SU452370A1 - Device for sorting lumpy mineral raw materials - Google Patents

Description

one

This invention relates to devices for sorting bulk minerals.

A device for sorting lumpy mineral raw materials is known, which contains a feeder for the subaround supply of sorted raw materials, an optical chamber with photometric analysis units, a control and separation device.

A disadvantage of the known device is the execution of the analyzing apparatus only in the form of photometric analysis blocks, which leads to a poor quality of sorting of ore mineral raw materials.

The invention eliminates the above disadvantages by using self-oscillating sensors in it.

In order to improve the quality of sorting and expansion of varieties of the sorted raw material, it is equipped with self-generating

sensors electrically connected to the input of the control device.

The invention is illustrated in the drawing.

The device contains a feeder, including a receiving hopper 1, vibrating chute 2 s

a vibrator 3 and a profiled belt conveyor 4 with an electric drive 5. The reflector 6 is installed behind the discharge end of the conveyor 4 for guiding the pieces of material vertically downward to the control zones of the sensors. Self-oscillating sensors for monitoring the electrical properties of the sorted material are installed in series along the material path along the height below the reflector 6. The auto-oscillating sensors contain overhead coils 7, 8 of inductance included in the oscillator circuit 9, 1О, harmonic oscillations and filters 11, 12 frequencies, transparent for the frequency spectrum of the output control signals and non-permeable vibration frequencies generated by oscillators 9, 1О

The optical camera 13 is located below the autogenerating sensors, in its erases, three photometric analysis units are mounted on the same level symmetrically with respect to the camera axis, including light sources 14 and photometric sensors .15, a control unit designed to evaluate the amplitude signals of the sensors and generate control commands that drive operating the separating device and including the amplitude selectors 16, the inputs of which are connected to the sensors 15, and the output from the inputs of the logic circuit 17 of type I and the amplitude selectors 18, 19, the inputs of which are connected to the inputs of the circuit 17 of type Or, via a time delay device 20,21 providing signals from self-oscillating sensors, are fed into the circuit Or simultaneously with the signals of photoelectric sensors. The separating device is made in the form of an electro-pneumatic valve 22 installed under the optical camera 13 connected to. the source 23 is compressed Air and electrically connected through the power amplifier 24 to the single vibrator 25 connected to the output of the logic circuit 17, the solenoid 22 being delayed to operate equal to the transit time of a separate piece of material from the control zone of the sensors 15 to its zone of operation the one-shot 25 is designed to provide a given g; The openness of its open state, providing portions of compressed air sufficient to discard the sorted pieces. Bins 26, 27 are designed to collect sorting products. The device works as follows. The material to be sorted — lump mineral raw materials — is loaded into a bunker, from where it is fed by vibrating chute 2 to trans-porter 4. Due to the profiledness of the conveyor belt 4 and the higher material transport speed than along chute 2, the pieces of material are distributed in one line at intervals. After dismounting the conveyor belt 4, each individual piece is guided by the reflector 6 vertically downwards: flies near the overhead inductance coils 7, 8, then moves in the optical chamber 13 and then, mines the electropneumatic valve 22, falls into the hopper 26 or is blown off by a compressed air jet from the electropneumatic valve 22 by the signal of the sensors into the bunker 27. During the passage of the piece in the magnetic field of the coils 7 and 8, eddy currents are induced in them, the magnetic field of which interacts with the field of the coils, as a result of which their equivalent Settings. Changes in the parameters of coils 7 and 8 are functionally related to the content in the controlled piece of components with low electrical resistivity, such as native gold or ore sulphide. minerals are converted by autogenerators 9 and 10 into an electrical signal. Through the filters 11. and 12 low frequencies, which do not allow the natural oscillators to oscillate the oscillators, the sensor signal enters the input of amplitude selectors 18 and 19, the selection threshold of which corresponds to a given signal level and, accordingly, the electrical resistance of the sorted pieces and the boundary gold, ore sulphide minerals, etc.). If the signal exceeds a predetermined level, it is delayed by time delay device 20 and 21 for a while until the piece reaches the control zone of the photoelectric sensors 15 and then enters the input of the logic circuit 17. The signal of the autogenerator sensor with a lower operating frequency carries information , the presence of large massive inclusions of components with low resistivity, which are sorted in pieces, and the sensor signal with a high operating frequency makes it possible to determine the presence of relatively small inclusions of such components. Further, when passing through the piece in the optical chamber 13, it is illuminated by the light sources 14, and the light reflected from its surface is converted by the photoelectric sensors 15 into an electrical signal whose level is proportional to the intensity of the reflected light. The presence of several sensors 15 permits each piece to be monitored simultaneously from several sides. The signals of the photoelectric sensors 15 are then fed to the inputs of the amplitude selectors 16. When a given level is exceeded, what happens when there are lighter components in the piece, such as inclusions of gangue quartz, with which Moi. It is possible to associate a useful component - gold or tin-containing material cassiterite, the signals are fed to the logic circuit 17 of the type Or simultaneously with the signals of the self-generating sensors. Thus, if the signal from at least auto-oscillating or photoelectric sensors exceeds a predetermined level, then the output of logic circuit 17 will turn on the output pulse, which is used as a control, which causes a; triggering the one-shot 25 and issuing a pulse acting upon amplification by the amplifier 24 to the electropneumatic valve 22, as a result of which the latter opens briefly. Control impulse

begins to act / when the sorted piece is in the optical chamber 13, but as a result of a slowdown, the electropneumatic valve 22 opens later and the piece has time to move to its zone of action and is thrown into the bunker 27 by a jet of compressed air.

If the sensor signals do not exceed the specified levels, then the electropneumatic valve 22 remains closed and the piece enters the hopper 26, which occurs when there are no inclusions in the piece that are light in color or low-resistance in electrical resistance.

When sorting ore, such as gold or tin, pieces of enclosing rock will fall into the bunker 26, and the ore material will be sorted into the bunker 27.

Subject invention

A device for sorting lumpy mineral raw materials, containing a feeder for the nodding of sorted raw materials,

an optical camera with photometric, analysis, control and separation devices, characterized in that, in order to improve the quality of sorting and expanding the varieties of the sorted raw material, it is equipped with autogenerator sensors electrically connected to the input of the control device. 25 df- 25 221-LJ СЭ k -p 2