SU1690845A1 - Ore sorting unit - Google Patents

Abstract

This invention relates to the separation and sorting of solid bulk materials. t T ////////////// 12 U 7777777777777777777777777777 7 30 FiV.2 The goal is to improve the quality of sorting The installation contains a bunker 1 and consistently installed vibratory feeders 2.5 in the form of endless tapes, a transporting device (P ) 13, a screening unit P, a separation unit with a detector unit 23 and an actuator 24 and P for removing sludge. Sifting N made in the form of installed console on adjacent tapes between them and between the conveyor P and the adjacent tape cantilever them wedge-shaped grates (K) 7.9 and 11.12. C 7.9 (11,12) between tape 2 (5) and transporting P 13 are installed. On the latter, chutes 15-18 are installed to receive and transport the appropriate size class to the area of the separation unit. The gutters 15-18 are narrowed down to unloading 1 L 00 N (L

Description

In this case, the П for removal of sludge is made with П for dewatering and is located on the chute 15 of the minimum size class. The chute 18 for the grating product is made with a damper located in its middle part. The separation unit has a stabilizing P 22, Moving along vibro tape 2, the mountain mass enters K 7 and 9, where a partial separation of the sludge takes place. Then the raw material moves along vibro tape 5, where it aggregates. With this K 7

and 9 oscillate with the same amplitude but different frequency. The fine fraction, separated, enters chute 15. Thereafter, the raw material enters K 11 and 12, which oscillate in vertical and horizontal directions, respectively, with different amplitudes and frequencies. The raw materials divided by K 1V and 12 enter the channels 16–18 and flow through them into the analysis zone, where the actuator 24 is divided into ore and rock. 3 il.

The invention relates to the technique of separation and sorting of solid and bulk materials, as well as the separation and pre-enrichment of mineral raw materials from mining production.

The purpose of the invention is to improve the quality of sorting,

FIG. 1 shows the installation, top view; in fig. 2 - the same, side view; in fig. 3 is a block diagram of a radiometer;

The ore-sorting installation contains a hopper 1, under which a vibrating feeder 2 is installed with a vibrating actuator 3 having a variable disturbing force and a low amplitude of oscillations. On frame A, located at an angle to the horizon, which is chosen depending on performance B, depending on the type of raw material being processed, a screening device is installed - the upper classifier. The top classifier is made in two stages and consists of a vibrating feeder 2 with a vibration amplifier 3 and a feeder 5, which , like feeder 2, is a vibro tape with vibrator b, identical to vibrator 3. At the end of the first vibro tape 2, wedge-shaped grate 7, stepping over vibrolentoy 2 and vypopnennye as irregular pyramid. Between the grate bars 7 installed kerchiefs 8 prismatic shape. ND one level with vibroengine 2, a vibrating feeder 5 is installed, made in the vibration mills, on which the grate 9 is installed. They are wedge-shaped and protrude above the vibroentor, cantilever I are attached to the flexible side 5 with a narrow part. Wide

a part of the grill, which goes under the strip V located on the vibro-tape 2, the grate 7 and 9, which are located in this way, form the first stage 10 of the upper classifier. The classifying surface of the first stage 10 of the upper classifier is formed by the edges of the grates 7 and 9.

At the end of the vibroment 5, grate 11 also cantileverly mounted, which, with the grate 12 mounted on the transporting device 13, form the second stage 14 of the first classifier, also dividing the raw material by

fractions, the shape of the grate 11 and 12 is identical to the shape of the grate 7 and 9, but the edges of the grate 11 and 12 are 5-10 times longer, which expands the range of raw material classification. Grate 12 mounted on

The transport device 13 is of the type of a tavrovaya beam (bases). Under the grate bars 11 and 12, forming the second stage 14 of the first classifier, grooves 15-17 are installed to receive and transport to the fraction analysis zone of the corresponding size class.

The number of grooves is chosen depending on the required classification scale and performance. Gutter 18

The plus fraction (head of the product) is located immediately and below the second stage 14 of the first classifier, depending on the size class of the raw material. Installed on chute 18

damping device 19, made in the form of a scarf, the sides of which are attached to the side gutter 18, and the top is facing toward the grate 31 and 12. On the trough

15, a device 20 for dewatering and removing sludge is installed. The chutes 16 and 17 are mounted on the transport device 13, their bottom 21 is made with an accelerating profile narrowing towards unloading. The gutters 15-18 are terminated with a separation unit according to the mineral composition of the resulting size classes. The separation unit contains a stabilizing device 22. A step a and b, interconnected by plates c. Stage a is a guideline on which the ore lumps (portions) are surveyed, which falls within the visibility range of the detector 23 located above step a, and step o is also a damper for ore lumps (portions) of the stabilizing device 22, B the separation unit also includes the detector unit 23 and the actuator 24. It is possible to install the detector unit 23 under the chute 18 or install several detector blocks 23 both above and below the chutes for a more complete view of the ore. So, in this case, the blocks of the detector 23 with the radiator are installed above the step a and below it in the gap between the plates c, and the actuator 24 is installed between the powers a and b also in the gap between the plates c, but below the detector 23 and above the damper b.

The separation unit can also be designed as a gutter 18 having a damping device 19, but not having a stabilizing device. The actuator 24 may be made of any known modification (for example, an electropneumatic valve).

The analysis zone in which the separation unit is located is enclosed in a leaded metal casing (not shown).

The transport device 13 has a vibrator 25 with an electric motor 26 and a tensioner 27. A receiving tank 28 is installed under the chute 15. A receiving tank 29, made in the form of a funnel, is installed under the collars 7 and 9, which form the first degree 10 of the upper classifier. Pipes 30 and 31 are connected to tanks 28 and 29. The installation is equipped with irrigators 32 and a control panel 33 with a radiometer 34. The frame 4 is installed at one end on the foundation 35, and the other on the lift 36.

The installation can be placed on a moving platform and be self-powered, which ensures its mobility.

The radiometer 34 consists of a detector unit 23, the output of which is connected to a pulse analyzer A. One of the outputs

the pulse analyzer A is connected to the threshold circuit B, the other outputs with counting blocks are scattered B and the characteristic G radiation, the output of which, in turn, is connected to one of the inputs of the comparison circuit. The output of the comparison circuit D is connected to the device forming the E of the executing pulse. The control unit consists of a control unit for calculating blocks and a device for forming an executing mechanism. One of the inputs of the shaping device E of the executing pulse is connected to the threshold circuit B, one input of which is connected to a generator of 3 clock pulses, and the output to one of the inputs of the control device F to the counting blocks, the second input of which is connected to the output of the counting block B of scattered radiation . The output of the shaping device E of the executing pulse is connected to one of the inputs of the control unit AND the executing mechanism, the output of which is connected by the direct executing mechanism 24. One of the inputs of the storage device K is connected to the counting unit G of the characteristic radiation, and the output is connected to one of the circuit inputs D. Comparison. One of its outputs is connected to the input of a recording device L and a reader, one of the outputs of which is connected to a memory device K, and the other to a device forming an E performing pulse. .

Ore-sorting plant operates as follows.

Claims (1)

Consider the option when the installation is located in an underground mine under ore release. The hearth is beaten off, without separation into fractions, enters the bunker 1, it is irrigated by sprinklers 32 located above the bunker 1. The horn, moving along vibrolent 2 driven by the movement of the booster 3, enters the first stage 10 of the upper classifier, where partial sludge separation occurs, entering the bunker 29. Next, the raw material, moving along the vibroent 5, driven by the booster 6, is irrigated with the sprinkler 32, located above the vibroentent 5. On the vibrating broom 5, the raw material segregates due to vibration and is washed off, the grate 7 gets into the drag force from the vibratory drivers 3, and the grate 9 from the vibration drivers 6, which give them vibrations with the same amplitude but different frequency. First of all, the small fraction is separated from the sludge and water, which enters the chute 15, where it is dehydrated and separated from shlgma. The raw material is then fed to the second stage 14 of the first classifier, which is formed by the grate 11 and 12. The grate 11 receives disturbing force from vibration generator 6, which gives them oscillations with low amplitude and high frequency in the vertical direction, and the grate 12 receives disturbing force from driver 25 through a vibrating feeder 13 in the horizontal direction with an amplitude greater, and less in frequency than that of the grates 11. Such constructive implementation of the second stage 14 of the first classifier provides a more complete and definitive classification of raw materials. Raw materials, divided into size classes, enters the chutes 1, 17 and 18 of the respective size classes. Next, the feedstocks on the chutes 16-16, having a bottom, made with an accelerating profile, under the action of vibration, due to the presence of the feeder 13 and the booster 25, enter the analysis zone, where the radiometer 34 performs an express determination of the content of the valuable component and compare it with the reference . When registering more content than the reference, the actuator 24 separates the raw materials into ore and rock. Claims Ore-sorting plant, including a bunker, installed sequentially, And I 5 32 v 20 W The vibrating feeders and the transporting device, the sifting device, the device for removing sludge, the separation unit with the detector unit and the actuating mechanism, are characterized in that, in order to improve the quality of sorting, the vibrating feeders are made in the form of endless ribbons, screening devices are made in the form of mounted cantilevers on adjacent belts between them and between the transporting device and the adjacent belt cantilever grates are cantilever on them, while under the grate bars installed between the belt and the transporting device, on the latter, channels are installed for receiving and transporting of the size of the unit to the area of the separation unit, made tapering to unloading, the sludge removal device is made with a dewatering device and located on the groove of the minimum size class, the groove for the nodule has a damper located in its middle part, and the separation unit is made with a stabilizing fixture. / W / and N // 777 Fig. / FIG. 3