CN113599866A - High-efficient stationary flow bucket with even cloth function - Google Patents

Abstract

The invention relates to the field of a flow stabilizing barrel of a thickener, and particularly discloses a high-efficiency flow stabilizing barrel with a uniform material distribution function, which comprises a barrel body, the eccentric position of the side edge of the top of the barrel body is communicated with a pipeline, the pipeline is connected with mineral aggregate, the upper end and the lower end of the inside of the barrel body are respectively and rotatably connected with a rotation limiting strip, the rotation limiting strip is respectively and fixedly sleeved with an upper rotating ring and a lower rotating ring, is used for solving the defects that the prior high-efficiency steady flow barrel with the function of uniform distribution often adopts a baffle plate to limit the flow of ore pulp when in use, and the baffle plate is often required to be frequently replaced by the mode, simultaneously, can lead to the mineral tiny particle to strike the mineral that has already deposiing in the concentrated pond when deposiing in the concentrated pond on the one hand, reduce the efficiency of deposiing, on the other hand still can lead to forming the vortex in the stationary flow bucket, is unfavorable for the deposit of mineral tiny particle.

Description

High-efficient stationary flow bucket with even cloth function

Technical Field

The invention relates to a flow stabilizing barrel, in particular to a high-efficiency flow stabilizing barrel with a uniform material distribution function, and belongs to the field of flow stabilizing barrels of thickeners.

Background

The steady flow bucket is used for concentrating minerals and is used together with equipment such as a concentration tank, a transmission device, a rake rack and the like, and the steady flow bucket has the effect of enabling the flow velocity of ore pulp to be stable when the ore pulp enters the concentration tank and facilitating the precipitation of mineral particles in the ore pulp.

But current high-efficient stationary flow bucket that has even cloth function still has certain defect when using, current stationary flow bucket often all adopts the baffle to come to restrict the flow of ore pulp, but adopt this kind of mode often can lead to the baffle to need frequently changing, and simultaneously, can lead to the mineral tiny particle in the concentration pond to deposit good mineral production impact in the concentration pond when deposiing on the one hand, reduce the efficiency of deposiing, on the other hand still can lead to forming the vortex in the stationary flow bucket, be unfavorable for the deposit of the tiny particle of mineral, for this reason, we provide a high-efficient stationary flow bucket with even cloth function.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a high-efficiency flow stabilizing barrel with a uniform material distribution function.

The purpose of the invention can be realized by the following technical scheme:

a high-efficiency steady flow barrel with a uniform material distribution function comprises a barrel body, wherein a pipeline is communicated with an eccentric position on the side edge of the top of the barrel body, the upper end and the lower end of the inside of the barrel body are respectively and rotatably connected with a rotation limiting strip, the two rotation limiting strips are respectively and fixedly sleeved with an upper rotating ring and a lower rotating ring, the upper rotating ring is positioned above the lower rotating ring, a plurality of vertical plates are rotatably connected between the upper rotating ring and the lower rotating ring, a plurality of connecting rods are fixedly connected with the inner side of the inner ring of the lower rotating ring, one end of each connecting rod, far away from the lower rotating ring, is fixedly connected with a cone, a plurality of guide plates are fixedly connected on the inclined plane of the cone, each guide plate is fixedly connected with an extension plate, the extension plates are obliquely arranged, one end, far away from the extension plates, of each guide plate is fixedly connected with the connecting rods, the top of the cone is fixedly connected with a rotating column in a transmission way, and is connected with a steady flow component, the material distributing component is connected with the flow stabilizing component in a transmission mode, the bottom of the barrel body is fixedly connected with a leakage hopper, and the bottom of the leakage hopper is hollow and is located above the cone.

Preferably, the steady flow subassembly includes dog, fly leaf, spoiler, rotary column, fixed strip, connection rope, pulley, rubber block, first spring, second spring, torsional spring and soft layer of connecing, fly leaf sliding connection is on the riser, the bottom fixedly connected with second spring of fly leaf, the one end fixed connection that the fly leaf was kept away from to the second spring is in the bottom in the riser, the tip of riser and the bottom of fly leaf all are equipped with spacing platform, through spacing platform activity joint between riser and the fly leaf, the soft layer of connecing of tip fixedly connected with of fly leaf, the soft layer of connecing and the inner wall sliding connection of staving, the equal fixedly connected with torsional spring in upper and lower both ends of fly leaf, the torsional spring rotates respectively and connects in the inside at last change and change.

Preferably, the spoiler is equipped with a plurality ofly and the spoiler all rotates to be connected on rotating the post, spoiler fixedly connected with rotary column, rotary column rotates to be connected on rotating the post, a plurality of dogs of outside fixedly connected with of rotation post, the equal sliding connection of dog has the equal sliding connection of block rubber and block rubber in rotating the post, the equal first spring of fixedly connected with in bottom of block rubber, the equal fixed connection of one end that the block rubber was kept away from to first spring is in the inside of rotating the post, the block rubber is located the both sides of spoiler and the laminating of block rubber and spoiler.

Preferably, the spoiler is located the equal fixedly connected with fixed strip of the inside tip of rotation post, the equal fixedly connected with in bottom of fixed strip connects the rope, connect rope sliding connection and have the pulley, the pulley rotates to be connected in the bottom of rotation post, connect rope and cloth subassembly transmission and be connected.

Preferably, the cloth subassembly includes third spring, rack, cam, gear, slip strip, fourth spring, axis of rotation, first stopper and second stopper, the one end fixedly connected with rack that the fixed strip was kept away from to the connection rope, the bottom of connecting the rope rotation post is through deflector to extension board and rack fixed connection, rack sliding connection is in the inside of extension board.

Preferably, the connecting rope is sleeved with a third spring, two ends of the third spring are respectively and fixedly connected to the inner wall plates of the rack and the extending plate, the rack is meshed with a gear, the gear is fixedly connected with a cam, the gear and the cam rotate concentrically, a rotating shaft is fixedly sleeved at the rotating center of the gear and the cam, and the rotating shaft is rotatably connected to the inside of the extending plate.

Preferably, cam sliding connection has the slider, slider sliding connection is in the inside of extending the board, the slider is parallel with the slip direction of extending the board and the rotation direction of rotating the post, the slider slides at the inside tip side fixedly connected with second stopper of extending the board, the top fixedly connected with fourth spring of second stopper, the first stopper of one end fixedly connected with of second stopper is kept away from to the fourth spring, first stopper fixed connection is on extending the board.

Preferably, the vertical plates, the connecting rods, the extension plates, the guide plates and the spoilers are the same in number.

Preferably, the center points of the vertical plate body and the spoiler plate body are located on the same plane.

The invention has the beneficial effects that:

1. through the design of torsional spring and fly leaf, effectual pair of board carries out duplicate protection on the one hand, and on the other hand makes fly leaf and soft layer of connecing rinse through the impact force of ore pulp, prevents that the ore pulp from condensing on the inner wall of staving, the effectual conveying efficiency of pipeline to the ore pulp of having guaranteed.

2. Through the design of spoiler and riser, make the velocity of flow of ore pulp reduce on the one hand, on the other hand is also effectual to have prevented the inside ore pulp formation vortex's of staving possibility, the spoiler still can play the effect that the vortex hinders to the flow of ore pulp simultaneously, make the upper swivel through spoiler and riser dual effort, lower swivel, the rotation post, the deflector, the extension board, connecting rod and cone rotate, the effectual pivoted power source of having guaranteed, the connecting rod can also break up the tiny particle of agglomeration in the ore pulp at the pivoted in-process simultaneously, be convenient for to the deposit of tiny particle in the ore pulp.

3. Design through the cloth subassembly, on the one hand make the granule in the ore pulp disperse, on the other hand also can make the tiny particle evenly distributed in the ore pulp deposit in the concentrated pond, the tiny particle in the ore pulp that will extend the board and contact through the slip stirs to the both sides of extending the board, and then make the distribution of tiny particle in the ore pulp in the concentrated pond more even, and then make the tiny particle in the ore pulp deposit more thoroughly, simultaneously because the tiny particle in the ore pulp tends to steadily between gravity and buoyancy, so can not produce the impact to the granule that the concentrated bottom of the pool portion has deposited when the tiny particle in the ore pulp deposits, make the deposit tend to stabilize.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view illustrating a connection structure of the upper swivel and the lower swivel shown in fig. 1 according to the present invention.

Fig. 3 is a schematic structural view of the rotating column shown in fig. 2 according to the present invention.

FIG. 4 is a schematic sectional view of the portion A-A of FIG. 3 according to the present invention.

FIG. 5 is an enlarged view of the portion B shown in FIG. 4 according to the present invention.

Fig. 6 is a schematic sectional view of the structure of the rotating column in fig. 3 according to the present invention.

FIG. 7 is an enlarged view of the structure of the portion C shown in FIG. 6 according to the present invention.

Fig. 8 is a schematic sectional view of the extension plate of fig. 6 according to the present invention.

Fig. 9 is a schematic sectional view of the upper swivel shown in fig. 1 according to the present invention.

Fig. 10 is a schematic cross-sectional view of the vertical plate of fig. 9 according to the present invention.

In the figure: 1. a barrel body; 11. a pipeline; 12. an upper swivel; 13. rotating the column; 14. a cone; 15. an extension plate; 16. a guide plate; 17. a vertical plate; 18. a connecting rod; 19. a lower swivel; 2. a flow stabilizing assembly; 20. a stopper; 21. a movable plate; 22. a spoiler; 23. turning the column; 24. a fixing strip; 25. connecting ropes; 26. a pulley; 27. a rubber block; 28. a first spring; 29. a second spring; 291. a torsion spring; 292. a soft bonding layer; 3. a cloth component; 31. a third spring; 32. a rack; 33. a cam; 34. a gear; 35. a slide bar; 36. a fourth spring; 37. a rotating shaft; 38. a first stopper; 39. a second limiting block; 4. a hopper; 41. the limiting strip is rotated.

Detailed Description

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

Referring to fig. 1-10, a high-efficiency steady flow barrel with a uniform material distribution function comprises a barrel body 1, a pipeline 11 is communicated with an eccentric position of the top side of the barrel body 1, the upper end and the lower end of the inside of the barrel body 1 are rotatably connected with rotation limiting strips 41, the two rotation limiting strips 41 are respectively fixedly sleeved with an upper rotating ring 12 and a lower rotating ring 19, the upper rotating ring 12 is positioned above the lower rotating ring 19, a plurality of vertical plates 17 are rotatably connected between the upper rotating ring 12 and the lower rotating ring 19, a plurality of connecting rods 18 are fixedly connected to the inner side of the inner ring of the lower rotating ring 19, a cone 14 is fixedly connected to one end of each connecting rod 18 far away from the lower rotating ring 19, a plurality of guide plates 16 are fixedly connected to the inclined plane of the cone 14, an extension plate 15 is fixedly connected to each guide plate 16, the extension plate 15 is obliquely arranged, one end of each guide plate 16 far away from the extension plate 15 is fixedly connected to the corresponding connecting rod 18, a rotation column 13 is fixedly connected to the top of the cone 14, rotate the transmission of post 13 and be connected with steady flow component 2, steady flow component 2 transmission is connected with cloth subassembly 3, the bottom fixedly connected with hopper 4 of staving 1, 4 bottoms cavity of hopper and hopper 4 are located the top of cone 14, the ground paste falls after staving 1 and hopper 4, the ore pulp gets into and deposits in the concentrated pond afterwards, there are tiny mineral particle in the ore pulp to deposit in the concentrated pond, the tiny particle in the ore pulp is owing to receive the dual function of gravity and buoyancy, tend to stable slow the sediment in the concentrated pond.

As a technical optimization scheme of the invention, the flow stabilizing assembly 2 comprises a stop 20, a movable plate 21, a spoiler 22, a rotary column 23, a fixing strip 24, a connecting rope 25, a pulley 26, a rubber block 27, a first spring 28, a second spring 29, a torsion spring 291 and a soft connection layer 292, wherein the movable plate 21 is slidably connected to a vertical plate 17, the bottom of the movable plate 21 is fixedly connected to the second spring 29, one end of the second spring 29, which is far away from the movable plate 21, is fixedly connected to the inner bottom of the vertical plate 17, both the end of the vertical plate 17 and the bottom of the movable plate 21 are provided with limit tables, the vertical plate 17 is movably clamped with the movable plate 21 through the limit tables, the end of the movable plate 21 is fixedly connected to the soft connection layer 292, the soft connection layer 292 is slidably connected to the inner wall of the barrel body 1, both the upper and lower ends of the movable plate 21 are fixedly connected to the torsion springs 291, the torsion springs 291 are rotatably connected to the inner parts of the upper rotary ring 12 and the lower rotary ring 19, the movable plate 21 is connected to the upper rotary ring 12 and the lower rotary ring 19 through the torsion spring 291, The lower swivel 19 is rotatably connected.

As a technical optimization scheme of the invention, a plurality of spoilers 22 are arranged, the spoilers 22 are rotatably connected to the rotating column 13, the rotating column 23 is rotatably connected to the rotating column 13, a plurality of stoppers 20 are fixedly connected to the outer side of the rotating column 13, the stoppers 20 are slidably connected to rubber blocks 27, the rubber blocks 27 are slidably connected to the rotating column 13, the bottoms of the rubber blocks 27 are fixedly connected to first springs 28, one ends of the first springs 28, which are far away from the rubber blocks 27, are fixedly connected to the inside of the rotating column 13, the rubber blocks 27 are positioned on two sides of the spoilers 22, the rubber blocks 27 are attached to the spoilers 22, the spoilers 22 spoil ore pulp, and the stoppers 20 are attached to the rubber blocks 27 to prevent the ore pulp from entering the inside of the rotating column 13.

As a technical optimization scheme of the invention, the end parts of the spoilers 22 positioned inside the rotating columns 13 are fixedly connected with the fixed strips 24, the bottoms of the fixed strips 24 are fixedly connected with the connecting ropes 25, the connecting ropes 25 are connected with the pulleys 26 in a sliding manner, the pulleys 26 are rotatably connected with the bottoms of the rotating columns 13, the connecting ropes 25 are in transmission connection with the distributing component 3, and the connecting ropes 25 are guided to deflect through the pulleys 26.

As a technical optimization scheme of the invention, the cloth component 3 comprises a third spring 31, a rack 32, a cam 33, a gear 34, a sliding strip 35, a fourth spring 36, a rotating shaft 37, a first limiting block 38 and a second limiting block 39, wherein the rack 32 is fixedly connected to one end of the connecting rope 25 far away from the fixing strip 24, the connecting rope 25 is fixedly connected with the rack 32 from the bottom of the rotating column 13 to the extending plate 15 through the guide plate 16, and the rack 32 is slidably connected inside the extending plate 15.

As a technical optimization scheme of the invention, the connecting rope 25 is sleeved with the third spring 31, two ends of the third spring 31 are respectively and fixedly connected to the rack 32 and the inner wall plate of the extension plate 15, the rack 32 is engaged and connected with the gear 34, the gear 34 is fixedly connected with the cam 33, the gear 34 and the cam 33 rotate concentrically, the rotating centers of the gear 34 and the cam 33 are fixedly sleeved with the rotating shaft 37, the rotating shaft 37 is rotatably connected inside the extension plate 15, and the rack 32 provides power for the rotation of the cam 33 through the gear 34.

As a technical optimization scheme of the invention, the cam 33 is slidably connected with the sliding bar 35, the sliding bar 35 is slidably connected inside the extension plate 15, the sliding direction of the sliding bar 35 and the extension plate 15 is parallel to the rotating direction of the rotating column 13, the end part side edge of the sliding bar 35 sliding inside the extension plate 15 is fixedly connected with the second limit block 39, the top of the second limit block 39 is fixedly connected with the fourth spring 36, one end of the fourth spring 36 far away from the second limit block 39 is fixedly connected with the first limit block 38, the first limit block 38 is fixedly connected on the extension plate 15, and the fourth spring 36 provides power for the rebound of the sliding bar 35 through the first limit block 38 and the second limit block 39.

As a technical optimization scheme of the invention, the vertical plates 17, the connecting rods 18, the extension plates 15, the guide plates 16 and the spoilers 22 are the same in number, and the connecting rods 18, the extension plates 15, the guide plates 16 and the spoilers 22 are the same in number, so that the slurry is uniformly distributed on the cone 14 when falling.

As a technical optimization scheme of the invention, the central points of the vertical plate 17 and the spoiler 22 are located on the same plane, and the central points of the vertical plate 17 and the spoiler 22 are located on the same plane, so that the spoiler 22 can more conveniently and effectively disturb ore pulp guided by the vertical plate 17.

When the invention is used, the pipeline 11 can convey the ore pulp to the inside of the barrel body 1, the ore pulp can impact the vertical plate 17 through the guiding of the pipeline 11 along with the ore pulp entering the inside of the barrel body 1, after the vertical plate 17 is impacted, the slurry is directed into the spoilers 22, the spoilers 22 exert a reaction force on the slurry after impact by the slurry, thereby causing the slurry to flow disorderly in the barrel body 1, further reducing the speed of the slurry flowing out from the inner part of the pipeline 11, and simultaneously, the spoiler 22 prevents the slurry from rotating in the barrel body 1, because once the ore pulp rotates in the barrel body 1, a turbocharging effect is achieved, the speed of the ore pulp flowing out from the leakage hopper 4 can not be slowed down but also be increased, therefore, the flow rate of the slurry is reduced by the action of the spoiler 22, and the possibility of vortex formation of the slurry inside the barrel body 1 is effectively prevented.

In the process, when the slurry impacts the vertical plate 17, the vertical plate 17 is impacted to drive the torsion spring 291 to rotate in the upper rotating ring 12 and the lower rotating ring 19, and meanwhile, the second spring 29 applies an elastic force to the movable plate 21, so that in the process of rotating the vertical plate 17 and the torsion spring 291, the movable plate 21 is ejected by the second spring 29, so that the movable plate 21 is attached to the inner wall of the barrel body 1, and the torsion spring 291 drives the vertical plate 17 to rotate, in the process, the movable plate 21 presses the second spring 29 downwards, so that the second spring 29 is contracted, at this time, the movable plate 21 vibrates in a small amplitude along the inner wall of the barrel body 1, so that the movable plate 21 brushes the inner wall of the barrel body 1 through the soft connection layer 292, the slurry is prevented from being condensed on the inner wall of the barrel body 1, and meanwhile, the impact force of the slurry flowing in the pipeline 11 on the vertical plate 17 is effectively absorbed and offset through the torsion spring 291, the second spring 29 can also apply a reaction force to the torsion spring 291 and the vertical plate 17, so that the vertical plate 17 is protected doubly, the service life of the vertical plate 17 is ensured, and through the design of the torsion spring 291 and the movable plate 21, on one hand, the vertical plate 17 can be effectively protected, and on the other hand, the movable plate 21 and the soft connection layer 292 are washed through the impact force of ore pulp, so that the ore pulp is prevented from being condensed on the inner wall of the barrel body 1.

In the process that the pulp is guided by the vertical plate 17 to act on the spoiler 22, the vertical plate 17 rotates in the upper swivel 12 and the lower swivel 19, the pipeline 11 is arranged at the eccentric position of the top of the side of the barrel body 1, so that the pulp in the pipeline 11 impacts the vertical plate 17 to enable the upper swivel 12 and the lower swivel 19 to rotate in the barrel body 1 through the rotation limiting strips 41, and meanwhile, when the pulp is guided by the vertical plate 17 to act on the spoiler 22, on one hand, the spoiler 22 plays a role in blocking the turbulent flow, on the other hand, the pulp can impact the spoiler 22 to enable the spoiler 22 to drive the rotating column 13 to rotate, and as the lower swivel 19 is fixedly connected with the rotating column 13 through the connecting rod 18 and the cone 14, the pulp can make the upper swivel 12, the lower swivel 19, the rotating column 13, the guide plate 16 and the extension plate 15 through dual acting forces of the spoiler 22 and the vertical plate 17, Connecting rod 18 and cone 14 rotate, and the effectual ring 12 that has guaranteed to go up, down the ring 19, rotate post 13, deflector 16, extension board 15, connecting rod 18 and cone 14 pivoted power source, connecting rod 18 can also break up the tiny particle of agglomeration in the ore pulp at the pivoted in-process simultaneously, is convenient for follow-up deposit to tiny particle in the ore pulp.

In the process of rotation of the spoiler 22 and the rotating column 13, after the spoiler 22 is impacted by the pulp, the spoiler 22 rotates around the rotating column 23, the rubber block 27 compresses the first spring 28 in the rotating process, and the rubber block 27 slides on the rotating column 13, in the process, through the design of the stop 20, on one hand, the pulp can be effectively prevented from entering the inside of the rotating column 13, on the other hand, the rotation amplitude of the spoiler 22 is also effectively controlled, in the process of rotation of the spoiler 22, the spoiler 22 can drive the fixing strip 24 to rotate, the fixing strip 24 can drive the rack 32 to move through the connecting rope 25 and the pulley 26, in the process, the spoiler 22 can also vibrate in a small amplitude under the impact of the pulp and the elastic force of the first spring 28, and the action of the spoiler 22 on the pulp can be optimized through the vibration, at the in-process that spoiler 22 kick-backed, can exert a reaction force to the ore pulp, and then make spoiler 22 more abundant to the vortex of ore pulp, and then make the ore pulp deposit in getting into the concentration tank through lou hopper 4.

After the ore pulp comes out from the leakage hopper 4, the ore pulp can fall into a gap between the guide plates 16, after the ore pulp is guided by the guide plates 16 and the cone 14, the ore pulp falls into the concentration tank, because the ore pulp tends to be stable after passing through the barrel body 1 and slowly falls, in the process, most small particles in the ore pulp are close to a suspension state in the concentration tank, the extension plate 15 is driven to rotate in the rotating process of the cone 14, and then the particles in the ore pulp are stirred into the concentration tank, on one hand, the particles in the ore pulp are dispersed, on the other hand, the small particles in the ore pulp can be uniformly distributed in the concentration tank to be precipitated, and most small particles in the ore pulp are close to the suspension state, so when the connecting rope 25 drives the rack 32 to move, the rack 32 is driven to move through the vibration of the spoiler 22, and the rack 32 further drives the gear 34 to rotate, the rotation of the gear 34 further drives the cam 33 to rotate, and the fourth spring 36 applies elastic force to the sliding strip 35 through the first limiting block 38 and the second limiting block 39, so that when the cam 33 rotates, the sliding strip 35 is driven to move, and the movement of the spoiler 22 is vibration, so that the cam 33 drives the sliding strip 35 to perform regular shrinkage pop-up, further the small particles in the ore pulp contacted with the extension plate 15 are shifted to two sides of the extension plate 15 through the sliding strip 35 in the rotating process of the extension plate 15, further the distribution of the small particles in the ore pulp in the concentration tank is more uniform, further the small particles in the ore pulp are more thoroughly precipitated, meanwhile, the small particles in the ore pulp tend to be stable between gravity and buoyancy, so that the impact on the precipitated particles at the bottom of the concentration tank can not be generated when the small particles in the ore pulp are precipitated, so that the precipitate tends to be stable.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (9)

1. The high-efficiency steady flow barrel with the function of uniform distribution comprises a barrel body (1) and is characterized in that a pipeline (11) is communicated with an eccentric position at the side edge of the top of the barrel body (1), the upper end and the lower end of the inside of the barrel body (1) are respectively and rotatably connected with a rotary limiting strip (41), the two rotary limiting strips (41) are respectively and fixedly sleeved with an upper rotating ring (12) and a lower rotating ring (19), the upper rotating ring (12) is positioned above the lower rotating ring (19), a plurality of vertical plates (17) are rotatably connected between the upper rotating ring (12) and the lower rotating ring (19), a plurality of connecting rods (18) are fixedly connected to the inner side of an inner ring of the lower rotating ring (19), one ends, far away from the lower rotating ring (19), of the connecting rods (18) are fixedly connected with a cone (14), a plurality of guide plates (16) are fixedly connected to the inclined plane of the cone (14), an extension plate (15) is fixedly connected with the guide plates (16), and the extension plate (15) is obliquely arranged, one end and connecting rod (18) fixed connection of extension board (15) are kept away from in deflector (16), the top fixedly connected with of cone (14) rotates post (13), it is connected with steady flow subassembly (2) to rotate post (13) transmission, steady flow subassembly (2) transmission is connected with cloth subassembly (3), the bottom fixedly connected with of staving (1) leaks hopper (4), leak hopper (4) bottom cavity and leak hopper (4) and be located the top of cone (14).

2. The efficient steady flow barrel with the function of uniform material distribution according to claim 1, wherein the steady flow component (2) comprises a stop block (20), a movable plate (21), a spoiler (22), a rotating column (23), a fixing strip (24), a connecting rope (25), a pulley (26), a rubber block (27), a first spring (28), a second spring (29), a torsion spring (291) and a soft connection layer (292), the movable plate (21) is slidably connected to the upright plate (17), the bottom of the movable plate (21) is fixedly connected with the second spring (29), one end of the second spring (29) far away from the movable plate (21) is fixedly connected to the inner bottom of the upright plate (17), the end of the upright plate (17) and the bottom of the movable plate (21) are both provided with a limit table, and the upright plate (17) and the movable plate (21) are movably clamped by the limit table, the soft layer (292) that connects of tip fixedly connected with of fly leaf (21), the soft inner wall sliding connection who connects layer (292) and staving (1), the equal fixedly connected with torsional spring (291) in upper and lower both ends of fly leaf (21), torsional spring (291) rotates respectively and connects the inside at last change (12) and lower change (19).

3. The efficient steady flow barrel with the function of uniform material distribution as claimed in claim 2, a plurality of spoilers (22) are arranged, the spoilers (22) are all rotationally connected to the rotating column (13), the spoiler (22) is fixedly connected with a rotary column (23), the rotary column (23) is rotationally connected to the rotary column (13), a plurality of check blocks (20) are fixedly connected with the outer side of the rotating column (13), the check blocks (20) are all connected with rubber blocks (27) in a sliding manner, the rubber blocks (27) are all connected in the rotating column (13) in a sliding manner, the bottoms of the rubber blocks (27) are fixedly connected with first springs (28), one end of the first spring (28) far away from the rubber block (27) is fixedly connected inside the rotating column (13), the rubber blocks (27) are positioned on two sides of the spoiler (22) and the rubber blocks (27) are attached to the spoiler (22).

4. The efficient steady flow barrel with the function of distributing materials uniformly according to claim 3, wherein the end parts of the spoilers (22) inside the rotating column (13) are fixedly connected with fixing strips (24), the bottom parts of the fixing strips (24) are fixedly connected with connecting ropes (25), the connecting ropes (25) are slidably connected with pulleys (26), the pulleys (26) are rotatably connected at the bottom parts of the rotating column (13), and the connecting ropes (25) are in transmission connection with the material distribution component (3).

5. The efficient flow stabilizing barrel with the function of uniform material distribution is characterized in that the material distribution assembly (3) comprises a third spring (31), a rack (32), a cam (33), a gear (34), a sliding strip (35), a fourth spring (36), a rotating shaft (37), a first limiting block (38) and a second limiting block (39), the rack (32) is fixedly connected to one end, far away from the fixing strip (24), of the connecting rope (25), the connecting rope (25) is fixedly connected with the rack (32) from the bottom of the rotating column (13) through the guide plate (16) to the extension plate (15), and the rack (32) is slidably connected to the inside of the extension plate (15).

6. The efficient steady flow barrel with the function of uniform material distribution is characterized in that a third spring (31) is sleeved on the connecting rope (25), two ends of the third spring (31) are fixedly connected to inner wall plates of a rack (32) and an extension plate (15) respectively, the rack (32) is engaged with a gear (34), the gear (34) is fixedly connected with a cam (33), the gear (34) and the cam (33) rotate concentrically, a rotating shaft (37) is fixedly sleeved at the rotating centers of the gear (34) and the cam (33), and the rotating shaft (37) is rotatably connected inside the extension plate (15).

7. The efficient flow stabilizing barrel with the function of uniform material distribution is characterized in that the cam (33) is connected with a sliding strip (35) in a sliding manner, the sliding strip (35) is connected inside the extension plate (15) in a sliding manner, the sliding direction of the sliding strip (35) and the extension plate (15) is parallel to the rotating direction of the rotating column (13), the end side edge of the sliding strip (35) inside the extension plate (15) is fixedly connected with a second limit block (39), the top of the second limit block (39) is fixedly connected with a fourth spring (36), one end of the fourth spring (36), which is far away from the second limit block (39), is fixedly connected with a first limit block (38), and the first limit block (38) is fixedly connected to the extension plate (15).

8. The efficient steady flow barrel with the function of uniform material distribution is characterized in that the number of the vertical plates (17), the connecting rods (18), the extension plates (15), the guide plates (16) and the spoilers (22) is the same.

9. The efficient steady flow barrel with the function of uniform material distribution as claimed in claim 1, wherein the center points of the plate body of the vertical plate (17) and the plate body of the spoiler (22) are located on the same plane.

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