CN112138860A

CN112138860A - Intelligent mineral sorting device

Info

Publication number: CN112138860A
Application number: CN202010853443.0A
Authority: CN
Inventors: 不公告发明人
Original assignee: Pei Wenping
Current assignee: Pei Wenping
Priority date: 2018-10-10
Filing date: 2018-10-10
Publication date: 2020-12-29
Also published as: CN109201306B; CN109201306A

Abstract

The invention provides an intelligent mineral sorting device which comprises a feeding mixing box, a sorting space, a pulse lifting mechanism, a first discharging mechanism and a second discharging mechanism, wherein the feeding mixing box is arranged on the top of the sorting space; the energy-saving device also comprises a spring and a buffer cushion which play a role in buffering or energy storage. The pulse lifting mechanism provides pulse lifting power by using an electromagnetic inductive principle and forms pulse water flow, so that minerals are separated according to density after being dispersed; the invention has the advantages of fine and controllable operation, small mechanical loss, wide application range, less bed layer interference, high sorting precision, low energy consumption and the like.

Description

Intelligent mineral sorting device

Technical Field

The invention relates to a mineral separation device, in particular to an intelligent mineral separation device.

Background

Mineral separation is a method for realizing separation according to mineral density difference, and plays an important role in the current mineral separation method. The mineral separation has the advantages that the ore treated by the mineral separation has wide granularity, the mineral separation can separate coarse-grained ores which cannot be separated by other mineral separation methods, the gravity separation equipment is generally relatively simple in structure and easy to manufacture, no valuable medicament is consumed in production, and meanwhile, the discharged waste tailings have little pollution to the environment.

Mineral separation equipment, called mineral separation equipment for short, is a general name of equipment which separates different minerals by utilizing specific gravity difference between the different minerals and utilizing gravity or centrifugal force and the like. Generally comprises mineral separation equipment such as a hydraulic classification box, a shaking table, a spiral chute, a jigger, a centrifugal mineral separator, a dense medium cyclone and the like. However, these mineral separation devices all adopt a traditional mechanical power mechanism, and have the disadvantages of high energy consumption, difficulty in precise control, serious part abrasion, low separation precision and the like, so that a mineral separation device adopting a novel power mechanism is urgently needed to overcome the problems.

Disclosure of Invention

The invention aims to provide an intelligent mineral sorting device which comprises a feeding mixing box, a sorting space, a pulse lifting mechanism, a first discharging mechanism and a second discharging mechanism.

The sorting space is of a cuboid container structure, a feeding port and a discharging port are formed in two ends of the sorting space in the length direction respectively, and the feeding port is connected with the feeding mixing box; the sorting space further comprises a rough sorting section close to the feeding port and a fine sorting section close to the discharging port; a first opening is formed in the bottom of the contact part of the rough selection section and the fine selection section, a second opening is further formed in the bottom between the fine selection section and the discharge hole, the first opening is connected with the first discharging mechanism, and the second opening is connected with the second discharging mechanism.

The first discharging mechanism comprises a first buoy arranged at the rough separation section, a double-row wheel discharging device and a first chute which is used for fixing and sealing the double-row wheel discharging device and used for collecting and discharging materials.

The bottom of the rough separation section and the bottom of the fine separation section are evenly provided with a plurality of rows of through holes parallel to the width direction of the separation space at equal intervals, each row of through holes comprise a plurality of through holes, two adjacent rows of through holes are arranged in a staggered mode, and the pulsation lifting mechanism is connected under each through hole.

The pulsation lifting mechanism comprises a base, a cylinder body positioned above the base, a flowmeter communicated with the upper end of the cylinder body, a first check valve with the bottom communicated with the flowmeter, an electromagnetic coil wound on the cylinder body, a control module and a power supply module; the interior of the cylinder body also comprises a reticular grid positioned at the upper end part, a permanent magnet which can move up and down freely and four vertical guide ropes, wherein one end of each vertical guide rope is fixed on the bottom of the cylinder body, and the other end of each vertical guide rope penetrates through four positioning holes formed in the permanent magnet and is fixed on the reticular grid; the lower end of the barrel is also provided with a water inlet which is sequentially connected with a second check valve and a water supply main pipe.

The pulse lifting mechanism further comprises eight grooves formed in outlets at two ends of the four positioning holes and a double-pulley mechanism embedded in the grooves.

Preferably, the feeding and mixing box is provided with a plurality of nozzles at an inlet and a plurality of grid plates at an outlet.

Preferably, the permanent magnet is a cylindrical Ru FeB permanent magnet.

Preferably, the flow meter is an ultrasonic flow meter.

Preferably, a central angle obtained by connecting the centers of any two adjacent positioning holes and the permanent magnet is a right angle.

Preferably, the winding height of the electromagnetic coil is 1/2 to 3/4 of the cylinder height.

Preferably, the discharge port is connected with a trapezoidal chute.

Preferably, the whole sorting space is supported by a metal steel plate, and the inner side of the sorting space is paved with wear-resistant bricks.

Preferably, the sorting space is of a cuboid container structure, and the length-width ratio of the sorting space is 3: 1-5: 1.

Preferably, the separation space has an included angle of 2-5 degrees with the horizontal plane.

In conclusion, the intelligent mineral separation device creatively adopts the structural characteristics of electromagnetic power, double-row-wheel discharging, a stop valve and the like, and has the advantages of fine and controllable operation, small mechanical loss, wide application range, less bed layer interference, high separation precision, low energy consumption and the like.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

Further objects, features and advantages of the present invention will become apparent from the following description of embodiments of the invention, with reference to the accompanying drawings, in which:

figure 1 shows schematically a perspective view of a mineral separation apparatus according to the present invention;

figure 2 shows schematically a flow diagram of a mineral sorting apparatus according to the invention;

FIG. 3 schematically illustrates a schematic structural view of a pulsating lifting mechanism of the mineral separation unit of the present invention;

FIG. 4 is a schematic diagram of the first discharge mechanism of the mineral separation apparatus of the present invention;

fig. 5 schematically shows a bed dynamics adjustment diagram of the mineral separation device according to the invention.

Detailed Description

The objects and functions of the present invention and methods for accomplishing the same will be apparent by reference to the exemplary embodiments. However, the present invention is not limited to the exemplary embodiments disclosed below; it can be implemented in different forms. The nature of the description is merely to assist those skilled in the relevant art in a comprehensive understanding of the specific details of the invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals denote the same or similar parts, or the same or similar steps.

Fig. 1 schematically shows a schematic perspective view of an intelligent mineral separation device according to the present invention, which mainly comprises: pan feeding mixing box 1, select separately space 2, pulsation hoist mechanism 3, first discharge mechanism 4 and second discharge mechanism 5. According to the intelligent mineral separation device, the raw mineral particles are layered according to relative density by utilizing the vertical alternating water flow, and three products, namely a heavy product with high density, a light product with low density and a medium product with density between the heavy product and the light product, are obtained by a proper method, so that the purpose of mineral separation is finally realized; the intelligent mineral separation device is widely applicable to separation of non-metal minerals or metal minerals, such as coal, iron manganese ores, tungsten ores, tin ores, gold ores, some rare metal ores and the like.

And the feeding and mixing box 1 is used for mixing raw ore materials and water. Specifically, raw ore is fed into the feeding mixing box 1 through an upstream feeder or belt conveyor, and simultaneously, a plurality of nozzles 11 at an inlet uniformly add a large amount of clear water or circulating water into the raw ore, so that the raw ore is completely immersed in the water and is sufficiently wet. Preferably, a plurality of grid plates 12 are arranged at the outlet of the feeding mixing box 1, so that the mixture of the raw ore and the water can uniformly flow into the separation space 2, and the separation effect of the separation space 2 is further ensured.

The separation space 2 provides a separation place for raw ores, and the mixture of the raw ores and water jointly forms a bed layer in the separation space 2. As shown in fig. 1 and 2, the sorting space 2 has a rectangular parallelepiped vessel structure and an aspect ratio of 3:1 to 5: 1. A feeding port 21 and a discharging port 22 are respectively arranged at two ends of the sorting space 2 in the length direction, wherein the feeding port 21 is connected with the feeding mixing box 1, and the discharging port 22 is directly connected with the trapezoidal chute 6.

The sorting space 2 comprises two parts, of which a rougher section 23 is situated close to the inlet 21 and a cleaner section 24 is situated close to the outlet 22. A first opening 25 for discharging heavy products is arranged at the bottom between the rough separation section 23 and the fine separation section 24 in the width direction (or at the bottom of the contact part), a second opening 26 for discharging medium products is also arranged at the bottom between the fine separation section 24 and the discharge port 22 in the width direction (or at the bottom of the contact part), the light products are directly discharged into the trapezoidal chute 6 from the discharge port 22, and further the first opening 25 is connected with the first discharging mechanism 4, and the second opening 26 is connected with the second discharging mechanism 5.

In addition, multiple rows of through holes 27 parallel to the width direction are uniformly formed at the bottoms of the rough separation section 23 and the fine separation section 24 of the separation space 2 at equal intervals, each row of through holes 27 comprises multiple through holes 27, and the adjacent two rows of through holes 27 are arranged in a staggered manner; furthermore, a pulsation lifting mechanism 3 is connected under each through hole 27, and a plurality of rows of pulsation lifting mechanisms 3 are connected under the plurality of rows of through holes 27.

Preferably, the whole separation space 2 is made of a metal steel plate, and the inner side of the separation space is paved with wear-resistant bricks, so that the wear resistance is improved, and the service life is prolonged; the inclination angle of the separation space 2 in the length direction is 2-5 degrees (namely the included angle between the length direction of the separation space 2 and the horizontal plane is 2-5 degrees), so that the raw ore separation amount in unit time is increased by accelerating the material passing speed.

The pulsation lifting mechanism 3 is located under the through hole 27, the end part of the pulsation lifting mechanism is connected with the through hole 27 and is subjected to sealing treatment, and the pulsation lifting mechanism 3 is used for upwards generating top water and impacting a bed layer which is located in the separation space 2 and consists of raw ores, so that the bed layer is lifted and is in a loose state, and effective separation is further realized according to a density principle.

As shown in fig. 3, the pulsation lift mechanism 3 includes a base 301 that functions as a support, a cylinder 302 that is located on the base 301, a flow meter 303 that communicates with an upper end portion of the cylinder 302, a first check valve 304 whose bottom portion communicates with the flow meter 303, and an electromagnetic coil 305 that is wound around the cylinder 302. A water inlet 302a is provided at a lower end of the cylinder 302, and the water inlet 302a is connected to a second check valve 314 and a main water supply pipe 315 in sequence.

More preferably, the pulsating lifting mechanism 3 further comprises a clean water tray 310 located above the base 301 and communicated with the bottom of the cylinder 302. The water inlet 310a is disposed on the water purification tray 310, and the water inlet 310a is connected to the second check valve 314 and the water main 315 in turn. The water purification disk 310 mainly filters impurities and fine particles in clean water or circulating water, prevents the impurities and the fine particles from entering the cylinder 302, and is communicated with the bottom end of the cylinder 302. The flow meter 303 preferably employs an unobstructed flow meter, such as an ultrasonic flow meter and an electromagnetic flow meter, to reduce drag during lift and reduce power consumption.

In addition, the pulsation lifting mechanism 3 further comprises a power supply module 311 for supplying electric energy to the electromagnetic coil 305 and the flowmeter 303, a control unit 316 for acquiring data of the flowmeter 303 in real time and making corresponding logic judgment and action in time, a cylindrical permanent magnet 306 and a guide rope 308 which are positioned inside the cylinder 302, a buffer pad 309 for reducing the downward collision strength of the permanent magnet 306 is further arranged at the lower end part of the cylinder 302, and a mesh grid 313 for uniform diversion is arranged at the upper end part of the cylinder 302, so that the accuracy of the ascending water flow which can uniformly pass through the flowmeter 303 and flow monitoring data is ensured.

Specifically, the pulsation lift mechanism 3 includes, from bottom to top, a base 301, a water purification tray 310, a cylinder 302, a flow meter 303, and a first check valve 304. The barrel 302 is cylindrical and preferably made of a non-metallic material (e.g., ceramic material, etc.), and further includes a plurality of strands of electromagnetic coil 305 wound around the outer surface of the barrel 302 (winding up the electromagnetic coil 305 from the bottom end of the barrel 302), the winding height of the electromagnetic coil 305 being approximately 1/2 to 3/4 of the height of the barrel 302. The cylinder 302 also comprises a spring 307 arranged below the mesh grid 313, a permanent magnet 306 which can move up and down freely, and four vertical guide ropes 308 of which one end is fixed on the bottom of the cylinder 302 and the other end passes through four positioning holes 306a arranged on the permanent magnet 306 and is fixed on the mesh grid 313. In addition, the central angle obtained after the line connecting the centers of any two adjacent positioning holes 306a and the permanent magnet 306 is a right angle, and the permanent magnet 306 preferably adopts a Ru FeB permanent magnet.

The pulsation lift mechanism 3 of the present invention further includes a water supply main pipe 315 communicating with the plurality of second check valves 314 for replenishing water into the cylinder 302 through the second check valves 314 and the water purification disks 310. Before the cylinder 302 is full of water, the water pressure P of the main water supply pipe 315₀Is greater than the water pressure P at the water inlet 310a₃Minimum opening water pressure P of the first check valve 304₁And the minimum opening water pressure P of the second check valve 314₂The sum of the three, i.e. P₀>(P₁+P₂+P₃) At this time, the second check valve 314 is in an open state, and the water supply main pipe 315 continues to replenish water in the cylinder 302 until the water is full; when the cylinder 302 is filled with water, the water pressure P of the main water supply pipe 315₀Water pressure P at water inlet 310a or less₃Minimum opening water pressure P of the first check valve 304₁And the minimum opening water pressure P of the second check valve 314₂The sum of the three, i.e. P₀≤(P₁+P₂+P₃) At this time, the second check valve 314 is in the closed state and the water supply is stopped.

Then, the power module 311 starts to supply power to the electromagnetic coil 305, and the electromagnetic coil 305 generates a strong magnetic field after current is introduced, so that the permanent magnet 306 is driven to lift upwards in the cylinder 302 along the guide rope 308 by utilizing the magnetic induction force generated between the strong magnetic field and the permanent magnet 306. In the lifting process, the permanent magnet 306 drives the water in the cylinder 302 to move upwards under the action of electromagnetic assistance, so that top water is formed and the first check valve 304 is flushed, further the top water impacts the bed layer to lift and disperse, and mineral separation is realized.

Preferably, the double-pulley mechanism 317 is further included for avoiding the direct sliding friction between the guide rope 308 and the positioning hole 306a, further, the permanent magnet 306 is provided with eight grooves 306b at the outlets of the two ends of the four positioning holes 306a, and the double-pulley mechanism 317 is embedded in the grooves 306b and achieves the sliding friction effect with the guide rope 308. Specifically, the double-pulley mechanism 317 comprises two pulleys arranged with a horizontal gap and a fixed shell 318, the guide rope 308 passes through the gap between the two pulley grooves, and the permanent magnet 306 can significantly reduce the friction resistance and improve the friction resistance by using the rolling friction between the guide rope 308 and the double-pulley mechanism 317 during the up-and-down movement, thereby further prolonging the service life of the permanent magnet 306, shortening the up-and-down movement time of the permanent magnet 306 and reducing the energy consumption supply.

During the ascent of the permanent magnet 306, the flow meter 303 monitors and records the flow data of the water flow throughout the ascent in real time and transmits the data to the control unit 316. Specifically, the flow rate value Q is gradually increased in the rising process until the peak value Q is reached_fThen, the flow rate value Q is gradually reduced to zero under the action of the rebound resistance of the spring 307, and the flow rate peak value Q is_fCan be adjusted by the power module 311 controlling the amount of current flowing into the solenoid 305. When the flow Q is zero or negative, the spring 307 is compressed and the power module 311 can cut off power to the solenoid 305. At the moment, the magnetic induction force disappears, the permanent magnet 306 rapidly descends along the guide rope 308 under the action of the self gravity and the restoring force of the spring 307 and collides with the buffer cushion 309, so that the permanent magnet 306 completes a bed layer lifting period, and simultaneously, a complete pulsating water flow period is correspondingly generated in the bed layer of the separation space 2, and at the moment, the magnetic induction force disappearsThe spring 307 and the buffer pad 309 play a role of buffering and energy storage, and further promote the reduction of energy consumption. The power module 311 then resumes supplying power to the solenoid 305 and proceeds to the next bed lifting cycle. Furthermore, the same row of pulse lifting mechanisms 3 simultaneously generate lifting motion, and the multiple rows of pulse lifting mechanisms 3 sequentially generate lifting motion and finally generate continuous pulse water flow in a bed layer, so that the pulse effective separation of minerals is realized.

One bed lifting cycle of the permanent magnet 306 takes about 2 to 3 seconds (including the ascending and descending processes), and the lifting frequency is about 20 to 30 times/minute; the lifting top water of the permanent magnet 306 enables the bed layer to generate vibration amplitude of 40-120 mm, and the separation requirement of the raw ore bed layer is met. The current flowing into the electromagnetic coil 305 is further controlled by the power module 311 to adjust the bed lifting period of the permanent magnet 306 and the vibration amplitude of the bed, so that the method has the advantages of fine and controllable operation, wide application range and the like.

And the first discharging mechanism 4 is positioned right below the first opening 25 and is used for timely discharging heavy products (products with higher density) at the lowest layer in the bed layer. As shown in fig. 4, the first discharging mechanism 4 mainly includes a first buoy 43 disposed at the rough separation section 23 of the separation space 2, a double-row wheel discharging device 41, and a first chute 42 for collecting and guiding discharged materials to a conveying device such as a scraper or a belt conveyor, wherein the first chute 42 also plays a role of fixing and closing the double-row wheel discharging device, and the double-row wheel discharging device 41 includes a driving discharging wheel 411 for providing power output and a driven discharging wheel 412 for passive rotation.

The driving discharging wheel 411 and the driven discharging wheel 412 are identical in structure and size and are arranged in a horizontal crossing mode, wherein the driving discharging wheel 411 comprises a driving wheel shaft 411a and a plurality of driving blades 411b, and the driven discharging wheel 412 comprises a driven wheel shaft 412a and a plurality of driven blades 412 b. The driving axle 411a and the driven axle 412a are arranged in parallel and have the length corresponding to the length of the first opening 25 (or the width of the sorting space 2), and the two ends of the driving axle 411a and the driven axle 412a are fixedly connected with the first chute 42 and are preferably connected by a sealing bearing. The driving vanes 411b and the driven vanes 412b are respectively arranged along the length direction of the driving hub 411a and the driven hub 412a and are integrally arranged in a radial shape, and in addition, the sealing treatment is carried out between the two end parts of the driving vanes 411b and the driven vanes 412b and the first chute 42, thereby reducing the occurrence of liquid leakage sites as much as possible.

The driving wheel shaft 411a drives the driven blades 412b and the driven wheel shaft 412a to synchronously rotate through the driving blades 411b on the driving wheel shaft in the rotating process, and one driving blade 411b and one driven blade 412b are always in pairwise cross contact and closely attached together in the rotating process, so that heavy products can enter the first chute 42 at intervals in batches, and the interference and the adverse effect on the bed separation effect are reduced. The bottom layer (heavy product layer) of the bed layer of the sorting space 2 enters the middle of the upper parts of the driving discharging wheel 411 and the driven discharging wheel 412 after passing through the first opening 25, and simultaneously enters the first chute 42 in the rotating process of the driving blade 411b and the driven blade 412b, the throughput of the heavy products in unit time can be increased or reduced by further adjusting the rotating speed of the driving wheel shaft 411a, and the rotating speed can be determined according to the value of the heavy product thickness layer in the bed layer monitored by the first buoy 43.

And the second discharging mechanism 5 is positioned right below the second opening 26 and is used for timely discharging products in the bed layer. The second discharging mechanism 5 comprises a single-row wheel discharging device 51, a second buoy 53 arranged at the fine sorting section 24 of the sorting space 2 and a second chute 52 for guiding discharging to a conveying device such as a scraper or a belt conveyor, wherein the rotating speed of the single-row wheel discharging device 51 is adjusted according to the thickness value of the medium product layer monitored by the first buoy 43 in the bed layer.

As shown in fig. 5, the sorting process of the bed layer dynamic adjustment of the intelligent mineral sorting device of the present invention is schematically shown in a lifting period, wherein S is a stroke curve of the top water, and C is a dynamic change process of the bed layer; the whole process can be divided into three stages: an initial lifting stage t0, a loose sorting stage t1 and a final compaction stage t2, wherein the bed layer of the initial lifting stage t0 is gradually lifted and gradually loosened from the compact under the action of top water, the bed layer of the loose sorting stage t1 is in a loose state and meets the condition of sorting according to density, and the bed layer of the final compaction stage t2 is gradually layered and compacted from the loose.

The figures are merely schematic and not drawn to scale. While the invention has been described in connection with preferred embodiments, it should be understood that the scope of the invention is not limited to the embodiments described herein.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

Claims

1. An intelligent mineral sorting device, comprising: the device comprises a feeding mixing box, a sorting space, a pulse lifting mechanism, a first discharging mechanism and a second discharging mechanism; the sorting space is of a cuboid container structure, a feeding port and a discharging port are formed in two ends of the sorting space in the length direction respectively, and the feeding port is connected with the feeding mixing box; the sorting space further comprises a rough sorting section close to the feeding port and a fine sorting section close to the discharging port; a first opening is formed in the bottom of the contact part of the rough selection section and the fine selection section, a second opening is formed in the bottom between the fine selection section and the discharge hole, the first opening is connected with the first discharge mechanism, and the second opening is connected with the second discharge mechanism;

the first discharging mechanism comprises a first buoy arranged at the rough separation section, a double-row wheel discharging device and a first chute which is used for fixing and sealing the double-row wheel discharging device and used for collecting and discharging materials;

multiple rows of through holes parallel to the width direction of the separation space are uniformly formed in the bottoms of the rough separation section and the fine separation section at equal intervals, each row of through holes comprises multiple through holes, two adjacent rows of through holes are arranged in a staggered mode, and the pulsation lifting mechanism is connected to the position right below each through hole;

the pulsation lifting mechanism comprises a base, a cylinder body positioned above the base, a flowmeter communicated with the upper end of the cylinder body, a first check valve with the bottom communicated with the flowmeter, an electromagnetic coil wound on the cylinder body, a control module and a power supply module; the interior of the cylinder body also comprises a reticular grid positioned at the upper end part, a permanent magnet which can move up and down freely and four vertical guide ropes, wherein one end of each vertical guide rope is fixed on the bottom of the cylinder body, and the other end of each vertical guide rope penetrates through four positioning holes formed in the permanent magnet and is fixed on the reticular grid; the lower end part of the cylinder body is also provided with a water inlet which is sequentially connected with a second check valve and a main water supply pipe;

2. The mineral separation apparatus of claim 1, wherein: the feeding and mixing box is provided with a plurality of nozzles at the inlet and a plurality of grid plates at the outlet.

3. The mineral separation apparatus of claim 2, wherein: the permanent magnet is a cylindrical Ru Fe B permanent magnet.

4. The mineral separation apparatus of claim 3, wherein: the flowmeter is an ultrasonic flowmeter.

5. The mineral separation apparatus of claim 4, wherein: and a central angle obtained after the connection line of any two adjacent positioning holes and the center of the permanent magnet is a right angle.

6. The mineral separation apparatus of claim 1, wherein: the winding height of the electromagnetic coil is 1/2-3/4 of the cylinder height.

7. The mineral separation apparatus of claim 6, wherein: the discharge port is connected with the trapezoidal chute.

8. The mineral separation apparatus of claim 7, wherein: the whole separation space is supported by a metal steel plate, and wear-resistant bricks are laid on the inner side of the separation space.

9. The mineral separation apparatus of claim 8, wherein: the sorting space is of a cuboid container structure, and the length-width ratio of the sorting space is 3: 1-5: 1.

10. The mineral separation apparatus of claim 9, wherein: the separation space is 2 ~ 5 degrees between the length direction and the horizontal plane contained angle.