CN113019696A

CN113019696A - Deironing device for mineral processing

Info

Publication number: CN113019696A
Application number: CN202110511513.9A
Authority: CN
Inventors: 童雄; 吴雅菡; 谢贤; 张明天
Original assignee: Kunming University of Science and Technology
Current assignee: Kunming University of Science and Technology
Priority date: 2021-05-11
Filing date: 2021-05-11
Publication date: 2021-06-25
Anticipated expiration: 2041-05-11
Also published as: CN113019696B

Abstract

The invention discloses an iron removal device for mineral processing, which relates to the technical field of mineral processing and comprises a main body, a separation mechanism and a feeding mechanism, wherein the separation mechanism is arranged on the upper side in the main body, and the upper end of the main body is connected with the feeding mechanism; the feed mechanism includes: the feeding bin is of a gourd-shaped hollow structure. The invention integrally forms a conveying belt with the electromagnetic bar through the insulating connecting sheets which are connected at intervals, the conveying belt is driven to rotate by the driving wheel matched with the driving motor, the electromagnetic bar is electrified by the conductive sheets arranged at the two ends of the electromagnetic bar, so that the electromagnetic bar adsorbs iron in the mineral conveying process, when the mineral is conveyed to the left end, the iron falls into the mineral collecting bin due to the gravity of the electromagnetic bar, the iron is continuously conveyed by the adsorption of the electromagnetic bar, when the mineral is conveyed to the gap of the conductive sheets, the electromagnetic bar is powered off, and the iron falls into the iron collecting bin due to the gravity of the electromagnetic bar, so that the iron in the mineral is separated.

Description

Deironing device for mineral processing

Technical Field

The invention relates to the technical field of mineral processing, in particular to an iron removal device for mineral processing.

Background

Minerals are natural compounds of a certain chemical composition, which have stable phase interfaces and crystal habits. The crystal form and symmetry of the mineral are determined by the internal crystal habit; the hardness, luster and conductive properties of the mineral are determined by the nature of the chemical bond; the color and specific gravity of the mineral are determined by the chemical composition of the mineral and the binding compactness. In the identification of minerals, the form and physical properties of minerals are the most common signs for identifying minerals due to easy identification, and iron ore is the most common mineral, and iron in the iron ore needs to be separated in the iron ore processing process, so that an iron removal device is needed.

Mineral processing deironing device on the market can't carry out the ration pay-off, appears easily that the pay-off is too much and leads to the shortcoming that iron can't accomplish the separation.

Disclosure of Invention

The invention aims to provide an iron removing device for mineral processing, which aims to solve the problems that the iron cannot be separated due to excessive feeding because the iron cannot be separated because the iron removing device for mineral processing in the background art cannot perform quantitative feeding.

In order to achieve the purpose, the invention provides the following technical scheme: an iron removal device for mineral processing, comprising:

a main body;

the separating mechanism is arranged on the upper side in the main body, and the upper end of the main body is connected with the feeding mechanism;

the feed mechanism includes:

the feeding bin is of a gourd-shaped hollow structure, and a large impeller is arranged on the upper side inside the feeding bin;

the small impeller is arranged on the lower side of the inner side of the feeding bin, the small impeller and the feeding bin are vertically distributed, and one end of the large impeller and one end of the small impeller are connected with a servo motor;

and the crushing mechanism is connected to the upper end of the feeding mechanism.

Preferably, the body comprises:

the main bin is of a rectangular hollow structure, and a mineral collecting port is arranged in the middle of the left side inside the main bin;

the limiting slide rail is arranged at the lower part of the left side in the main bin, the limiting slide rail and the main bin are vertically distributed, and the outer side of the limiting slide rail is connected with a limiting slide block;

the positioning knobs penetrate through the inner sides of the limiting sliding blocks, the number of the positioning knobs is two, and the other sides of the limiting sliding blocks are connected with mineral collecting bins;

the visual window is arranged in the middle of the front end of the mineral collection bin and is connected with the mineral collection bin in an embedded mode, and an iron collection port is formed in the middle of the right side of the interior of the main bin;

and the iron collecting bin is arranged at the lower part of the right side in the main bin.

Preferably, be fixed connection between spacing slider and the mineral collection storehouse, and the mineral collection storehouse passes through to constitute sliding construction between spacing slider and the spacing slide rail and the main storehouse to the shape structure in iron collection storehouse is unanimous with the shape structure in mineral collection storehouse.

Preferably, the separation mechanism includes:

one end of the driving wheel is connected with a driving motor, and the outer side of the driving wheel is connected with an insulating connecting sheet;

the electromagnetic bar is connected to one side of the insulating connecting sheet, the electromagnetic bar and the insulating connecting sheet are connected at intervals, and two ends of the electromagnetic bar are connected with the conducting strips.

Preferably, be fixed connection between insulating connection piece and the electromagnetic rod, and constitute the full enclosed construction between insulating connection piece and electromagnetic rod and the drive wheel to the conducting strip is along the axis symmetric distribution of electromagnetic rod.

Preferably, the feeding mechanism further comprises:

the conveying cylinder is connected to the left side of the upper end of the feeding bin, the packing auger is arranged inside the conveying cylinder, and the packing auger and the conveying cylinder are distributed in a concentric circle;

and the auxiliary motor is connected to one end of the packing auger.

Preferably, a communicating structure is formed between the conveying cylinder and the feeding bin, and the auger forms a rotating structure with the conveying cylinder through the auxiliary motor.

Preferably, the crushing mechanism comprises:

the crushing bin is of an inverted trapezoidal hollow structure, and a first crushing wheel is arranged on one side inside the crushing bin;

the first gear is connected to one end of the first crushing wheel, the first crushing wheel and the first gear are concentrically distributed, and one side of the first gear is meshed with a motor gear;

the main motor is connected to the middle part of the motor gear, and the other side of the motor gear is meshed with a second gear;

and the second crushing wheel is connected to the middle part of the second gear, a transmission box is arranged outside the right side of the crushing bin, and a feeding hole is formed in the upper end of the crushing bin.

Preferably, the first crushing wheel and the second crushing wheel are distributed in a parallel shape, and the first crushing wheel and the second crushing wheel are meshed with each other.

The invention provides an iron removal device for mineral processing, which has the following beneficial effects: the iron removing device for mineral processing has the quantitative feeding effect through the mutual matching of the mechanisms, so that the continuity and effectiveness of iron removing separation of minerals are ensured, the condition that the iron removing separation of the minerals is insufficient due to uneven feeding is avoided, and the separated minerals and iron are convenient to distinguish and collect;

1. the limiting slide block is arranged on the outer side of the mineral collecting bin, the limiting slide rail is arranged in the main bin in a matching mode, so that the mineral collecting bin can slide in the main bin, the mineral collecting bin can be conveniently drawn out to collect and process internal minerals, the limiting slide block on the lower portion of the mineral collecting bin can be fixedly positioned in a matching mode with the positioning knob, the stability of the mineral collecting bin in the working process is guaranteed, the visual window is arranged at the front end of the mineral collecting bin, the mineral collecting condition in the mineral collecting bin can be checked in real time to be cleaned in time, and meanwhile, the shape structure of the iron collecting bin is consistent with that of the mineral collecting bin, so that the iron collecting bin is convenient to maintain and is convenient to use in practice.

2. The insulating connecting sheets and the electromagnetic rods which are fixedly connected can ensure the connection firmness, the insulating connecting sheets and the electromagnetic rods which are connected at intervals integrally form a conveying belt, the conveying belt is driven to rotate by matching a driving wheel with a driving motor, and the electromagnetic rods are electrified by matching with the conductive sheets arranged at the two ends of the electromagnetic rods, so that the iron in the minerals is adsorbed by the electromagnetic rods in the process of conveying the minerals, when the minerals are conveyed to the left end, the iron falls into the mineral collecting bin due to the gravity of the iron, the iron is conveyed continuously by the adsorption of the electromagnetic rods, when the minerals are conveyed to the gaps of the conductive sheets, the power of the electromagnetic rods is cut off, and the iron falls into the iron collecting bin due to the gravity of the iron, so that the iron in the minerals is separated.

3. According to the invention, through the gourd-shaped hollow feeding bin, the large impeller and the small impeller which are arranged in the feeding bin are matched to rotate under the driving of the servo motor, so that the minerals entering the feeding bin can be quantitatively conveyed, the condition that iron cannot be completely separated due to uneven feeding is avoided, and the continuity and effectiveness of the working of the iron removing device are ensured.

4. According to the invention, through the communicated conveying cylinder and the feeding bin, the continuity of mineral entering the feeding bin can be ensured, the situation that the mineral cannot be fed due to blockage is avoided, the broken mineral entering the conveying cylinder can be conveyed by the auger arranged in the conveying cylinder under the driving of the auxiliary motor, and the stability of the auger in the rotating process can be ensured by the auger and the conveying cylinder which are distributed concentrically.

5. According to the invention, the mineral needing iron removal can be crushed through the crushing mechanism arranged at the upper end of the feeding mechanism, so that the iron removal effect is ensured, the motor gear, the first gear and the second gear are driven by the main motor, so that the first crushing wheel and the second crushing wheel complete the crushing work of the mineral, and the motor gear, the first gear and the second gear which are meshed with each other can ensure the stability in the transmission process.

Drawings

FIG. 1 is a schematic view of the overall structure of an iron removing device for mineral processing according to the present invention;

FIG. 2 is a schematic view of a mineral collection bin of an iron removal device for mineral processing according to the present invention;

FIG. 3 is a schematic top view of the separation mechanism of the iron removing device for mineral processing according to the present invention;

FIG. 4 is a schematic perspective view of a conductive sheet of an iron removal device for mineral processing according to the present invention;

FIG. 5 is a schematic top view of a crushing bin of an iron removing device for mineral processing according to the present invention;

FIG. 6 is a schematic view of the internal structure of a transmission case of the iron removing device for mineral processing according to the present invention.

In the figure: 1. a main body; 101. a main bin; 102. a mineral collection port; 103. a limiting slide rail; 104. a limiting slide block; 105. positioning a knob; 106. a mineral collection bin; 107. a visible window; 108. an iron collection port; 109. an iron collecting bin; 2. a separating mechanism; 201. a drive wheel; 202. a drive motor; 203. insulating the connecting sheet; 204. an electromagnetic bar; 205. a conductive sheet; 3. a feeding mechanism; 301. a feeding bin; 302. a large impeller; 303. a small impeller; 304. a servo motor; 305. a delivery cartridge; 306. a packing auger; 307. a secondary motor; 4. a crushing mechanism; 401. a crushing bin; 402. a first crushing wheel; 403. a first gear; 404. a motor gear; 405. a main motor; 406. a second gear; 407. a second crushing wheel; 408. a transmission case; 409. and (4) feeding a material inlet.

Detailed Description

Referring to fig. 1-2, an iron removing apparatus for mineral processing includes: a main body 1; the main body 1 includes: the main bin 101 is of a rectangular hollow structure, and a mineral collecting port 102 is formed in the middle of the left side inside the main bin 101; the limiting slide rail 103 is arranged at the lower part of the left side inside the main bin 101, the limiting slide rail 103 and the main bin 101 are vertically distributed, and the limiting slide block 104 is connected to the outer side of the limiting slide rail 103; the positioning knobs 105 penetrate through the inner sides of the limiting sliding blocks 104, two positioning knobs 105 are arranged, and the other sides of the limiting sliding blocks 104 are connected with mineral collecting bins 106; the limiting sliding block 104 is fixedly connected with the mineral collecting bin 106, the mineral collecting bin 106 forms a sliding structure with the main bin 101 through the limiting sliding block 104 and the limiting sliding rail 103, the limiting sliding block 104 is arranged on the outer side of the mineral collecting bin 106 and is matched with the limiting sliding rail 103 arranged in the main bin 101, so that the mineral collecting bin 106 can slide in the main bin 101, the mineral collecting bin 106 can be conveniently drawn out to collect and treat minerals in the mineral collecting bin, the limiting sliding block 104 arranged on the lower portion of the mineral collecting bin 106 can be positioned and fixed by matching with the positioning knob 105 arranged, the stability of the mineral collecting bin 106 in the working process is ensured, the visual window 107 is arranged in the middle of the front end of the mineral collecting bin 106, the visual window 107 is connected with the mineral collecting bin 106 in an embedded mode, the visual window 107 arranged at the front end of the mineral collecting bin 106 can be checked in real time, and the situation of mineral collecting in the mineral collecting bin, so as to clean the iron in time, and an iron collecting port 108 is arranged in the middle of the right side inside the main bin 101; the iron collecting bin 109 is arranged at the lower part of the right side inside the main bin 101, and the shape and structure of the iron collecting bin 109 are consistent with those of the mineral collecting bin 106, so that the iron collecting bin is convenient to maintain and practical use;

referring to fig. 1, 3 and 4, an iron removing apparatus for mineral processing, a separating mechanism 2 is disposed at an upper side of an inside of a main body 1, and a feeding mechanism 3 is connected to an upper end of the main body 1; the separation mechanism 2 includes: one end of the driving wheel 201 is connected with a driving motor 202, and the outer side of the driving wheel 201 is connected with an insulating connecting sheet 203; the electromagnetic rod 204 is connected to one side of the insulating connecting sheet 203, the electromagnetic rod 204 is connected with the insulating connecting sheet 203 at intervals, the insulating connecting sheet 203 is fixedly connected with the electromagnetic rod 204, the insulating connecting sheet 203, the electromagnetic rod 204 and the driving wheel 201 form a full-surrounding structure, the insulating connecting sheet 203 and the electromagnetic rod 204 which are fixedly connected can ensure the connection firmness, the insulating connecting sheet 203 and the electromagnetic rod 204 which are connected at intervals integrally form a conveying belt, two ends of the electromagnetic rod 204 are connected with the conducting sheets 205, the conducting sheets 205 are symmetrically divided along the central axis of the electromagnetic rod 204 and are driven to rotate by the driving wheel 201 in cooperation with the driving motor 202, the conducting sheets 205 which are arranged at two ends of the electromagnetic rod 204 are matched to electrify the electromagnetic rod 204, so that the electromagnetic rod 204 adsorbs iron in minerals in the process of conveying the minerals, when the minerals are conveyed to the left end, the iron falls into the mineral collection bin 106 due to the gravity of the iron, the iron is continuously conveyed by the adsorption of the electromagnetic rod 204, the electromagnetic rod 204 is powered off when the iron is conveyed to the notch of the conducting strip 205, and the iron falls into the iron collection bin 109 due to the gravity of the iron, so that the iron in the minerals is separated;

referring to fig. 1, a deironing device for mineral processing, a feeding mechanism 3 includes: the feeding bin 301 is of a gourd-shaped hollow structure, and a large impeller 302 is arranged on the upper side inside the feeding bin 301; the small impeller 303 is arranged on the lower side of the inner side of the feeding bin 301, the small impeller 303 and the feeding bin 301 are vertically distributed, and one ends of the large impeller 302 and the small impeller 303 are connected with a servo motor 304; through the feeding storehouse 301 of calabash form cavity form, the inside big impeller 302 that is provided with of cooperation feeding storehouse 301 is rotatory under servo motor 304's drive with little impeller 303, can carry out the ration to the mineral that gets into feeding storehouse 301 and carry out, avoids the inhomogeneous condition that leads to the unable complete separation of iron of pay-off, guarantees the continuation and the validity of this deironing device work, and feed mechanism 3 still includes: the conveying cylinder 305 is connected to the left side of the upper end of the feeding bin 301, the packing auger 306 is arranged inside the conveying cylinder 305, and the packing auger 306 and the conveying cylinder 305 are concentrically distributed; the auxiliary motor 307 is connected to one end of the auger 306, a communicating structure is formed between the conveying cylinder 305 and the feeding bin 301, the auger 306 forms a rotating structure through the auxiliary motor 307 and the conveying cylinder 305, the communicating conveying cylinder 305 and the feeding bin 301 can ensure the continuity of mineral entering the feeding bin 301, and avoid the situation that the mineral cannot be fed due to blockage, the auger 306 arranged in the conveying cylinder 305 can convey broken mineral entering the conveying cylinder 305 under the driving of the auxiliary motor 307, and the auger 306 and the conveying cylinder 305 which are distributed concentrically can ensure the stability of the auger 306 in the rotating process;

referring to fig. 1, 5 and 6, a deironing device for mineral processing, a crushing mechanism 4 is connected to an upper end of a feeding mechanism 3, the crushing mechanism 4 includes: the crushing bin 401 is of an inverted trapezoidal hollow structure, and a first crushing wheel 402 is arranged on one side inside the crushing bin 401; a first gear 403 connected to one end of the first crushing wheel 402, wherein the first crushing wheel 402 and the first gear 403 are concentrically distributed, and one side of the first gear 403 is engaged with a motor gear 404; a main motor 405 connected to the middle of the motor gear 404, the other side of the motor gear 404 being engaged with a second gear 406; second crushing wheel 407, it is connected in the middle part of second gear 406, first crushing wheel 402 is the parallel form with second crushing wheel 407 and distributes, and intermeshing between first crushing wheel 402 and the second crushing wheel 407, the crushing mechanism 4 of setting in feed mechanism 3 upper end, can carry out the mineral of deironing to needs and carry out the breakage, thereby guarantee the effect of deironing, drive motor gear 404 through main motor 405, first gear 403 and second gear 406, make first crushing wheel 402 and second crushing wheel 407 accomplish the crushing work to mineral, intermeshing's motor gear 404, first gear 403 and second gear 406, can guarantee the stability of transmission in-process, the right side outside of crushing storehouse 401 is provided with transmission case 408, feed inlet 409 has been seted up to the upper end of crushing storehouse 401.

In summary, when the iron removing device for mineral processing is used, minerals are added into a crushing bin 401 through a feeding hole 409, then a main motor 405 drives a motor gear 404, a first gear 403 and a second gear 406 to enable a first crushing wheel 402 and a second crushing wheel 407 to complete crushing work on the minerals, the crushed minerals fall into a conveying cylinder 305, a packing auger 306 arranged inside the conveying cylinder 305 can convey the crushed minerals entering the conveying cylinder 305 under the driving of an auxiliary motor 307, the packing auger 306 and the conveying cylinder 305 which are distributed concentrically can ensure the stability of the packing auger 306 in the rotating process, the conveying cylinder 305 and the feeding bin 301 which are communicated can ensure the continuity of the minerals entering the feeding bin 301, and avoid the situation that the minerals cannot be fed due to blockage, the feeding bin 301 which is hollow in a gourd shape is matched with a large impeller 302 and a small impeller 303 arranged inside the feeding bin 301 to rotate under the driving of a servo motor 304, can carry out quantitative conveying to the mineral entering into the feeding bin 301, the mineral falls to the upper end of the separating mechanism 2 through the small impeller 303, the insulating connecting sheet 203 and the electromagnetic rod 204 which are connected at intervals integrally form a conveying belt, the conveying belt is driven to rotate by the driving wheel 201 matching with the driving motor 202, the electromagnetic rod 204 is electrified by the conducting sheet 205 arranged at the two ends of the electromagnetic rod 204, so that the iron in the mineral is adsorbed by the electromagnetic rod 204 in the mineral conveying process, when the mineral is conveyed to the left end, the iron falls into the mineral collecting bin 106 due to the gravity of the iron, and is continuously conveyed by the adsorption of the electromagnetic rod 204, when the mineral is conveyed to the notch of the conducting sheet 205, the electromagnetic rod 204 is powered off, the iron falls into the iron collecting bin 109 due to the gravity of the iron, the iron separation work in the mineral is realized, and the limiting slide block 104 arranged outside the mineral collecting bin 106, the inside spacing slide rail 103 that is provided with of cooperation main storehouse 101 for mineral collection storehouse 106 can slide inside main storehouse 101, be convenient for take mineral collection storehouse 106 out and collect the processing to the mineral of inside, the cooperation is provided with location knob 105, can fix a position spacing slider 104 of storehouse 106 lower part is collected to mineral, guarantee the stability of storehouse 106 is collected to mineral in the course of the work, set up the visual window 107 at storehouse 106 front end is collected to mineral, can look over the inside mineral collection's in storehouse 106 condition of mineral in real time, in order to clear up it in time.

Claims

1. An iron removal device for mineral processing, comprising:

a main body (1);

the method is characterized in that:

the separation mechanism (2) is arranged on the upper side in the main body (1), and the upper end of the main body (1) is connected with the feeding mechanism (3);

the feed mechanism (3) comprises:

the feeding bin (301), the feeding bin (301) is of a gourd-shaped hollow structure, and a large impeller (302) is arranged on the upper side inside the feeding bin (301);

the small impeller (303) is arranged on the lower side of the inner side of the feeding bin (301), the small impeller (303) and the feeding bin (301) are vertically distributed, and one ends of the large impeller (302) and the small impeller (303) are connected with a servo motor (304);

a crushing mechanism (4) connected to the upper end of the feeding mechanism (3).

2. The iron removing device for mineral processing according to claim 1, wherein said main body (1) comprises:

the device comprises a main bin (101), wherein the main bin (101) is of a rectangular hollow structure, and a mineral collecting port (102) is formed in the middle of the left side inside the main bin (101);

the limiting slide rail (103) is arranged at the lower part of the left side in the main bin (101), the limiting slide rail (103) is vertically distributed with the main bin (101), and the outer side of the limiting slide rail (103) is connected with a limiting slide block (104);

the positioning knobs (105) penetrate through the inner side of the limiting sliding block (104), two positioning knobs (105) are arranged, and the other side of the limiting sliding block (104) is connected with a mineral collecting bin (106);

the visual window (107) is arranged in the middle of the front end of the mineral collection bin (106), the visual window (107) is connected with the mineral collection bin (106) in an embedded mode, and an iron collection port (108) is arranged in the middle of the right side inside the main bin (101);

and the iron collecting bin (109) is arranged at the lower part of the right side inside the main bin (101).

3. The iron removing device for mineral processing according to claim 2, wherein the limiting slide block (104) is fixedly connected with the mineral collecting bin (106), the mineral collecting bin (106) forms a sliding structure with the main bin (101) through the limiting slide block (104) and the limiting slide rail (103), and the shape structure of the iron collecting bin (109) is consistent with that of the mineral collecting bin (106).

4. The iron removing device for mineral processing according to claim 1, wherein the separation mechanism (2) comprises:

one end of the driving wheel (201) is connected with a driving motor (202), and the outer side of the driving wheel (201) is connected with an insulating connecting sheet (203);

the electromagnetic rod (204) is connected to one side of the insulating connecting sheet (203), the electromagnetic rod (204) is connected with the insulating connecting sheet (203) at intervals, and the two ends of the electromagnetic rod (204) are connected with the conducting sheets (205).

5. The iron removing device for mineral processing according to claim 4, wherein the insulating connecting sheet (203) is fixedly connected with the electromagnetic rod (204), a full surrounding structure is formed among the insulating connecting sheet (203), the electromagnetic rod (204) and the driving wheel (201), and the conducting sheets (205) are symmetrically distributed along the central axis of the electromagnetic rod (204).

6. The iron removing device for mineral processing according to claim 1, wherein the feeding mechanism (3) further comprises:

the conveying cylinder (305) is connected to the left side of the upper end of the feeding bin (301), the packing auger (306) is arranged inside the conveying cylinder (305), and the packing auger (306) and the conveying cylinder (305) are concentrically distributed;

and the auxiliary motor (307) is connected to one end of the packing auger (306).

7. The iron removing device for mineral processing according to claim 6, wherein the conveying cylinder (305) and the feeding bin (301) are in a communicating structure, and the auger (306) and the conveying cylinder (305) form a rotating structure through the auxiliary motor (307).

8. The iron removing device for mineral processing according to claim 1, wherein the crushing mechanism (4) comprises:

the crushing bin (401) is of an inverted trapezoidal hollow structure, and a first crushing wheel (402) is arranged on one side inside the crushing bin (401);

the first gear (403) is connected to one end of the first crushing wheel (402), the first crushing wheel (402) and the first gear (403) are concentrically distributed, and one side of the first gear (403) is meshed with the motor gear (404);

a main motor (405) connected to the middle of the motor gear (404), and a second gear (406) engaged with the other side of the motor gear (404);

and the second crushing wheel (407) is connected to the middle part of the second gear (406), a transmission case (408) is arranged outside the right side of the crushing bin (401), and a feeding hole (409) is formed in the upper end of the crushing bin (401).

9. The iron removing device for mineral processing according to claim 8, wherein the first crushing wheel (402) and the second crushing wheel (407) are distributed in parallel, and the first crushing wheel (402) and the second crushing wheel (407) are engaged with each other.