CN111888810A

CN111888810A - Mineral impurity precipitation machine

Info

Publication number: CN111888810A
Application number: CN202010780586.3A
Authority: CN
Inventors: 那亚洲
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-06
Filing date: 2020-08-06
Publication date: 2020-11-06

Abstract

The invention discloses an ore impurity settling machine, which relates to the technical field of mining equipment and comprises a barrel, a material blocking part, an impurity crushing mechanism, a stirring part, a rotating seat, a jacking control part, a position fixing part, a settling assembly and a rack. The barrel and the both ends of establishing respectively at the frame of rotating the seat, the both ends of barrel are equipped with one respectively and keep off material spare, and the upper end at the barrel can be unpicked and washed in the broken mechanism of impurity, and the lower extreme at the barrel is established to the stirring piece, and roof pressure control piece cooperation is connected on rotating the seat, evenly encircles on the roof pressure control piece and is equipped with four position mounting, and four sediment subassemblies can be dismantled respectively and connect on four position mounting, and two sediment subassemblies of horizontal direction are corresponding the setting with two fender material spares respectively.

Description

Mineral impurity precipitation machine

Technical Field

The invention relates to the technical field of mining equipment, in particular to an ore impurity precipitator.

Background

The invention provides an ore impurity settling machine with the prior patent number of CN201810213194.1, which comprises a supporting bottom plate, a reflux plate and a positioning groove, wherein a servo motor is fixedly arranged in the center of the bottom of the supporting bottom plate, and the periphery of the bottom of the servo motor is fixed at the bottom end of the inner side of a vertical rectangular supporting plate arranged at two ends of the top of the supporting bottom plate through an I-shaped fixing frame body of a ring sleeve; the top rotating shaft of the servo motor is rotatably connected inside the upper mixing homogenizer, and six support columns are arranged between the bottom of the mixing homogenizer and the support bottom plate and surround the servo motor. According to the arrangement of the T-shaped pipe and the electromagnetic control valves, the T-shaped pipe is arranged at the top of the mixing homogenizer, and the two symmetric electromagnetic control valves are arranged on the T-shaped pipe, so that two groups of symmetric structures are arranged on two sides of the mixing homogenizer, the device on one side can be kept to normally operate when a sedimentation cylinder is replaced, the continuity of the process is guaranteed, and the production pause cost is reduced. But the device cannot replace different settling assemblies according to the viscosity of the ore pulp.

Disclosure of Invention

The invention aims to provide an ore impurity settling machine, which has the beneficial effects that different settling components can be replaced according to different viscosities of ore pulp, and further a settling mode adaptive to the viscosity of the ore pulp is selected.

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

the utility model provides an ore deposit impurity deposits machine, includes the barrel, keeps off material spare, the broken mechanism of impurity, stirs the piece, rotates seat, roof pressure control piece, position fixing spare, deposits subassembly and frame, the barrel with rotate the seat and establish respectively at the both ends of frame, the both ends of barrel are equipped with one respectively and keep off material spare, the broken mechanism of impurity can unpick and wash the upper end of connecting at the barrel, the stirring piece is established at the lower extreme of barrel, roof pressure control piece cooperation is connected on rotating the seat, evenly encircle on the roof pressure control piece and be equipped with four position fixing spare, four deposit the subassembly and can dismantle respectively and connect on four position fixing spare, two sediment subassemblies of horizontal direction correspond the setting with two material blocking spare respectively.

As a further optimization of the technical scheme, the ore impurity precipitating machine is characterized in that a material separating barrel, a material outlet and a jack are arranged on a barrel body; two ends of the cylinder body are respectively fixedly connected and communicated with a material separating barrel, the lower ends of the two material separating barrels are respectively provided with a discharge hole, and the upper end of the cylinder body is symmetrically provided with two insertion holes; the stirring piece comprises a first motor and a stirring plate; the first motor is fixedly connected to the lower end of the barrel through a motor frame, an output shaft of the first motor is connected to the bottom surface of the barrel in a sealing and rotating mode, and the plurality of stirring plates are fixedly connected to the output shaft of the first motor; the stirring plate is positioned at the lower end inside the barrel.

As a further optimization of the technical scheme, the ore impurity precipitator comprises two material blocking pieces which are respectively blocked on two discharge holes, wherein the two material blocking pieces respectively comprise two elastic blocking pieces which are oppositely arranged, and each elastic blocking piece comprises a rotating shaft, a spring seat, a spring and a baffle; the pivot fixed connection is on the spring holder, and spring holder fixed connection is on the inside bottom surface of branch feed cylinder, and the both ends of spring are fixed connection spring holder and baffle respectively, and the outer end of baffle rotates to be connected in the pivot, and baffle lid box is on the discharge opening.

As a further optimization of the technical scheme, the invention relates to an ore impurity precipitating machine, wherein an impurity crushing mechanism comprises a circular ring seat, an annular groove, L-shaped screw seats, inserting screws, a top plate, a second motor, a rotating frame, an inclined frame, a third motor and a crushing rotary table, the circular ring seat is internally provided with the annular groove, two ends of the circular ring seat are respectively and fixedly connected with the L-shaped screw seats, the two L-shaped screw seats are respectively and cooperatively connected with one inserting screw through threads, the inner ends of the two inserting screws are respectively inserted into the two inserting holes, the top plate is fixedly connected on the circular ring seat, the second motor is fixedly connected on the top plate through a motor frame, an output shaft of the second motor is rotatably connected on the top plate, the rotating frame is fixedly connected on an output shaft of the second motor, the outer end of the rotating frame is slidably and cooperatively connected in the annular groove, the lower end of the rotating frame is symmetrically and fixedly connected with the two inclined frames, the two third motors are, two broken turntables are fixed connection respectively on the output shaft of two third motors, and the outer end of two broken turntables is close to each other and is the angle setting.

As a further optimization of the technical scheme, the mine impurity precipitating machine provided by the invention comprises a rotating seat, a rotating shaft and a rotating shaft, wherein the rotating shaft is arranged; the middle part of the cylinder is fixedly connected with a disc, four mounting grooves are uniformly arranged on the disc in a surrounding manner, a screw frame is fixedly connected to the lower end of the cylinder, a long screw is connected to the screw frame in a thread fit manner, and four vertical sliding grooves are arranged at the upper end of the cylinder in a surrounding manner; the rack comprises a barrel frame, a bracket and a through hole; the barrel frame is fixedly connected to the support, two through holes are formed in the front end of the support, the lower end of the long screw is inserted into one through hole, the cylinder is rotatably connected to the support, and the barrel is fixedly connected to the barrel frame; the jacking control part is arranged at the upper end of the cylinder.

As a further optimization of the technical scheme, the ore impurity settling machine provided by the invention is characterized in that the jacking control part comprises a fourth motor, a screw and a cross; the fourth motor is fixedly connected to the upper end of the cylinder through a motor frame, an output shaft of the fourth motor is connected with the screw rod through a coupler, the middle of the cross is connected to the screw rod through thread fit, four outer ends of the cross are connected to four vertical sliding grooves in a sliding fit mode respectively, and four outer ends of the cross are fixedly connected with a position fixing piece respectively.

As a further optimization of the technical scheme, the position fixing piece of the mineral impurity precipitating machine comprises a middle frame, a guide rod, a two-way screw rod, a driven gear, a driving gear, a fifth motor, a folding rod and an inserting rod; middle frame fixed connection is on the cross, guide arm fixed connection is on middle frame, two-way screw rod rotates to be connected on middle frame, driven gear fixed connection is at the middle part of two-way screw rod, driven gear is connected with the driving gear meshing transmission, driving gear fixed connection is on the output shaft of fifth motor, fifth motor passes through motor frame fixed connection on middle frame, two folding rods are connected at the both ends of two-way screw rod through screw-thread fit respectively, an inserted bar of fixed connection is respectively in the inner of two folding rods, two inserted bars all insert in a precipitation component.

As a further optimization of the technical scheme, the ore impurity precipitating machine provided by the invention comprises a precipitating assembly, a first motor, a second motor, a third motor, a fourth motor, a fifth motor, a sixth motor, a third motor, a fourth motor, a sixth motor, a; the conical sleeve seat is connected to the lower end of the hollow cylinder in a threaded fit manner, and the upper end of the hollow cylinder is symmetrically and fixedly connected with the two slot seats; the insertion rod is inserted into the insertion slot seat, the feeding pipe and the liquid discharge pipe are respectively fixedly connected and communicated with the upper end and the lower end of the conical sleeve seat, the sixth motor is fixedly connected to the lower end of the conical sleeve seat through a motor frame, an output shaft of the sixth motor is connected with the driving shaft through a coupler, the driving shaft is connected to the lower end of the conical sleeve seat in a sealing and rotating mode, the spiral conveying blade is fixedly connected to the driving shaft, and the spiral conveying blade is located in the hollow cylinder; the diameter of the hollow cylinders on the two transverse sedimentation assemblies is not equal to that of the hollow cylinders on the two longitudinal sedimentation assemblies.

As a further optimization of the technical scheme, the ore impurity precipitator is characterized in that a plurality of filter holes are formed in the crushing rotary disc.

As a further optimization of the technical scheme, the mine impurity precipitating machine is characterized in that the top surface of the cylinder body is symmetrically provided with two grooves, and two L-shaped screw seats are respectively connected in the two grooves in a clearance fit manner.

The mineral impurity precipitator provided by the invention has the beneficial effects that:

according to the ore impurity settling machine, the impurity crushing mechanism and the stirring piece rotate in opposite directions to stir ore pulp with high viscosity, the angle of the rotating seat is changed, two settling assemblies with different capacities correspond to the lower end of the cylinder body, the ore impurity settling machine is suitable for settling the ore pulp with different viscosities, and the impurity crushing mechanism can grind lumps in the ore pulp to enable the ore pulp to be more uniform in texture, so that the ore pulp can better react with attachments of insoluble salt settling media to generate settlement.

Drawings

FIG. 1 is a first schematic structural diagram of a mineral impurity precipitator in accordance with the present invention;

FIG. 2 is a schematic structural diagram II of a mineral impurity precipitator according to the present invention;

FIG. 3 is a schematic view of a portion of the structure of an ore impurity precipitator in accordance with the present invention;

FIG. 4 is a schematic cross-sectional view of a mineral impurity precipitator in accordance with the present invention;

FIG. 5 is a first schematic structural view of the cylinder and the stirring member;

FIG. 6 is a second schematic structural view of the cylinder and the stirring member;

FIG. 7 is a schematic structural view of the elastic stopper;

FIG. 8 is a schematic structural view of a foreign matter crushing mechanism;

FIG. 9 is a schematic structural view of the rotary base and the frame;

FIG. 10 is a schematic view of the pressing member and the fixing member;

fig. 11 is a schematic structural view of the precipitation assembly.

In the figure: a cylinder body 1; a material separating barrel 1-1; a discharge hole 1-2; 1-3 of jacks; 1-4 of a groove; an elastic stopper 2; a rotating shaft 2-1; a spring seat 2-2; 2-3 of a spring; 2-4 of a baffle plate; an impurity crushing mechanism 3; 3-1 of a circular ring seat; an annular groove 3-2; 3-3 of an L-shaped screw seat; 3-4 of inserting screws; a top plate 3-5; a second electric machine 3-6; 3-7 of a rotating frame; 3-8 parts of a sloping frame; a third motor 3-9; 3-10 parts of a crushing rotary table; a stirring member 4; a first motor 4-1; 4-2 of a stirring plate; a rotating seat 5; 5-1 of a cylinder; 5-2 of a disc; mounting grooves 5-3; 5-4 parts of a screw frame; 5-5 of long screws; 5-6 of vertical sliding chute; pressing the control part 6; a fourth motor 6-1; 6-2 parts of a screw; 6-3 of a cross; the position is fixed into 7; a middle frame 7-1; a guide rod 7-2; 7-3 of a bidirectional screw; 7-4 of a driven gear; a driving gear 7-5; a fifth motor 7-6; 7-7 of folding rods; 7-8 parts of inserted bar; a precipitation assembly 8; 8-1 of a hollow cylinder; a conical sleeve seat 8-2; 8-3 of a slot seat; a feed pipe 8-4; 8-5 of a liquid discharge pipe; a sixth motor 8-6; a drive shaft 8-7; 8-8 parts of spiral conveying blades; a frame 9; a barrel frame 9-1; a support 9-2; and (4) a through hole 9-3.

Detailed Description

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Moreover, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; the electrical components that appear in this application all external intercommunication power and control switch when using.

The present invention is described in further detail below with reference to the accompanying figures 1-11 and the detailed description.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 11, and an ore impurity precipitator includes a barrel 1, a material blocking member, an impurity crushing mechanism 3, a stirring member 4, a rotating base 5, a top pressure control member 6, a position fixing member 7, precipitation assemblies 8 and a frame 9, wherein the barrel 1 and the rotating base 5 are respectively disposed at two ends of the frame 9, the two ends of the barrel 1 are respectively provided with the material blocking member, the impurity crushing mechanism 3 is detachably connected to the upper end of the barrel 1, the stirring member 4 is disposed at the lower end of the barrel 1, the top pressure control member 6 is connected to the rotating base 5 in a matching manner, the top pressure control member 6 is uniformly provided with four position fixing members 7 in a surrounding manner, the four precipitation assemblies 8 are respectively detachably connected to the four position fixing members 7, and the two precipitation assemblies 8 in a horizontal direction are respectively arranged corresponding to the two material blocking. When the device is used, ore pulp to be precipitated is added into the barrel 1, attachments of insoluble salt precipitating media are added into the precipitating assemblies 8, the impurity crushing mechanism 3 and the stirring piece 4 rotate in opposite directions to stir the ore pulp with high viscosity, the jacking control piece 6 moves upwards to drive the four precipitating assemblies 8 to move upwards through the four position fixing pieces 7, the two precipitating assemblies 8 corresponding to the lower ends of the left end and the right end of the barrel 1 move upwards to jack the two material blocking pieces, the ore pulp flows into the two precipitating assemblies 8 to react with the attachments of the insoluble salt precipitating media in the two precipitating assemblies 8 to generate precipitates, the precipitates are deposited at the lower ends of the precipitating assemblies 8, the lower ends of the precipitating assemblies 8 can be opened to clear the precipitates, the rotating seat 5 is rotated to change the position of the rotating seat 5 on the rack 9, so that the two precipitating assemblies 8 with different volumes correspond to the lower end of the barrel 1, the method is suitable for the precipitation treatment of ore pulp with different viscosities.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 11, wherein the cylinder 1 is provided with a material separating cylinder 1-1, a material outlet 1-2 and an insertion hole 1-3; two ends of the cylinder body 1 are respectively fixedly connected and communicated with a material dividing cylinder 1-1, the lower ends of the two material dividing cylinders 1-1 are respectively provided with a discharge hole 1-2, and the upper end of the cylinder body 1 is symmetrically provided with two insertion holes 1-3; the stirring piece 4 comprises a first motor 4-1 and a stirring plate 4-2; the first motor 4-1 is fixedly connected to the lower end of the barrel 1 through a motor frame, an output shaft of the first motor 4-1 is hermetically and rotatably connected to the bottom surface of the barrel 1, and the plurality of stirring plates 4-2 are fixedly connected to the output shaft of the first motor 4-1; the stirring plate 4-2 is positioned at the lower end of the interior of the barrel body 1. When the stirring device is used, ore pulp is put into the barrel body 1, the first motor 4-1 is started to drive the stirring plates 4-2 to rotate clockwise, and the stirring plates 4-2 stir the ore pulp.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 11, two material blocking members are respectively blocked on two discharging holes 1 to 2, the two material blocking members are respectively composed of two elastic blocking members 2 oppositely arranged, and each elastic blocking member 2 includes a rotating shaft 2-1, a spring seat 2-2, a spring 2-3 and a baffle 2-4; the rotating shaft 2-1 is fixedly connected to the spring seat 2-2, the spring seat 2-2 is fixedly connected to the bottom surface inside the material separating barrel 1-1, two ends of the spring 2-3 are respectively and fixedly connected with the spring seat 2-2 and the baffle plate 2-4, the outer end of the baffle plate 2-4 is rotatably connected to the rotating shaft 2-1, and the baffle plate 2-4 covers the box on the discharging hole 1-2. When the device is used, the two material blocking parts respectively close the two discharge holes 1-2, when the sedimentation component 8 upwards extrudes the two baffle plates 2-4, the two springs 2-3 are compressed, the discharge holes 1-2 are opened, ore pulp can enter the sedimentation component 8 through the discharge holes 1-2 for sedimentation reaction, and the springs 2-3 are convenient for the baffle plates 2-4 to reset quickly when not stressed so as to close the discharge holes 1-2.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-11, the impurity crushing mechanism 3 includes a circular ring base 3-1, an annular groove 3-2, an L-shaped screw base 3-3, insertion screws 3-4, a top plate 3-5, a second motor 3-6, a rotating frame 3-7, an inclined frame 3-8, a third motor 3-9 and a crushing rotary disk 3-10, the annular groove 3-2 is arranged inside the circular ring base 3-1, two ends of the circular ring base 3-1 are respectively and fixedly connected with the L-shaped screw base 3-3, the two L-shaped screw bases 3-3 are respectively connected with the insertion screws 3-4 through screw thread fit, inner ends of the two insertion screws 3-4 are respectively inserted into the two insertion holes 1-3, the top plate 3-5 is fixedly connected to the circular ring base 3-1, the second motor 3-6 is fixedly connected to the top plate 3-5 through a motor frame, an output shaft of the second motor 3-6 is rotatably connected to the top plate 3-5, the rotating frame 3-7 is fixedly connected to an output shaft of the second motor 3-6, the outer end of the rotating frame 3-7 is connected to the annular groove 3-2 in a sliding fit mode, the lower end of the rotating frame 3-7 is symmetrically and fixedly connected with two inclined frames 3-8, the two third motors 3-9 are fixedly connected to the two inclined frames 3-8 through the motor frame respectively, the two crushing rotary tables 3-10 are fixedly connected to output shafts of the two third motors 3-9 respectively, and the outer ends of the two crushing rotary tables 3-10 are arranged close to each other and form an angle. When the impurity crushing mechanism is used, the inner ends of the two inserting screws 3-4 are respectively inserted into the two inserting holes 1-3, the two inserting screws 3-4 are screwed out to be separated from the two inserting holes 1-3, the impurity crushing mechanism 3 can be integrally dismounted from the barrel body 1, and the impurity crushing mechanism 3 is convenient to clean; the second motor 3-6 is started to drive the rotating frame 3-7 to rotate anticlockwise in the annular groove 3-2, the annular seat 3-1 supports the outer end of the rotating frame 3-7, the rotating frame 3-7 drives the two crushing rotary tables 3-10 to do anticlockwise circular motion around the axis of the output shaft of the second motor 3-6, large lumps in ore pulp enter between the two crushing rotary tables 3-10 in the anticlockwise circular motion process of the two crushing rotary tables 3-10 arranged at an angle, the two third motors 3-9 drive the two crushing rotary tables 3-10 to rotate towards the direction of the near end of the two crushing rotary tables 3-10, and under the action of the rotation of the two crushing rotary tables 3-10 and the angle formed by the two crushing rotary tables 3-10, the lumps entering between the two crushing rotary tables 3-10 are ground and crushed by the two crushing rotary tables 3-10 with the same rotation direction And crushing, wherein the clockwise rotation of the stirring plates 4-2 is opposite to the direction of circular motion of the two crushing turntables 3-10, so that slurry generates clockwise rotational flow under the drive of the stirring plates 4-2, agglomerates in the slurry can move between the two crushing turntables 3-10 in a manner of meeting, and the agglomerates are pushed to an angle formed by the two crushing turntables 3-10 by the rotational flow, so that the agglomerates are more fully ground and crushed, and meanwhile, under the action force of the rotational flow and the rotating action of the two crushing turntables 3-10 which are in the same direction, the polished agglomerates are prevented from leaking between the two crushing turntables 3-10.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-11, and the rotating base 5 includes a cylinder 5-1, a disk 5-2, a mounting groove 5-3, a screw rack 5-4, a long screw 5-5 and a vertical sliding groove 5-6; the middle part of the cylinder 5-1 is fixedly connected with a disc 5-2, four mounting grooves 5-3 are uniformly arranged on the disc 5-2 in a surrounding manner, a screw frame 5-4 is fixedly connected to the lower end of the cylinder 5-1, a long screw 5-5 is connected to the screw frame 5-4 through thread fit, and four vertical sliding grooves 5-6 are arranged at the upper end of the cylinder 5-1 in a surrounding manner; the rack 9 comprises a barrel frame 9-1, a bracket 9-2 and a through hole 9-3; the barrel frame 9-1 is fixedly connected to the support 9-2, the front end of the support 9-2 is provided with two through holes 9-3, the lower end of a long screw 5-5 is inserted into one through hole 9-3, the cylinder 5-1 is rotatably connected to the support 9-2, and the barrel 1 is fixedly connected to the barrel frame 9-1; the jacking control piece 6 is arranged at the upper end of the column 5-1. When the long screw 5-5 is screwed out and inserted into the other through hole 9-3 in use, the cylinder 5-1 rotates 90 degrees on the bracket 9-2 to drive the disc 5-2 to rotate 90 degrees, the disc 5-2 drives the four sedimentation assemblies 8 to rotate 90 degrees through the jacking control part 6 and the four position fixing parts 7, the other two sedimentation assemblies 8 with different capacities are switched to the lower ends of the two elastic blocking parts 2, and sedimentation treatment is conveniently carried out on ore pulps with different viscosities.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 11, wherein the pressing control member 6 includes a fourth motor 6-1, a screw 6-2 and a cross 6-3; the fourth motor 6-1 is fixedly connected to the upper end of the column 5-1 through a motor frame, an output shaft of the fourth motor 6-1 is connected with the screw 6-2 through a coupler, the middle of the cross 6-3 is connected to the screw 6-2 through thread fit, four outer ends of the cross 6-3 are respectively connected into the four vertical sliding grooves 5-6 in a sliding fit mode, and four outer ends of the cross 6-3 are respectively fixedly connected with a position fixing piece 7. When the device is used, the fourth motor 6-1 is started to drive the cross 6-3 to move up and down through the screw 6-2, and the cross 6-3 drives the four position fixing pieces 7 and the four sedimentation assemblies 8 to move up and down.

The seventh embodiment:

referring to fig. 1-11, the position fixing member 7 includes an intermediate frame 7-1, a guide rod 7-2, a two-way screw 7-3, a driven gear 7-4, a driving gear 7-5, a fifth motor 7-6, a folding rod 7-7, and an insertion rod 7-8; the middle frame 7-1 is fixedly connected to the cross 6-3, the guide rod 7-2 is fixedly connected to the middle frame 7-1, the bidirectional screw 7-3 is rotatably connected to the middle frame 7-1, the driven gear 7-4 is fixedly connected to the middle of the bidirectional screw 7-3, the driven gear 7-4 is in meshing transmission connection with the driving gear 7-5, the driving gear 7-5 is fixedly connected to an output shaft of the fifth motor 7-6, the fifth motor 7-6 is fixedly connected to the middle frame 7-1 through the motor frame, the two folding rods 7-7 are respectively connected to two ends of the bidirectional screw 7-3 through thread matching, the inner ends of the two folding rods 7-7 are respectively and fixedly connected with the inserting rods 7-8, and the two inserting rods 7-8 are all inserted into the precipitation assembly 8. When the sedimentation device is used, the fifth motor 7-6 is started to drive the driven gear 7-4 and the bidirectional screw 7-3 to rotate through the driving gear 7-5, the bidirectional screw 7-3 drives the two folding rods 7-7 and the two insertion rods 7-8 to be close to or far away from each other, and the two insertion rods 7-8 are close to each other and inserted into the sedimentation assembly 8 to fix the position of the sedimentation assembly 8.

The specific implementation mode is eight:

the present embodiment will be described with reference to fig. 1-11, wherein the settling assembly 8 comprises a hollow cylinder 8-1, a conical sleeve seat 8-2, a socket seat 8-3, a feeding pipe 8-4 with a screw cap, a discharge pipe 8-5 with a control valve, a sixth motor 8-6, a driving shaft 8-7 and a spiral conveying blade 8-8; the conical sleeve seat 8-2 is connected to the lower end of the hollow cylinder 8-1 in a threaded fit manner, and the upper end of the hollow cylinder 8-1 is symmetrically and fixedly connected with the two slot seats 8-3; the insertion rod 7-8 is inserted into the insertion groove seat 8-3, the feeding pipe 8-4 and the liquid discharge pipe 8-5 are respectively fixedly connected and communicated with the upper end and the lower end of the conical sleeve seat 8-2, the sixth motor 8-6 is fixedly connected with the lower end of the conical sleeve seat 8-2 through a motor frame, an output shaft of the sixth motor 8-6 is connected with the driving shaft 8-7 through a coupling, the driving shaft 8-7 is connected with the lower end of the conical sleeve seat 8-2 in a sealing and rotating mode, the spiral conveying blade 8-8 is fixedly connected to the driving shaft 8-7, and the spiral conveying blade 8-8 is located in the hollow cylinder 8-1; the diameter of the hollow cylinders 8-1 on the two transverse settling assemblies 8 is not equal to the diameter of the hollow cylinders 8-1 on the two longitudinal settling assemblies 8. When in use, the two insert rods 7-8 are inserted into the two slot seats 8-3 to fix the position of the sedimentation assembly 8, and when the two insert rods 7-8 are separated from the two slot seats 8-3, the sedimentation assembly 8 can be detached and replaced by sedimentation assemblies 8 with different capacities; after a cover on a feeding pipe 8-4 is unscrewed, attachments of insoluble salt precipitation media can be put into a conical sleeve seat 8-2 through the feeding pipe 8-4, a position fixing piece 7 drives a hollow cylinder 8-1 to move upwards, the upper end of a spiral conveying blade 8-8 penetrates out of the hollow cylinder 8-1, the spiral conveying blade 8-8 pushes a baffle 2-4 upwards to drive the baffle 2-4 to rotate upwards to open a discharge hole 1-2, the hollow cylinder 8-1 is abutted against the bottom surface of a charging barrel 1-1, the upper end of the spiral conveying blade 8-8 is inserted into the charging barrel 1-1, a sixth motor 8-6 is started to drive the spiral conveying blade 8-8 to rotate, the rotating spiral conveying blade 8-8 drives ore pulp in the charging barrel 1-1 to flow downwards, and the phenomenon that the ore pulp cannot automatically flow downwards into the hollow cylinder 8-1 due to high viscosity is avoided, the ore pulp enters the conical sleeve seat 8-2 to react with attachments of insoluble salt precipitation media to generate precipitation, the precipitated ore pulp is discharged from the liquid discharge pipe 8-5, the precipitation is deposited in the conical sleeve seat 8-2, and the precipitation in the conical sleeve seat 8-2 and the spiral conveying blades 8-8 can be cleaned by screwing off the conical sleeve seat 8-2; the diameters of the hollow cylinders 8-1 on the two transverse sedimentation assemblies 8 are not equal to the diameters of the hollow cylinders 8-1 on the two longitudinal sedimentation assemblies 8, when the pulp has high viscosity, the rotating seat 5 drives the four sedimentation assemblies 8 to rotate by 90 degrees, and the other two hollow cylinders 8-1 with large diameters move to the lower ends of the two material distributing cylinders 1-1, so that the pulp with high viscosity is drained downwards for sedimentation treatment; the device can simultaneously carry out precipitation treatment on ore pulp from two directions, the four precipitation components 8 are detachably connected on the four position fixing pieces 7, and hollow cylinders 8-1 with different diameters can be adjusted to be positioned at the lower ends of the two charging branch cylinders 1-1, so that the precipitation treatment of the ore pulp under different modes or with different efficiencies can be carried out; the conical sleeve seat 8-2 is arranged to be conical, so that the bottom of the conical sleeve seat 8-2 is larger, more attachments of the insoluble salt precipitating medium can be conveniently contained, and meanwhile, the ore pulp can have enough space to more fully react with the attachments of the insoluble salt precipitating medium.

The specific implementation method nine:

the present embodiment will be described with reference to fig. 1 to 11, wherein the crushing turntable 3 to 10 is provided with a plurality of filtering holes. The ground agglomerates can be discharged from the filter holes.

The detailed implementation mode is ten:

in the following, referring to fig. 1-11, the top surface of the barrel 1 is symmetrically provided with two grooves 1-4, and two L-shaped screw seats 3-3 are respectively connected in the two grooves 1-4 in a clearance fit manner. When the impurity crushing mechanism 3 is arranged on the barrel 1, the inserting screws 3-4 can be accurately aligned to the inserting holes 1-3, and the inserting screws 3-4 are not required to be aligned to the inserting holes 1-3 when the impurity crushing mechanism 3 is rotated.

The working principle of the ore impurity precipitator is as follows: when the device is used, ore pulp to be precipitated is added into a barrel 1, attachments of insoluble salt precipitating media are added into precipitating assemblies 8, an impurity crushing mechanism 3 and a stirring piece 4 rotate in opposite directions to stir the ore pulp with high viscosity, a jacking control piece 6 moves upwards to drive the four precipitating assemblies 8 to move upwards through four position fixing pieces 7, two precipitating assemblies 8 corresponding to the lower ends of the left end and the right end of the barrel 1 move upwards to jack two material blocking pieces, the ore pulp flows into the two precipitating assemblies 8 to react with the attachments of the insoluble salt precipitating media in the two precipitating assemblies 8 to generate precipitates, the precipitates are deposited at the lower ends of the precipitating assemblies 8, the lower ends of the precipitating assemblies 8 can be opened to clear the precipitates, a rotating seat 5 is rotated to change the position of the rotating seat 5 on a rack 9, so that the two precipitating assemblies 8 with different volumes correspond to the lower end of the barrel 1, the method is suitable for the precipitation treatment of ore pulp with different viscosities.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a mineral impurity deposits machine, includes barrel (1), keeps off material spare, impurity crushing mechanism (3), stirring (4), rotates seat (5), roof pressure control piece (6), position fixing spare (7), deposits subassembly (8) and frame (9), its characterized in that: barrel (1) and rotate seat (5) and establish the both ends in frame (9) respectively, the both ends of barrel (1) are equipped with one respectively and keep off material spare, impurity crushing mechanism (3) can be unpicked and washed and connect the upper end in barrel (1), the lower extreme in barrel (1) is established in stirring piece (4), roof pressure control piece (6) cooperation is connected on rotating seat (5), evenly encircle on roof pressure control piece (6) and be equipped with four position mounting (7), connection can be dismantled respectively on four position mounting (7) in four sediment subassembly (8), two sediment subassemblies (8) of horizontal direction correspond the setting with two material blocking spare respectively.

2. The mineral impurity precipitation machine according to claim 1, characterized in that: the cylinder body (1) is provided with a material separating barrel (1-1), a material outlet (1-2) and an insertion hole (1-3); two ends of the cylinder body (1) are respectively fixedly connected and communicated with one material distribution cylinder (1-1), the lower ends of the two material distribution cylinders (1-1) are respectively provided with a discharge hole (1-2), and the upper end of the cylinder body (1) is symmetrically provided with two insertion holes (1-3); the stirring piece (4) comprises a first motor (4-1) and a stirring plate (4-2); the first motor (4-1) is fixedly connected to the lower end of the barrel body (1) through a motor frame, an output shaft of the first motor (4-1) is connected to the bottom surface of the barrel body (1) in a sealing and rotating mode, and the plurality of stirring plates (4-2) are fixedly connected to the output shaft of the first motor (4-1); the stirring plate (4-2) is positioned at the lower end of the interior of the barrel body (1).

3. The mine impurity precipitation machine according to claim 2, wherein: the two material blocking pieces are respectively blocked on the two discharging holes (1-2), the two material blocking pieces are respectively composed of two elastic blocking pieces (2) which are oppositely arranged, and each elastic blocking piece (2) comprises a rotating shaft (2-1), a spring seat (2-2), a spring (2-3) and a baffle (2-4); the rotating shaft (2-1) is fixedly connected to the spring seat (2-2), the spring seat (2-2) is fixedly connected to the bottom surface inside the material separating barrel (1-1), the two ends of the spring (2-3) are respectively fixedly connected with the spring seat (2-2) and the baffle (2-4), the outer end of the baffle (2-4) is rotatably connected to the rotating shaft (2-1), and the baffle (2-4) covers the box on the discharge hole (1-2).

4. A mineral impurity precipitation machine according to claim 3, characterized in that: the impurity crushing mechanism (3) comprises a circular ring seat (3-1), an annular groove (3-2), L-shaped screw seats (3-3), inserting screws (3-4), a top plate (3-5), a second motor (3-6), a rotating frame (3-7), an inclined frame (3-8), a third motor (3-9) and a crushing rotary table (3-10), wherein the annular groove (3-2) is arranged inside the circular ring seat (3-1), two ends of the circular ring seat (3-1) are respectively and fixedly connected with the L-shaped screw seats (3-3), the two L-shaped screw seats (3-3) are respectively connected with the inserting screws (3-4) in a threaded fit manner, the inner ends of the two inserting screws (3-4) are respectively inserted into the two insertion holes (1-3), the top plate (3-5) is fixedly connected to the circular ring seat (3-1), the second motor (3-6) is fixedly connected to the top plate (3-5) through a motor frame, an output shaft of the second motor (3-6) is rotatably connected to the top plate (3-5), the rotating frame (3-7) is fixedly connected to an output shaft of the second motor (3-6), the outer end of the rotating frame (3-7) is connected to the annular groove (3-2) in a sliding fit manner, the lower end of the rotating frame (3-7) is symmetrically and fixedly connected with two inclined frames (3-8), the two third motors (3-9) are respectively and fixedly connected to the two inclined frames (3-8) through motor frames, the two crushing rotary tables (3-10) are respectively and fixedly connected to output shafts of the two third motors (3-9), the outer ends of the two crushing turntables (3-10) are arranged close to each other at an angle.

5. The mineral impurity precipitation machine of claim 4, wherein: the rotating seat (5) comprises a cylinder (5-1), a disc (5-2), a mounting groove (5-3), a screw frame (5-4), a long screw (5-5) and a vertical sliding groove (5-6); the middle part of the cylinder (5-1) is fixedly connected with a disc (5-2), four mounting grooves (5-3) are uniformly arranged on the disc (5-2) in a surrounding manner, a screw frame (5-4) is fixedly connected to the lower end of the cylinder (5-1), a long screw (5-5) is connected to the screw frame (5-4) in a threaded fit manner, and four vertical sliding grooves (5-6) are arranged at the upper end of the cylinder (5-1) in a surrounding manner; the rack (9) comprises a barrel frame (9-1), a bracket (9-2) and a through hole (9-3); the barrel frame (9-1) is fixedly connected to the support (9-2), two through holes (9-3) are formed in the front end of the support (9-2), the lower end of the long screw (5-5) is inserted into one through hole (9-3), the cylinder (5-1) is rotatably connected to the support (9-2), and the barrel body (1) is fixedly connected to the barrel frame (9-1); the jacking control piece (6) is arranged at the upper end of the cylinder (5-1).

6. The mineral impurity precipitation machine of claim 5, wherein: the jacking control part (6) comprises a fourth motor (6-1), a screw (6-2) and a cross (6-3); the fourth motor (6-1) is fixedly connected to the upper end of the cylinder (5-1) through a motor frame, an output shaft of the fourth motor (6-1) is connected with the screw rod (6-2) through a coupler, the middle of the cross (6-3) is connected to the screw rod (6-2) through thread fit, four outer ends of the cross (6-3) are connected into the four vertical sliding grooves (5-6) in a sliding fit mode respectively, and four outer ends of the cross (6-3) are fixedly connected with one position fixing piece (7) respectively.

7. The mineral impurity precipitation machine of claim 6, wherein: the position fixing piece (7) comprises a middle frame (7-1), a guide rod (7-2), a bidirectional screw rod (7-3), a driven gear (7-4), a driving gear (7-5), a fifth motor (7-6), a folding rod (7-7) and an inserting rod (7-8); the middle frame (7-1) is fixedly connected to the cross frame (6-3), the guide rod (7-2) is fixedly connected to the middle frame (7-1), the bidirectional screw (7-3) is rotatably connected to the middle frame (7-1), the driven gear (7-4) is fixedly connected to the middle of the bidirectional screw (7-3), the driven gear (7-4) is in meshing transmission connection with the driving gear (7-5), the driving gear (7-5) is fixedly connected to an output shaft of the fifth motor (7-6), the fifth motor (7-6) is fixedly connected to the middle frame (7-1) through a motor frame, the two folding rods (7-7) are respectively connected to two ends of the bidirectional screw (7-3) through thread matching, the inner ends of the two folding rods (7-7) are respectively and fixedly connected with an inserting rod (7-8), both insertion rods (7-8) are inserted into a settling assembly (8).

8. The mine impurity precipitation machine of claim 7, wherein: the sedimentation component (8) comprises a hollow cylinder (8-1), a conical sleeve seat (8-2), a slot seat (8-3), a feeding pipe (8-4) with a screw cap, a liquid discharge pipe (8-5) with a control valve, a sixth motor (8-6), a driving shaft (8-7) and a spiral conveying blade (8-8); the conical sleeve seat (8-2) is connected to the lower end of the hollow cylinder (8-1) in a threaded fit manner, and the upper end of the hollow cylinder (8-1) is symmetrically and fixedly connected with two slot seats (8-3); the inserting rod (7-8) is inserted into the inserting groove seat (8-3), the feeding pipe (8-4) and the liquid discharge pipe (8-5) are respectively fixedly connected and communicated with the upper end and the lower end of the conical sleeve seat (8-2), the sixth motor (8-6) is fixedly connected with the lower end of the conical sleeve seat (8-2) through a motor frame, an output shaft of the sixth motor (8-6) is connected with the driving shaft (8-7) through a coupler, the driving shaft (8-7) is hermetically and rotatably connected with the lower end of the conical sleeve seat (8-2), the spiral conveying blade (8-8) is fixedly connected onto the driving shaft (8-7), and the spiral conveying blade (8-8) is positioned in the hollow cylinder (8-1); the diameter of the hollow cylinder (8-1) on the two transverse sedimentation assemblies (8) is not equal to the diameter of the hollow cylinder (8-1) on the two longitudinal sedimentation assemblies (8).

9. The mine impurity precipitation machine of claim 8, wherein: the crushing rotary disc (3-10) is provided with a plurality of filter holes.

10. The mine impurity precipitation machine according to claim 2, wherein: the top surface of the barrel body (1) is symmetrically provided with two grooves (1-4), and two L-shaped screw seats (3-3) are respectively connected in the two grooves (1-4) in a clearance fit manner.