RU2234383C1 - Method and device for separating diamond containing materials - Google Patents

Abstract

FIELD: separating solids from solids.

SUBSTANCE: method includes supplying material with a constant velocity to the zone of irradiation and recording of a constant width, irradiation of material with penetrating radiation, recording current amplitude of the luminescence signal, comparing the current signal amplitude with a given limit amplitude, generating the signal for the mineral shut off at a moment when the current amplitude begins to exceed the limit one, and separating the luminescent mineral used the results of the comparison. The device has hopper, transporting mechanism, source of penetrating radiation, unit for recording current amplitude of the luminescence signal from the mineral whose output is connected with the first input of the block of comparison, second input is connected with the output of the limit amplitude signal controller, and output is connected with the block for generating commands, whose output is connected to a servomechanism. The block for generating commands has pulse generator whose output is in communication with the second input of the shift register, whose first input is the input of the block for generating commands. The block for generating commands is additionally provided with the second pulse generator whose output is connected with the second input of the counter whose first input is connected with the outlet of the shift register and whose output, which is the output of the block for generating commands, is in communication with the third input of the counter .

EFFECT: enhanced efficiency of separating.

2 cl, 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 diamond-containing materials containing luminescent minerals.

A known method of separation of minerals, including supplying minerals to the exciting radiation zone at a constant speed, irradiating minerals with penetrating radiation, recording the current amplitude of the mineral luminescence signal, setting a threshold amplitude of the luminescence signal of a useful mineral, comparing the current amplitude of the mineral luminescence signal with a given threshold amplitude value, separating the luminescent mineral according to the result of comparison with the generated signal of constant duration (RF patent No. 2066244, IPC ⁶ V 07 C 5/342, 1996, BI No. 25).

A device for separating minerals is known, which contains a hopper, a transporting mechanism, a source of penetrating radiation, a unit for recording the current amplitude of the mineral luminescence signal, connected to the first input of the comparison unit, the second input of which is connected to the output of the threshold amplitude luminescence signal of the useful mineral, and the output is connected to a command generation unit connected to an actuator (RF patent No. 2066244, IPC ⁶ V 07 C 5/342, 1996, BI No. 25).

A disadvantage of the known method and device is the low separation efficiency due to omissions of luminescent minerals due to the lack of technological methods and means for recording the luminescence signal from each luminescent mineral at an increased frequency of their passage through the irradiation and registration zone, as well as the separation of each luminescent useful mineral.

A known method of separation of mineral raw materials, including feeding material at a constant speed into the irradiation zone and recording a constant width, irradiating the material with penetrating radiation, recording the current amplitude of the mineral luminescence signal, setting the threshold amplitude of the luminescence signal of a useful mineral, comparing the current amplitude of the luminescence signal of the mineral at the moment of luminescent input mineral into the zone of exciting radiation and its exit from this zone with a given threshold value of the amplitude, formation at the moment the luminescent mineral enters the irradiation zone and the control signal is recorded to the useful mineral cutoff of constant duration, determined depending on the maximum size of the useful mineral and the “dispersion” of its speed through the irradiation and registration zone, separation of the useful luminescent mineral according to the result of comparison with the generated constant signal duration (RF patent No. 2101101, IPC ⁶ V 07 C 5/342, 1998, BI No. 1, prototype).

A device for separating mineral raw materials is known, containing a hopper, a transporting mechanism, a source of penetrating radiation, a unit for recording the current amplitude of the mineral luminescence signal, connected to the third input of the comparison unit and the input of the mineral spatial spatial determination unit, the output of which is connected to the gating unit, the output of which is connected with the second input of the comparison unit, the first input of which is connected to the output of the threshold amplitude luminescence signal of the useful miner ala, and the output is connected to the unit for generating and generating commands, the output connected to the actuator (RF patent No. 2101101, IPC ⁶ 07 07 5/342, 1998, BI No. 1, prototype).

However, the known method and device partially eliminate the disadvantages indicated in criticizing the analogue, i.e. there are technological methods and means for recording the leading edge of the amplitude of the luminescence signal at the moment the luminescent mineral enters the irradiation and registration zone, and when the luminescent mineral leaves the irradiation zone and recording, the trailing edge of the luminescence signal is recorded.

However, with a high content of luminescent minerals in the separator feed and a fixed output, their repetition rate increases and the time between signals from luminescent minerals decreases. With a further increase in the repetition rate, the signals from the luminescent minerals “merge” so much that the moment the mineral enters the excitation zone and its registration and exit from this zone disappear, and the signals begin to be perceived as one signal from an oversized luminescent mineral. Thus, if the mineral repetition rate exceeds a critical value, then “gaps” will disappear between the luminescence signals and the ability to determine the moments of entry and exit of luminescent minerals into the irradiation and registration zone will disappear. And since the signals from the brightly luminescent minerals causing the amplifier of the recording path overload are equal to the voltage of the amplifier’s power supply, when they “merge”, a signal will be present at the amplifier’s output, the amplitude of which is equal to the voltage of the power source, and the duration is the sum of the durations from the luminescence signals that caused amplifier overload. Usually, minerals of different sizes are present in the separator's feed, and it is not possible to determine how many luminescent minerals passed through the irradiation and registration zone. Given that the prototype device generates control signals for cutting off a useful mineral by an actuator of constant duration only when a moment is detected when the luminescent mineral enters the irradiation and registration zone, only the first and those luminescent minerals will be detected and cut off, the signals from which have distinct entry moments mineral in the zone of excitation and registration. In this case, all other luminescent minerals that caused an overload of the recording path amplifier, but passed through the irradiation and registration zone so close to each other that there are no “dips” on the signal indicating the moments of entry and exit, will be lost, i.e. go to the tails.

The increased yield of the concentrate is due to the fact that the control signal for separating the useful mineral has a fixed duration necessary to separate the useful mineral of maximum size, taking into account the possible dispersion of its speed through the irradiation and registration zone. When separating a useful mineral of a minimum size due to the increased cut-off time, grains of associated minerals are simultaneously cut off, which increases the yield of concentrate.

The technical result of the invention is to increase the separation efficiency by increasing the recovery of the useful mineral at any frequency through the irradiation and registration zone and reducing the yield of associated minerals in the concentrate by generating recording and control signals to separate the useful mineral depending on the duration of the luminescence signals of the minerals simultaneously moving through irradiation and registration area.

The technical result is achieved by the method of separation of diamond-containing material, including feeding the material at a constant speed into the irradiation zone and recording a constant width, irradiating the material with penetrating radiation, recording the current amplitude of the mineral luminescence signal, setting the threshold amplitude of the luminescence signal of a useful mineral, comparing the current amplitude of the mineral luminescence signal with a given mineral threshold amplitude, generating a useful mineral cutoff signal when current amplitudes are exceeded a mineral luminescence signal of a predetermined threshold amplitude of a useful mineral luminescence signal and separating a luminescent mineral according to a comparison result in which a current amplitude of a mineral luminescence signal and a comparison of a current amplitude of a mineral luminescence signal with a predetermined threshold amplitude of a mineral luminescence signal of a useful mineral are recorded continuously during the luminescence propagation time irradiation and registration, form a cut-off signal and separate the useful lumin the ascending mineral according to the result of comparison over a time selected in proportion to the time the luminescent mineral passes through the irradiation and registration zones.

The technical result is achieved by a device for the separation of diamond-containing material, containing a hopper, a transport mechanism, a source of penetrating radiation, a unit for recording the current amplitude of the mineral luminescence signal, connected to the first input of the comparison unit, the second input of which is connected to the output of the threshold amplitude luminescence signal of the useful mineral, and the output is connected to the input of the unit for generating and generating commands, the output of which is connected to the actuator, while the block generation and generation of commands contains a pulse generator, the output connected to the second input of the shift register, the first input of which is the input of the unit for generating and generating commands, which additionally contains a second pulse generator, the output connected to the second input of the counter, the first input of which is connected to the output of the shift register, and the output, which is the output of the unit for generating and generating commands, is connected to the third input of the counter.

The method is as follows.

A diamond-containing material containing luminescent minerals of size d (mm) with a constant speed V (m / s) is fed into the irradiation zone and recording a constant width L (mm).

Under the action of x-ray radiation, the mineral begins to luminesce at the moment of entering the irradiation and registration zone, during the passage of the irradiation and registration zone and when leaving the irradiation and registration zone. Throughout this period of time, the current amplitude of the mineral luminescence signal is continuously recorded.

The magnitude of the amplitude of the luminescence signal of a useful mineral is determined by the voltage of the reference voltage source, which is set in proportion to the intensity of the source of penetrating radiation. The duration of the luminescence signal of a useful mineral crossing the irradiation and registration zone is determined by the time it spent in this zone, which is determined by the formula:

t = (L + 2 × d) V.

The duration of the cutoff signal (cutoff time) of the luminescent useful mineral is determined by the time spent by the luminescent mineral in the irradiation and registration zone. It follows that with a constant width of the irradiation and registration zone and a constant velocity of the mineral moving, the duration of the mineral luminescence signal, the duration of the cutoff signal (cutoff time) are proportional to its size.

If the luminescent minerals repetition rate is so high that the second and subsequent luminescent minerals begin to enter the irradiation and registration zone at the moment when the previous luminescent mineral has not left the irradiation and registration zone, then in this case the signal from the luminescent minerals will be recorded as the total signal from several luminescent minerals that simultaneously find themselves in the irradiation and registration zone, i.e. in proportion to the total size of these minerals. Thus, by recording the current amplitude of the luminescence signal from one or more luminescent useful minerals continuously during the time they pass through the irradiation and registration zones, effective detection of a useful mineral of any size, both weakly luminescent and bright luminescent, is achieved.

Signal generation to the cut-off and to the separation of the useful mineral depending on the time the luminescent mineral passes through the irradiation and registration zones, i.e. proportionally to the time that the luminescent mineral passes through the irradiation and registration zone, which corresponds to the duration of the luminescence signal (the latter is proportional to the size of one mineral or to the total size of luminescent minerals that simultaneously entered the irradiation and registration zone), it allows reducing the yield of accompanying minerals to the concentrate at a high frequency of their passage through the irradiation zone registration.

The device shown in the drawing contains a hopper 1, a transport mechanism 2, designed to move at a constant speed the diamond-containing material through the irradiation zone and register a constant width, a source of penetrating radiation 3, a unit 4 for recording the current amplitude of the mineral luminescence signal, a comparison unit 5, a setter 6 threshold amplitude of the luminescence signal of a useful mineral, block 7 for generating and generating commands for cutting off a useful mineral, actuator 8. Moreover, the output of block 4 reg the stratum is connected to the second input of the comparison unit 5, the first input of which is connected to the output of the threshold amplitude setter 6. The output of the comparison unit 5 is connected to the input of the unit 7 of the formation and generation of commands, the output of which is connected to the actuator 8.

Block 4 recording the current amplitude of the luminescence signal of the mineral contains a series-connected photoelectronic multiplier (FEU-85) and an operational amplifier (140th series), the output of which is the output of block 4.

Comparison unit 5 contains an operational amplifier (140th series) and is intended to compare the current amplitude of the mineral luminescence signal with a given threshold amplitude of the luminescence signal of a useful mineral.

The adjuster 6 of the threshold amplitude of the luminescence signal of the useful mineral contains a reference voltage source, the voltage of which is set in proportion to the intensity of the penetrating radiation source.

Block 7 of the formation and generation of commands is designed to generate the duration of the signal for cutting off the useful mineral and issuing a command to the actuator 8 (electromechanical shutoff) to cut off the useful mineral, contains a shift register 9, a counter 10 and two pulse generators 11 and 12. The first "information "the input of the shift register 9, which is the input of the unit 7 for generating and generating commands, is connected to the output of the comparison unit 5. The second "clock input" of the shift register 9 is connected to the output of the first pulse generator 11, and the output is connected to the first input of the "zeroing" counter 10, the second "counting" input of which is connected to the output of the second pulse generator 12, and the output, which is the output of block 7 formation and generation of commands, connected to the third input of the "resolution of the account" of the counter 10 and with the actuator 8.

The device operates as follows.

When the material enters the irradiation and registration zone, it enters the stream of penetrating radiation of source 3 and the luminescent minerals begin to luminesce. The registration unit 4 continuously during the time the luminescent mineral passes through the irradiation and registration zone registers and outputs the current amplitude of the mineral luminescence signal to the second input of the comparison unit 5, the first input of which receives a signal from the output unit 6 of the threshold amplitude of the luminescence signal of the useful mineral, proportional to the intensity of the penetrating radiation source 3. Block 5 comparison continuously during the passage of time by the luminescent mineral of the irradiation zone and registration compares the current amplitude of the mineral luminescence signal with a predetermined threshold amplitude of the setter 6. When the amplitude of the mineral luminescence signal of a predetermined threshold amplitude is exceeded, the comparison unit 5 generates a logical "unit" signal at the first "information" input of the shift register 9 (input of the unit 7 for generating and generating commands), duration which is determined by the time the luminescent mineral passes through the irradiation and registration zones. A signal from the first pulse generator 11 is supplied to the second “sync input” of the shift register 9, through which the signal of the logical “unit” from the comparison unit 5 is recorded in the first bit of the shift register 9. With each pulse of the first generator 11, the signal of the logical "unit" alternately passes through all the bits and goes to the output of the shift register 9. The signal of a logical “unit”, the duration of which is determined by the time the luminescent mineral passes through the irradiation and registration zone, from the output of the shift register 9 is fed to the first input of the “zero” counter 10 and sets it to “zero” when the luminescent mineral arrives in the cutoff zone. From the output of counter 10 (output of block 7 of the formation and generation of commands), a zero level signal is supplied to the third input of counter 10, removes the "prohibition of counting", drives and holds the actuator 8 in the cut-off state of the luminescent mineral for a time equal to the time that the luminescent mineral passes through the zone exposure and registration. At the end of the signal of the logical "unit" at the output of the shift register 9, a logical "zero" signal appears, which is fed to the first input of the "setting to zero" of the counter 10. The counter 10 starts to count the pulses of the second generator 12, arriving at its second input. After the time required for the cutoff of the luminescent mineral of the minimum size, determined depending on the width of the irradiation zone and registration, the speed of movement of the material and the time the actuator 8 was set to the cutoff state, a logical “unit” signal appears at the output of the counter 10, which is fed to the third the input of the "resolution of the count" of the counter 10, prohibits counting and returns the actuator 8 to its initial state - the luminescent mineral is cut off into the concentrate and the cutoff cycle is completed.

Thus, when using the proposed method and device for the separation of diamond-containing material containing luminescent minerals of various sizes and with different luminescent characteristics, the separation efficiency is increased (the extraction of useful mineral increases and the yield of associated minerals in the concentrate decreases) by matching the time of recording the current amplitude of the luminescence signal useful mineral with the passage time of the luminescent mineral of the irradiation zone and registration and, establishing the time for the formation of the cutoff time depending on the time the luminescent mineral passes through the irradiation and registration zones, which characterizes its size.

Claims (2)

1. A method for separating diamond-containing material, including feeding the material at a constant speed into the irradiation zone and recording a constant width, irradiating the material with penetrating radiation, recording the current amplitude of the mineral luminescence signal, setting the threshold amplitude of the luminescence signal of a useful mineral, comparing the current amplitude of the mineral luminescence signal with a given threshold amplitude, the formation of the cut-off signal of a useful mineral when exceeding the current amplitude of the mineral luminescence signal for of the threshold amplitude of the luminescence signal of the useful mineral and the separation of the luminescent mineral according to the comparison result, characterized in that the current amplitude of the luminescence signal of the mineral is recorded and the current amplitude of the luminescence signal of the mineral is compared with a given threshold amplitude of the luminescence signal of the useful mineral continuously during the passage of the luminescent and luminescent mineral zone registration, form a cutoff signal and separate the useful luminescent mineral according to the result of avneniya for a time proportional to the propagation time selectable luminescent mineral irradiation and detection area. 2. A device for separating diamond-containing material, containing a hopper, a transport mechanism, a source of penetrating radiation, a unit for recording the current amplitude of the mineral luminescence signal, connected to the first input of the comparison unit, the second input of which is connected to the output of the threshold amplitude luminescence signal of the useful mineral, and the output connected to the unit for generating and generating commands, the output of which is connected to the actuator, while the unit for generating and generating commands contains a pulse generator, with an output connected to the second input of the shift register, the first input of which is an input of the unit for generating and generating commands, characterized in that the unit for generating and generating commands additionally contains a second pulse generator, with an output connected to the second input of the counter, the first input of which is connected to the output shift register, and the output, which is the output of the unit forming and generating commands, is connected to the third input of the counter.