CN110844477B - Iron tailing sand raw material quantitative separation equipment - Google Patents

Abstract

The invention relates to a separation device, in particular to a quantitative separation device for iron tailing sand raw materials. The technical problem to be solved is how to provide the quantitative separation equipment for the iron tailing sand raw material, which can avoid excessive production and waste. A quantitative separation device for iron tailing sand raw materials comprises a bottom plate, a first supporting plate, a first weighting block, a first collecting box, a partition plate and the like; the first supporting plate and the first weight block used for keeping balance are fixedly connected to two sides of the top of the bottom plate, and the first weight block is located on one side of the first supporting plate. According to the quantitative screening device, through the action of the quantitative component, when a certain amount of tailings are screened, the conveying component can be controlled to stop working, so that quantitative screening can be performed, over-production can be avoided, further waste can be avoided, the tailings can be shoveled onto the second conveying belt through the bucket, manual operation can be replaced, and workers can be more relaxed.

Description

Iron tailing sand raw material quantitative separation equipment

Technical Field

The invention relates to a separation device, in particular to a quantitative separation device for iron tailing sand raw materials.

Background

The tailings are waste after mineral separation and are main components of industrial solid waste, the tailings are not completely discarded, the tailings can be utilized through processing of some equipment, the tailings are subjected to harmless treatment, the tailings are screened into coarse sand and fine sand, the coarse sand can be used for the building industry, the fine sand is subjected to harmless treatment, and the tailings are completely recycled.

In the existing tailings separation equipment, for example, patent with publication number CN209577306U discloses a magnesite tailings screening device, which comprises a feeding device and a screening device, wherein the materials to be selected with different particle sizes are fed through the feeding device, then air is blown into a screen pipe, the materials to be selected are blown into the screening device, after being screened by the screen pipe, small particles are retained in a housing through fine meshes on the side wall of the screen pipe, and after falling, the small particles are collected in a storage tank through a collecting hopper; the large granule is stayed in the screen pipe, blows out from the screen pipe other end and collects separately, but the device structure is comparatively simple, can't realize quantitative separation, causes overproduction easily, and then causes the waste.

We have developed an apparatus that avoids the problems of over-production and waste, and to solve the problems of the prior art.

Disclosure of Invention

In order to overcome current tailing sieving mechanism structure comparatively simple, can't realize quantitative separation, cause overproduction easily, and then cause extravagant shortcoming, the technical problem that solves is: the iron tailing sand raw material quantitative separation equipment can avoid excessive production and waste.

The technical scheme of the invention is as follows: the quantitative separation equipment for the iron tailing sand raw materials comprises a bottom plate, wherein two sides of the top of the bottom plate are fixedly connected with a first supporting plate and a first weighting block for keeping balance, the first weighting block is positioned on one side of the first supporting plate, a partition plate and a second supporting plate are fixedly connected between the first supporting plates on the two sides, and the partition plate is positioned below the second supporting plate; the first collecting box is placed on the bottom plate between the first supporting plates on the two sides; a single-shaft motor bolted to the upper side of the second support plate; a quantitative assembly mounted on the first support plate, the quantitative assembly for controlling the amount of tailings; the double-shaft motor is bolted on the bottom plate between the first supporting plate and the first weighting block; the adjusting assembly is arranged on the bottom plate close to one side of the first supporting plate and is used for adjusting the angle of the conveying assembly; the screening assembly is arranged between the first supporting plates at the two sides and is used for screening tailings; a conveying assembly mounted on the second support plate, the conveying assembly for conveying tailings.

Furthermore, the quantitative component comprises a first driving wheel, a first gear, a first belt, a first support frame, a fixing ring, a push block, a first spring, a second gear, a second driving wheel, a first rotating rod, a second belt, a connecting plate, a first slide bar, a first slide block, a second collecting box, a movable clamping block, a second support frame, a first guide wheel, a pull rope, a second slide bar, a lead block, a push rod, a first rack, a third gear, a C-shaped guide groove, a second rack, a guide sleeve and a connecting rod, wherein the first gear is rotatably arranged on one first support plate close to one side of the second support plate, the first driving wheel is arranged on an output shaft of the single-shaft motor, the first driving wheel is also arranged on the first gear, the first belt is wound between the two first driving wheels, the first support frame is fixedly connected to the first support plate far away from one side of the first gear, the first support frame is fixedly sleeved with a fixed ring, the first support frame is movably sleeved with a push block, a first spring is connected between the push block and the fixed ring, the first spring is wound on the first support frame, an arc-shaped groove is formed in the first support plate close to one side of the first gear, a second gear is arranged in the arc-shaped groove and meshed with the first gear, a first rotating rod is rotatably arranged between the first support plates on two sides, a second driving wheel is arranged on the first rotating rod, a second driving wheel is also arranged on the second gear, a second belt is wound between the two second driving wheels, a connecting plate is rotatably connected between the two second driving wheels and contacted with the push block, a first slide bar, a second support frame and a second slide bar are fixedly connected to two sides of the top of the bottom plate, and the second support frame is positioned between the first slide bar and the second slide bar, the first sliding rod is sleeved with a first sliding block in a sliding manner, the first sliding block is detachably connected with a second collecting box through a movable clamping block, the second sliding rod is sleeved with a lead block in a sliding manner, a first guide wheel is rotatably mounted at the upper part of a second supporting frame, a pull rope is wound on the first guide wheel, one end of the pull rope is fixedly connected with the lead block, the other end of the pull rope is connected with the first sliding block, a C-shaped guide groove and a guide sleeve are fixedly connected onto a first supporting plate between the first supporting frame and the arc-shaped groove, a push rod is movably connected in the guide sleeve in a penetrating manner, the push rod is contacted with the lead block, a first rack is mounted at the lower part of the push rod, a second rack is slidably mounted in the C-shaped guide groove, a connecting rod is rotatably connected between the second rack and the connecting plate, and a third gear is rotatably mounted on the first supporting plate between the C, the third gear is engaged with the second rack.

Furthermore, the adjusting component comprises a second rotating rod, a worm wheel, a third rotating rod, a worm, a spline, a first bevel gear, a third sliding rod, a pushing sleeve and a second bevel gear, wherein the second rotating rod and the third rotating rod are connected to the bottom plate between the first weighting blocks on the two sides in a rotating mode, the worm wheel is fixedly sleeved on the second rotating rod, the worm is installed on the outer side of the third rotating rod and meshed with the worm wheel and the worm, the spline is installed at the end part of the third rotating rod and connected with the bottom plate in a rotating mode, the first bevel gear and the pushing sleeve are slidably sleeved on the spline, the first bevel gear is located in the pushing sleeve, the third sliding rod is slidably sleeved in the pushing sleeve, the third sliding rod is fixedly connected with one of the first supporting plates, the second bevel gear is installed at one end of the double-shaft motor, and the second bevel gear.

Furthermore, the screening component comprises a third transmission wheel, a fourth gear, a third belt, a fourth rotating rod, a fifth gear, a sixth gear, a seventh gear, a cam, a screen, a fixed rod, a second slider and a second spring, the fourth gear is rotatably installed on the side surface of the other first support plate, the third transmission wheel is installed on the fourth gear, the third transmission wheel is also installed at the other end of the double-shaft motor, the third belt is wound between the two third transmission wheels, the fourth rotating rod is rotatably installed between the first support plates at two sides, the fifth gear and the two sixth gears are fixedly sleeved on the fourth rotating rod, the two sixth gears are both positioned between the first support plates at two sides, the fifth gear is meshed with the fourth gear, the seventh gear is rotatably installed on the inner side of the first support plate, the two seventh gears are respectively meshed with the two sixth gears, the cam is installed to seventh gear inboard, open flutedly in the first backup pad inboard, the inboard rigid coupling of recess has the dead lever, the slip cover is equipped with the second slider on the dead lever, around being equipped with the second spring on the dead lever, the one end and the second slider of second spring are connected, the other end and the recess inner wall of second spring are connected, and the rotary type is connected with the screen cloth between the second slider of both sides.

Further, the conveying assembly comprises a first transmission roller, a hollow roller, a first conveying belt, a second transmission roller, a fourth belt, a third supporting plate, a second fixing block, a fourth supporting plate, a double-groove guide wheel, a reel, a steel wire rope, a third transmission roller, a fifth belt, a fourth transmission roller, a sixth belt and a second conveying belt, the first transmission roller is fixedly sleeved on the first rotating rod, the hollow roller is arranged on the first rotating rod, the hollow roller is also arranged on the first supporting plate at one side far away from the first rotating rod, the first conveying belt is wound between the two hollow rollers, the second transmission roller is rotatably arranged between the first supporting plates at two sides above the first rotating rod, the fourth belt is wound between the second transmission roller and the first transmission roller, at least two third supporting plates are fixedly sleeved on the second transmission roller, and the second fixing block is connected between the third supporting plates, the equal rigid coupling in second backup pad top both sides has the fourth backup pad that extends along vertical direction, and the double flute leading wheel is installed to the rotary type between the fourth backup pad of both sides, fixed cover is equipped with the reel on the second bull stick, around there being wire rope on the reel, wire rope walk around the double flute leading wheel and with the second fixed block is connected, is close to third driving drum and fourth driving drum are installed to the last rotation type of the third backup pad of second fixed block one side, around being equipped with the fifth belt between third driving drum and the second driving drum, around being equipped with the sixth belt between third driving drum and the fourth driving drum, around being equipped with the second conveyer belt between fourth driving drum and the second driving drum.

Further, still including connecting rod, bracing piece, scraper bowl, disc, second weight and swash plate, third driving pulley's end connection has the connecting rod, connecting rod outside evenly distributed has eight at least bracing pieces, all is connected with the scraper bowl on every bracing piece, the disc is installed to connecting rod outside rotary type, the orientation it has the chute to open on the disc of third backup pad one side, and the rigid coupling has the swash plate in the chute, the orientation the rigid coupling has the second weight on the disc of third backup pad one side, and the second weight is located the chute below.

Furthermore, the lead block protective device further comprises a buffer cushion, wherein the buffer cushion playing a role in protection is fixedly connected to the lower sides of the lead blocks on the two sides.

The invention has the beneficial effects that: according to the invention, through the action of the quantitative component, when a certain amount of tailings are screened, the conveying component can be controlled to stop working, so that quantitative screening can be carried out, thus the excessive production can be avoided, and further the waste can be avoided; the tailings can be shoveled onto the second conveying belt through the bucket, so that manual operation can be replaced, and workers can feel easier; through the effect of lead block, can avoid producing huge sound to can avoid blotter or bottom plate impaired.

Drawings

Fig. 1 is a schematic front perspective view of the present invention.

Fig. 2 is an enlarged schematic view of part a of the present invention.

Fig. 3 is a schematic perspective view of the adjusting assembly of the present invention.

Fig. 4 is a schematic perspective view of the present invention with the rear first support plate removed.

Fig. 5 is an enlarged schematic view of part B of the present invention.

Fig. 6 is a schematic perspective view of the present invention with the rear first support plate and screen removed.

Fig. 7 is an enlarged schematic view of part C of the present invention.

Fig. 8 is a perspective view of another embodiment of the present invention.

Fig. 9 is an enlarged schematic view of part D of the present invention.

In the reference symbols: 1 a bottom plate, 2 a first supporting plate, 201 a first weighting block, 3 a first collecting box, 4 a partition plate, 5 a second supporting plate, 6 a single-shaft motor, 7 a quantitative component, 701 a first driving wheel, 702 a first gear, 703 a first belt, 7301 a first supporting frame, 704 a fixing ring, 705 a pushing block, 706 a first spring, 707 an arc groove, 708 a second gear, 709 a second driving wheel, 710 a first rotating rod, 7101 a second belt, 711 a connecting plate, 712 a first sliding rod, 713 a first sliding block, 714 a second collecting box, 715 a movable clamping block, 716 a second supporting frame, 717 a first guide wheel, 718 a pulling rope, a second sliding rod, 720 a lead block, 721 a pushing rod, 722 a first rack, 723 a third gear, a 724C-shaped guide groove, 725 a second rack, a guide sleeve 726, 727 a 727 connecting rod, 8 a double-shaft motor, 9 an adjusting component, 901 a second rotating rod, a worm wheel, 902, 903 a third rotating rod, 904, 905, 906 a first bevel gear, 907 third slide bar, 908 push sleeve, 909 second bevel gear, 10 screening component, 101 third transmission wheel, 102 fourth gear, 103 third belt, 104 fourth rotating bar, 105 fifth gear, 106 sixth gear, 107 seventh gear, 108 cam, 109 screen, 110 groove, 111 fixing bar, 112 second slider, 113 second spring, 11 transmission component, 1101 first transmission roller, 1102 hollow roller, 1103 first transmission belt, 1104 second transmission roller, 1105 fourth belt, 1106 third support plate, 1107 second fixing block, 1108 fourth support plate, 1109 double-groove guide wheel, 1110 reel, 1111 steel wire rope, 1112 third transmission roller, 1113 fifth belt, 1114 fourth transmission roller, 1115 sixth belt, 1116 second transmission belt, 12 connecting bar, 13 supporting bar, 14 bucket, 15 disc, 16 second weighting block, 17 chute, 18, 19 cushion.

Detailed Description

The following description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

Embodiment mode 1

A quantitative separation device for iron tailing sand raw materials is shown in figures 1-9 and comprises a bottom plate 1, a first supporting plate 2, a first weighting block 201, a first collecting box 3, a partition plate 4, a second supporting plate 5, a single-shaft motor 6, a quantifying assembly 7, a double-shaft motor 8, an adjusting assembly 9, a screening assembly 10 and a conveying assembly 11, wherein the first supporting plate 2 and the first weighting block 201 for keeping balance are fixedly connected to two sides of the top of the bottom plate 1, the first weighting block 201 is positioned on one side of the first supporting plate 2, the first collecting box 3 is arranged on the bottom plate 1 between the first supporting plates 2 on two sides, the partition plate 4 and the second supporting plate 5 are fixedly connected between the first supporting plates 2 on two sides, the partition plate 4 is positioned below the second supporting plate 5, the single-shaft motor 6 is bolted to the upper side of the second supporting plate 5, the double-shaft motor 8 is bolted to the bottom plate 1 between the first supporting plate 2 and the first weighting block 201, install quantitative subassembly 7 on the first backup pad 2, quantitative subassembly 7 is used for controlling the volume of tailing, install conveying subassembly 11 on the second backup pad 5, conveying subassembly 11 is used for conveying the tailing, is close to install adjusting part 9 on the bottom plate 1 of first backup pad 2 one side, adjusting part 9 is used for adjusting conveying subassembly 11's angle, is equipped with between the first backup pad 2 of both sides and screens subassembly 10, screens subassembly 10 is used for screening the tailing.

The quantitative component 7 comprises a first driving wheel 701, a first gear 702, a first belt 703, a first supporting frame 7301, a fixed ring 704, a pushing block 705, a first spring 706, a second gear 708, a second driving wheel 709, a first rotating rod 710, a second belt 7101, a connecting plate 711, a first sliding rod 712, a first sliding block 713, a second collecting box 714, a movable clamping block 715, a second supporting frame 716, a first guide wheel 717, a pulling rope 718, a second sliding rod 719, a lead block 720, a pushing rod 721, a first rack 722, a third gear 723, a C-shaped guide groove 724, a second rack 725, a guide sleeve 726 and a connecting rod 727, wherein the first gear 702 is rotatably installed on one of the first supporting plates 2 close to one side of the second supporting plate 5, the first driving wheel 701 is installed on an output shaft of the single-shaft motor 6, the first driving wheel 701 is also installed on the first gear 702, the first belt 703 is wound between the two first driving wheels 701, a first support 7301 is fixedly connected to the first support plate 2 far from one side of the first gear 702, a fixing ring 704 is fixedly sleeved on the first support 7301, a push block 705 is movably sleeved on the first support 7301, a first spring 706 is connected between the push block 705 and the fixing ring 704, the first spring 706 is wound on the first support plate 7301, an arc groove 707 is formed on the first support plate 2 near one side of the first gear 702, a second gear 708 is arranged in the arc groove 707, the second gear 708 is meshed with the first gear 702, a first rotating rod 710 is rotatably arranged between the first support plates 2 at two sides, a second driving wheel 709 is arranged on the first rotating rod 710, a second driving wheel 709 is also arranged on the second gear 708, a second belt 7101 is wound between the two second driving wheels 709, a connecting plate 711 is rotatably connected between the two second driving wheels 709, the connecting plate 711 is contacted with the push block 705, a first sliding rod 712, a second supporting frame 716 and a second sliding rod 719 are fixedly connected to two sides of the top of the bottom plate 1, the second supporting frame 716 is located between the first sliding rod 712 and the second sliding rod 719, a first sliding block 713 is slidably sleeved on the first sliding rod 712, a second collecting box 714 is detachably connected to the first sliding block 713 through a movable clamping block 715, a lead block 720 is slidably sleeved on the second sliding rod 719, a first guide wheel 717 is rotatably installed on the upper portion of the second supporting frame 716, a pull rope 718 is wound on the first guide wheel 717, one end of the pull rope 718 is fixedly connected with the lead block 720, the other end of the pull rope 718 is connected with the first sliding block 713, a C-shaped guide groove 724 and a guide sleeve 726 are fixedly connected to the first supporting plate 2 between the first supporting frame 7301 and the arc-shaped groove 707, a push rod 721 is movably penetrated in the guide sleeve 726, and the push rod 721 is in contact with the lead block 720, a first rack 722 is installed at the lower part of the push rod 721, a second rack 725 is slidably sleeved in the C-shaped guide groove 724, a connecting rod 727 is rotatably connected between the second rack 725 and the connecting plate 711, a third gear 723 is rotatably installed on the first supporting plate 2 between the C-shaped guide groove 724 and the guide sleeve 726, and the third gear 723 is engaged with the second rack 725.

The adjusting assembly 9 comprises a second rotating rod 901, a worm wheel 902, a third rotating rod 903, a worm 904, a spline 905, a first bevel gear 906, a third sliding rod 907, a pushing sleeve 908 and a second bevel gear 909, the second rotating rod 901 and the third rotating rod 903 are rotatably connected on the bottom plate 1 between the first weighting blocks 201 on two sides, a worm wheel 902 is fixedly sleeved on the second rotating rod 901, a worm 904 is arranged on the outer side of the third rotating rod 903, the worm wheel 902 is meshed with the worm 904, a spline 905 is arranged at the end part of the third rotating rod 903, the spline 905 is rotatably connected with the bottom plate 1, a first bevel gear 906 and a push sleeve 908 are slidably sleeved on the spline 905, the first bevel gear 906 is positioned in the push sleeve 908, a third sliding rod 907 is slidably penetrated in the push sleeve 908, the third sliding rod 907 is fixedly connected with one of the first supporting plates 2, one end of the double-shaft motor 8 is provided with a second bevel gear 909, and the second bevel gear 909 is meshed with the first bevel gear 906.

The screening assembly 10 includes a third transmission wheel 101, a fourth gear 102, a third belt 103, a fourth rotating rod 104, a fifth gear 105, a sixth gear 106, a seventh gear 107, a cam 108, a screen 109, a fixing rod 111, a second slider 112 and a second spring 113, the fourth gear 102 is rotatably mounted on the side surface of the other first support plate 2, the third transmission wheel 101 is mounted on the fourth gear 102, the third transmission wheel 101 is also mounted at the other end of the biaxial motor 8, the third belt 103 is wound between the two third transmission wheels 101, the fourth rotating rod 104 is rotatably mounted between the first support plates 2 on both sides, the fifth gear 105 and the two sixth gears 106 are fixedly sleeved on the fourth rotating rod 104, the two sixth gears 106 are both located between the first support plates 2 on both sides, the fifth gear 105 is engaged with the fourth gear 102, the seventh gear 107 is rotatably mounted on the inner side of the first support plates 2, two seventh gears 107 mesh with two sixth gears 106 respectively, and cam 108 is installed to seventh gear 107 inboard, 2 inboard openings of first backup pad have recess 110, the inboard rigid coupling of recess 110 has dead lever 111, sliding sleeve is equipped with second slider 112 on the dead lever 111, around being equipped with second spring 113 on the dead lever 111, the one end and the second slider 112 of second spring 113 are connected, the other end and the recess 110 inner wall connection of second spring 113, and the rotary type is connected with screen cloth 109 between the second slider 112 of both sides.

The conveying assembly 11 comprises a first transmission roller 1101, a hollow roller 1102, a first conveying belt 1103, a second transmission roller 1104, a fourth belt 1105, a third supporting plate 1106, a second fixing block 1107, a fourth supporting plate 1108, a double-groove guide wheel 1109, a reel 1110, a steel wire rope 1111, a third transmission roller 1112, a fifth belt 1113, a fourth transmission roller 1114, a sixth belt 1115 and a second conveying belt 1116, wherein the first transmission roller 1101 is fixedly sleeved on a first rotating rod 710, the hollow roller 1102 is arranged on the first rotating rod 710, the hollow roller 1102 is also arranged on the first supporting plate 2 at one side far away from the first rotating rod 710, the first conveying belt 1103 is wound between the two hollow rollers 1102, the second transmission roller 1104 is rotatably arranged between the first supporting plates 2 at two sides above the first rotating rod 710, the fourth belt 1105 is wound between the second transmission roller 1104 and the first transmission roller 1101, at least two third supporting plates 1106 are fixedly sleeved on the second transmission roller 1104, a second fixing block 1107 is connected between the third supporting plates 1106, the two sides of the top of the second supporting plate 5 are fixedly connected with fourth supporting plates 1108 extending along the vertical direction, a double-groove guide wheel 1109 is rotatably arranged between the fourth supporting plates 1108 at the two sides, a winding wheel 1110 is fixedly sleeved on the second rotating rod 901, a steel wire rope 1111 is wound on the winding wheel 1110, the steel wire 1111 bypasses the double-groove guide wheel 1109 and is connected with the second fixed block 1107, a third transmission roller 1112 and a fourth transmission roller 1114 are rotatably mounted on the third support plate 1106 close to one side of the second fixed block 1107, a fifth belt 1113 is wound between the third transmission roller 1112 and the second transmission roller 1104, a sixth belt 1115 is wound between the third transmission roller 1112 and the fourth transmission roller 1114, and a second conveyor belt 1116 is wound between the fourth transmission roller 1114 and the second transmission roller 1104.

The workman controls adjusting part 9 and adjusts conveying part 11 to the angle, then start unipolar motor 6 and the work of biaxial motor 8, unipolar motor 6 drive ration subassembly 7 and the work of conveying part 11, the work of biaxial motor 8 drive screening subassembly 10, the workman shovels the tailing on conveying part 11 again, conveying part 11 can be with the tailing transmission to screening subassembly 10 on, screening subassembly 10 can filter the tailing, thinner tailing falls in first collecting box 3, thicker tailing falls in ration subassembly 7. When being equipped with a quantitative thicker tailing in the subassembly 7, conveying subassembly 11 stop work, the workman can close unipolar motor 6 and biaxial motor 8, so, can carry out the ration screening to can avoid causing overproduction, and then can avoid causing the waste.

The worker starts the single-shaft motor 6 to work, the single-shaft motor 6 drives the first driving wheel 701 above to rotate clockwise, the first driving wheel 701 below is driven to rotate clockwise through the first belt 703, so as to drive the first gear 702 to rotate clockwise, further drive the second gear 708 to rotate anticlockwise, the second gear 708 drives the second driving wheel 709 at the left side to rotate anticlockwise, the second driving wheel 709 at the right side is driven to rotate anticlockwise through the second belt 7101, the first rotating rod 710 rotates anticlockwise, the first rotating rod 710 drives the conveying assembly 11 to work, the worker shovels the tailings onto the conveying assembly 11, the conveying assembly 11 can convey the tailings onto the screening assembly 10, the screening assembly 10 can screen the tailings, the thinner tailings fall into the first collecting box 3, the thicker tailings fall into the second collecting box 714, the weight of the second collecting box 714 is gradually increased, so that the second collecting box 714 slowly moves downwards, the lead block 720 is driven to move upwards by the pull rope 718, the lead block 720 pushes the push rod 721 and the first rack 722 to move upwards, when the first rack 722 moves upwards to be meshed with the third gear 723, the first rack 722 drives the third gear 723 to rotate clockwise, so that the second rack 725 is driven to move downwards, the connecting plate 711 is driven to swing downwards by the connecting rod 727, the connecting plate 711 pushes the push block 705 to move downwards, the first spring 706 is compressed, the connecting plate 711 swings downwards and can also drive the second transmission wheel 709 on the left side to swing downwards, so that the second gear 708 can be driven to swing downwards, when the second gear 708 swings downwards and is not meshed with the first gear 702, the first gear 702 does not drive the second gear 708 to rotate anticlockwise any more, the first rotating rod 710 stops rotating anticlockwise, so that the conveying assembly 11 stops working, which shows that a certain amount of thicker tailings are already filled in the second collecting tank 714, a worker can close the single-shaft motor 6, then the second collecting box 714 is taken off from the first sliding block 713, the pulling rope 718 is loosened, the lead block 720 moves downwards under the action of self gravity, the push rod 721 and the first rack 722 move downwards along with the lead block, the first rack 722 drives the third gear 723 to rotate anticlockwise so as to drive the second rack 725 to move upwards, the connecting plate 711 is driven to swing upwards through the connecting rod 727, the push block 705 moves upwards under the action of the first spring 706, the push block 705 pushes the connecting plate 711 to swing upwards, and then the second gear 708 is driven to move upwards, so that the second gear 708 is meshed with the first gear 702.

The worker starts the double-shaft motor 8 to rotate clockwise, the double-shaft motor 8 drives the second bevel gear 909 to rotate clockwise, so as to drive the first bevel gear 906 to rotate anticlockwise, the third rotating rod 903 is driven to rotate anticlockwise through the spline 905, so as to drive the worm 904 to rotate anticlockwise, so as to drive the worm gear 902 to rotate clockwise, the second rotating rod 901 rotates clockwise, the second rotating rod 901 drives the conveying component 11 to swing downwards, so as to adjust the angle of the conveying component 11, after the adjustment is completed, the worker closes the double-shaft motor 8, the worker can also start the double-shaft motor 8 to rotate clockwise, the double-shaft motor 8 drives the second rotating rod 901 to rotate anticlockwise, the second rotating rod 901 drives the conveying component 11 to swing upwards, so as to adjust the angle of the conveying component 11, after the adjustment is completed, the worker closes the double-shaft motor 8, then pushes the push sleeve 908 to the right, the, the first bevel gear 906 is disengaged from the second bevel gear 909.

The conveying assembly 11 can convey the tailings to the screen 109, a worker starts the double-shaft motor 8 to work, the double-shaft motor 8 drives the left third driving wheel 101 to rotate, the right third driving wheel 101 is driven to rotate through the third belt 103, the fourth gear 102 is driven to rotate, the fifth gear 105 is driven to rotate, the sixth gear 106 is driven to rotate through the fourth rotating rod 104, the seventh gear 107 is driven to rotate, the cam 108 rotates along with the seventh gear, the cam 108 continuously pushes the screen 109, the screen 109 continuously moves up and down under the action of the second spring 113, the tailings are screened, the finer tailings fall into the first collecting box 3 through the screen 109, and the coarser tailings fall into the second collecting box 714.

When the second rotating rod 901 rotates clockwise, the second rotating rod 901 drives the reel 1110 to rotate clockwise, the steel wire rope 1111 is discharged, under the action of the self gravity of the second fixing block 1107, the second fixing block 1107 swings downwards, so that the third supporting plate 1106 swings downwards, the second conveying belt 1116 swings downwards along with the second fixing block 1107, when the second rotating rod 901 rotates anticlockwise, the second rotating rod 901 drives the reel 1110 to rotate anticlockwise, the steel wire rope 1111 is wound on the reel 1110, the second fixing block 1107 is driven to swing upwards through the steel wire rope 1111, so that the third supporting plate 1106 is driven to swing upwards, and the angle of the third supporting plate 1106 is adjusted. When the first rotating rod 710 rotates counterclockwise, the first rotating rod 710 drives the first transmission roller 1101 to rotate counterclockwise, the fourth belt 1105 drives the second transmission roller 1104 to rotate counterclockwise, the fifth belt 1113 drives the third transmission roller 1112 to rotate counterclockwise, the sixth belt 1115 drives the fourth transmission roller 1114 to rotate counterclockwise, so as to drive the second transmission belt 1116 to rotate counterclockwise, the worker shovels the tailings onto the second transmission belt 1116 again, and the second transmission belt 1116 can transmit the tailings onto the screen 109.

Embodiment mode 2

On the basis of embodiment 1, as shown in fig. 1, 2 and 4, the device further includes a connecting rod 12, supporting rods 13, a bucket 14, a circular disc 15, a second weighting block 16 and an inclined plate 18, the end portion of the third transmission drum 1112 is connected with the connecting rod 12, eight supporting rods 13 are uniformly distributed on the outer side of the connecting rod 12, the bucket 14 is connected to each supporting rod 13, the circular disc 15 is rotatably installed on the outer side of the connecting rod 12, a chute 17 is formed in the circular disc 15 facing one side of the third supporting plate 1106, the inclined plate 18 is fixedly connected to the inside of the chute 17, the second weighting block 16 is fixedly connected to the circular disc 15 facing one side of the third supporting plate 1106, and the second weighting block 16 is located below the chute 17.

The lead block comprises a cushion pad 19, and the lower sides of the lead blocks 720 on the two sides are fixedly connected with the cushion pad 19 for protection.

When third drive drum 1112 anticlockwise rotates, third drive drum 1112 drives connecting rod 12 anticlockwise rotation, thereby drive bracing piece 13 anticlockwise rotation, and then drive scraper bowl 14 anticlockwise rotation, shovel the scraper bowl 14 with the tailing in, disc 15 can block the tailing in the scraper bowl 14, avoid the tailing in the scraper bowl 14 toward whereabouts, effect through second weighting piece 16, can provide decurrent gravity, make disc 15 can remain at current state throughout, when scraper bowl 14 corresponds with swash plate 18, the tailing in the scraper bowl 14 falls on swash plate 18, then on second conveyer belt 1116 is fallen through swash plate 18, thereby can replace manual operation, make the workman can be lighter.

When the lead block 720 moves downwards, the lead block 720 drives the cushion pad 19 to move downwards, the cushion pad 19 is in contact with the bottom plate 1, and the lead block 720 is prevented from being directly in contact with the bottom plate 1, so that great sound can be prevented from being generated, and the lead block 720 or the bottom plate 1 can be prevented from being damaged.

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

Claims (4)

1. The utility model provides an iron tailings sand raw materials quantitative separation equipment, characterized by includes:

the device comprises a bottom plate (1), wherein a first supporting plate (2) and a first weighting block (201) for keeping balance are fixedly connected to two sides of the top of the bottom plate (1), the first weighting block (201) is positioned on one side of the first supporting plate (2), a partition plate (4) and a second supporting plate (5) are fixedly connected between the first supporting plates (2) on two sides, and the partition plate (4) is positioned below the second supporting plate (5);

the first collecting box (3), the first collecting box (3) is placed on the bottom plate (1) between the first supporting plates (2) at two sides;

a single-shaft motor (6), wherein the single-shaft motor (6) is bolted to the upper side of the second supporting plate (5);

a dosing assembly (7), the dosing assembly (7) being mounted on the first support plate (2), the dosing assembly (7) being for controlling the amount of tailings;

the double-shaft motor (8), the double-shaft motor (8) is bolted on the bottom plate (1) between the first supporting plate (2) and the first weighting block (201);

the adjusting assembly (9), the adjusting assembly (9) is installed on the bottom plate (1) close to one side of the first supporting plate (2), and the adjusting assembly (9) is used for adjusting the angle of the conveying assembly (11);

the screening assembly (10) is installed between the first supporting plates (2) on the two sides, and the screening assembly (10) is used for screening tailings;

a conveyor assembly (11), the conveyor assembly (11) being mounted on the second support plate (5), the conveyor assembly (11) being for conveying tailings;

the quantitative component (7) comprises a first transmission wheel (701), a first gear (702), a first belt (703), a first support frame (7301), a fixed ring (704), a push block (705), a first spring (706), a second gear (708), a second transmission wheel (709), a first rotating rod (710), a second belt (7101), a connecting plate (711), a first sliding rod (712), a first sliding block (713), a second collecting box (714), a movable clamping block (715), a second support frame (716), a first guide wheel (717), a pull rope (718), a second sliding rod (719), a lead block (720), a push rod (721), a first rack (722), a third gear (723), a C-shaped guide groove (724), a second rack (725), a guide sleeve (726) and a connecting rod (727), wherein the first gear (702) is rotatably mounted on one of the first support plates (2) close to one side of the second support plates (5), install first drive wheel (701) on the output shaft of unipolar motor (6), also install first drive wheel (701) on first gear (702), around being equipped with first belt (703) between two first drive wheels (701), keep away from rigid coupling has first support frame (7301) on first backup pad (2) of first gear (702) one side, fixed cover is equipped with solid fixed ring (704) on first support frame (7301), movable sleeve is equipped with ejector pad (705) on first support frame (7301), is connected with first spring (706) between ejector pad (705) and solid fixed ring (704), and first spring (706) is around establishing on first support frame (7301), has seted up arc wall (707) on being close to first backup pad (2) of first gear (702) one side, is equipped with second gear (708) in arc wall (707), and second gear (708) and first gear (702) meshing, a first rotating rod (710) is rotatably installed between the first supporting plates (2) on two sides, a second driving wheel (709) is installed on the first rotating rod (710), a second driving wheel (709) is also installed on the second gear (708), a second belt (7101) is wound between the two second driving wheels (709), a connecting plate (711) is rotatably connected between the two second driving wheels (709), the connecting plate (711) is in contact with the push block (705), a first sliding rod (712), a second supporting frame (716) and a second sliding rod (719) are fixedly connected to two sides of the top of the bottom plate (1), the second supporting frame (716) is located between the first sliding rod (712) and the second sliding rod (719), a first sliding block (713) is slidably sleeved on the first sliding rod (712), and a second collecting box (714) is detachably connected to the first sliding block (713) through a movable clamping block (715), a lead block (720) is slidably sleeved on the second sliding rod (719), a first guide wheel (717) is rotatably installed at the upper part of the second supporting frame (716), a pull rope (718) is wound on the first guide wheel (717), one end of the pull rope (718) is fixedly connected with the lead block (720), the other end of the pull rope (718) is connected with the first sliding block (713), a C-shaped guide groove (724) and a guide sleeve (726) are fixedly connected to the first supporting plate (2) between the first supporting frame (7301) and the arc-shaped groove (707), a push rod (721) is movably connected in the guide sleeve (726) in a penetrating manner, the push rod (721) is in contact with the lead block (720), a first rack (722) is installed at the lower part of the push rod (721), a second rack (725) is sleeved in the C-shaped guide groove (724), a connecting rod (727) is rotatably connected between the second rack (725) and the connecting plate (711), a third gear (723) is rotatably arranged on the first supporting plate (2) between the C-shaped guide groove (724) and the guide sleeve (726), and the third gear (723) is meshed with the second rack (725);

the adjusting component (9) comprises a second rotating rod (901), a worm wheel (902), a third rotating rod (903), a worm (904), a spline (905), a first bevel gear (906), a third sliding rod (907), a push sleeve (908) and a second bevel gear (909), the second rotating rod (901) and the third rotating rod (903) are rotatably connected on the bottom plate (1) between the first weighting blocks (201) on the two sides, the worm wheel (902) is fixedly sleeved on the second rotating rod (901), the worm (904) is installed on the outer side of the third rotating rod (903), the worm wheel (902) is meshed with the worm (904), the spline (905) is installed at the end part of the third rotating rod (903), the spline (905) is rotatably connected with the bottom plate (1), the first bevel gear (906) and the push sleeve (908) are slidably sleeved on the spline (905), the first bevel gear (906) is located in the push sleeve (908), and the third sliding rod (907) is slidably connected in the push sleeve (908), the third sliding rod (907) is fixedly connected with one of the first supporting plates (2), one end of the double-shaft motor (8) is provided with a second bevel gear (909), and the second bevel gear (909) is meshed with the first bevel gear (906);

the screening component (10) comprises a third transmission wheel (101), a fourth gear (102), a third belt (103), a fourth rotating rod (104), a fifth gear (105), a sixth gear (106), a seventh gear (107), a cam (108), a screen (109), a fixed rod (111), a second slider (112) and a second spring (113), the fourth gear (102) is rotatably installed on the side surface of the other first supporting plate (2), the third transmission wheel (101) is installed on the fourth gear (102), the third transmission wheel (101) is also installed at the other end of the double-shaft motor (8), the third belt (103) is wound between the two third transmission wheels (101), the fourth rotating rod (104) is rotatably installed between the first supporting plates (2) at the two sides, the fifth gear (105) and the two sixth gears (106) are fixedly sleeved on the fourth rotating rod (104), two sixth gears (106) are positioned between the first supporting plates (2) at two sides, the fifth gear (105) is meshed with the fourth gear (102), seventh gears (107) are rotatably arranged on the inner side of the first supporting plate (2), the two seventh gears (107) are respectively meshed with the two sixth gears (106), a cam (108) is arranged on the inner side of the seventh gear (107), the inner side of the first supporting plate (2) is provided with a groove (110), the inner side of the groove (110) is fixedly connected with a fixing rod (111), a second sliding block (112) is slidably sleeved on the fixed rod (111), a second spring (113) is wound on the fixed rod (111), one end of the second spring (113) is connected with the second sliding block (112), the other end of the second spring (113) is connected with the inner wall of the groove (110), and a screen (109) is rotatably connected between the second sliding blocks (112) on two sides.

2. The quantitative separation equipment for iron tailing sand raw materials as claimed in claim 1, characterized in that the conveying assembly (11) comprises a first transmission roller (1101), a hollow roller (1102), a first conveying belt (1103), a second transmission roller (1104), a fourth belt (1105), a third supporting plate (1106), a second fixed block (1107), a fourth supporting plate (1108), a double-groove guide wheel (1109), a reel (1110), a steel wire rope (1111), a third transmission roller (1112), a fifth belt (1113), a fourth transmission roller (1114), a sixth belt (1115) and a second conveying belt (1116), the first transmission roller (1101) is fixedly connected to the first rotating rod (710), the hollow roller (1102) is arranged on the first rotating rod (710), the hollow roller (1102) is also arranged on the first supporting plate (2) on one side far away from the first rotating rod (710), a first conveying belt (1103) is wound between the two hollow rollers (1102), a second transmission roller (1104) is rotatably installed between the first supporting plates (2) at two sides above the first rotating rod (710), a fourth belt (1105) is wound between the second transmission roller (1104) and the first transmission roller (1101), at least two third supporting plates (1106) are fixedly installed on the second transmission roller (1104), a second fixing block (1107) is connected between the third supporting plates (1106), fourth supporting plates (1108) extending along the vertical direction are fixedly connected to two sides of the top of the second supporting plate (5), a rotary double-groove guide wheel (1109) is installed between the fourth supporting plates (1108) at two sides, a winding wheel (1110) is fixedly installed on the second rotating rod (901), a steel wire rope (1111) is wound on the winding wheel (1111), the steel wire rope (1111) bypasses the double-groove guide wheel (1109) and is connected with the second fixing block (1107), a third transmission roller (1112) and a fourth transmission roller (1114) are rotatably mounted on a third supporting plate (1106) close to one side of the second fixing block (1107), a fifth belt (1113) is wound between the third transmission roller (1112) and the second transmission roller (1104), a sixth belt (1115) is wound between the third transmission roller (1112) and the fourth transmission roller (1114), and a second conveying belt (1116) is wound between the fourth transmission roller (1114) and the second transmission roller (1104).

3. The quantitative separation equipment for iron tailing sand raw materials as claimed in claim 2, characterized by further comprising a connecting rod (12), a supporting rod (13), a bucket (14), a disc (15), a second weight (16) and an inclined plate (18), the end part of the third transmission roller (1112) is connected with a connecting rod (12), at least eight supporting rods (13) are uniformly distributed on the outer side of the connecting rod (12), each supporting rod (13) is connected with a bucket (14), disc (15) are installed to connecting rod (12) outside rotary type, and the orientation it has chute (17) to open on disc (15) of third backup pad (1106) one side, and the rigid coupling has swash plate (18) in chute (17), and the orientation the rigid coupling has second weight (16) on disc (15) of third backup pad (1106) one side, and second weight (16) are located chute (17) below.

4. The quantitative separation equipment for iron tailing sand raw materials as claimed in claim 3, characterized by further comprising a buffer pad (19), wherein the buffer pads (19) with protection function are fixedly connected to the lower sides of the lead blocks (720) at the two sides.

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