CN119460464A - A coal-water slurry additive storage device based on coal chemical industry - Google Patents

Abstract

The invention relates to the field of additive storage, in particular to a coal water slurry additive storage device based on coal chemical industry, which comprises a barrel body, a bottom plate, a top plate, a connecting cylinder, a rotating rod, an agitating plate, a blocking component and the like; the barrel body is rotatably connected with a bottom plate, the barrel body is connected with a top plate, the bottom plate is fixedly connected with a connecting cylinder, the connecting cylinder is connected with a rotating rod, and the rotating rod is fixedly connected with an agitating plate. According to the invention, after the barrel body is inverted, the dispersing powder needs to flow through the stirring plate, and dispersing powder blocks which are mutually adhered together and flow through the stirring plate are scattered by the stirring plate, so that the problem that a worker can normally pour out the dispersing powder in the storage device after dredging the outlet of the storage device and work load is generated on the worker is avoided.

Description

Coal chemical industry-based coal water slurry additive storage device

Technical Field

The invention relates to the field of additive storage, in particular to a coal water slurry additive storage device based on coal chemical industry.

Background

The water-coal-slurry dispersing agent is a common water-coal-slurry additive, and is usually in powder form, after the production of the water-coal-slurry dispersing agent is completed, the dispersing agent is required to be filled into a storage device, then the storage device filled with the dispersing agent is transported by a transport vehicle, and in the process of filling the dispersing agent into the storage device by workers, the storage device is usually dithered after the dispersing agent is filled, so that the distance between dispersing agent powders is reduced, part of dispersing agent can be continuously filled into the storage device, therefore, the storage device is usually stored with sufficient dispersing agent, then in the transportation process, part of road surface is uneven, the storage device and the dispersing agent are dithered further, the dispersing agent powders in the storage device are mutually extruded, the friction force among the powders is increased, and the electrostatic effect among powder particles is promoted, the agglomeration phenomenon is easy, and part of dispersing agent powders are mutually clustered to form dispersing agent powder blocks, so that when the dispersing agent powders in the storage device are poured out by workers, the outlet of the storage device is easily blocked, the dispersing agent powder blocks are required to be filled into the storage device by workers, and the outlet of the storage device is frequently carried out, and the dispersing agent powders can be dredged by workers.

Disclosure of Invention

In order to overcome the defect that the dispersing agent powder in the storage device can be poured out normally after a worker needs to dredge the outlet of the storage device frequently due to the fact that the outlet of the storage device is blocked easily by the dispersing agent powder blocks, and work load is generated on the worker, the invention provides the coal water slurry additive storage device based on the coal chemical industry.

The technical scheme is that the coal water slurry additive storage device based on the coal chemical industry comprises barrel bodies, bottom plates and top plates, wherein each barrel body is rotatably connected with one bottom plate, each barrel body is connected with one top plate, the top plate is provided with an inlet part, the coal water slurry additive storage device further comprises connecting cylinders, rotating rods, stirring plates and blocking components, each bottom plate is fixedly connected with one connecting cylinder, each connecting cylinder is connected with one rotating rod, each rotating rod is fixedly connected with a plurality of stirring plates, the rotating rods are connected with blocking components, and dispersing agent powder blocks adhered to each other can be fully scattered by the stirring plates through the blocking components.

Further, the blocking assembly comprises a shielding plate I, a damping ring and shielding plates II, wherein the shielding plates I are rotatably connected to a rotating rod, the shielding plates I are provided with a plurality of protruding block portions I, the damping ring is rotatably connected to an inlet portion, the damping ring is provided with a matching groove, the matching groove is embedded with the shielding plates I, the shielding plates II are fixedly connected to the rotating rod, the number of the shielding plates II is consistent with that of the protruding block portions I, each shielding plate II is provided with a protruding block portion II, and the shielding plates II are matched with the shielding plates I.

Furthermore, the inclined planes are arranged on the bump part I and the bump part II, and the inclined planes on the bump part I and the bump part II are positioned in the same rotation direction.

Further, the grinding plate is further included, the shielding plates I and the shielding plates II are arranged to incline upwards, and each shielding plate II is fixedly connected with the grinding plate.

Further, the middle part of the top plate is in a convex state.

The telescopic connecting device comprises a rotary rod, a sliding rod, limiting blocks, telescopic rods, connecting ropes and springs, wherein the rotary rod is provided with a guide rail part, a connecting cylinder is provided with a sliding groove part, the guide rail part slides in the sliding groove part, the connecting cylinder is provided with the limiting parts, the limiting parts are communicated with the sliding groove part, the rotary rod is slidably connected with the limiting blocks, the telescopic rods are fixedly connected between two adjacent limiting blocks, the connecting ropes are arranged below the telescopic rods, the rotary rod is slidably connected with the sliding rod, the sliding rod is provided with a pressing part, the pressing part is arranged between the telescopic rod at the lowest part and the connecting ropes, and the springs are fixedly connected between the connecting cylinder and the rotary rod.

Further, the roof is provided with a plurality of bellying II, and the tip and the roof laminating of top stirring board.

The device further comprises a clamping ring and a clamping block, wherein the bottom plate is fixedly connected with a plurality of clamping rings, the bottom plate is fixedly connected with a plurality of clamping blocks distributed in an annular array, and the clamping rings are staggered with the clamping blocks.

Further, the middle part of the bottom plate is in a concave state.

Further, the lower side surface of the bottom plate is provided with a plurality of protruding parts I.

The invention has the beneficial effects that after the barrel body is inverted, the dispersing powder needs to flow through the stirring plate, and dispersing powder blocks which are mutually bonded together and flow through the stirring plate are scattered by the stirring plate, so that the problem that a worker can normally pour the dispersing powder in the storage device after dredging the outlet of the storage device and work load is generated on the worker is avoided;

According to the invention, the dispersing powder is blocked by the dislocation of the shielding plate II and the shielding plate I, so that the dispersing powder blocks which are mutually adhered together can be fully scattered by the stirring plate, the discharged dispersing powder can be fully mixed with other mixed substances (coal water slurry) when being poured into the mixing container, and the crushing and mixing burden of the mixing container to the dispersing powder is reduced;

according to the invention, the stirring plate rotates to pass through the plurality of protruding parts II, so that the shielding plates I and II repeatedly shake, the dispersing agent cannot be blocked between the shielding plates I, and the problem that the dispersing agent cannot flow out normally due to the blocking of dispersing agent powder between the shielding plates I is avoided

According to the invention, the small blocks of the dispersing agent powder are crushed into the dispersing agent powder through the crushing plate, and the dispersing agent powder on the periphery of the shielding plate II is stirred, so that the dispersing agent powder is convenient to pour out, and the dispersing and discharging effects of the dispersing agent powder are further improved;

According to the invention, the barrel bodies are connected together through the clamping rings and the clamping blocks, so that when a transport vehicle passes through an uneven road surface, the shaking of the barrel bodies can be reduced, the mutual extrusion among dispersing agent powder in the barrel bodies is reduced, and the formation of dispersing agent powder blocks is reduced.

Drawings

FIG. 1 is a state diagram of a plurality of barrels connected with each other, disclosed by a coal chemical industry-based water-coal slurry additive storage device;

FIG. 2 is a schematic diagram of the combined structure of a barrel and a top plate disclosed by the coal chemical industry-based water-coal slurry additive storage device;

FIG. 3 is a schematic diagram of the combined structure of a barrel, a bottom plate, a clamping ring and a clamping block disclosed by the coal chemical industry-based water-coal slurry additive storage device;

FIG. 4 is a sectional view of a barrel, bottom plate, top plate, disclosed herein, of a coal slurry additive storage device based on coal chemistry;

FIG. 5 is a schematic diagram of the combined structure of a barrel, a top plate, a rotating rod, a shielding plate I, a damping ring, a shielding plate II and a sliding rod disclosed by the coal chemical industry-based water-coal slurry additive storage device;

FIG. 6 is a schematic diagram of the combined structure of the barrel, top plate and damping ring disclosed by the coal chemical industry-based water-coal slurry additive storage device;

FIG. 7 is an enlarged view of the invention at A in FIG. 6;

FIG. 8 is a schematic diagram of the combined structure of a rotating rod, a shielding plate I, a shielding plate II and a grinding plate disclosed by the coal chemical industry-based water-coal slurry additive storage device;

FIG. 9 is an exploded view of a rotating rod baffle I, a baffle II and a grinding plate disclosed in the coal chemical industry-based water-coal slurry additive storage device of the present invention;

FIG. 10 is a sectional view of a connecting cylinder and a rotating rod of the coal-based water slurry additive storage device of the present invention;

FIG. 11 is a schematic diagram of the combined structure of a connecting cylinder, a rotating rod, a sliding rod, a limiting block, a telescopic rod and a connecting rope disclosed by the coal chemical industry-based water-coal slurry additive storage device;

FIG. 12 is a drawing showing the state of pressing down the rotating rod disclosed by the additive storage device for coal water slurry based on coal chemical industry.

The device comprises a 1-barrel body, a 2-bottom plate, a 3-top plate, a 4-connecting cylinder, a 5-rotating rod, a 6-stirring plate, a 101-shielding plate I, a 102-damping ring, a 103-shielding plate II, a 201-crushing plate, a 301-sliding rod, a 302-limiting block, a 303-telescopic rod, a 304-connecting rope, a 305-spring, a 401-clamping ring, a 402-clamping block, a 2001-protruding part I, a 3001-inlet part, a 3002-protruding part II, a 4001-sliding groove part, a 4002-limiting part, a 5001-guide rail part, a 10101-protruding part I, a 10201-matching groove, a 10301-protruding part II and a 30101-pressing part.

Detailed Description

The above-described aspects are further described below in conjunction with specific embodiments. It should be understood that these examples are illustrative of the present application and are not intended to limit the scope of the present application. The implementation conditions used in the examples may be further adjusted according to the conditions of the specific manufacturer, and the implementation conditions not specified are generally those in routine experiments.

Example 1

The coal chemical industry-based coal water slurry additive storage device comprises barrel bodies 1, bottom plates 2 and top plates 3, wherein each barrel body 1 is rotatably connected with one bottom plate 2, each barrel body 1 is connected with one top plate 3, and the top plate 3 is provided with an inlet 3001;

The stirring device further comprises connecting cylinders 4, rotating rods 5, stirring plates 6 and blocking components, each bottom plate 2 is fixedly connected with one connecting cylinder 4, each connecting cylinder 4 is connected with one rotating rod 5, each rotating rod 5 is fixedly connected with six stirring plates 6, the rotating rods 5 are connected with the blocking components, the dispersing powder is blocked through the blocking components, and dispersing powder blocks which are mutually adhered together are guaranteed to be sufficiently scattered by the stirring plates 6.

The blocking assembly comprises a shielding plate I101, a damping ring 102 and shielding plates II103, wherein the shielding plate I101 is rotationally connected to a rotating rod 5, a plurality of protruding block portions I10101 are arranged on the shielding plate I101, the damping ring 102 is rotationally connected to an inlet portion 3001 in a damping mode, a matching groove 10201 is formed in the damping ring 102, the matching groove 10201 is embedded with the shielding plate I101, a plurality of shielding plates II103 are fixedly connected to the rotating rod 5, the number of the shielding plates II103 is consistent with that of the protruding block portions I10101, protruding block portions II10301 are arranged on each shielding plate II103, and the shielding plates II103 are matched with the shielding plates I101.

The inclined planes are arranged on the bump part I10101 and the bump part II10301, and the inclined planes on the bump part I10101 and the bump part II10301 are in the same rotation direction, so that the shielding plate II103 and the shielding plate I101 cannot coincide, and dispersing agent powder is prevented from being clamped between the shielding plate II103 and the shielding plate I101.

The stirring device also comprises a grinding plate 201, wherein the shielding plates I101 and II103 are arranged to incline upwards, each shielding plate II103 is fixedly connected with the grinding plate 201, and the small blocks of the dispersing agent powder scattered by the stirring plate 6 are ground into the dispersing agent powder through the grinding plate 201.

The middle of the top plate 3 is in a convex state, so that after the barrel body 1 is inverted, small dispersing agent powder blocks scattered by the stirring plate 6 cannot flow to the periphery of the top plate 3, and the crushing plate 201 is convenient for crushing the small dispersing agent powder blocks.

The novel telescopic connecting rod comprises a sliding rod 301, limiting blocks 302, telescopic rods 303, connecting ropes 304 and springs 305, wherein the rotating rod 5 is provided with guide rail parts 5001, a connecting cylinder 4 is provided with sliding groove parts 4001, the guide rail parts 5001 slide in the sliding groove parts 4001, limiting parts 4002 are arranged on the connecting cylinder 4 and are communicated with the sliding groove parts 4001, the rotating rod 5 is connected with the two limiting blocks 302 in a sliding mode, two telescopic rods 303 are fixedly connected between the two adjacent limiting blocks 302, two connecting ropes 304 are fixedly connected between the two adjacent limiting blocks 302, the connecting ropes 304 are arranged below the telescopic rods 303, the rotating rod 5 is connected with the sliding rod 301 in a sliding mode, a pressing part 30101 is arranged on the sliding rod 301, the pressing part 30101 is arranged between the telescopic rod 303 at the lowest position and the connecting ropes 304, and the springs 305 are fixedly connected between the connecting cylinder 4 and the rotating rod 5.

The roof 3 is provided with a plurality of bellying II3002, and the tip and the roof 3 laminating of top stirring board 6, extrudees stirring board 6 through bellying II3002 for stirring board 6 at pivoted in-process, stirring board 6 and dwang 5 can shake repeatedly.

When a worker needs to convey a dispersing agent into the barrel body 1, the worker firstly opens a cover on the inlet portion 3001, then presses the rotating rod 5, so that the rotating rod 5 and all parts connected with the rotating rod 5 move downwards, the rotating rod 5 drives the shielding plate I101 and the shielding plate II103 to move downwards, the spring 305 is compressed, and as the telescopic rod 303 is in a compressed state in an initial state, when the limiting block 302 moves downwards to the position of the limiting portion 4002, the telescopic rod 303 resets to push the limiting block 302 to move away from each other, so that the limiting block 302 enters the limiting portion 4002, the sliding rod 301 and the rotating rod 5 are limited, the rotating rod 5 cannot move downwards any more, and the spring 305 cannot push all parts connected with the rotating rod 5 upwards, so that the distance between the shielding plate I101 and the shielding plate II103 and the inlet portion 3001 is always kept at a certain distance, and the upper side of the sliding rod 301 is aligned with the lower side of the inlet portion 3001 at the moment, and then the dispersing agent is conveyed to the position of the limiting block 2 through the limiting block I and the dispersing agent I and the shielding plate II1 in a state shown in fig. 12, and then the dispersing agent is conveyed to the position of the barrel body 101 and the shielding plate I and the shielding plate II can be prevented from entering the gap I and the shielding plate 1 through the inlet portion 3001, and the dispersing agent I can be conveyed to the inlet portion 101 and the shielding plate II and the shielding plate 1 through the inlet portion and the shielding plate 1; when the dispersant has passed the agitating plate 6, the dispersant delivery device stops delivering the dispersant, and then the worker presses the slide lever 301, so that the slide lever 301 moves downward in the rotating lever 5, therefore, the middle part of the connecting rope 304 is pulled to move downwards through the pressing part 30101, the connecting rope 304 pulls the limiting block 302 to move towards each other, the telescopic rod 303 is compressed, then the limiting block 302 is separated from the limiting part 4002, the limiting block 302 does not limit the rotating rod 5 any more, then the spring 305 pushes the rotating rod 5 and all parts connected with the rotating rod to move upwards to reset, the shielding plate I101 enters the matching groove 10201, then a worker installs the cover on the inlet part 3001, and storage of the dispersing agent is completed.

When a worker needs to pour the dispersing agent from the barrel body 1, the worker rotates the bottom plate 2 firstly, so that the bottom plate 2 rotates clockwise from top to bottom in the view angle shown in fig. 3, the bottom plate 2 drives the shielding plate II103 to rotate through the connecting cylinder 4 and the rotating rod 5, as the damping ring 102 is in damping rotation connection with the inlet part 3001, when the inclined side surface of the convex block part I10101 contacts with the right-angle surface of the convex block part II10301, the shielding plate II103 pushes the shielding plate I101 and the damping ring 102 to rotate, at the moment, the shielding plate I101 and the shielding plate II103 are converted from superposition into a misplaced state, then the worker stops rotating the bottom plate 2, so that dispersing agent is blocked from flowing out through the shielding plate II103 and the shielding plate I101, part of dispersing agent is prevented from flowing out on the hand of the worker as soon as the cover on the top plate 3 is opened by the subsequent worker, the part of dispersing agent is taken away by the worker, then the worker rotates the barrel body 1, the top plate 3 is made to face downwards so as to invert the barrel body 1 on a mixing container which needs to convey the dispersing agent, the bottom plate 2 at this time is made to face upwards, then a worker opens the cover from the inlet portion 3001, and rotates the bottom plate 2 again so that the bottom plate 2 rotates anticlockwise from the view angle shown in fig. 3, when the inclined side face of the bump portion II10301I is stuck with the right-angle face of the bump portion I10101, the shielding plate II103 pushes the shielding plate I101 and the damping ring 102 to rotate, at this time, the shielding plate I101 and the shielding plate II103 are in a overlapped state, the decomposing agent can flow out from the gap between the shielding plates I101, the rotating rod 5 drives the stirring plate 6 to rotate, the dispersing agent powder blocks which are stuck with each other and flow through the stirring plate 6 are broken up through the stirring plate 6, the outlet of the storing device is prevented from being blocked, the worker needs to dredge the outlet of the storing device, the dispersing agent powder in the storage device can be poured out normally, the problem of work load is caused to workers, the stirring plate 6 rotates, the discharged dispersing agent powder can be stirred, the phenomenon that the dispersing agent powder is accumulated during discharging is avoided, the discharging is affected, the dispersing agent cannot flow out immediately, the dispersing agent cannot flow out again after the dispersing agent is in an inverted state by more than ten degrees through the gap between the shielding plates I101, the dispersing agent powder blocks adhered together can be fully dispersed by the stirring plate 6, the discharged dispersing agent powder can be fully mixed with other mixed substances (coal water slurry) when being poured into a mixing container, the crushing and mixing load of the dispersing agent powder is relieved by the mixing container, when the required dispersing agent quantity is poured out, the workers rotate the bottom plate 2 clockwise at the view angle shown in the figure 3, the dispersing agent cannot flow out immediately, the problem that the redundant dispersing agent flows out after the barrel body 1 rotates by more than ten degrees is needed, then the workers rotate the barrel body 1 to enable the dispersing agent to be in a nine-up state, and then the workers rotate the top plate 3 to finish the cover after the dispersing agent is completely poured out, and the cover is completely poured out.

Since after the stirring plate 6 rotates to scatter the dispersant powder blocks which are adhered together, part of the dispersant powder blocks may be split into a plurality of small blocks, and then the dispersant powder is easy to block between the shielding plates I101 due to friction force between the dispersant powder small blocks and the dispersant powder, so that the dispersant cannot flow out normally, the stirring plate 6 passes through a plurality of protruding parts II3002 due to the fact that the end of the stirring plate 6 is attached to the lower side face of the top plate 3 in the process of the rotation of the stirring plate 6, the stirring plate 6 and the rotating rod 5 and all parts connected with the stirring plate are repeatedly shaken, the rotating rod 5 drives the shielding plates I101 and the shielding plates II103 to be repeatedly shaken, and therefore the dispersant cannot be blocked between the shielding plates I101, and the problem that the dispersant cannot flow out normally due to the blocking of the dispersant powder between the shielding plates I101 is avoided.

During the stirring plate 6 rotates to break up the dispersant powder pieces adhered to each other, part of the dispersant powder pieces move along the baffle plate II103 toward the top plate 3, when the dispersant powder pieces move to the middle of the top plate 3, the dispersant powder pieces are located between the adjacent grinding plates 201, and because the middle of the top plate 3 is in a concave state, the dispersant powder pieces cannot flow to the periphery of the top plate 3, and then during the stirring plate 6 rotates, the baffle plate II103 drives the grinding plates 201 to rotate, so that the dispersant powder pieces are crushed into dispersant powder by the grinding plates 201, and the dispersant powder on the periphery of the baffle plate II103 is stirred, so that the dispersant powder is convenient to pour out, and the breaking up and discharging effects of the dispersant powder of the invention are further improved.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and 3, the device further comprises a clamping ring 401 and a clamping block 402, wherein the bottom plate 2 is fixedly connected with two clamping rings 401 distributed in an annular array, the bottom plate 2 is fixedly connected with two clamping blocks 402 distributed in an annular array, and the clamping rings 401 and the clamping blocks 402 are staggered.

The middle part of the bottom plate 2 is in a concave state, so that the top plate 3 and the bottom plate 2 are matched with each other, and the stability of the stacked barrel body 1 is improved.

The bottom plate 2 downside is provided with a plurality of bellying I2001, makes bottom plate 2 and the area of contact on ground reduce through bellying I2001 to make the frictional force of bottom plate 2 and ground reduce, and then the staff can kick block ring 401 or block 402 more easily, makes bottom plate 2 rotate.

When the invention needs to be transported, a worker carries the barrel body 1 into a transport vehicle, then after two barrel bodies 1 are aligned, the worker kicks the clamping ring 401 or the clamping block 402 on one barrel body 1 to rotate, so that the clamping ring 401 is clamped with the clamping block 402 on the adjacent barrel body 1, or the worker kicks the clamping block 402 to be clamped with the adjacent clamping ring 401, so that the two adjacent barrel bodies 1 are connected with each other, then after one row of the barrel bodies is placed, the worker places the barrel body 1 on the barrel body 1 which is already placed, and enables the protruding part of the top plate 3 on the lower barrel body 1 to enter the concave part of the bottom plate 2 on the upper barrel body 1, so that the barrel body 1 is aligned up and down, and is connected with the barrel body 1 adjacent to the clamping block 402 again through the clamping ring 401, after the transport vehicle is fully loaded with the transport vehicle, the worker stops to put the barrel body 1, then the dispersant is required to be separated from the barrel body 1 through the clamping ring 401, and the dispersant is reduced, and the powder can be separated from the barrel body 1, so that the powder can be reduced from the two barrel bodies 1 and the dispersant can be separated from the barrel body 1, and the powder can be reduced, and the powder can be separated from the barrel body 1 and the barrel body 1 can be separated from the barrel body 1.

The foregoing is merely illustrative of the present invention, and the present invention is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (9)

1. The coal chemical industry-based coal water slurry additive storage device comprises barrel bodies (1), bottom plates (2) and top plates (3), wherein each barrel body (1) is rotatably connected with one bottom plate (2), each barrel body (1) is connected with one top plate (3), the top plates (3) are provided with inlet parts (3001), and the coal chemical industry-based coal water slurry additive storage device is characterized by further comprising connecting cylinders (4), rotating rods (5), stirring plates (6) and blocking components, each bottom plate (2) is fixedly connected with one connecting cylinder (4), each connecting cylinder (4) is connected with one rotating rod (5), each rotating rod (5) is fixedly connected with a plurality of stirring plates (6), and each rotating rod (5) is connected with the blocking components used for blocking dispersed powder;

The blocking assembly comprises a shielding plate I (101), a damping ring (102) and shielding plates II (103), wherein the shielding plate I (101) is rotationally connected to a rotating rod (5), a plurality of protruding block portions I (10101) are arranged on the shielding plate I (101), the damping ring (102) is rotationally connected to an inlet portion (3001), the damping ring (102) is provided with a matching groove (10201), the matching groove (10201) is embedded with the shielding plate I (101), the shielding plates II (103) are fixedly connected to the rotating rod (5), the number of the shielding plates II (103) is identical to that of the protruding block portions I (10101), and each shielding plate II (103) is provided with a protruding block portion II (10301).

2. The coal chemical industry based coal water slurry additive storage device of claim 1, wherein the bump part I (10101) and the bump part II (10301) are respectively provided with an inclined plane, and the inclined planes of the bump part I (10101) and the bump part II (10301) are in the same rotation direction.

3. The coal chemical industry-based water-coal slurry additive storage device according to claim 1, further comprising grinding plates (201), wherein the shielding plates I (101) and the shielding plates II (103) are arranged to incline upwards, and each shielding plate II (103) is fixedly connected with the grinding plate (201).

4. The coal chemical industry-based coal water slurry additive storage device according to claim 1 is characterized in that the middle of the top plate (3) is in a protruding state.

5. The coal chemical industry-based coal water slurry additive storage device is characterized by further comprising a sliding rod (301), limiting blocks (302), telescopic rods (303), connecting ropes (304) and springs (305), wherein the rotating rod (5) is provided with guide rail portions (5001), the connecting cylinder (4) is provided with sliding groove portions (4001), the guide rail portions (5001) slide in the sliding groove portions (4001), limiting portions (4002) are arranged on the connecting cylinder (4), the limiting portions (4002) are communicated with the sliding groove portions (4001), the rotating rod (5) is in sliding connection with a plurality of limiting blocks (302), a plurality of telescopic rods (303) are fixedly connected between two adjacent limiting blocks (302), a plurality of connecting ropes (304) are fixedly connected between two adjacent limiting blocks (302), the connecting ropes (304) are located below the telescopic rods (303), the rotating rod (5) is in sliding connection with the sliding rod (301), the sliding rod (301) is provided with a pressing portion (30101), the pressing portion (01) is located below the sliding rod (303), and the telescopic rods (304) are fixedly connected between the rotating rod (302) and the rotating rod (4).

6. The coal chemical industry-based coal water slurry additive storage device according to claim 1, wherein the top plate (3) is provided with a plurality of protruding parts II (3002), and the end part of the upper stirring plate (6) is attached to the top plate (3).

7. The coal chemical industry-based coal water slurry additive storage device is characterized by further comprising clamping rings (401) and clamping blocks (402), wherein the bottom plate (2) is fixedly connected with the plurality of clamping rings (401), the bottom plate (2) is fixedly connected with the plurality of clamping blocks (402) distributed in an annular array, and the clamping rings (401) are staggered with the clamping blocks (402).

8. The coal chemical industry-based coal water slurry additive storage device according to claim 7, wherein the middle part of the bottom plate (2) is in a concave state.

9. The coal chemical industry-based coal water slurry additive storage device according to any one of claims 7 to 8, wherein the lower side surface of the bottom plate (2) is provided with a plurality of protruding parts I (2001).