SU971523A1 - Lumeniscent separator - Google Patents

Description

(54) LUMINESCENT SEPARATOR

Claims (1)

The invention relates to the sorting of materials and can be used for luminescent separation of materials. A luminescent separator is known, which includes a feeder, a transport mechanism, a system for pulsed luminescence excitation, a photodetector associated with the first inputs of the background level memory and the mineral luminescence signal processing system, the output of which is connected to the actuators 1. The disadvantage of this separator is the omission of useful minerals because of the low accuracy of the background level measurement, the value of which determines the magnitude of the separation threshold for the mineral luminescence signals, due to the frequent coincidence of the background radiation signals and the mineral luminescence. The aim of the invention is to increase the yield of the useful component. This goal is achieved in that a luminescent separator comprising a feeder, a transport mechanism, a pulsed luminescence excitation system, a photo detector, associated with the first inputs of the background level memory and a mineral luminescence signal processing system, the output of which is connected to actuators, according to the invention are entered a unit for storing the level of luminescence signals of minerals, an adder and a synchronization unit, the input of which is connected to the output of a pulse excitation system, is first This output is connected to the second input of the mineral luminescence signal processing system, the second output is connected to the second input of the background level memory, the third output is to the first input of the mineral level luminescence memory, the second input of which is connected to the photoelectric receiver, and the output to the adder's input, the second the input of which is connected with the output of the block for storing the background level, and the output with the third input of the mineral luminescence signal processing system. FIG. 1 schematically shows a luminescent separator; in fig. Figure 2 shows the reaction of air and minerals in the excitation zone, the separator contains a photodetector 1; synchronization unit 2; background level storing unit 2; unit 4 for memorizing the luminescence level of minerals; system 5 processing the luminescence signals of minerals; adder 6; pulsed excitation system 7; actuators 8 In the drawing, the following notation is used: 9 — X-ray impulse; 10 - impulse luminescence of minerals; 11- air luminescence pulse; 12- pulse of the light sum of luminescence of minerals and air; T is the pulse duration; X-ray radiation; Tp is the duration of the impulse1:, sa permission to memorize the background level; t is the resolution pulse duration for memorizing the maximum luminescence level of minerals; T, is the pulse duration for processing the luminescence signals; i is the beginning of the x-ray pulse; to is the end of the x-ray pulse; q is the level of background radiation produced by the luminescence of air; B is the maximum luminescence level of minerals. The separator works as follows. Under the action of a pulse 9 created by system 7, the luminescence of air is excited in the form of a pulse 11, creating a background luminous flux, and simultaneously the luminescence of minerals. Due to the inertia of this process, the intensity of the pulse 11 takes the steady-state value a from the beginning of the -fc pulse 9, and the intensity of the pulse 10 increases taking into account the constant ignition time and takes the maximum value of b at the end of t. pulse 9. The photodetector 1 converts the light signal into an electrical pulse and supplies it to the first inputs of block 3 of system 5 and the second input of block 4. 4 Block 2, triggered by system 7, generates a pulse of duration T, resolution to memorize the background level and feeds it to 2 block 3 at the time immediately preceding the end of the excitation pulse. Block 3 remembers the total signal a + b of the luminescence of air and minerals and feeds it to one of the inputs of the adder 6. At the end of the excitation pulse, the luminescence signal of the minerals fades out, and Block 2 generates a pulse of duration Cj resolution by | , memorizing the maximum luminescence level of the minerals and feeds it to the input 1 of block 4 immediately after the end of the excitation pulse t. Block 4 memorizes the maximum value of the L level of luminescence of minerals and feeds it to another input of the adder 6. After subtracting the signal b from the total signal a + b, the output of the background level, caused only by air luminescence, is output from the output of the adders 6. The selected signal q is fed to the input 3 of the system 5. The block 2 at the end of a pulse of duration t produces a pulse of duration T. permission to process the luminescence signals of minerals and feeds it to the input 2 of system 5, at one of the outputs a, b, with which the processing These signals generate a signal to trigger the corresponding mechanism 8. Thus, the threshold for separating the luminescence signals depends only on the intensity of the luminescence of the air and the sensitivity of the photodetector and does not depend on the manufacturer oc ™ separation and the amount of luminescing x ™ products in the ore, which increases the useful component output. The formula of the invention. Neither a luminescent separator including a feeder, a transporting mechanism, a pulsed luminescence excitation system, a photodetector associated with the first inputs of the background level memory and signal processing system, mineral luminescence, the output of which is connected to the actuators are distinguished from. The fact is that, in order to determine the yield of the useful component, a block for storing the level of luminescence signals of minerals was introduced into it, the accumulator and synchronization unit, whose input is connected to the output of the impulse excitation system, the first output is connected to the second input of the signal processing system, mineral luminescence, the second 5 output - to the second input of the background level memory, the third output - to the first input of the memory block the luminescence level of minerals, the second input of which is connected to the photodetector, and the output - to 10 the first input of the adder, the second input of which is connected with the output of the background level memory, and the output with the third input of the mineral luminescence signal processing system. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 544195, cl. On 03/13/06, 1975.