density of coherently resettled gamma-quanta Fz and the flux density of incoherently scattered gamma-quanta TCs. During the first clock cycle i sec. In the counter 14, the number n, i, ti pulses are written, and in the counter 13 the number m 5 i, t) pulses. Considering that f. proportional to F and Fz, we can write the approximate equality

And, O. (F, P „.

(ABOUT

P24aChfpfn

(2)

where a is the coefficient of proportionality.

After the time t | By a signal from the control unit 10, the output of the gas discharge meters 6 is connected to the subtractive input of the reversible pulse counter 13 via an electronic switch 11, current is supplied to the driver 9, and the pipe 8 is turned so that the filters 16 are installed in front of the gas discharge counters 6 (FIG. 2). At the same time, the gamma quanta scattered forward reach the counters 6 only through filters 16, the diagram shown in FIG. 3 determines the Lo, that for coherently scattered gamma rays f with energy 59, 6 keV, 5, and for Incoherently scattered gamma quanta with an energy of not more than 59.39 keV. At the same time, the flux density of coherently scattered gamma-quanta on the counters is 9j; -exp (- (lJk 0.5 (, |. During the second cycle in TC / s, 1 +0.033 q is fed to the subtracting input of the reversible counter 13) T pulses. At the expiration of the second clock cycle, at the output of counter 14, there are n pulses, and at the output of the reversible counter 13n ngr 0.4b7.a, F pulses. These numbers of pulses u and P are considered to be a ratio meter 15, Next the processing algorithm can be, for example, such WV-0.467-n4 0.467-01-F + O., 467-a P WV -o -0.467-01., 467-0 RC. and P | are linear f By assigning, respectively, flux densities coherently and incoherently scattered gamma-rays Φ | and Φz, Now, using values of n, which are proportional to flux densities j and, establish the desired composition. Mixtures. The algorithm for determining the composition of mixture C can be, for example, the following - .. cc where A and B are the coefficients of the calibration equation C is the relative content of the heavy component in the mixture, while the value of the HZ / P ratio does not depend on fluctuations in the density and humidity of the mixture within considerable limits, and tax density does not depend on the particle curvature - ,. At the same time, the sensitivity of the ratio P to the composition of mixture C is quite high, as the average atomic number of the mixture increases, the ratio simultaneously increases by 8% with increasing ash content by 1% (whereas p increases by 4% and n5 decreases only by 2%). % with an increase in the ash content of coal by 1%). Another advantage of the proposed probe is its simplicity — for a spectrometry of gamma radiation with a resolution of 0:21 keV, a filter from a thule and a gas discharge counter are used. If the device is used, for example, to control the composition of the mixture in selected dried samples with stabilized bulk density (which can be achieved, for example, by filling the standard weight of the sample into a standard measuring cell), then the algorithm for processing the obtained numbers P and Pg can be different, - When controlling the content of a three-component mixture with the content of the average component C and the heavy component of the SL as an algorithm, we can recommend solving the set of three linear equations n bi + bj – Cg – tb.Cj PdL –bc – Cr –HH C, + C2+ Szi where b. - b, are the coefficients of the calibration equations. The solution of the system of equations allows determining the composition of the three-component mixture with high accuracy. This is explained by the good conditionality (close to ideal) of the system of equations (51, since n increases, and P decreases with increasing content of the average and heavy components in the controlled mixture. Thus, an additional measurement of the intensity of coherently scattered forward gamma radiation and determining the intensity of an incoherent forward scattered gamma pattern allows to increase the accuracy when controlling the composition of a binary mixture or to control the composition of three-component mixtures, filtering the forward scattered gamma radiation for an individual, using a filter made of a material whose K-jump energy is close to the energy of the primary gamma-ray source, simplifies the control of the composition and ensures a clear separation of the gamma quantum into coherent and non-coherent, using simple and reliable integral non-tectometric, counting detectors . In controlling the composition with a significant range of changes in the content of components in the mixture instead of linear, nonlinear calibration equations are used, whose coefficients, as in the linear equations, can be determined by known methods (least squares, confluent analysis, maximum likelihood, etc.) . During the first measurement cycle, the tube 8 is rotated so that the gamma quanta scattered forward in the carbon layer hit the counters 6 through the thin fiberglass wall of the tube 8i. At the same time, the pulse count rate from the detector is directly proportional to the total flux of scattered gamma rays. quanta. During this time, when the pipe 8 rotates 360 / m (where m is the number of gas-discharge meters located symmetrically with respect to the cylinder axis, the filters 16 become opposite to the gas-discharge counters 6 and the forward gamma-quanta scattered forward filters, having undergone absorption in them, on counters. The operation of the device is described on the example of using a filter from tuli, 39 keV) with a surface density of D-J 0.233, in 1 quality of frequency divider 12 a conventional trigger with a division factor of 2 is used, and olzuets americium-241 (6 keV). The proposed device allows improving the accuracy of coal quality control on a conveyor belt.

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Claims (1)

A COAL QUALITY CONTROL DEVICE ON A CONVEYOR BELT, containing a ratio meter, a gamma radiation source with a collimator, a tape *, a screen and a detector mounted above an angle layer perpendicular to its surface, and a control unit, the first output of which is connected to electromagnetic drive, characterized in that, in order to improve the accuracy of control, it is equipped with an electronic switch, frequency divider, counter, reversible counter, moreover, the detector is designed as inserted into the pipe. a cylinder with axisymmetric peripheral manholes into which gas discharge counters are inserted, the pipe is made of a material with a low atomic number, for example fiberglass, the filters are made in the form of longitudinal inserts into the pipe, which are located against the grooves of the cylinder, the drive shaft of the pipe is connected to an electromagnetic drive , the second output of the control unit is connected to the control input of the electronic switch, the input of which is connected to 5 gas-discharge meters, and the inputs of the frequency divider are connected respectively to the outputs, with a counter and a reversible counter, to the summing input of which the output of the frequency divider is connected, and the first input of the meter is connected to the output, the second input of which is connected to the output of the counter, while the filter is made of material whose k-jump energy satisfies the conditions of 0.9E _and <E _k <E _and , where E _d is the energy of the gamma radiation of the source. 1 1139505. 1