RU2066244C1 - Apparatus for x-ray-luminescent separation of minerals - Google Patents

Abstract

FIELD: minerals benefication by luminescence activated initiated by-ray radiation treatment. SUBSTANCE: apparatus has X-ray radiation source 3, intensity of air and minerals luminescence registration unit 4, minerals luminescence signals formation unit 5, air luminescence intensity registration unit 6, control signal forming imit 7, executive mechanism control unit 8, control unit 9. Air luminescence registration unit has summator 10, power unit 11, peak-detector 12 and differential amplifier 13. EFFECT: improved design. 1 dwg

Description

 The device relates to devices for the separation of luminescent minerals by their luminescence excited by x-ray radiation.

 A device for sorting luminescent materials is known, comprising a source of x-ray radiation, a unit for recording the intensity of luminescence of air and minerals, an output connected to an input of a unit for recording air intensity and with a first input of a unit for generating luminescence signals of minerals, an output connected to a first input of a control signal generating unit, and an output connected to the control unit for the actuator (a.p. N 971523, class B 07 C 5/342, 1982).

 The disadvantage of this device is its low accuracy.

 The closest in technical essence and the achieved result is a device for x-ray luminescent separation of minerals (application N 4944088 with the floor. Decision of 04.29.93.). The device contains an x-ray source, a unit for recording the luminescence intensity of air and minerals, an output connected to the input of the unit for recording the luminescence intensity of air and the first input of the unit for generating luminescence signals of minerals, the output of the latter is connected to the first unit of the control signal, the second input of which is connected to the second input of the formation unit mineral luminescence signals and the output of the unit for recording air luminescence intensity, and the output is connected to the control unit with an actuator, the latter is connected to the actuator. The air luminescence intensity recording unit comprises voltage sources connected in series, a first adder, a repeater and a differential amplifier, and a second adder and a peak detector connected in series with an output connected to the second input of the differential amplifier, the output of which is the output of the unit.

 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. Process weak luminescence signals, i.e. to compare them with a given level of separation, it becomes difficult due to various errors of errors introduced by the circuit (device). 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 aim of the invention is to improve the accuracy of the measurement of the luminescence signal of minerals and the correction of the separation threshold.

 This goal is achieved by the fact that in the device for x-ray luminescent mineral separation containing an x-ray source, an air and mineral luminescence intensity recording unit, connected to an input of an air luminescence intensity recording unit and a first input of a mineral luminescence signal generating unit, an output of the latter is connected to a first input a control signal generating unit, the second input of which is connected to a second input of the luminescence signal generating unit and minerals and the output of the unit for recording the intensity of air luminescence, and the output is connected to the control unit for the actuator, the latter is connected to the actuator, the unit for recording the intensity of luminescence of air contains a series-connected adder, a peak detector, a differential amplifier and a power supply connected to the second input of the adder and the second input of the differential amplifier, the output of which is the output of the unit for recording the intensity of air luminescence, and the first input q adder is the input of the unit for recording the intensity of luminescence of air.

Также было проанализировано устройство по предполагаемому изобретению и составлено уравнение

.For a more accurate measurement of the luminescence signal of minerals and more accurate automatic correction of the separation threshold, it is necessary to measure the intensity of the luminescence signal of air as accurately as possible, so that the "pure" luminescence signal of minerals can be more accurately extracted from the full luminescence signal of air and mineral, and a threshold signal can be generated more accurately separation. Based on the task were analyzed, the reasons that reduce the accuracy of the measurement of the signal of the luminescence of air in the prototype. Based on the analysis, an equation was compiled that has the form:

The device according to the alleged invention was also analyzed and the equation

.

,

.Thus, after comparing the two obtained expressions, it can be seen that the error for the prototype and the claimed device, respectively, has the form

,

.

,

.If we open the brackets in both equations and substitute the values of K _d = _2/3 , K _{y1 +} = 3, K _y1- = 2 and K _{y2 +} = 2, then we obtain the equation

,

.

 If now subtract the second from the first equation, then we get the difference, which will determine the error of the prototype compared with the claimed device.

. (I)
Следовательно, заявляемое устройство по сравнению с прототипом позволяет полностью исключить ошибку, описываемую уравнением (I), а значит более точно измерить уровень люминесценции воздуха и в соответствии с этим более точно измерить сигнал люминесценции минералов и более точно установить порог разделения.

. (I)
Therefore, the claimed device in comparison with the prototype allows you to completely eliminate the error described by equation (I), and therefore more accurately measure the level of luminescence of air and in accordance with this more accurately measure the luminescence signal of minerals and more accurately set the separation threshold.

 The drawing shows a block diagram of a device.

 The device comprises a hopper 1, a transport mechanism 2 (not shown), an X-ray source 3, an air and mineral luminescence intensity recording unit 4, mineral luminescence signal generating unit 5, an air luminescence intensity recording unit 6, a control signal generating unit 7, a control unit 8 actuator, actuator 9, for example a pneumatic ejector, concentrate and tail receiver (not shown).

 In this case, the unit 4 for recording the intensity of luminescence of air and minerals is connected by an output to the first input of the unit 5 for generating signals of mineral luminescence, the output is connected to the first input of the unit 7 for generating a control signal and input 6 for recording the intensity of luminescence of air, the latter being connected to the second inputs of the unit 5 for generating the signal luminescence of minerals and control signal generating unit 7, the output of which is connected to actuator control unit 8, the latter being connected to itelnym mechanism 9.

 The unit 4 for recording the luminescence intensity of air and minerals is designed to convert luminescence signals of air and minerals into electrical signals and amplify them in the frequency range from 0 to 1 kHz and can be performed on a photoelectronic multiplier and a DC amplifier.

 Block 5 of the formation of luminescence signals of minerals is made on the basis of a differential amplifier.

 The air luminescence intensity recording unit 6 comprises an adder 10, a power supply 11, a peak detector 12, and a differential amplifier 13. The first input of the adder 10, which is the input of the air luminescence intensity recording unit 6, is connected to the output and the first input, respectively, of the air luminescence intensity recording unit 4 and minerals and block 5 of the formation of luminescence signals of minerals. The second input of the adder 10 is connected to the second input of the differential amplifier 13 and the output of the power supply 11. The output of the adder 10 is connected to the input of the peak detector 12, the last output is connected to the first input of the differential amplifier 13, the output of which is the output of the unit 6 for recording the luminescence intensity of the air, connected with the second inputs of block 5 of the formation of luminescence signals of minerals and block 7 of the formation of the control signal.

 Block 7 of the formation of the control signal is made on the basis of operational amplifiers 140 series and is intended for automatic correction of a given separation threshold and comparing the luminescence signal of a mineral with a given separation level.

 The actuator control unit 8 is made on 176 series microcircuits.

 The adder 10 is based on a resistor divider.

 Peak detector 12 and differential amplifier 13 are made on operational amplifiers 140 series.

 The device operates as follows.

 Before sorting in block 7 of the formation of the control signal, a threshold value of the luminescence intensity is set by applying voltage from a reference source.

 Then, before sorting and when there are no luminescent minerals in the detection zone, the unit 4 for recording the luminescence intensity of air and minerals is automatically measured according to the “scheme”; unit 6 for recording the intensity of luminescence of air and enter the measured signal in block 7 of the formation of the control signal, where it is (signal of luminescence of air) is summed with a signal of a threshold value of voltage intensity for automatic correction of a given separation threshold, and in block 5 of the formation of mineral luminescence signals for the isolation of full fluorescence signal (fluorescence signal air and mineral) mineral fluorescence signal and its amplification without distortion.

 In the sorting process, x-rays from the x-ray source 3 cause luminescence of air and luminescence of minerals coming from the transport mechanism in the detection zone.

 The total luminescence signal of air and minerals is converted by the unit 4 for recording the luminescence intensity of air and minerals into electrical signals and, after amplification, are simultaneously transmitted to the first input of the unit 5 for generating luminescence signals of minerals and the input of the side 6 for recording the intensity of luminescence of air (first input of the adder 10). Simultaneously, the voltage from the power supply 11 is supplied to the second input of the adder 10 and the second input of the differential amplifier 13.

 From the output of the adder 10, a signal equal to the half-sum of the voltage of the power supply unit 11 and the luminescence signal from the unit 4 for recording the luminescence intensity of air and minerals is fed to the input of the peak detector 12, which stores the maximum value of this signal and gives it further to the first input of the differential amplifier 13.

 The differential amplifier 13 amplifies the signal received at the first input, equal to half the voltage of the power supply 11 and the luminescence signal of air and minerals, stored by the peak detector 12, and subtracts the voltage of the power supply 11 supplied to the second input of the differential amplifier from the amplified signal. Thus, the voltage of the power supply 11 is "removed" from the processed signals and the output of the differential amplifier 13 (the output of the unit 6 for recording the intensity of the luminescence of air) is allocated a signal of luminescence of air, is fed to the second input of the block 5 of the formation of signals of mineral luminescence and to the second input of the block 7 of the formation of the control signal, where it is summed with the set threshold value of the luminescence intensity, the total signal is fed to the comparison circuit. In the event of a change in the luminescence signal of air, the total signal of the threshold value of the luminescence intensity also changes. Thus, automatic correction of the separation threshold occurs.

 In block 5 of the formation of mineral luminescence signals, the common-mode luminescence signal of the air is attenuated, and the luminescence signal of the mineral is amplified to the required level. The amplified mineral luminescence signal from the output of block 5 is fed to the first input of the control signal generating unit 7, where it is compared with the automatic separation threshold, and if the luminescence signal exceeds the separation level threshold, the control signal generating unit 7 gives a signal to the actuator control unit 8 , which includes an actuator for cutting off a useful mineral.

 The use of the invention improves the accuracy of the extraction of useful minerals in the separation of raw materials with a high content of luminescent minerals.

Claims (1)

 A device for x-ray luminescent mineral separation containing an x-ray source, serially connected unit for recording the luminescence intensity of air and minerals, a unit for generating luminescence signals of minerals, a unit for generating a control signal and an actuator control unit, the output of the unit for recording luminescence intensity of air and minerals is connected to the input of the registration unit luminescence intensities of air that contains series-connected sums an amplifier, a peak detector, a differential amplifier and a power supply connected to the second input of the adder, the first input of the adder and the output of the differential amplifier are, respectively, the input and output of the air luminescence intensity recording unit, the output of which is connected to the second input of the mineral luminescence signal generation unit, and to the second input of the control signal generating unit, characterized in that the second input of the differential amplifier is connected to the second input of the adder and the power supply.