RU2196013C1 - Method of mineral separation - Google Patents

Abstract

FIELD: mineral concentration, more specifically, methods of radiometric ore separation; applicable in separation of luminescenting minerals. SUBSTANCE: method of mineral separation consists in pulse excitation of luminescence of minerals and air, recording of current value of summarized signal amplitude of mineral and air luminescence at moment of attaining of X-ray radiation maximum intensity, separation and memorizing directly in the course of separation of minimal amplitude of luminescence corresponding to air luminescence from all sequence of signals. Minimal signal amplitude is used for stabilization of level of separation and recording of amplitude of attenuation single of mineral luminescence long-lived component upon expiration of time corresponding to minimal value of attenuation time constant of mineral luminescence signal. Besides, method consists in settling of separation threshold by amplitude of attenuation signal of mineral luminescence long-lived component, comparison of amplitude of attenuation signal of mineral luminescence long-lived component upon expiration of time corresponding to minimal value of attenuation tine constant of mineral luminescence signal with preset threshold and separation of mineral by comparison results. EFFECT: higher recovery of valuable mineral due to stabilization of separation level. 1 dwg

Description

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

 A known method of separation of minerals, which consists in irradiating the flow of minerals with pulsed x-ray radiation, recording and storing the amplitude of the total luminescence signal of the mineral and air (background) at a point in time preceding the end of the x-ray pulse, recording and storing the amplitude of the luminescence signal of the mineral at a time immediately after X-ray pulse, recording the amplitude of the attenuation signal of the long-term component of the luminescence of the mineral after time the value corresponding to the minimum value of the decay time constant of the useful mineral mineral luminescence signal, to set the separation threshold for the attenuation signal amplitude of the long-term component of the useful mineral luminescence, to compare the amplitude of the decay signal of the long mineral luminescence component recorded after a time corresponding to the minimum value of the decay time constant of the useful mineral luminescence signal with a given threshold, and the allocation of a useful mineral according to the results of Aviation, determining the amplitude of the luminescence signal of air (background) from the difference between the amplitudes of the total luminescence signal of the mineral and air (background) at the time point preceding the end of the x-ray pulse and the amplitude of the luminescence signal of the mineral at the time immediately after the end of the x-ray pulse, using the obtained difference amplitudes to establish the level of separation of the luminescence signals of minerals [and.with. USSR 971523, class B 07 C 5/342, 1982].

 However, the known method has a low accuracy of maintaining a given level of separation (X-ray luminescent sensitivity) with a high content of useful and / or associated luminescent minerals in the power of the separator.

This is due to the fact that
- useful and associated luminescent minerals have a large dynamic range of the luminescence signal (at least two orders of magnitude) and due to this, the separator’s electronic path is “taken out” of the linear mode of operation both when memorizing the total luminescence signal of air (background) and minerals, and when memorizing the signal luminescence of the mineral, and, as a result, the accuracy of measuring the background level drops sharply;
- if there are accompanying luminescent minerals in the separator’s power supply having a fast component of the luminescence signal, the measurement of the air level (background) will be incorrect, since the amplitude of the luminescence signal of the mineral having a fast component due to the low inertia of the process takes a steady value almost from the beginning of the excitation pulse and is summed with the background level, and at the end of the excitation pulse, the total luminescence signal of the accompanying luminescent mineral and the air level (background) will is equal to zero, which will also significantly reduce the accuracy of maintaining a given separation level;
- when two of the above factors coincide, the device is all the more unable to provide the required accuracy of maintaining a given level of separation.

 For clarification, imagine signal processing using formulas.

In the description, the notation of the time intervals τ ₂ (the time instant preceding the end of the x-ray pulse) and τ ₃ (time instant immediately after the end of the x-ray pulse) is used in accordance with the time diagram shown in the prototype.

 To correctly evaluate the operation of the registration path, we will introduce the mandatory assumption on the operation of the device registration path in linear mode, i.e. the amplitude of the signals in the path should be less than the voltage of the power source.

The signal in the registration path at time τ ₂ preceding the end of the x-ray pulse is described by the formula
U _c1 = U _in + U _mb + U _md1 <U _p , (1)
where U _c1 is the total signal at time τ ₂ ;
U _in - the signal of luminescence of air at time τ ₂ ;
U _mb is the luminescence signal of the mineral, in the presence of a fast luminescence component, at time τ ₂ ;
U _md1 is the luminescence signal of the mineral, in the presence of a long-term luminescence component, at time τ ₂ ;
U _p is the voltage of the power source of the registration path.

The signal in the registration path at time τ ₃ , immediately after the end of the x-ray pulse, is described by the formula
U _c2 = U _md2 <U _p , (2)
where U _c2 is the total signal at time τ ₃ ;
U _md2 is the luminescence signal of the mineral, in the presence of a long-term luminescence component, at time τ ₃ ;
When subtracting from (1) (2), we neglect the insignificant error that may be caused by the incomplete equality of U _md1 and U _md2
U _c1 -U _c2 = U _in + U _mb + U _md1 -U _md2 = U _in + U _mb <U _p (3)
It can be seen from (3) that, in the absence of minerals in the registration zone, the air (background) level is determined only by the level of air luminescence, and if there are minerals in the registration zone that have a fast luminescence component when measuring (storing) the air level (background), a large the error determined by the signal U _mb .

Consider also the options for the operation of the registration path in nonlinear mode, which can be caused by several factors:
1. U _mb > U _p
Since the value of U _c1 in the registration path cannot be greater than U _p , then
U _c1 = U _p ;
U _c1 -U _c2 = U _p -U _MD2 ,
those. in this example, it is measured (remembered) not the background level, but some random signal, which does not depend on the value of the background level, but is determined by the amplitude of the signal of the long-term luminescence component.

2. U _md1 = U _md2 > U _p
Since the value of U _c1 and U _c2 in the registration path cannot be greater than U _p , then
U _c1 = U _p ;
U _c2 = U _p ;
U _c1 -U _c2 = 0,
i.e., in this example, the measured (stored) level of air (background) is zero.

 Thus, the higher the content of luminescent minerals (useful or related) in the separator power supply, the greater the error is introduced in the measurement of the luminescence signal of air (background) and, as a result, in maintaining a given separation level.

 The technical result of the invention is to increase the extraction of valuable mineral (diamonds) by stabilizing the level of separation.

 The technical result is achieved by the fact that in the method of mineral separation, which consists in pulsed excitation of the luminescence of minerals and air (background), recording the amplitude of the total luminescence signal of the mineral and air (background), recording the amplitude of the decay signal of the long-term component of the luminescence of the mineral after a time corresponding to the minimum value the decay time constant of the luminescence signal of a useful mineral, setting the separation threshold by the amplitude of the decay signal of the long-term component l minnescence of the useful mineral, comparing the amplitude of the decay signal of the long component of the luminescence of the mineral, registered after a time corresponding to the minimum value of the decay time constant of the luminescence signal of the useful mineral with a given threshold, the allocation of the useful mineral according to the comparison results, additionally record the current value of the amplitude of the total luminescence signal of the mineral and air (background) at the moment when the intensity of x-ray radiation reaches its maximum value cheniya and directly during separation of the whole recovered signal sequence and storing the minimum amplitude of the luminescence signal corresponding air luminescence (background), the minimum signal amplitude is used to stabilize the level of separation.

The operations used in the separation method: recording the amplitude of the decay signal of the long-term component of the luminescence of the mineral, setting the separation threshold, stabilizing the separation level, are fundamental for characterizing the technological parameters of the X-ray luminescent separation process, while
- the amplitude of the attenuation signal of the long-term component of the luminescence of the mineral is the value of the intensity of the luminescence of the mineral with a constant time of rise and decay of the luminescence of more than 0.5 ms (the minimum value of the constant of the decay time of the luminescence signal of a useful mineral);
- the separation threshold is the value of the luminescence intensity of the mineral, determined by its natural properties and the properties of the technical means that carry out the separation of minerals (in this case, all luminescent minerals with a luminescence intensity greater than the separation threshold will be separated into concentrate);
- the separation level of luminescent minerals is the absolute value of the luminescence intensity of the mineral, determined by its natural properties, and used as an indicator characterizing the degree of extraction of useful and related minerals.

 When the mineral stream is irradiated with pulsed x-ray radiation, a sequence of luminescence signals is formed, which includes either luminescence signals of air (background) at the moments when there are no luminescent minerals in the irradiation and registration zone, or a total luminescence signal of air (background) and minerals useful and / or accompanying, while the magnitude of the total signal depends both on the parameters of the x-ray pulse (intensity) and on the properties of the luminescent mineral (fast and / or long-term component minescence, time constant of luminescence acceleration and luminescence intensity in static). Those. in the inventive method, the isolation and storing of the minimum amplitude of the air luminescence signal (background) is performed at the time the x-ray radiation intensity reaches its maximum value and it is necessary to consider a formula similar to (1).

U _c = U _in + U _mb + U _ppm <U _p , (4)
where U _with - the total signal at the time the x-ray radiation intensity reaches its maximum value;
U _in - the signal of luminescence of air at the time the intensity of x-ray radiation reaches its maximum value;
U _mb is the luminescence signal of the mineral, in the presence of a fast luminescence component, at the time when the intensity of x-ray radiation reaches its maximum value;
U _md is the luminescence signal of the mineral, in the presence of a long-term luminescence component, at the time when the intensity of x-ray radiation reaches its maximum value;
U _p is the voltage of the power source of the registration path.

From the analysis (4) we obtain various options:
1. U _mb > U _p and / or U _md > U _p
Since the value of U _with in the registration path cannot be greater than U _p , then
U _c = U _p (5)
2. U _mb = 0
U _a = U _a + U _ppm <U _n (6)
3. U _ppm = 0
U _c = U _in + U _mb <U _p (7)
5. U _mb = 0; U _ppm = 0
U _c = U _in <U _p (8)
Comparing expressions (5), (6), (7), (8) with each other, we find that expression (8), which corresponds to the minimum signal in the recording path in amplitude, corresponds to the "real" level of luminescence of air (background).

 The time constant of the acceleration and decay of the luminescence of air contains only the fast component of luminescence, and the amplitude of the luminescence signal of the air (background), due to the low inertia, repeats the shape of the x-ray pulse and reaches a maximum when the x-ray intensity reaches its maximum value. If a useful and / or concomitant mineral appears in the irradiation and registration zone, then the amplitude of the total luminescence signal of air (background) and mineral is greater than the amplitude of the luminescence signal of air (background). Thus, from the entire sequence of signals, isolating and remembering the minimum amplitude of the luminescence signal, at the time the x-ray radiation intensity reaches its maximum value, which corresponds to the luminescence of air (background), and using it to stabilize the separation level, thereby increasing the extraction of valuable mineral (diamonds) )

 The method can be implemented by the device shown in the drawing.

 The device comprises a hopper 1, a transport mechanism 2, designed to move minerals through the irradiation and registration zone, a source of pulsed x-ray radiation 3, a photodetector 4 for recording the amplitude of the total luminescence signal of the mineral and air (background) and recording the amplitude of the decay signal of the long-term component of the mineral luminescence after time corresponding to the minimum value of the decay time constant of the luminescence signal of a useful mineral, the signal processing system 5 minescence, designed to enhance and compare the amplitude of the attenuation signal of the long-term component of the mineral luminescence with a predetermined separation threshold and maintain a predetermined separation level, synchronization unit 6 for synchronizing operating modes, unit 7 for extracting and storing the minimum amplitude of the air luminescence signal (background) at the time the x-ray intensity is reached radiation of maximum value, actuator 8.

 The luminescence signal processing system 5 comprises a unit 9 for recording the amplitude of the attenuation signal of the long-term mineral luminescence component, a comparison unit 10, an automatic control system (CAP) 11, a separation threshold adjuster 12 and a separation level adjuster 13, the unit for recording the amplitude of the attenuation signal of the decay signal of the long-term mineral luminescence component the output is connected to the first input of the comparison unit 10, the third input is connected to the output of the CAP 11, and the second input of the comparison unit 10 is connected to the output of the setpoint 12 of the separation threshold. The output level separator 13 is connected to the second input of the CAP 11.

 The photodetector 4 is connected to the first inputs of the unit 7 for extracting and storing the minimum amplitude of the air luminescence signal (background) and the luminescence signal processing system 5 (the first input of the unit for recording the amplitude of the attenuation signal 9 of the continuous mineral luminescence component).

 Block 6 synchronization output connected to the input of the source 3 of the pulsed x-ray radiation and the second inputs of the system 5 for processing luminescence signals (second input of the unit 9 for recording the amplitude of the attenuation signal of the long component of the luminescence of the mineral) and block 7 for extracting and storing the minimum amplitude of the luminescence signal of air (background), output which is connected to the third input of the luminescence signal processing system 5, which is the first input of the CAP 11.

 The actuator 8 is connected by an input to the output of the luminescence signal processing system 5, which is the output of the comparison unit 10.

 Photodetector 4 is made on the basis of a PMT - 85 photomultiplier tube and 140 series microcircuits.

 The luminescence signal processing system 5 is implemented on microcircuits 140 and 176 series.

 Block 6 synchronization is made on chips of the 176 series.

 Block 7 selection and storage of the minimum amplitude of the luminescence signal of the air (background) is made on the microcircuit 140 series.

 The device operates as follows.

 During operation, the device under the action of pulses of x-ray radiation generated by the source 3 of the pulsed x-ray radiation, luminesces the air volume in the irradiation and registration zone and the minerals that are in the irradiation and registration zone. The photodetector 4 converts the light signals into electric ones, which are fed to the first input of the amplitude recording unit 9 of the attenuation signal of the long-term component of the mineral luminescence (first input of the luminescence signal processing system 5) and the first input of the unit 7 for extracting and storing the minimum amplitude of the air luminescence signal (background).

 Under the control of synchronization unit 6, the total luminescence signals of air (background) and mineral that occur when the x-ray radiation intensity reaches its maximum value are analyzed by block 7 for extracting and storing the minimum amplitude of the luminescence signal of air (background), i.e., from the entire sequence of signals arriving at its input, the minimum signal is selected corresponding to the luminescence of the air volume (background) in the irradiation and registration zone (since when the luminescent mineral is in the zone of teaching and recording the total air luminescence signal (background) and mineral will always be more than just air luminescence signal (background) regardless of mineral luminescent properties: luminescence amplitude, fast availability and / or prolonged luminescence components, time constant and damping buildup).

 The selected signal is stored and from the output of the block 7 for extracting and storing the minimum amplitude of the air luminescence signal (background) is fed to the first input of CAP 11 (third input of the luminescence signal processing system 5), the second input of which receives a signal from the splitter 13. The signals supplied to the first and second inputs of CAP 11 generate a signal that controls the maintenance of the specified separation level, which is fed to the third input of the amplitude recording unit 9 of the attenuation signal of the long-term mineral luminescence component and controls the electronic gain control of the amplification unit of the 9 recording of the attenuation signal of the attenuation signal of the long-term component mineral luminescence (luminescence signal processing system 5).

 At the end of the x-ray pulse, the synchronization unit 6 provides a signal to the second input of the amplitude recording unit 9 of the attenuation signal of the long-term mineral luminescence component (second input of the luminescence signal processing system 5), which performs the necessary processing of the amplitude of the decay signal of the long-term mineral luminescence component. From the output of the unit 9 for recording the amplitude of the attenuation signal of the long-term component of the luminescence of the mineral, the processed signal is fed to the first input of the comparison unit 10, the second input of which receives a signal from the setpoint 12 of the separation threshold. If the amplitude of the attenuation signal of the long-term mineral luminescence component of a given threshold is exceeded, the comparison unit 10 (output of the luminescence signal processing system 5) issues a command to the actuator 8 to cut off the useful mineral at the moment when the useful mineral reaches the cut-off zone.

Claims (1)

 The method of mineral separation, which consists in pulsed excitation of the luminescence of minerals and air, recording the amplitude of the total luminescence signal of the mineral and air, recording the amplitude of the decay signal of the long-term component of the luminescence of the mineral after a time corresponding to the minimum value of the decay time of the luminescence signal of the useful mineral, setting the separation threshold in amplitude attenuation signal of the long-term luminescence component of a useful mineral, comparing the signal amplitude the attenuation of the long-term component of the luminescence of the mineral, registered after a time corresponding to the minimum value of the decay time constant of the luminescence signal of the useful mineral with a given threshold and the allocation of the useful mineral according to the comparison results, characterized in that the current value of the amplitude of the total luminescence signal of the mineral and air is recorded at the moment of reaching X-ray intensities of the maximum value and directly in the process of separation from sequences of signals isolate and store the minimum amplitude of the luminescence signal corresponding to the luminescence of air, use the amplitude of the minimum signal to stabilize the separation level.