RU2219001C1 - Device for separation of mineral raw material - Google Patents

Abstract

FIELD: concentration of minerals; devices for radiometric separation of ores. SUBSTANCE: proposed device has bin, transporting mechanism, radiation source, air and mineral luminescence intensity measurement unit whose output is connected with first input of mineral luminescence signal measurement unit and input of air luminescence intensity measurement unit whose output is connected with second input of comparison unit and second input of mineral luminescence signal measurement unit whose output is connected with command generation unit which is connected with actuating mechanism. Air luminescence intensity measurement unit consists of minimum signal detector and follower; input of minimum signal detector and output of follower are respectively input and output of air luminescence intensity measurement unit. EFFECT: enhanced accuracy of measurement. 1 dwg

Description

 The invention relates to the field of mineral processing, and more particularly to devices for radiometric separation of ores, and can be used for the separation of luminescent minerals.

 A device for separating minerals is known, comprising a hopper, a transporting mechanism, a radiation source, an air and mineral luminescence intensity measuring unit, output connected to an input of an air luminescence intensity measuring unit and a first input of a mineral luminescence measuring unit, the output of the latter being connected to a first input of a comparison unit, the second input of which is connected to the second input of the unit for measuring the luminescence of minerals and the output of the unit for measuring the intensity of luminescence of air, and you the stroke is connected to the command generation unit, the latter is connected to the actuator (patent 2004356, class B 07 C 5/342).

 The disadvantage of this device is the omission of luminescent minerals at a "high" frequency of their passage through the irradiation and registration zone.

 Closest to the claimed device is the patent 2066244, class. 07 C 5/342, containing a hopper, a transporting mechanism, a radiation source, an air and mineral luminescence intensity measuring unit, output connected to the first input of the mineral luminescence signal measuring unit and the first adder input (input of the air luminescence intensity measuring unit), the output of which is connected with the input of the peak detector, the output of which is connected to the first input of the differential amplifier, the second input of which is connected to the second input of the adder and the power supply, and the output (the output of the measurement unit Intensity of the luminescence of air) is connected to a second input of the comparison and a second input of the luminescence signal measurement unit minerals, whose output is connected to a first input of the comparator, whose output is connected to the command generating unit, the latter is connected to the actuator.

 However, this device does not provide a sufficiently high measurement accuracy, which is especially true for the separation of minerals with an extremely low level of luminescence. It becomes difficult to process weak luminescence signals, i.e., compare them with a given separation level, due to various errors - errors introduced by the circuit (device) due to the spread in the values of the adder resistances, gain of the differential amplifier, and ripple of the power source. Therefore, to increase the accuracy of separation of weakly luminescent minerals, it is necessary to ensure high accuracy in measuring the luminescence intensity of air, since measurement of luminescence signals is carried out against the background of the signal intensity of luminescence of air.

 The technical result of the invention is to increase the accuracy of the measurement of the luminescence signal of minerals and the correction of the separation threshold, which ultimately improves the efficiency of the process of separation of diamond-containing raw materials.

 The technical result is achieved in that a device for the separation of mineral raw materials containing a hopper, a transporting mechanism, a radiation source, a unit for measuring the luminescence intensity of air and mineral, connected to the first input of the unit for measuring the luminescence signals of minerals and the input of the unit for measuring the luminescence of air, the output of which is connected with the second input of the comparison unit and the second input of the unit for measuring the luminescence signals of minerals, the output of which is connected to the first input of the unit a signal whose output is connected to the command generation unit, the latter is connected to the actuator, in addition, the air luminescence intensity measuring unit contains a minimum signal detector and a repeater connected in series, while the minimum signal detector input and the repeater output are respectively the input and output of the air luminescence intensity measurement unit .

 The solution of the technical problem, namely, improving the accuracy of measuring the luminescence signal of minerals and correcting the separation threshold, is feasible provided that the level of luminescence of the air is more accurately measured. In the claimed technical solution, it is proposed to exclude the influence of the spread of the transfer coefficient of the adder, the spread of the gain of the differential amplifier and the ripple of the power source, which improves the accuracy of measuring the intensity of luminescence of air.

 We estimate the error of the unit for measuring the intensity of air luminescence when measuring the level of air luminescence by the prototype and the device according to the invention.

где E_п - напряжение источника питания;
U_вх - переменная составляющая сигнала;
U_ош.п.д. - сигнал "ошибки" пикового детектора;
U_oш.Σ - сигнал "ошибки" сумматора;
U_{пульс.п} - пульсации источника питания;
К_у2+, К_у1- - коэффициент усиления дифференциального усилителя по входам;
U_см.у - напряжение смещения дифференциального усилителя,
и для заявляемого устройства:
-U_вх±U_ош.д.м±U_см.п, (2)
где U_вх - переменная составляющая сигнала;
U_ош.д.м. - сигнал "ошибки" детектора минимального сигнала;
U_см.п - напряжение смещения повторителя.Based on the analysis, we will compose an equation describing the operation of the unit for measuring the intensity of air luminescence, for the prototype

where E _p is the voltage of the power source;
U _I - the variable component of the signal;
U _er.p.d. - signal "error" of the peak detector;
U _er.Σ - signal of the “error” of the adder;
U _puls.p - ripple of the power source;
To _{y2 +} , To _y1- - gain of the differential amplifier at the inputs;
U _{see u} - bias voltage of the differential amplifier,
and for the claimed device:
-U _I ± V _U.d.m ± U _cm.p , (2)
where U _I - the variable component of the signal;
U _er.dm - signal "error" of the detector of the minimum signal;
U _{see p} - the bias voltage of the repeater.

 Let us analyze the signals from equations (1) and (2).

U _er.p.≅ U _od.d.m. ; (3)
U _see u _≅U see _p ; (4)
and subtract equation (2) from equation (1), taking into account equations (3) and (4). The result will characterize the prototype error in comparison with the claimed device.

± 2U _{error Σ} ± U _{error p} ± U _{pulse p} (5)
As follows from equation (5), the inventive device completely eliminates the double error of the adder, the ripple of the power source and the error of the peak detector.

 The drawing shows a block diagram of a device for the separation of mineral raw materials.

 A device for separating mineral raw materials contains a hopper 1, a transport mechanism 2, a radiation source 3, a unit 4 for measuring the intensity of the luminescence of air and mineral, a unit 5 for measuring the signals of the luminescence of minerals, a unit 6 for measuring the intensity of the luminescence of air, a unit for comparison 7, a unit 8 for generating commands, an executive mechanism 9. Block 6 measuring the intensity of the luminescence of air contains the detector 10 of the minimum signal and the repeater 11.

 Unit 4 for measuring the luminescence intensity of air and mineral is made on the basis of an FEU-85 photomultiplier and a 140-series operational amplifier.

 Block 5 measuring the intensity of the luminescence of minerals is based on the operational amplifier of the 140th series.

 Unit 6 for measuring the intensity of air luminescence is made on operational amplifiers of the 140th series.

 Comparison unit 7 is made on operational amplifiers of the 140th series and is intended to compare the intensity of the luminescence signal of a mineral with a given boundary value of the luminescence intensity of minerals.

 Block 8 of the development of commands is executed on the microcircuits of the 176th series and is intended for the timely issuance of the command to cut off the useful mineral by the actuator 9.

 The detector 10 of the minimum signal is made on an operational amplifier of the 140th series and is designed to isolate the signal of the corresponding luminescence of air.

 The repeater 11 is made on an operational amplifier of the 140th series and is designed to match the high output impedance of the minimum signal detector 10 and the low input impedance of the comparison unit 7.

 The output of air and mineral luminescence intensity measurement unit 4 is connected to the first input of mineral luminescence signal measurement unit 5 and the input of the minimum signal detector 10 (input of air luminescence intensity measurement unit 6), the output of which is connected to a repeater 11, the output of which (output of intensity measurement unit 6 luminescence of air) is connected to the second input of the comparison unit 7 and the second input of the unit 5 for measuring mineral luminescence signals, the output of which is connected to the first input of the comparison unit 7, Exit is connected to the unit 8 generate commands, the latter is connected to the actuator 9.

 The device operates as follows.

 Before sorting, in the block 7 comparison set the threshold value of the luminescence intensity by applying voltage from a reference source. From the output of unit 4 for measuring the intensity of luminescence of air and mineral, the luminescence signals of air and minerals are fed to the first input of unit 5 for measuring signals of luminescence of minerals and to the input of detector 10 of the minimum signal (input of unit 6 for measuring intensity of luminescence of air). In the detector 10, the signal corresponding to air luminescence (the minimum signal) is stored and, via the matching repeater 11 (output of the air luminescence intensity measuring unit 6), is supplied to the second input of the comparison unit 7, where it (air luminescence signal) is summed with the signal of the threshold voltage intensity value for automatic correction of a given separation threshold, and to the second input of the block 5 for measuring the luminescence signals of minerals to extract from the full luminescence signal (luminescence signal Ear and mineral) mineral fluorescence signal and its subsequent amplification without distortion. When luminescent minerals enter the irradiation zone and register at the output of the unit 5 for measuring the luminescence intensity of the mineral, luminescence signals appear that are fed to the first input of the comparison unit 7. If the luminescence signal of the mineral is greater than the predetermined separation threshold, then from the output of the comparison unit 7, the signal is sent to the command generation unit 8 and then to the actuator 9 for cutting off the useful mineral into the concentrate.

 The proposed technical solution allows, due to more accurate measurement of the air luminescence signal, to increase the accuracy of measuring the mineral luminescence signal and ensure its amplification without distortion, as well as improve the correction of the separation threshold, thereby increasing the probability of detecting diamond and increasing the separation efficiency.

Claims (1)

A device for separating mineral raw materials containing a hopper, a transport mechanism, a radiation source, an air and mineral luminescence intensity measuring unit, output connected to a first input of a mineral luminescence signal measuring unit and an input of an air luminescence measuring unit, the output of which is connected to a second input of a comparison unit and the second input of the unit for measuring the signals of luminescence of minerals, the output of which is connected to the first input of the comparison unit, the output of which is connected to the block The operation of the commands, the latter is connected to the actuator, characterized in that the unit for measuring the intensity of the luminescence of air is made of series-connected detector of the minimum signal and the repeater, while the input of the detector of the minimum signal and the output of the repeater are respectively the input and output of the unit for measuring the intensity of luminescence of air.