CN203470148U

CN203470148U - Iron-titanium ore magnetic separator

Info

Publication number: CN203470148U
Application number: CN201320541559.6U
Authority: CN
Inventors: 罗烈怀; 杜洋
Original assignee: PANZHIHUA CHANGSEN INDUSTRIAL AND TRADING Co Ltd
Current assignee: PANZHIHUA CHANGSEN INDUSTRIAL AND TRADING Co Ltd
Priority date: 2013-09-02
Filing date: 2013-09-02
Publication date: 2014-03-12
Anticipated expiration: 2023-09-02

Abstract

The utility model relates to an iron-titanium ore magnetic separator which comprises a frame, a magnetic separation mechanism and a feeding hopper, wherein the magnetic separation mechanism comprises a titanium concentration device, an iron-titanium separation device, a titanium concentration motor and an iron-titanium separation motor; the titanium concentration device is driven by the titanium concentration motor, and a titanium concentrate discharging hopper, a titanium ore recovery hopper and a tailing discharging hopper are arranged on the lower side of the titanium concentration device; a titanium concentrate precision adjuster is arranged on one side of a feeding hole of the titanium ore recovery hopper and the titanium concentrate discharging hopper; a tailing precision adjuster is arranged on one side of a feeding hole of the tailing discharging hopper; the iron-titanium separation device is driven by the iron-titanium separation motor and comprises a first iron-titanium separation device and a second iron-titanium separation device; iron-titanium separation precision adjusters are arranged on one side of an iron-titanium mixture ore discharging hopper and an iron-titanium powder ore discharging hopper which are arranged on the lower side of the first iron-titanium separation device, and on one side of a titanium-in-iron discharging hopper and an iron powder discharging hopper which are arranged on the lower side of the second iron-titanium separation device. The iron-titanium ore magnetic separator is simple and reasonable in structural design, high in magnetic separation efficiency, good in effect and environment-friendly, and can be used for effectively screening and separating minerals.

Description

Iron-titanium ore magnetic separator

Technical Field

The utility model relates to a magnetic separation equipment especially relates to a ferro-titanium ore magnet separator.

Background

The magnetic separator is one of the most widely used machines in the industry and has high versatility, and is suitable for removing iron powder and the like from recycled powder granules. The magnetic separator is widely used for resource recovery in factories of timber industry, mining industry, kiln industry, chemistry, food and the like. The magnetic separator is suitable for wet or dry magnetic separation of materials such as manganese ore, magnetite ore, pyrrhotite, roasted ore, ilmenite and the like with the granularity of less than 3mm, and is also used for iron removal operation of materials such as coal, non-metal ore, building materials and the like. The magnetic separation process is realized by the action of magnetic force and mechanical force on ore particles in the magnetic field of a magnetic separator. The different magnetic particles follow different trajectories and are thus sorted into two or more separate beneficiation products. However, the existing magnetic separator is complex in structure, high in cost, low in magnetic separation efficiency, poor in effect and low in selection amount, can not effectively screen some minerals, is poor in screening quality, can not meet the existing industrial requirements, can achieve the quality of the selected mineral products after multiple times of selection, directly discharges dust in the production process without treatment, and is very large in production working environment and not environment-friendly.

As described above, it is necessary to further improve the conventional techniques.

Disclosure of Invention

The utility model relates to a solve present magnet separator structure complicacy, with high costs, magnetic separation inefficiency, effect subalternation problem and provide a structural design simply, magnetic separation efficiency is high, effectual, can effectively screen and separate the high iron and titanium ore deposit magnet separator of screening quality to the mineral.

The utility model discloses a realize through following technical scheme:

the iron-titanium ore magnetic separator comprises a rack, a magnetic separation mechanism arranged on the rack in a matching manner, and a feed hopper arranged in a matching manner with the magnetic separation mechanism; the magnetic separation mechanism comprises a titanium selection device and an iron-titanium selection device which are arranged in the rack in a matched mode, a titanium selection motor matched with the titanium selection device, and an iron-titanium selection motor matched with the iron-titanium selection device; the titanium fine-selection device is driven by the titanium selection motor, and a titanium concentrate discharge hopper, a titanium ore recovery hopper and a tailing discharge hopper are arranged on the lower side of the titanium fine-selection device in a matching manner; one side of the feed inlet of the titanium concentrate discharge hopper and one side of the feed inlet of the titanium ore recovery hopper are provided with a titanium concentrate precision regulator in a matching way; one side of a feeding hole of the tailing discharging hopper is provided with a tailing precision regulator in a matching manner; the ferrotitanium sorting device is driven by the ferrotitanium sorting motor and comprises a first ferrotitanium sorting device matched with the lower side of the feed hopper and a second ferrotitanium sorting device matched with the inner bottom end of the rack; an iron-titanium mixture ore discharge hopper and an iron-titanium powder ore discharge hopper are arranged on the lower side of the first iron-titanium separation device in a matching manner; a first iron-titanium separation precision regulator is arranged on one side of the feeding holes of the iron-titanium mixture ore discharge hopper and the iron-titanium powder ore discharge hopper in a matching manner; the lower side of the second ferrotitanium sorting device is provided with a titanium discharging hopper and an iron powder discharging hopper in the iron in a matching manner, and one side of a feed inlet of the titanium discharging hopper and one side of a feed inlet of the iron powder discharging hopper in the iron are provided with a second ferrotitanium sorting precision regulator in a matching manner.

The iron-titanium ore magnetic separator, wherein: the titanium fine-selection device is at least one pair of titanium fine-selection devices symmetrically arranged on two sides in the rack, and each titanium fine-selection device comprises a titanium fine-selection magnetic roller, titanium fine-selection end covers matched with and arranged at two ends of a roller body of the titanium fine-selection magnetic roller, and a titanium fine-selection rotating shaft matched with and arranged in the roller body of the titanium fine-selection magnetic roller in a penetrating mode, and two ends of the titanium fine-selection rotating shaft are respectively hinged and limited to the rack; the first ferrotitanium sorting device and the second ferrotitanium sorting device respectively comprise a ferrotitanium sorting magnetic roller, ferrotitanium sorting cover plates which are matched and arranged at two ends of a barrel body of the ferrotitanium sorting magnetic roller, and a ferrotitanium sorting rotating shaft which is matched and arranged in the barrel body of the ferrotitanium sorting magnetic roller in a penetrating way, and two ends of the ferrotitanium sorting rotating shaft are respectively hinged and limited on the rack; the titanium selection motors are at least one pair symmetrically arranged on two opposite sides of the rack, and each titanium selection motor is connected with the titanium selection rotating shaft in a matching way through a belt; the ferrotitanium separation motor comprises a first ferrotitanium separation motor and a second ferrotitanium separation motor; the first ferrotitanium separation motors are at least one pair symmetrically arranged on two opposite sides of the rack, and each first ferrotitanium separation motor is positioned on one side of the titanium separation motor and is in matched connection with the ferrotitanium separation rotating shaft through a belt; the second ferrotitanium separation motor is arranged in the middle of the bottom end of the rack and is also connected with the other ferrotitanium separation rotating shaft in a matching manner through a belt.

The iron-titanium ore magnetic separator, wherein: the titanium concentrate discharge hopper and the titanium ore recovery hopper are both vertically arranged, and discharge ports at the lower ends of the titanium concentrate discharge hopper and the titanium ore recovery hopper protrude out of the bottom of the rack; the tailing discharge hopper is inclined at a certain angle from top to bottom towards the outer side of the rack.

The iron-titanium ore magnetic separator, wherein: the discharge holes of the iron-titanium mixture ore discharge hopper and the iron-titanium powder ore discharge hopper are matched and aligned with the upper end of the second iron-titanium separation device; the iron-titanium mixture ore discharge hopper is inclined towards the center of the rack at a certain angle from top to bottom, and a discharge hole is aligned to the upper end of the second iron-titanium separation device in a matching manner; the iron-titanium powder ore discharging hopper is inclined towards the outer side of the rack at a certain angle from top to bottom, and the discharging port is aligned to the upper end of the titanium refining device in a matching mode.

The iron-titanium ore magnetic separator, wherein: the titanium discharge hopper and the iron powder discharge hopper are vertically arranged side by side, and discharge ports at the lower ends of the titanium discharge hopper and the iron powder discharge hopper protrude out of the bottom of the rack.

The iron-titanium ore magnetic separator, wherein: the feed hoppers are at least one pair which is symmetrically arranged at the inner side of the top end of the rack; every the feeder hopper all is the centrum structure of inversion, its upper end feed inlet with the top parallel and level of frame just is open state, and the bottom discharge gate is equipped with the feed regulator.

The iron-titanium ore magnetic separator, wherein: the bottom of the frame is symmetrically provided with support legs, and a group of opposite side walls are respectively symmetrically provided with at least one pair of dust exhaust ports.

The iron-titanium ore magnetic separator, wherein: the magnetic separator also comprises a dust exhaust fan which is arranged inside the rack in a matching mode, and an air outlet of the dust exhaust fan is aligned with the dust exhaust port in a matching mode.

Has the advantages that:

the utility model has simple and reasonable structure design, wherein, the magnetic system structure is optimized through the analysis of the technical performance characteristics of the magnetic system, the magnetic field intensity and the magnetic field gradient of the magnetic separator are improved, and the action depth of the magnetic field force is increased; the product structure of the magnetic separator is adjusted, so that the single magnetic separation is upgraded to the multiple magnetic separation, the rolling times of magnetic minerals in a magnetic field are increased, and the concentrate grade is improved; the treatment capacity per hour can reach 20 tons, the production cost is greatly reduced, and the production efficiency is improved; after the ore obtained by the pre-separation and tailing discarding is subjected to step grinding and step separation by a magnetic separator, the iron ore concentrate with the Fe taste of 57.08% and the recovery rate of 53.16% can be obtained; the magnetic separator can reduce the titanium taste in the titanium tailings to 1.5 percent, the titanium content of the selected iron ore concentrate to 15 percent, and the dry separation operation recovery rate to more than 85 percent; meanwhile, the dust is not directly discharged into the air in the production process by adding the dust exhaust fan which is designed autonomously, so that the working environment can be greatly improved; the end covers, the rotating shaft, the rack and other important parts of the titanium selection device and the ferrotitanium selection device are made of vanadium-titanium microalloyed steel, and the cylinders of the magnetic drums of the titanium selection device and the ferrotitanium selection device are made of stainless steel, so that the wear resistance and the performance stability of the magnetic separator are improved; the whole magnetic separator is high in magnetic separation efficiency, good in effect, capable of effectively screening and separating minerals, high in screening quality, more environment-friendly and suitable for popularization and application.

Drawings

FIG. 1 is a schematic structural view of the magnetic separator for iron-titanium ore of the present invention;

FIG. 2 is another schematic structural diagram of the magnetic separator for ilmenite of the present invention.

Detailed Description

The orientation words "upper", "lower" and "top", "bottom", "inner" and "outer" related to the present invention are all consistent with the orientation of fig. 1.

As shown in figures 1 and 2, the utility model discloses iron titanium ore magnet separator, including frame 1, feeder hopper 2, magnetic separation mechanism 3 and dust exhaust fan 4.

The frame 1 is a symmetrical box structure, the bottom of which is symmetrically provided with support legs 11, and a group of opposite side walls are respectively symmetrically provided with at least one pair of dust exhaust ports 12.

The feed hoppers 2 are symmetrically arranged on at least one pair of the inner sides of the top end of the rack 1, each feed hopper 2 is of an inverted cone structure, the feed inlet at the upper end of each feed hopper is flush with the top of the rack 1 and is in an open state, the discharge outlet at the bottom end of each feed hopper is positioned on the inner side of the top end of the rack 1 and is also provided with a feeding regulator 21, and the discharge speed of each feed hopper 2 can be timely controlled through the feeding regulators 21.

The magnetic separation mechanism 3 is installed on the frame 1 in a matching manner and comprises a titanium separation motor 31, a ferrotitanium separation motor 32, a titanium separation device 33 and a ferrotitanium separation device 34.

The titanium selection motors 31 are at least one pair symmetrically arranged on two opposite sides of the frame 1, wherein each titanium selection motor 31 is connected with the titanium selection device 33 in a matching way through a belt 5.

The ferrotitanium sorting motor 32 includes a first ferrotitanium sorting motor 321 and a second ferrotitanium sorting motor 322;

the first ferrotitanium separation motors 321 are at least one pair symmetrically arranged on two opposite sides of the rack 1, and each first ferrotitanium separation motor 321 is positioned on one side of the titanium separation motor 31 and is in matching connection with the ferrotitanium separation device 34 through a belt 5;

this second ferrotitanium selects separately motor 322 locates the bottom middle part of frame 1, and it also matches with ferrotitanium sorting unit 34 through belt 5 and is connected.

The titanium selection devices 33 are at least one pair which are symmetrically arranged on two sides in the rack 1, each titanium selection device 33 is composed of a titanium selection magnetic roller, titanium selection end covers which are matched with two ends of a barrel body of the titanium selection magnetic roller, and a titanium selection rotating shaft which is arranged in the barrel body of the titanium selection magnetic roller in a penetrating mode, two ends of the titanium selection rotating shaft are respectively hinged and limited to the rack 1, and the titanium selection rotating shaft is connected with the titanium selection motor 3 in a matching mode through a belt 5; in the embodiment, the titanium selection end cover and the titanium selection rotating shaft are both made of vanadium-titanium-containing microalloy steel, and the cylinder body of the titanium selection magnetic roller is made of stainless steel. Each titanium fine-selection device 33 is driven by a titanium selection motor 31, and a titanium concentrate discharge hopper 331, a titanium ore recovery hopper 332 and a tailing discharge hopper 333 are arranged on the lower side of the titanium fine-selection device in a matching manner; the titanium concentrate discharge hopper 331 and the titanium ore recovery hopper 332 are both vertically arranged, a titanium concentrate precision regulator 334 is matched and arranged on one side of the upper end feed inlet, the lower end discharge outlet protrudes out of the bottom of the rack 1, and the precision of the titanium concentrate discharged from the titanium concentration device 33 can be timely regulated and controlled through the titanium concentrate precision regulator 334; the tailings discharging hopper 333 is arranged from top to bottom in a certain angle inclined towards the outer side of the rack 1, a tailings precision regulator 335 is arranged on one side of the feeding hole at the upper end of the tailings discharging hopper, and the tailings discharged from the titanium fine-selecting device 33 can be timely regulated and controlled through the tailings precision regulator 335.

The ferrotitanium sorting device 34 is also arranged inside the rack 1 in a matching manner, and comprises a ferrotitanium sorting magnetic roller, a ferrotitanium sorting cover plate which is arranged at two ends of a barrel of the ferrotitanium sorting magnetic roller in a matching manner, and a ferrotitanium sorting rotating shaft which is arranged inside the barrel of the ferrotitanium sorting magnetic roller in a matching manner in a penetrating manner and is hinged and limited to the rack 1 at two ends respectively, wherein the ferrotitanium sorting rotating shaft is connected with a ferrotitanium sorting motor 32 in a matching manner through a belt 5; in the embodiment, the ferrotitanium separation cover plate and the ferrotitanium separation rotating shaft are both made of vanadium-titanium-containing microalloy steel, and the barrel of the ferrotitanium separation magnetic roller is made of stainless steel; wherein the ferrotitanium sorting device 34 comprises a first ferrotitanium sorting device 341 and a second ferrotitanium sorting device 342;

the first iron-titanium sorting devices 341 are at least one pair arranged on the lower sides of a pair of feed hoppers 2 in a matching way, each first iron-titanium sorting device 341 is arranged on the lower side of the discharge port of each feed hopper 2 in a matching way and is driven by an iron-titanium sorting motor 32, and an iron-titanium mixture ore discharge hopper 343 and an iron-titanium powder ore discharge hopper 344 are also arranged on the lower sides of the first iron-titanium sorting devices 341 in a matching way; wherein,

the iron-titanium mixture ore discharge hopper 343 is inclined at a certain angle from top to bottom toward the center of the rack 1, and a discharge port is aligned with the upper end of the second iron-titanium separation device 342 in a matching manner; the iron titanium powder ore discharge hopper 344 is inclined at a certain angle from top to bottom towards the outer side of the rack 1, and a discharge hole is matched and aligned with the upper end of the titanium refining device 5; a first iron-titanium separation precision regulator 345 is also arranged on one side of the upper end feed inlets of the iron-titanium mixture ore discharge hopper 343 and the iron-titanium powder ore discharge hopper 344 in a matching manner, and the precision of the iron-titanium ore discharged from the iron-titanium separation device 34 can be timely regulated and controlled through the first iron-titanium separation precision regulator 345.

The second iron-titanium separation device 342 is arranged on the inner bottom side of the frame 1 and between the pair of titanium concentration devices 5, is driven by the second iron-titanium separation motor 322, and has the upper end aligned with the discharge ports of the iron-titanium mixture ore discharge hopper 343 and the iron-titanium powder ore discharge hopper 344; the lower side of the second ferrotitanium separating device 342 is also provided with a ferrotitanium discharging hopper 346 and an iron powder discharging hopper 347 in a matching manner, the ferrotitanium discharging hopper 346 and the iron powder discharging hopper 347 are vertically arranged side by side, one side of the upper side feed inlet is also provided with a second ferrotitanium separating precision regulator 348 in a matching manner, and the lower end discharge outlet protrudes out of the bottom of the rack 1.

The dust exhaust fan 4 is located inside the rack 1, is arranged inside the rack 1 in a matching manner, and has an air outlet aligned with the dust exhaust port 12 of the rack 1, so that dust inside the rack 1 can be exhausted from the dust exhaust port 12.

The utility model has the advantages of simple and reasonable design, wherein, not only magnetic separation is efficient, effectual, can effectively filter and separate the mineral moreover, and the screening quality is high, is suitable for popularization and application.

Claims

1. A kind of iron-titanium ore magnetic separator, including the stander, match and load onto the magnetic separation organization of the said stander and match the feeder hopper that sets up with the said magnetic separation organization; the method is characterized in that: the magnetic separation mechanism comprises a titanium selection device and an iron-titanium selection device which are arranged in the rack in a matched mode, a titanium selection motor matched with the titanium selection device, and an iron-titanium selection motor matched with the iron-titanium selection device;

the titanium fine-selection device is driven by the titanium selection motor, and a titanium concentrate discharge hopper, a titanium ore recovery hopper and a tailing discharge hopper are arranged on the lower side of the titanium fine-selection device in a matching manner; one side of the feed inlet of the titanium concentrate discharge hopper and one side of the feed inlet of the titanium ore recovery hopper are provided with a titanium concentrate precision regulator in a matching way; one side of a feeding hole of the tailing discharging hopper is provided with a tailing precision regulator in a matching manner;

the ferrotitanium sorting device is driven by the ferrotitanium sorting motor and comprises a first ferrotitanium sorting device matched with the lower side of the feed hopper and a second ferrotitanium sorting device matched with the inner bottom end of the rack;

an iron-titanium mixture ore discharge hopper and an iron-titanium powder ore discharge hopper are arranged on the lower side of the first iron-titanium separation device in a matching manner; a first iron-titanium separation precision regulator is arranged on one side of the feeding holes of the iron-titanium mixture ore discharge hopper and the iron-titanium powder ore discharge hopper in a matching manner;

the lower side of the second ferrotitanium sorting device is provided with a titanium discharging hopper and an iron powder discharging hopper in the iron in a matching manner, and one side of a feed inlet of the titanium discharging hopper and one side of a feed inlet of the iron powder discharging hopper in the iron are provided with a second ferrotitanium sorting precision regulator in a matching manner.

2. The ilmenite magnetic separator of claim 1, characterized in that: the titanium fine-selection device is at least one pair of titanium fine-selection devices symmetrically arranged on two sides in the rack, and each titanium fine-selection device comprises a titanium fine-selection magnetic roller, titanium fine-selection end covers matched with and arranged at two ends of a roller body of the titanium fine-selection magnetic roller, and a titanium fine-selection rotating shaft matched with and arranged in the roller body of the titanium fine-selection magnetic roller in a penetrating mode, and two ends of the titanium fine-selection rotating shaft are respectively hinged and limited to the rack;

the first ferrotitanium sorting device and the second ferrotitanium sorting device respectively comprise a ferrotitanium sorting magnetic roller, ferrotitanium sorting cover plates which are matched and arranged at two ends of a barrel body of the ferrotitanium sorting magnetic roller, and a ferrotitanium sorting rotating shaft which is matched and arranged in the barrel body of the ferrotitanium sorting magnetic roller in a penetrating way, and two ends of the ferrotitanium sorting rotating shaft are respectively hinged and limited on the rack;

the titanium selection motors are at least one pair symmetrically arranged on two opposite sides of the rack, and each titanium selection motor is connected with the titanium selection rotating shaft in a matching way through a belt;

the ferrotitanium separation motor comprises a first ferrotitanium separation motor and a second ferrotitanium separation motor;

the first ferrotitanium separation motors are at least one pair symmetrically arranged on two opposite sides of the rack, and each first ferrotitanium separation motor is positioned on one side of the titanium separation motor and is in matched connection with the ferrotitanium separation rotating shaft through a belt;

the second ferrotitanium separation motor is arranged in the middle of the bottom end of the rack and is also connected with the other ferrotitanium separation rotating shaft in a matching manner through a belt.

3. The ilmenite magnetic separator of claim 1, characterized in that: the titanium concentrate discharge hopper and the titanium ore recovery hopper are both vertically arranged, and discharge ports at the lower ends of the titanium concentrate discharge hopper and the titanium ore recovery hopper protrude out of the bottom of the rack;

the tailing discharge hopper is inclined at a certain angle from top to bottom towards the outer side of the rack.

4. The ilmenite magnetic separator of claim 1, characterized in that: the discharge holes of the iron-titanium mixture ore discharge hopper and the iron-titanium powder ore discharge hopper are matched and aligned with the upper end of the second iron-titanium separation device;

the iron-titanium mixture ore discharge hopper is inclined towards the center of the rack at a certain angle from top to bottom, and a discharge hole is aligned to the upper end of the second iron-titanium separation device in a matching manner;

the iron-titanium powder ore discharging hopper is inclined towards the outer side of the rack at a certain angle from top to bottom, and the discharging port is aligned to the upper end of the titanium refining device in a matching mode.

5. The ilmenite magnetic separator of claim 1, characterized in that: the titanium discharge hopper and the iron powder discharge hopper are vertically arranged side by side, and discharge ports at the lower ends of the titanium discharge hopper and the iron powder discharge hopper protrude out of the bottom of the rack.

6. The ilmenite magnetic separator of claim 1, characterized in that: the feed hoppers are at least one pair which is symmetrically arranged at the inner side of the top end of the rack; every the feeder hopper all is the centrum structure of inversion, its upper end feed inlet with the top parallel and level of frame just is open state, and the bottom discharge gate is equipped with the feed regulator.

7. The iron-titanium ore magnetic separator recited in any one of claims 1 to 6 wherein: the bottom of the frame is symmetrically provided with support legs, and a group of opposite side walls are respectively symmetrically provided with at least one pair of dust exhaust ports.

8. The ilmenite magnetic separator of claim 7, characterized in that: the magnetic separator also comprises a dust exhaust fan which is arranged inside the rack in a matching mode, and an air outlet of the dust exhaust fan is aligned with the dust exhaust port in a matching mode.