CN109513386B - Iron ore is large-scale compounding device for agglomeration - Google Patents

Abstract

The invention discloses a large-scale mixing device for iron ore agglomeration, which has the technical scheme that: the automatic feeding device comprises a frame, be fixed with first servo motor in the frame, be fixed with first gear on first servo motor's the motor shaft, it is connected with mixing barrel to rotate in the frame, mixing barrel's external fixation has the second gear, first gear and second gear intermeshing, still be fixed with a plurality of rakes in the mixing barrel, still rotate in the mixing box and be connected with first paddle dead lever and second paddle dead lever, all be fixed with a plurality of stirring paddle on first paddle dead lever and the second paddle dead lever, first paddle dead lever and second paddle dead lever are rotated by the drive of power portion, still be provided with the first material loading portion and the second material loading portion that make things convenient for the material loading in the frame, iron ore agglomeration can realize automatic material loading with large-scale compounding device, and comparatively abundant even when the stirring, adapts to large-scale production.

Description

Iron ore is large-scale compounding device for agglomeration

Technical Field

The invention relates to the field of iron ore agglomeration devices, in particular to a large mixing device for iron ore agglomeration.

Background

Iron ore is an important raw material for iron and steel production enterprises, and iron ore is a mineral aggregate containing iron simple substance or iron compound that can be economically utilized. The natural ore (iron ore) is crushed, ground, magnetically separated, floated, reselected, agglomerated and the like, and then can be sent to a blast furnace for ironmaking.

Agglomeration is a raw material processing technology for producing artificial rich ore. The purpose of iron ore agglomeration is to fully utilize poor iron ore and rich ore powder and expand the resources for steel production; improving the metallurgical property of the iron ore by agglomeration, and providing high-quality raw materials for a blast furnace to improve smelting indexes; comprehensively utilizes other dust, dust mud and slag (furnace dust, iron scale, sulfate slag and steel slag) which are useful for continuous iron making, and reduces the pollution of steel production to the environment.

Mixing materials during agglomeration, wherein the mixing materials during agglomeration are the operation of mixing reselected fine iron slag stones with dust, dust mud and furnace slag.

The current chinese patent that discloses a CN108097086A discloses a compounding device of metallurgical usefulness, which comprises a frame, four side edges of frame bottom all are equipped with damping base device, frame upper end both sides all are equipped with agitator tank vibration damper, agitator tank vibration damper top is equipped with the agitator tank, agitator tank right side lower part is equipped with a motor base, be equipped with a motor on the motor base, be equipped with a gear on the motor output shaft, the upper left side of a gear is equipped with No. two gears, No. two gear housing establish at an axle right-hand member, an epaxial No. two gear left sides that lie in are equipped with a bearing, a bearing left side is equipped with No. three bearings.

Although the mixing device for metallurgy can realize mixing and has a good damping effect during mixing, the mixing device cannot realize automatic feeding and cannot adapt to large-scale production.

Disclosure of Invention

Aiming at the problems mentioned in the background technology, the invention aims to provide a large-scale mixing device for iron ore agglomeration, which has the advantages that: the large-scale mixing device for iron ore agglomeration can realize automatic feeding, is relatively sufficient and uniform during stirring, and is suitable for large-scale production.

The technical purpose of the invention is realized by the following technical scheme:

a large-scale mixing device for iron ore agglomeration comprises a frame, wherein a first servo motor is fixed on the frame, a first gear is fixed on a motor shaft of the first servo motor, a mixing barrel is rotatably connected on the frame, a second gear is fixed outside the mixing barrel, the first gear and the second gear are mutually meshed, a plurality of rake rods are fixed in the mixing barrel, a blocking plate is also connected in the mixing barrel in a sliding manner along the horizontal direction, a cylinder body of an air cylinder is fixed outside the mixing barrel, the end part of a piston rod of the air cylinder is fixed on the blocking plate, a feed inlet and a discharge outlet are formed in the mixing barrel, a discharge outlet of the mixing barrel is connected in a mixing box, the mixing box is fixed on the frame, a first paddle fixing rod and a second paddle fixing rod are further rotatably connected in the mixing box, and a plurality of mixing paddles are respectively fixed on the first paddle fixing rod and the second paddle fixing rod, the bottom of compounding case still communicates there is first pipeline, first paddle dead lever and second paddle dead lever are rotated by the drive of power portion, still be provided with first material loading portion and the second material loading portion of convenient follow feed inlet material loading in the frame.

By adopting the technical scheme, when the reselected iron ore and dust, dust mud and slag which are useful for steelmaking are mixed by a large-scale mixing device for iron ore agglomeration, the reselected iron ore is conveyed into a mixing barrel through a first feeding part, the dust, dust mud and slag which are useful for steelmaking are conveyed into the mixing barrel through a second feeding part, then a first servo motor is started, the mixing barrel is driven to rotate on a frame through a first gear and a second gear, a rake rod can preliminarily mix the materials, then an air cylinder is started, the air cylinder drives a blocking plate to slide in the mixing barrel, the mixed materials fall into the mixing barrel, a first blade fixing rod and a second blade fixing rod can be driven to rotate through a power part, and a first stirring blade and a second stirring blade are driven to mix the materials; therefore, the large-scale mixing device for iron ore agglomeration can realize automatic feeding, is relatively sufficient and uniform during stirring, and is suitable for large-scale production.

Preferably, the power part comprises a second servo motor, a third gear, a fourth gear, a fifth gear and a sixth gear, the second servo motor is fixed on the frame, the second servo motor drives the third gear to rotate, the third gear is fixed at the end of the first blade fixing rod, the sixth gear is fixed at the end of the second blade fixing rod, the fourth gear and the fifth gear are both rotatably connected to the outside of the mixing box, the third gear and the fourth gear are meshed with each other, the fourth gear and the fifth gear are meshed with each other, and the fifth gear and the sixth gear are meshed with each other.

Through adopting above-mentioned technical scheme, when the second servo motor in the power portion started, will drive the third gear rotation, because intermeshing between third gear and the fourth gear, intermeshing between fourth gear and the fifth gear, intermeshing between fifth gear and the sixth gear, the event can drive first paddle dead lever and second paddle dead lever and rotate to carry out intensive mixing to the material.

Preferably, the first feeding portion comprises a third servo motor, a first conveyor belt, a first drive roller and a first driven roller, the third servo motor is fixed on the rack, two ends of the first drive roller and two ends of the first driven roller are respectively connected to the rack in a rotating mode, the third servo motor drives the first drive roller to rotate, the first drive roller and the first driven roller are connected through the first conveyor belt in a transmission mode, and the first conveyor belt is arranged in an inclined mode.

Through adopting above-mentioned technical scheme, first material loading portion can be used for the iron ore that automatic material loading reselected, and the iron ore that reselects passes through the conveying of first conveyer belt, can be conveyed to the feed inlet top of mixing barrel to can fall into in the mixing barrel from the feed inlet.

Preferably, the second feeding portion comprises a fourth servo motor, a second conveyor belt, a second driving roller and a second driven roller, the fourth servo motor is fixed on the rack, two ends of the second driving roller and two ends of the second driven roller are respectively connected to the rack in a rotating mode, the fourth servo motor drives the second driving roller to rotate, the second driving roller and the second driven roller are connected through the second conveyor belt in a transmission mode, and the second conveyor belt is arranged in an inclined mode.

By adopting the technical scheme, the second feeding part can be used for automatically feeding the dust, the dust mud and the slag which are useful for steel making, and the dust, the dust mud and the slag which are useful for steel making can be conveyed to the inlet of the mixing barrel by the second conveying belt in the second feeding part and can fall into the mixing barrel from the inlet of the mixing barrel.

Preferably, the rack is further provided with a transmission part below the first pipeline, the transmission part comprises a fifth servo motor, a third conveyor belt, a third drive roller and a third driven roller, the fifth servo motor is fixed on the rack, two ends of the third drive roller and two ends of the third driven roller are respectively rotatably connected to the rack, the fifth servo motor drives the third drive roller to rotate, the third drive roller and the third driven roller are in transmission connection through the third conveyor belt, and the third conveyor belt is horizontally arranged.

Through adopting above-mentioned technical scheme, can convey the material after mixing to the sintering workshop through the third conveyer belt in the transmission part and agglomerate, degree of automation is higher.

Preferably, a speed reducer is arranged between the second servo motor and the third gear, the input end of the speed reducer is connected with a motor shaft of the second servo motor, and the output end of the speed reducer is connected with the third gear.

Through adopting above-mentioned technical scheme, the output speed that the reduction gear can reduce second servo motor for first paddle dead lever and second paddle dead lever are more steady when the stirring compounding.

Preferably, the first frame is provided with a feeding hopper above the lower ends of the first conveyor belt and the second conveyor belt, and the bottom of the feeding hopper is provided with a valve.

Through adopting above-mentioned technical scheme, the loading hopper of first material loading portion department can be convenient to the feed of first material loading portion, conveniently adds the iron ore of reselecting to first conveyer belt, and the loading hopper of second material loading portion department can conveniently be to the feed of second material loading portion, conveniently adds useful dust, dirt mud and the slag of steelmaking to the second conveyer belt.

Preferably, a plurality of partition plates are fixed on the first conveyor belt and the second conveyor belt at equal intervals.

Through adopting above-mentioned technical scheme, the partition plate on first conveyer belt and the second conveyer belt can be divided into the heap with the material on first conveyer belt and the second conveyer belt to can prevent that the material from rolling off from inclined first conveyer belt and second conveyer belt.

In summary, the invention mainly has the following beneficial effects:

iron ore is large-scale compounding device for agglomeration can realize automatic feeding through first material loading portion and second material loading portion, and can make comparatively abundant even of stirring when the material mixes through utilizing rake arm, stirring paddle leaf, and the device can adapt to mass production simultaneously.

Drawings

FIG. 1 is one of schematic structural views of a large-sized mixing apparatus for iron ore agglomeration;

FIG. 2 is an enlarged view at C in FIG. 1;

FIG. 3 is a second schematic view of a large-scale mixing apparatus for iron ore agglomeration;

FIG. 4 is a third schematic view of a large-scale mixing apparatus for iron ore agglomeration;

FIG. 5 is a sectional view showing the structure of a large-sized mixing apparatus for iron ore agglomeration;

FIG. 6 is a schematic structural view of a large-sized mixing device for iron ore agglomeration after a mixing box is hidden;

fig. 7 is an enlarged view at D in fig. 6.

Reference numerals: 1. a frame; 2. a first servo motor; 3. a first gear; 4. a mixing barrel; 5. a second gear; 6. a harrow bar; 9. a feed inlet; 10. a discharge port; 11. a mixing box; 12. a first blade-fixing lever; 13. a second blade securing lever; 14. a stirring paddle; 15. a first conduit; 16. a second servo motor; 17. a third gear; 18. a fourth gear; 19. a fifth gear; 20. a sixth gear; 21. a third servo motor; 22. a first conveyor belt; 23. a first drive roll; 24. a first driven roller; 26. a fourth servo motor; 27. a second conveyor belt; 28. a second drive roll; 29. a second driven roller; 30. a fifth servo motor; 31. a third conveyor belt; 32. a third drive roll; 33. a third driven roller; 34. a speed reducer; 35. a hopper; 36. a valve; 37. and (5) dividing the plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Examples

As shown in fig. 1 to 7, a large-scale mixing device for iron ore agglomeration comprises a frame 1, wherein a first servo motor 2 is fixed on the frame 1, a first gear 3 is fixed on a motor shaft of the first servo motor 2, a mixing barrel 4 is rotatably connected on the frame 1, a second gear 5 is fixed on the outer part of the mixing barrel 4, the first gear 3 and the second gear 5 are meshed with each other, and the first servo motor 2 can drive the mixing barrel 4 to rotate; twelve rake rods 6 are also fixed in the mixing cylinder 4, and the rake rods 6 are beneficial to the uniformity of the primary mixing; in order to prevent the materials from falling down uncontrollably, a blocking plate is also connected in the mixing cylinder 4 in a sliding way along the horizontal direction, a cylinder body of an air cylinder is also fixed outside the mixing cylinder 4, wherein the end part of a piston rod of the air cylinder is fixed on the blocking plate, and the air cylinder can drive the blocking plate to slide; the mixing barrel 4 is provided with a feeding hole 9 and a discharging hole 10, the feeding hole 9 is used for feeding materials, and the discharging hole 10 is used for discharging materials; in order to uniformly mix materials, a discharge port 10 of a mixing cylinder 4 is connected in a mixing box 11, wherein the mixing box 11 is fixed on a frame 1, a first blade fixing rod 12 and a second blade fixing rod 13 are further rotatably connected in the mixing box 11, thirty-two stirring blades 14 are respectively fixed on the first blade fixing rod 12 and the second blade fixing rod 13, the bottom of the mixing box 11 is further communicated with a first pipeline 15, wherein the first blade fixing rod 12 and the second blade fixing rod 13 are driven by a power part to rotate, and the frame 1 is further provided with a first feeding part and a second feeding part which are convenient for feeding from a feeding port 9; when the reselected iron ore and dust, dust mud and slag which are useful for steelmaking are mixed by using a large-scale mixing device for iron ore agglomeration, the reselected iron ore is conveyed into a mixing barrel 4 through a first feeding part, the dust, dust mud and slag which are useful for steelmaking are conveyed into the mixing barrel 4 through a second feeding part, then a first servo motor 2 is started, the mixing barrel 4 is driven to rotate on a frame 1 through a first gear 3 and a second gear 5, a rake lever 6 can preliminarily mix the materials, then a cylinder is started, a blocking plate is driven to slide in the mixing barrel 4 by the cylinder, the mixed materials fall into a mixing box 11, a first blade fixing rod 12 and a second blade fixing rod 13 can be driven to rotate through a power part, and a first stirring blade 14 and a second stirring blade 14 are driven to mix the materials; therefore, the large-scale mixing device for iron ore agglomeration can realize automatic feeding, is relatively sufficient and uniform during stirring, and is suitable for large-scale production.

As shown in fig. 1 to 7, the power section includes a second servo motor 16, a third gear 17, a fourth gear 18, a fifth gear 19 and a sixth gear 20, wherein the second servo motor 16 is fixed on the frame 1, the third gear 17 is driven to rotate by the second servo motor 16, the third gear 17 is fixed at the end of the first blade fixing rod 12, the sixth gear 20 is fixed at the end of the second blade fixing rod 13, and the fourth gear 18 and the fifth gear 19 are both rotatably connected to the outside of the mixing box 11, wherein the third gear 17 and the fourth gear 18 are engaged with each other, the fourth gear 18 and the fifth gear 19 are engaged with each other, and the fifth gear 19 and the sixth gear 20 are engaged with each other; when the second servo motor 16 in the power part is started, the third gear 17 is driven to rotate, and the third gear 17 and the fourth gear 18 are meshed with each other, the fourth gear 18 and the fifth gear 19 are meshed with each other, and the fifth gear 19 and the sixth gear 20 are meshed with each other, so that the first blade fixing rod 12 and the second blade fixing rod 13 can be driven to rotate, and materials are fully stirred; the first feeding part comprises a third servo motor 21, a first conveying belt 22, a first driving roller 23 and a first driven roller 24, wherein the third servo motor 21 is fixed on the rack 1, two ends of the first driving roller 23 and two ends of the first driven roller 24 are respectively connected to the rack 1 in a rotating mode, the third servo motor 21 is used for driving the first driving roller 23 to rotate, the first driving roller 23 and the first driven roller 24 are connected through the first conveying belt 22 in a transmission mode, the first conveying belt 22 is arranged in an inclined mode, and the inclination angle of the first conveying belt 22 is 30 degrees; the first feeding part can be used for automatically feeding reselected iron ores, and the reselected iron ores can be conveyed to the position above the feeding hole 9 of the mixing barrel 4 through the first conveyor belt 22 and can fall into the mixing barrel 4 from the feeding hole 9; the second feeding part comprises a fourth servo motor 26, a second conveyor belt 27, a second driving roller 28 and a second driven roller 29, wherein the fourth servo motor 26 is fixed on the rack 1, two ends of the second driving roller 28 and two ends of the second driven roller 29 are respectively connected to the rack 1 in a rotating mode, the fourth servo motor 26 is used for driving the second driving roller 28 to rotate, the second driving roller 28 and the second driven roller 29 are in transmission connection through the second conveyor belt 27, the second conveyor belt 27 is arranged in an inclined mode, and the inclination angle of the second conveyor belt 27 is 30 degrees; the second loading section can be used for automatically loading the dust, sludge and slag useful for steel making, which can be conveyed to the inlet of the mixing drum 4 by the second conveyor belt 27 in the second loading section and can fall into the mixing drum 4 from the feed opening 9 of the mixing drum 4.

As shown in fig. 1 to 7, the frame 1 is further provided with a transmission part below the first pipeline 15, wherein the transmission part includes a fifth servo motor 30, a third conveyor belt 31, a third drive roller 32 and a third driven roller 33, the fifth servo motor 30 is fixed on the frame 1, two ends of the third drive roller 32 and the third driven roller 33 are respectively rotatably connected to the frame 1, the fifth servo motor 30 is used to drive the third drive roller 32 to rotate, the third drive roller 32 and the third driven roller 33 are in transmission connection through the third conveyor belt 31, the third conveyor belt 31 is horizontally arranged, the mixed materials can be conveyed to a sintering workshop through the third conveyor belt 31 in the transmission part for agglomeration, and the degree of automation is high; in order to decelerate the second servo motor 16, a reducer 34 is arranged between the second servo motor 16 and the third gear 17, wherein the input end of the reducer 34 is connected with a motor shaft of the second servo motor 16, the output end of the reducer 34 is connected with the third gear 17, and the reducer 34 can reduce the output speed of the second servo motor 16, so that the first blade fixing rod 12 and the second blade fixing rod 13 are more stable during stirring and mixing; meanwhile, a feeding hopper 35 is erected above the lower ends of the first conveyor belt 22 and the second conveyor belt 27 on the first rack 1, a valve 36 is arranged at the bottom of the feeding hopper 35, the feeding hopper 35 at the first feeding part can conveniently feed materials to the first feeding part, gravity-separated iron ores can be conveniently added to the first conveyor belt 22, the feeding hopper 35 at the second feeding part can conveniently feed materials to the second feeding part, and dust, dust and slag which are useful for steel making can be conveniently added to the second conveyor belt 27; meanwhile, a plurality of partition plates 37 are fixed on the first conveyor belt 22 and the second conveyor belt at equal intervals, and the partition plates 37 on the first conveyor belt 22 and the second conveyor belt 27 can partition the materials on the first conveyor belt 22 and the second conveyor belt 27 into small piles and can prevent the materials from rolling off from the inclined first conveyor belt 22 and the inclined second conveyor belt 27.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (1)

1. The utility model provides an iron ore agglomeration is with large-scale compounding device, includes frame (1), its characterized in that: a first servo motor (2) is fixed on the frame (1), a first gear (3) is fixed on a motor shaft of the first servo motor (2), a mixing barrel (4) is connected to the frame (1) in a rotating manner, a second gear (5) is fixed outside the mixing barrel (4), the first gear (3) and the second gear (5) are meshed with each other, a plurality of rake rods (6) are fixed in the mixing barrel (4), in order to prevent materials from falling down uncontrollably, the mixing barrel (4) is also connected with a blocking plate in a sliding manner along the horizontal direction, the rake rods (6) can preliminarily mix the materials, then the cylinder is started to drive the blocking plate to slide in the mixing barrel (4), the mixed materials fall into the mixing box (11), a cylinder body of the cylinder is fixed outside the mixing barrel (4), and the end part of a piston rod of the cylinder is fixed on the blocking plate, the mixing device is characterized in that a feeding hole (9) and a discharging hole (10) are formed in the mixing cylinder (4), the discharging hole (10) of the mixing cylinder (4) is connected into a mixing box (11), the mixing box (11) is fixed on the rack (1), a first blade fixing rod (12) and a second blade fixing rod (13) are further rotatably connected into the mixing box (11), a plurality of stirring blades (14) are respectively fixed on the first blade fixing rod (12) and the second blade fixing rod (13), a first pipeline (15) is further communicated with the bottom of the mixing box (11), the first blade fixing rod (12) and the second blade fixing rod (13) are driven to rotate by a power part, and a first feeding part and a second feeding part which are convenient to feed from the feeding hole (9) are further arranged on the rack (1);

the power part comprises a second servo motor (16), a third gear (17), a fourth gear (18), a fifth gear (19) and a sixth gear (20), the second servo motor (16) is fixed on the rack (1), the second servo motor (16) drives the third gear (17) to rotate, the third gear (17) is fixed at the end part of the first blade fixing rod (12), the sixth gear (20) is fixed at the end part of the second blade fixing rod (13), the fourth gear (18) and the fifth gear (19) are both rotationally connected to the outer part of the mixing box (11), the third gear (17) and the fourth gear (18) are meshed with each other, the fourth gear (18) and the fifth gear (19) are meshed with each other, and the fifth gear (19) and the sixth gear (20) are meshed with each other;

the first feeding part comprises a third servo motor (21), a first conveying belt (22), a first driving roller (23) and a first driven roller (24), the third servo motor (21) is fixed on the rack (1), two ends of the first driving roller (23) and two ends of the first driven roller (24) are respectively connected to the rack (1) in a rotating mode, the third servo motor (21) drives the first driving roller (23) to rotate, the first driving roller (23) and the first driven roller (24) are in transmission connection through the first conveying belt (22), and the first conveying belt (22) is arranged in an inclined mode;

the second feeding part comprises a fourth servo motor (26), a second conveying belt (27), a second driving roller (28) and a second driven roller (29), the fourth servo motor (26) is fixed on the rack (1), two ends of the second driving roller (28) and two ends of the second driven roller (29) are respectively connected to the rack (1) in a rotating mode, the fourth servo motor (26) drives the second driving roller (28) to rotate, the second driving roller (28) and the second driven roller (29) are connected through the second conveying belt (27) in a transmission mode, and the second conveying belt (27) is arranged in an inclined mode;

the rack (1) is further provided with a transmission part below the first pipeline (15), the transmission part comprises a fifth servo motor (30), a third conveyor belt (31), a third driving roller (32) and a third driven roller (33), the fifth servo motor (30) is fixed on the rack (1), two ends of the third driving roller (32) and two ends of the third driven roller (33) are respectively connected to the rack (1) in a rotating mode, the fifth servo motor (30) drives the third driving roller (32) to rotate, the third driving roller (32) and the third driven roller (33) are in transmission connection through the third conveyor belt (31), and the third conveyor belt (31) is horizontally arranged;

a speed reducer (34) is arranged between the second servo motor (16) and the third gear (17), the input end of the speed reducer (34) is connected with a motor shaft of the second servo motor (16), and the output end of the speed reducer (34) is connected with the third gear (17);

a feeding hopper (35) is further erected above the lower ends of the first conveyor belt (22) and the second conveyor belt (27) of the rack (1), and a valve (36) is arranged at the bottom of the feeding hopper (35);

a plurality of partition plates (37) are fixed on the first conveyor belt (22) and the second conveyor belt at equal intervals.

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