CN219898527U - Vibration high-gradient magnetic separation device - Google Patents

Abstract

The utility model discloses a vibration high-gradient magnetic separation device which comprises a magnetic separation assembly, a pipeline assembly and a dredging assembly, wherein the magnetic separation assembly comprises a supporting frame, a tailing collecting hopper arranged between the supporting frames, a concentrate collecting hopper arranged on the front surface of the tailing collecting hopper and a magnetic cylinder body movably arranged at the tops of the tailing collecting hopper and the concentrate collecting hopper, the dredging assembly comprises a protective cover arranged on one side of a concentrate output pipe, a transverse electric shaft penetrating through one side of the protective cover, an introducing box arranged on one side of the transverse electric shaft, a transverse cone head arranged on one side of the introducing box, brackets arranged on the inner walls of two sides of the introducing box, radial telescopic shafts arranged between the brackets and radial dredging cone heads arranged at two ends of the radial telescopic shafts.

Description

Vibration high-gradient magnetic separation device

Technical Field

The utility model relates to the technical field of magnetic separation devices, in particular to a vibration high-gradient magnetic separation device.

Background

The vibration high-gradient magnetic separator is a novel strong magnetic separator developed on the basis of a general strong magnetic separator, is suitable for ore separation of weak magnetic minerals, and is characterized in that ore pulp flows into a tank body through an ore feeding box, and ore particles enter an ore feeding area of the tank body in a loose state under the action of water flow of an ore feeding water spray pipe, and are adsorbed on a cylinder under the action of a magnetic field. When the magnetic stirring device rotates along with the cylinder, magnetic stirring is generated due to the alternation of magnetic poles, non-magnetic minerals, namely tailings, fall off in the process of turning, and concentrate sucked on the surface of the cylinder is discharged into a concentrate hopper under the action of flushing water flow sprayed by a concentrate discharge water pipe.

Most of the existing vibrating high-gradient magnetic separation devices are often blocked in a material conveying pipeline under a concentrate hopper during operation, so that the normal operation of the device is affected, the working efficiency is greatly reduced, and a plurality of inconveniences are caused for workers.

Disclosure of Invention

The utility model aims to provide a vibrating high-gradient magnetic separation device so as to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a vibration high gradient magnetic separation device, includes magnetic separation subassembly, pipeline subassembly and mediation subassembly, the magnetic separation subassembly includes braced frame, installs the tailing between braced frame and collects fill, installs and collect fill and movable mounting is collected fill and concentrate collection fill magnetic cylinder at top at the positive concentrate of tailing, pipeline subassembly is including running through the concentrate output tube of installing in concentrate collection fill bottom, the mediation subassembly is including installing the safety cover in concentrate output tube one side, running through the horizontal motor shaft of installing in safety cover one side, install the leading-in box in horizontal motor shaft one side, install the horizontal conical head in leading-in box one side, install the support at leading-in box both sides inner wall, install the radial telescopic shaft between the support and install the radial mediation conical head at radial telescopic shaft both ends.

Preferably, the leading-in box is located inside the protection cover, the transverse cone head is located on one side of the concentrate output pipe, and the radial dredging cone head is located inside the leading-in box.

Preferably, the top of the support frame is provided with a rail, and the rail is positioned at two sides of the tailing collecting hopper and the concentrate collecting hopper.

Preferably, the rotating shafts are arranged on two sides of the magnetic cylinder body, limit clamps are symmetrically arranged at the top of the transverse bar, and the inner walls of the limit clamps are in contact with the outer sides of the rotating shafts.

Preferably, a stabilizing diaphragm is arranged on one side of the diaphragm, a driving motor is arranged at the top of the stabilizing diaphragm, and the output end of the driving motor is connected with a rotating shaft on one side.

Preferably, the valve seat is installed in the outside of concentrate output tube, the valve seat is located the below of safety cover, one side movable mounting of valve seat has the ooff valve, slant baffle is installed to one side inner wall of concentrate output tube, slant baffle is located the top of safety cover.

Preferably, the top and the bottom of the leading-in box are provided with through holes, and the through holes are positioned above and below the radial dredging conical head.

By adopting the technical scheme, the beneficial effects obtained by the utility model are as follows:

the utility model is provided with the transverse electric shaft, the transverse conical head, the radial expansion shaft and the radial dredging conical head, when the concentrate output pipe is blocked, one side of the transverse electric shaft stretches, the leading-in box is driven to move into the concentrate output pipe, the transverse blocking surface of the pipe can be opened on the transverse conical head arranged on one side of the leading-in box, when the leading-in box enters the concentrate output pipe, the upper end and the lower end of the radial expansion shaft stretch back and forth, the radial dredging conical heads are arranged at the two ends of the radial expansion shaft, the radial dredging conical heads can effectively break the blocking of the concentrate output pipe in the radial direction, and the blocked concentrate output pipe is dredged through the back and forth stretching movement of the radial expansion shaft, so that the normal work of the device is further ensured, the working efficiency is improved, and great convenience is provided for staff.

Drawings

Fig. 1 is a schematic perspective view of the whole device of the present utility model.

Fig. 2 is a perspective view of a piping component according to the present utility model.

Fig. 3 is a schematic cross-sectional view of a tailings collection hopper of the present utility model.

FIG. 4 is a schematic cross-sectional view of a pull through assembly of the present utility model.

In the figure: 100. a magnetic separation component; 101. a support frame; 102. a tailings collection hopper; 103. concentrate collection hopper; 104. a magnetic cylinder; 105. a rail; 106. a limit clamp; 107. a stabilizing cross plate; 108. a driving motor; 109. a rotating shaft;

200. a conduit assembly; 201. concentrate output pipe; 202. a valve seat; 203. a switch valve; 204. an inclined baffle;

300. a dredging assembly; 301. a protective cover; 302. a transverse electric shaft; 303. an introduction box; 304. a transverse cone head; 305. a bracket; 306. a radial telescopic shaft; 307. radial dredging cone head; 308. and a through hole.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, a vibratory high gradient magnetic separation apparatus;

the device comprises a transverse electric shaft 302, a transverse conical head 304, a radial telescopic shaft 306 and a radial dredging conical head 307, wherein a tailing collecting hopper 102 is arranged between supporting frames 101, a concentrate collecting hopper 103 is arranged on the front surface of the tailing collecting hopper 102, a magnetic cylinder 104 is movably arranged at the tops of the tailing collecting hopper 102 and the concentrate collecting hopper 103, a transverse bar 105 is arranged at the top of the supporting frames 101, the transverse bar 105 is positioned at two sides of the tailing collecting hopper 102 and the concentrate collecting hopper 103, two sides of the magnetic cylinder 104 are provided with rotating shafts 109, limit clamps 106 are symmetrically arranged at the tops of the transverse bars 105, the inner walls of the limit clamps 106 are mutually contacted with the outer sides of the rotating shafts 109, a stabilizing transverse plate 107 is arranged at one side of the transverse bar 105, a driving motor 108 is arranged at the top of the stabilizing transverse plate 107, the output end of the driving motor 108 is connected with one side of the rotating shafts 109, a concentrate output pipe 201 is arranged at the bottom of the concentrate collecting hopper 103 in a penetrating manner, the valve seat 202 is arranged on the outer side of the concentrate output pipe 201, the valve seat 202 is positioned below the protective cover 301, the switch valve 203 is movably arranged on one side of the valve seat 202, the inclined baffle 204 is arranged on the inner wall of one side of the concentrate output pipe 201, the protective cover 301 is arranged on one side of the concentrate output pipe 201, the transverse electric shaft 302 is arranged on one side of the protective cover 301 in a penetrating manner, the leading-in box 303 is arranged on one side of the transverse electric shaft 302, the leading-in box 303 is positioned in the protective cover 301, the transverse conical head 304 is arranged on one side of the leading-in box 303, the brackets 305 are arranged on the inner walls of two sides of the leading-in box 303, the radial expansion shafts 306 are arranged between the brackets 305, the radial dredging conical heads 307 are arranged at two ends of the radial expansion shafts 306, the radial dredging conical heads 307 are positioned in the leading-in box 303, the top and the bottom of the leading-in box 303 are provided with through holes 308, the through holes 308 are located above and below the radial pull through bit 307.

Specifically, the device is in operation, the supporting frame 101 is a device main body structure and is used for providing mounting positions for other structures, ensuring the stability of other structures in operation, when ore pulp is spread on the magnetic cylinder 104, magnetic ore particles, namely ore concentrate, are adsorbed on the magnetic cylinder 104, non-magnetic ore, namely ore tailings fall off in the tailing collecting hopper 102 in the process of turning and are discharged, the ore concentrate absorbed on the magnetic cylinder 104 is discharged into the ore concentrate collecting hopper 103 under the action of flushing water flow, the device finishes the work of screening ore concentrate, the magnetic cylinder 104 is erected in the limit clamp 106 through the rotating shaft 109, the stability of the magnetic cylinder 104 in rotation is ensured, the driving motor 108 is used for driving the magnetic cylinder 104 to rotate, the inclined baffle 204 arranged on the inner wall of the ore concentrate output pipe 201 can effectively prevent the ore concentrate from entering the inside of the protective cover 301 in the falling process, when the concentrate output pipe 201 is blocked, the transverse electric shaft 302 stretches to one side, at the moment, the leading-in box 303 is driven to move in the concentrate output pipe 201, the transverse blocking surface of the pipeline can be opened on the transverse conical head 304 arranged on one side of the leading-in box 303, after the leading-in box 303 enters the concentrate output pipe 201, the radial telescopic shaft 306 stretches up and down to reciprocate, the radial dredging conical heads 307 are arranged at the two ends of the radial telescopic shaft 306, the blocking of the concentrate output pipe 201 in the radial direction can be effectively broken through the radial dredging conical heads 307, the blocked concentrate output pipe 201 is dredged through the reciprocating telescopic movement of the radial telescopic shaft 306, the normal operation of the device is further ensured, the working efficiency is improved, and great convenience is provided for workers.

Working principle: when ore pulp is spread on the magnetic cylinder 104, magnetic ore particles, namely ore concentrate, are adsorbed on the magnetic cylinder 104, non-magnetic ore, namely ore tailings, fall off and are discharged into the ore tailing collecting hopper 102 in the process of turning, ore concentrate absorbed on the magnetic cylinder 104 is discharged into the ore concentrate collecting hopper 103 under the action of flushing water flow, the device completes the work of screening ore concentrate, when the ore concentrate output pipe 201 is blocked, the transverse electric shaft 302 stretches to one side, the leading-in box 303 is driven to move into the ore concentrate output pipe 201 at the moment, the transverse blocking surface of the pipe can be opened on the transverse conical head 304 arranged on one side of the leading-in box 303, after the leading-in box 303 enters the inside of the ore concentrate output pipe 201, the radial telescopic shaft 306 stretches back and forth to the upper end and the lower end, the radial telescopic shaft 306 is provided with the radial dredging conical head 307, the radial dredging conical head 307 can effectively break the blocking of the ore concentrate output pipe 201 in the radial direction, and the blocked ore concentrate output pipe 201 is dredged back and forth through the telescopic movement of the radial telescopic shaft 306.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (7)

1. A vibratory high gradient magnetic separation apparatus, comprising:

the magnetic separation assembly (100) comprises a supporting frame (101), a tailing collecting hopper (102) arranged between the supporting frames (101), a concentrate collecting hopper (103) arranged on the front surface of the tailing collecting hopper (102) and a magnetic cylinder (104) movably arranged at the tops of the tailing collecting hopper (102) and the concentrate collecting hopper (103);

a pipeline assembly (200) comprising a concentrate output pipe (201) penetrating through the bottom of the concentrate collection hopper (103);

the dredging assembly (300) comprises a protective cover (301) arranged on one side of a concentrate output pipe (201), a transverse electric shaft (302) penetrating through one side of the protective cover (301), an introduction box (303) arranged on one side of the transverse electric shaft (302), a transverse conical head (304) arranged on one side of the introduction box (303), supports (305) arranged on inner walls on two sides of the introduction box (303), a radial telescopic shaft (306) arranged between the supports (305) and radial dredging conical heads (307) arranged at two ends of the radial telescopic shaft (306).

2. The vibrating high gradient magnetic separation device according to claim 1, wherein the lead-in box (303) is located inside the protective cover (301), the transverse conical head (304) is located at one side of the concentrate output pipe (201), and the radial dredging conical head (307) is located inside the lead-in box (303).

3. The vibratory high gradient magnetic separation apparatus of claim 1, wherein a rail (105) is mounted on top of the support frame (101), the rail (105) being located on both sides of the tailings collection hopper (102) and the concentrate collection hopper (103).

4. A vibrating high gradient magnetic separation device according to claim 3, wherein the two sides of the magnetic cylinder body (104) are provided with rotating shafts (109), the top of the transverse bar (105) is symmetrically provided with limiting clamps (106), and the inner walls of the limiting clamps (106) are in contact with the outer sides of the rotating shafts (109).

5. A vibratory high gradient magnetic separator according to claim 3, wherein a stabilizing cross plate (107) is mounted on one side of the cross bar (105), a driving motor (108) is mounted on top of the stabilizing cross plate (107), and an output end of the driving motor (108) is connected with a side rotating shaft (109).

6. The vibrating high-gradient magnetic separation device according to claim 1, wherein a valve seat (202) is installed on the outer side of the concentrate output pipe (201), the valve seat (202) is located below the protective cover (301), a switch valve (203) is movably installed on one side of the valve seat (202), an inclined baffle (204) is installed on the inner wall of one side of the concentrate output pipe (201), and the inclined baffle (204) is located above the protective cover (301).

7. The vibrating high gradient magnetic separation device according to claim 1, wherein the top and the bottom of the lead-in box (303) are provided with through holes (308), and the through holes (308) are positioned above and below the radial dredging conical head (307).