CN116853840A

CN116853840A - Graphite tailing guide device and use method

Info

Publication number: CN116853840A
Application number: CN202310999237.4A
Authority: CN
Inventors: 王成; 刘江玉
Original assignee: Heilongjiang Bohao Graphite Co ltd
Current assignee: Heilongjiang Bohao Graphite Co ltd
Priority date: 2023-08-09
Filing date: 2023-08-09
Publication date: 2023-10-10

Abstract

A graphite tailing guiding device and a using method thereof belong to the field of tailing treatment equipment. Comprises a shell, a movable device, a transmission device and a limiting device; a movable device capable of moving up and down is arranged in the shell; the transmission device is in sliding fit with the shell, one part of the transmission device is positioned below the movable device, and the other part of the transmission device is positioned above the movable device; the limiting device is fixedly connected inside the shell and is positioned at the upper end of the movable device. The invention not only does not need to start and stop the conveyor belt to cooperate to achieve the tailing transfer of the preset weight, but also does not need to consider that dust generated during the tailing transfer falls on electronic elements or electric equipment in severe working environments such as mines, outdoors and the like, thereby influencing heat dissipation and saving maintenance cost.

Description

Graphite tailing guide device and use method

Technical Field

The invention relates to a graphite tailing guide device and a use method thereof, and belongs to the field of tailing treatment equipment.

Background

The accumulation of graphite tailings occupies a large amount of agriculture and forestry land, and silt-like tailings powder exposed on the ground surface is extremely easy to form a sand weather and even form a tailing sand storm every time wind blows. In addition, the beneficiation reagent remained in the graphite tailings can generate harmful gas and acid water, and can directly cause serious pollution to the atmosphere, water and soil, so that soil pollution, land degradation and vegetation destruction are caused. The comprehensive utilization mode of the graphite waste tailing powder mainly comprises three approaches: 1. recovering valuable minerals by utilizing graphite tailing sand; 2. manufacturing other mineral materials by utilizing graphite tailing sand; 3. and manufacturing the building material by using graphite tailing sand. When building materials are made of tailings, raw materials are required to be added according to a certain proportion, and although equipment of the type is available on the market at present, a conveyor belt is required to be continuously started and stopped for matching, so that time is wasted, the working efficiency is reduced, and therefore, improvement is necessary.

Disclosure of Invention

The invention aims to solve the problems in the background art and provides a graphite tailing guiding device and a using method thereof.

The invention achieves the above purpose, adopts the following technical scheme:

a graphite tailing guiding device comprises a shell, a movable device, a transmission device and a limiting device; a movable device capable of moving up and down is arranged in the shell; the transmission device is in sliding fit with the shell, one part of the transmission device is positioned below the movable device, and the other part of the transmission device is positioned above the movable device; the limiting device is fixedly connected inside the shell and is positioned at the upper end of the movable device.

The application method of the graphite tailing guide device comprises the following steps:

step one: putting tailings into the limiting device through a gap between the limiting device and the partition plate by using the conveyor belt, so that the tailings enter a storage barrel positioned at the lower end of the limiting device;

step two: after the weight of the storage barrel is increased to a preset weight, pushing the slide bar to compress the spring and sliding downwards;

step three: the arc-shaped rod is used for limiting and rotating, so that the other storage barrel is driven to move to the lower end of the limiting device, and continuous fixed weight feeding is realized.

Compared with the prior art, the invention has the beneficial effects that: the invention not only does not need to start and stop the conveyor belt to cooperate to achieve the tailing transfer of the preset weight, but also does not need to consider that dust generated during the tailing transfer falls on electronic elements or electric equipment in severe working environments such as mines, outdoors and the like, thereby influencing heat dissipation and saving maintenance cost.

Drawings

FIG. 1 is a front view of a graphite tailing guide apparatus of the present invention;

FIG. 2 is a front view of the housing of a graphite tailing guide apparatus of the present invention;

FIG. 3 is a side cross-sectional view of a cylinder of a graphite tailing guide of the present invention;

FIG. 4 is a front view of a connecting rod of a graphite tailing guide apparatus of the present invention;

FIG. 5 is a side view of a connecting rod of a graphite tailing guide apparatus of the present invention;

FIG. 6 is a schematic structural view of a movable device of the graphite tailing guiding device of the present invention;

fig. 7 is a left side view of a storage bucket of a graphite tailing guide apparatus of the present invention;

fig. 8 is a right side view of a storage bucket of a graphite tailing guide apparatus of the present invention;

fig. 9 is a front view of a drive of a graphite tailing guide of the present invention;

FIG. 10 is a side view of a divider plate of a graphite tailing guide apparatus of the present invention;

FIG. 11 is a schematic structural view of a limiting device of a graphite tailing guiding device according to the present invention;

fig. 12 is a top view of a restriction device of a graphite tailing guide device of the present invention.

Detailed Description

The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the invention, but not all embodiments, and all other embodiments obtained by those skilled in the art without making creative efforts based on the embodiments of the present invention are all within the protection scope of the present invention.

The first embodiment is as follows: as shown in fig. 1-12, this embodiment describes a graphite tailing guiding device, which includes a housing 1, a movable device 2, a transmission device 3 and a limiting device 4; a movable device 2 which can move up and down is arranged in the shell 1; the transmission device 3 is in sliding fit with the shell 1, one part of the transmission device 3 is positioned below the movable device 2, and the other part of the transmission device 3 is positioned above the movable device 2; the limiting device 4 is fixedly connected inside the shell 1, and the limiting device 4 is positioned at the upper end of the movable device 2.

The housing 1 comprises a cylinder 11; a supporting rod 17 is fixedly connected to the top end of the cylinder 11; the top end of the supporting rod 17 is fixedly connected with a cross rod 19; the center of the bottom end of the cross rod 19 is fixedly connected with a round rod 110, and the lower end of the round rod 110 is connected with a rotary drum 111 through a bearing; the bottom end of the rotary drum 111 is hollowed out, and a connecting rod 118 is fixedly connected to the inner top wall of the hollowed-out end of the rotary drum 111; the lower end of the connecting rod 118 is provided with a perforation 116, and the inner wall of the perforation 116 is transversely and fixedly connected with a shaft lever I117; an arc-shaped rod 13 which is obliquely arranged is fixedly connected to the inner wall of the cylinder 11.

The mobile device 2 comprises a storage tub 21; the storage barrels 21 are arc-shaped, two storage barrels 21 are arranged, a chute 22 is arranged on the outer arc surface of each storage barrel 21, a discharge hole 23 is arranged on the inner arc surface of each storage barrel 21, and the bottom end of each storage barrel 21 is fixedly connected with a connecting rod 26; the lower end of the connecting rod 26 is hinged with a bidirectional telescopic rod 27, and a round hole 28 sleeved on the shaft lever I117 is arranged in the center of the bidirectional telescopic rod 27; the bi-directional telescoping rod 27 is in sliding engagement with the aperture 116. The storage barrel 21 corresponds to a central angle of 140-180 deg..

The storage tub 21 located at the high position is contacted with the arc-shaped rod 13 when being moved downward, so that the storage tub 21 is moved downward under the action of gravity and is also displaced in the horizontal direction.

The outer side of the cylinder 11 is fixedly connected with a connecting cylinder 14; a sliding rod 16 which is in sliding fit with the connecting cylinder 14 is arranged in the connecting cylinder; the sliding rod 16 penetrates through the cylinder 11, one end of the sliding rod 16 positioned in the cylinder 11 is an inclined plane, and a spring 15 is fixedly connected between the sliding rod 16 and the inner wall of the connecting cylinder 14; the slide bar 16 is in sliding engagement with the slide slot 22.

A fixed rod 24 is fixedly connected to the inner cambered surface of the storage barrel 21, and a magnet 25 is fixedly connected to the fixed rod 24; the side surface of the rotary drum 111 is provided with a vertical slideway 112 which is in sliding fit with the fixed rod 24; the upper end of the connecting rod 118 is provided with a groove 115; the groove 115 is fixedly connected with a shaft lever II 113; the shaft lever II 113 is connected with a rotating rod 114 through a bearing.

The magnetism of the magnets 25 on the two storage barrels 21 is different; a magnetic strip is fixedly connected to the side surface of the rotating rod 114, and the magnetic strip has the same magnetism as the magnet 25 nearest to the magnetic strip; when the distance between the rotating rod 114 and the two magnets 25 is the same, the stress on both sides of the rotating rod 114 is different.

The transmission device 3 comprises a transmission rod I31, a connecting rod 32, a transmission rod II 33, a partition plate 34 and an elastic telescopic rod 35; the side of the cylinder 11 is provided with a vertical track 12 penetrating the cylinder 11; the cross rod 19 is provided with a through hole 18; the connecting rod 32 is U-shaped, one end of the connecting rod 32 is in sliding fit with the track 12, and the upper end surface of the connecting rod 32 is fixedly connected with a transmission rod I31; a transmission rod II 33 which is in sliding fit with the through hole 18 is fixedly connected to the lower end surface of the other end of the connecting rod 32, and the lower end of the transmission rod II 33 is fixedly connected with a separation plate 34; one end of the elastic telescopic rod 35 is fixedly connected with the connecting rod 32, and the other end of the elastic telescopic rod 35 is fixedly connected with the upper end of the cross rod 19; the partition 34 is in an upwardly convex arc shape, and the projected area of the partition 34 in the vertical direction is the same as the projected area of the storage tub 21 in the vertical direction.

The limiting device 4 comprises two side baffles 41 and two arc baffles 42; two ends of opposite surfaces of the two arc-shaped baffles 42 are fixedly connected with side baffles 41 respectively, and one arc-shaped baffle 42 is fixedly connected to the inner wall of the cylinder 11; the partition plate 34 is in sliding fit with the limiting device 4, and the projection area of the partition plate 34 in the vertical direction is equal to the area of the bottom end opening of the limiting device 4.

The central angle corresponding to the storage barrel 21 and the partition plate 34 is equal to the central angle corresponding to the bottom end of the limiting device 4.

step one: putting tailings into the limiting device 4 through a gap between the limiting device 4 and the partition plate 34 by a conveyor belt, so that the tailings enter a storage barrel 21 positioned at the lower end of the limiting device 4;

step two: after the weight of the storage barrel 21 is increased to a preset weight, the sliding rod 16 is pushed to compress the spring 15 and slide downwards;

step three: the arc-shaped rod 13 is limited to rotate, so that the other storage barrel 21 is driven to move to the lower end of the limiting device 4, and continuous fixed weight feeding is realized.

The working principle of the invention is as follows: when the device is used, tailings are thrown into the limiting device 4 through a gap between the limiting device 4 and the partition plate 34 by the conveyor belt, so that the tailings pass through the limiting device 4 and enter the storage barrel 21 positioned at the lower end of the limiting device 4;

after the weight of the storage barrel 21 is increased to a preset weight, the gravity born by the storage barrel 21 is larger than the elastic force of the spring 15, and the sliding rod 16 is pushed to move into the connecting barrel 14 and compress the spring 15, so that the storage barrel 21 can slide downwards;

in the process of downward sliding of the storage barrel 21, the storage barrel 21 contacts the transmission rod I31 and pushes the transmission rod I31 to move downward, so that the transmission rod I31 drives the connecting rod 32, the transmission rod II 33 and the partition plate 34 to move downward together, the elastic telescopic rod 35 is compressed, the partition plate 34 moves downward to the middle lower end of the inside of the limiting device 4, the middle upper part of the side baffle 41 is provided with an inclined plate, more falling tailings can be received, the middle lower part of the side baffle 41 is provided with a vertical plate, the vertical plate is attached to two sides of the partition plate 34 to form a collecting container, and two sides of the partition plate 34 are contacted with vertical plate parts of the two side baffles 41; after the separation plate 34 moves to the middle lower part of the side plate of the limiting device 4 to contact with the vertical plate, tailings conveyed by the conveyor belt fall on the upper end of the separation plate 34 and are temporarily stored by a container formed by the limiting device 4 and the separation plate 34; when the storage barrel 21 moves downwards, the storage barrel 21 contacts the arc-shaped rod 13, and as the arc-shaped rod 13 is obliquely arranged, the storage barrel 21 also abuts against the inner wall of the cylinder 11, so that when the storage barrel 21 moves downwards and contacts the arc-shaped rod 13, displacement occurs in the horizontal direction along the oblique direction of the arc-shaped rod 13, the storage barrel 21 drives the bidirectional telescopic rod 27 to rotate through the connecting rod 26, and then drives the other storage barrel 21 to rotate, and the downward-moving storage barrel 21 also drives the bidirectional telescopic rod 27 to rotate around the shaft rod I117, and then drives the other storage barrel 21 to move upwards at the same time, and the discharge hole 23 at the lower end of the storage barrel 21 is exposed after moving to the lower end of the rotary drum 111, so that discharging can be completed; when the storage barrel 21 moving downwards is separated from the arc-shaped rod 13, the storage barrel 21 moving downwards is separated from the transmission rod I31 at the same time due to the displacement of the storage barrel 21 in the horizontal direction, the other storage barrel 21 moving upwards moves to the lower end of the limiting device 4, and meanwhile, the sliding rod 16 is embedded into the sliding groove 22; under the elastic force of the elastic telescopic rod 35, the transmission rod I31, the connecting rod 32 and the transmission rod II 33 move upwards, the transmission rod II 33 drives the separation plate 34 to move upwards, after the separation plate 34 is separated from the vertical plate part of the side baffle 41, as the middle upper part of the side baffle 41 is an inclined plate which is inclined outwards, a gap between the separation plate 34 and the inclined plate at the middle upper part of the side baffle 41 is gradually enlarged after the separation plate 34 moves upwards, and the separation plate 34 is an arc plate which is raised by the mountain, and under the action of gravity, tailings slide to two ends along the arc surface at the upper end of the separation plate 34 and slide into the storage barrel 41 through the gap between the separation plate 34 and the side baffle 41, so that the starting and stopping of a conveyor belt are not required to be controlled to control the output of the tailings;

because the distance between the rotating rod 114 and the two magnets 25 is the same, the two sides of the rotating rod 114 are stressed differently, when the magnetic force between the magnets 25 on the side surface of the storage barrel 21 positioned at a high position and the rotating rod 114 is larger, the lower end of the rotating rod 114 is pushed to move away from the storage barrel 21 positioned at the high position, the lower end of the rotating rod 114 knocks the magnets 25 positioned at a low position to generate vibration, after the lower end of the rotating rod 114 contacts the magnets 25 connected with the storage barrel 21 positioned at the low position, the repulsive force between the rotating rod 114 and the magnets 25 positioned at the low position is larger than the repulsive force received by the other side of the rotating rod 114, the repulsive force can reversely move, and after a certain distance is moved, the repulsive force received by the magnets 25 positioned at the high position knocks the magnets 25 again to generate vibration, so that the balance state is repeatedly achieved; when the magnetic force between the magnet 25 on the side surface of the storage barrel 21 positioned at the lower position and the rotating rod 114 is large, the lower end of the rotating rod 114 is pushed to move towards the direction close to the storage barrel 21 positioned at the upper position, the lower end of the rotating rod 114 knocks the inner wall of the rotary drum 111, the lower end of the rotating rod 114 contacts the magnet 25 connected with the storage barrel 21 positioned at the upper position while the lower end of the rotating rod 114 contacts the inner wall of the rotary drum 111, after the rotating rod 114 contacts the magnet 25 positioned at the lower position, the repulsive force between the rotating rod and the magnet 25 is larger than the repulsive force received by the other side of the rotating rod 114, the rotating rod moves reversely, and after a certain distance is moved, the repulsive force received by the magnet 25 positioned at the lower position knocks the magnet 25 again to generate vibration, so that the rotating rod is repeated until the equilibrium state is finally reached;

after vibration is generated, vibration can be transmitted to the two storage barrels 21, small particle tailings in the storage barrels 21 located at high positions are fully filled in gaps between large particle tailings, the phenomenon that the height of the tailings in the storage barrels 21 at high positions is too high, so that the tailings slide from two sides is avoided, and meanwhile the small particle tailings adsorbed on the inner wall of the storage barrel 21 located at low positions can be vibrated down through vibration.

Claims

1. The utility model provides a graphite tailing guide device which characterized in that: comprises a shell (1), a movable device (2), a transmission device (3) and a limiting device (4); a movable device (2) capable of moving up and down is arranged in the shell (1); the transmission device (3) is in sliding fit with the shell (1), one part of the transmission device (3) is positioned below the movable device (2), and the other part of the transmission device (3) is positioned above the movable device (2); the limiting device (4) is fixedly connected inside the shell (1), and the limiting device (4) is positioned at the upper end of the movable device (2).

2. A graphite tailing guide apparatus as claimed in claim 1, wherein: the housing (1) comprises a cylinder (11); a supporting rod (17) is fixedly connected to the top end of the cylinder (11); the top end of the supporting rod (17) is fixedly connected with a cross rod (19); the center of the bottom end of the cross rod (19) is fixedly connected with a round rod (110), and the lower end of the round rod (110) is connected with a rotary drum (111) through a bearing; the bottom end of the rotary drum (111) is hollowed out, and a connecting rod (118) is fixedly connected to the inner top wall of the hollowed-out end of the rotary drum (111); the lower end of the connecting rod (118) is provided with a perforation (116), and the inner wall of the perforation (116) is transversely and fixedly connected with a shaft lever I (117); the inner wall of the cylinder (11) is fixedly connected with an arc-shaped rod (13) which is obliquely arranged.

3. A graphite tailing guide apparatus as claimed in claim 2, wherein: the movable device (2) comprises a storage barrel (21); the storage barrels (21) are arc-shaped, two storage barrels (21) are arranged, a chute (22) is arranged on the outer arc surface of each storage barrel (21), a discharge hole (23) is arranged on the inner arc surface of each storage barrel (21), and a connecting rod (26) is fixedly connected to the bottom end of each storage barrel (21); the lower end of the connecting rod (26) is hinged with a bidirectional telescopic rod (27), and a round hole (28) sleeved on the shaft lever I (117) is arranged in the center of the bidirectional telescopic rod (27); the bidirectional telescopic rod (27) is in sliding fit with the perforation (116).

4. A graphite tailing guide apparatus as claimed in claim 3, wherein: the storage barrel (21) positioned at the high position is contacted with the arc-shaped rod (13) when moving downwards, so that the storage barrel (21) moves downwards under the action of gravity and also moves horizontally.

5. The graphite tailing guide device as claimed in claim 4, wherein: the outer side of the cylinder (11) is fixedly connected with a connecting cylinder (14); a sliding rod (16) which is in sliding fit with the connecting cylinder (14) is arranged in the connecting cylinder; the sliding rod (16) penetrates through the cylinder (11), one end of the sliding rod (16) positioned in the cylinder (11) is an inclined plane, and a spring (15) is fixedly connected between the sliding rod (16) and the inner wall of the connecting cylinder (14); the sliding rod (16) is in sliding fit with the sliding groove (22).

6. The graphite tailing guide device as claimed in claim 5, wherein: a fixed rod (24) is fixedly connected to the inner cambered surface of the storage barrel (21), and a magnet (25) is fixedly connected to the fixed rod (24); the side surface of the rotary drum (111) is provided with a vertical slideway (112) which is in sliding fit with the fixed rod (24); the upper end of the connecting rod (118) is provided with a groove (115); a shaft lever II (113) is fixedly connected in the groove (115); the shaft lever II (113) is connected with a rotating rod (114) through a bearing.

7. The graphite tailing guide device as claimed in claim 6, wherein: the magnetism of the magnets (25) on the two storage barrels (21) is different; a magnetic strip is fixedly connected to the side face of the rotating rod (114), and the magnetic strip has the same magnetism as the magnet (25) nearest to the magnetic strip; when the distance between the rotating rod (114) and the two magnets (25) is the same, the stress on the two sides of the rotating rod (114) is different.

8. The graphite tailing guide device as claimed in claim 7, wherein: the transmission device (3) comprises a transmission rod I (31), a connecting rod (32), a transmission rod II (33), a separation plate (34) and an elastic telescopic rod (35); the side surface of the cylinder (11) is provided with a vertical track (12) penetrating through the cylinder (11); the cross rod (19) is provided with a through hole (18); the connecting rod (32) is U-shaped, one end of the connecting rod (32) is in sliding fit with the track (12), and the upper end surface of the connecting rod is fixedly connected with the transmission rod I (31); a transmission rod II (33) which is in sliding fit with the through hole (18) is fixedly connected to the lower end surface of the other end of the connecting rod (32), and a separation plate (34) is fixedly connected to the lower end of the transmission rod II (33); one end of the elastic telescopic rod (35) is fixedly connected with the connecting rod (32), and the other end of the elastic telescopic rod (35) is fixedly connected with the upper end of the cross rod (19); the partition plate (34) is in an upward protruding arc shape, and the projection area of the partition plate (34) in the vertical direction is the same as the projection area of the storage barrel (21) in the vertical direction.

9. The graphite tailing guide device as claimed in claim 8, wherein: the limiting device (4) comprises two side baffles (41) and two arc baffles (42); two ends of opposite surfaces of the two arc-shaped baffles (42) are fixedly connected with side baffles (41) respectively, and one arc-shaped baffle (42) is fixedly connected to the inner wall of the cylinder (11); the division plate (34) is in sliding fit with the limiting device (4), and the projection area of the division plate (34) in the vertical direction is equal to the area of the bottom end opening of the limiting device (4).

10. The method for using the graphite tailing guide device according to claim 9, wherein: the using method comprises the following steps:

step one: putting tailings into the limiting device (4) through a gap between the limiting device (4) and the partition plate (34) through a conveyor belt, so that the tailings enter a storage barrel (21) positioned at the lower end of the limiting device (4);

step two: after the weight of the storage barrel (21) is increased to a preset weight, the sliding rod (16) is pushed to compress the spring (15) and slide downwards;

step three: the arc-shaped rod (13) is used for limiting and rotating, so that the other storage barrel (21) is driven to move to the lower end of the limiting device (4), and continuous fixed weight feeding is realized.