CN115920712B

CN115920712B - High-efficient agitated vessel of high concentration self-colored fiber

Info

Publication number: CN115920712B
Application number: CN202310224885.2A
Authority: CN
Inventors: 李军配; 宁理科; 王涛; 杨文东; 李怡霞; 袁鹏飞; 陈军
Original assignee: Zhejiang Wuhua Technology Co ltd
Current assignee: Zhejiang Wuhua Technology Co ltd
Priority date: 2023-03-10
Filing date: 2023-03-10
Publication date: 2023-07-18
Anticipated expiration: 2043-03-10
Also published as: CN115920712A

Abstract

The utility model provides a high-efficient agitated vessel of high concentration self-colored fiber, includes the base, base one end fixedly connected with backup pad, and the upper end of base still is provided with the agitator, and the upper end of agitator is provided with the bung, is provided with stirring structure in the agitator, stirring structure power connection has broken bubble structure, stirring structure still power connection has clear wall structure, stirring structure is including the (mixing) shaft of rotating and being connected with the bung inner wall, and the (mixing) shaft lower extreme is provided with flip structure, be provided with the elevation structure that is connected with the bung in the backup pad, be provided with on the bung with elevation structure matched with pouring structure, pouring structure is connected with the agitator, still be provided with on the base with pouring structure matched with connect the material structure, effectually solved stirring structure mode among the prior art comparatively singlely, stirring effect, inefficiency, the speed of ejection of compact is slower, the waste of material, the problem of increasing cost.

Description

High-efficient agitated vessel of high concentration self-colored fiber

Technical Field

The invention relates to the technical field of high-concentration self-coloring fiber stirring equipment, in particular to high-efficiency high-concentration self-coloring fiber stirring equipment.

Background

With the progress of the times, in order to pursue the sense of fashion, the clothes are colorful in color, the high-concentration self-colored fibers can be used for coloring and dyeing the clothes, the brightness and the wear resistance of the clothes are improved, the high-concentration self-colored fibers are usually required to be stirred before the clothes are colored, the uniformity of components is ensured, and the performance is improved.

But current stirring structure working method is comparatively single, and the stirring effect is relatively poor, and is inefficiency, and because the concentration of this material is higher, traditional material pouring mode not only leads to the material to spill easily, and the speed of ejection of compact is slower, and inconvenient material that is stained with on the stirring structure is cleared up, can cause the waste of material, increase cost.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides the high-efficiency stirring equipment for the high-concentration self-coloring fibers, which effectively solves the problems that the working mode of a stirring structure in the prior art is single, the stirring effect is poor, the efficiency is low, the material is easy to spill out in the traditional material pouring mode, the discharging speed is low, the material stained on the stirring structure is inconvenient to clean, the material is wasted, and the cost is increased.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the utility model provides a high-efficient agitated vessel of high concentration self-colored fiber, includes the base, base one end fixedly connected with backup pad, and the upper end of base still is provided with the agitator, and the upper end of agitator is provided with the bung, is provided with in the agitator and can carry out the stirring structure of limit circumference stirring edge-to-edge upset to the material of different degree of depth in the bucket, stirring structure power connection has the bubble broken bubble structure that can reciprocate the snatch limit of the bubble that the upper end produced in the material stirring process in the bucket, stirring structure still power connection has clear wall structure, and clear wall structure is including the brush that can rotate intermittently limit circumference rotation to the agitator inner wall, stirring structure is including the (mixing) shaft with bung inner wall rotation connection, and the (mixing) shaft lower extreme is provided with the stirring structure that can carry out limit circumference rotation limit upset to the material in the agitator, be provided with the elevation structure that is connected with the bung on the backup pad, be provided with on the bung and elevation structure matched with the pouring structure, pouring structure and agitator are connected, still be provided with on the base and connect the material structure with the brush that holds, connect material structure and shelves the board and place the board that is provided with on the sliding connection.

Further, the stirring structure further comprises a first motor connected with the barrel cover, the output end of the first motor is fixedly connected with the stirring shaft, the upper end of the stirring shaft is fixedly connected with a rotating plate and a cam respectively, one end of the rotating plate is provided with a second fixing rod, the inner wall of the second fixing rod is slidably connected with a lower pressing rod, the upper end of the lower pressing rod is provided with a second sliding column slidably connected with the inner wall of the cam, the upper end of the stirring shaft is slidably connected with an upper sliding block fixedly connected with the lower pressing rod, the two ends of the upper sliding block are respectively and rotatably connected with a second stirring rod, the lower end of the stirring shaft is fixedly connected with a lower fixing block corresponding to the upper sliding block, the two ends of the lower fixing block are respectively and rotatably connected with a first stirring rod, the middle parts of the first stirring rod and the second stirring rod are in cross-rotation connection, one ends of the first stirring rod and the second stirring rod are provided with stirring columns, and the two ends of each stirring column are respectively provided with stirring balls.

Further, broken bubble structure is including the first dead lever with rotating board lower extreme fixed connection, and the lower extreme of first dead lever rotates and is connected with the connecting rod, and the one end of connecting rod is provided with the first traveller with cam inner wall sliding connection, and the other end of connecting rod is provided with sector gear, the one end fixedly connected with pole of rotating board, pole sliding connection has the sliding sleeve, the one end fixedly connected with of sliding sleeve and sector gear engaged with straight rack, the lower extreme fixedly connected with supporting disk of pole, the lower extreme of sliding sleeve rotates respectively and is connected with a plurality of first broken bubble poles, and first broken bubble pole rotates and is connected with the broken bubble pole of second, and the middle part and the supporting disk inner wall rotation of the broken bubble pole of second are connected.

Further, the wall cleaning structure further comprises a wall cleaning rod which is rotationally connected with the other end of the rotating plate, a brush is arranged on the wall cleaning rod, the upper end of the wall cleaning rod is fixedly connected with a connecting gear, the lower end of the barrel cover is provided with a connecting disc, and an incomplete gear meshed with the connecting gear is arranged on the connecting disc.

Further, the turnover structure further comprises a protection box connected with the lower end of the stirring shaft, a first driving bevel gear fixedly connected with the stirring shaft is arranged in the protection box, two ends of the first driving bevel gear are respectively meshed with a first driven bevel gear, the first driven bevel gear is fixedly connected with a turnover shaft rotatably connected with the protection box, and a plurality of turnover rods are arranged on the turnover shaft.

Further, the lifting structure comprises a second motor fixedly connected with the upper end of the supporting plate, the output end of the second motor is fixedly connected with a screw rod rotationally connected with the base, and a threaded sleeve in threaded connection with the screw rod is arranged on the inner wall of one end of the barrel cover.

Further, the material pouring structure comprises a driving belt pulley fixedly connected with the upper end of the stirring shaft, the driving belt pulley is connected with a driven belt pulley rotationally connected with the barrel cover, the driven belt pulley is coaxially and fixedly connected with a first gear, a rotating rod is rotationally connected to the supporting rod, the upper end of the rotating rod is provided with a second gear meshed with the first gear, the lower end of the rotating rod is fixedly connected with a second driving bevel gear meshed with a second driven bevel gear, the second driven bevel gear is fixedly connected with a rotary barrel column rotationally connected with the base, and the rotary barrel column is fixedly connected with the lower end of the stirring barrel.

Further, the material receiving structure comprises a material baffle fixedly connected with the lower end of a discharge hole formed in one end of the stirring barrel, two ends of the material baffle are respectively fixedly connected with a limiting rod, the limiting rods are respectively and slidably connected with limiting blocks, one ends of the limiting blocks are rotationally connected with first connecting rods, the lower ends of the first connecting rods are rotationally connected with a base, the upper part of the lower ends of the first connecting rods is rotationally connected with second connecting rods, the lower ends of the second connecting rods are rotationally connected with a shelving plate, and sliding grooves which are in sliding connection with the shelving plate are formed in the base.

Compared with the prior art, the invention has the beneficial effects that:

1. when the stirring device is used, the stirring structure and the overturning structure are arranged, materials with different depths in the stirring barrel are stirred in a circumferential manner and overturned up and down by the stirring structure, meanwhile, the overturning structure works, the materials at the bottom of the stirring barrel are turned in a circumferential manner and overturned up and down, and the stirring structure and the overturning structure are matched with each other to stir the materials rapidly and efficiently.

2. The invention can clean the material polluted on the structure in the barrel after the barrel cover is moved upwards.

3. According to the invention, the stirring barrel is rotated by taking the bottom of the stirring barrel as the shaft through arranging the material pouring structure and the material receiving structure, so that materials in the stirring barrel can be conveniently poured out, and meanwhile, the material receiving barrel is placed in the placing groove on the placing plate, and the position of the material outlet of the stirring barrel is changed in the process of overturning the stirring barrel, so that the position of the placing plate is changed along with the position of the material outlet, the materials can be ensured to fall in the material receiving barrel, and the material is effectively prevented from being sprayed out.

4. According to the invention, the bubble breaking structure is arranged, and a large number of bubbles are generated at the upper end of the material in the stirring process, so that heat in the material cannot be timely dissipated, the quality of the material is influenced, the bubble breaking structure works, the bubbles generated at the upper end in the stirring process of the material in the barrel are reciprocally grabbed while rotating circumferentially, the purpose of breaking the bubbles is realized, and the dissipation of heat is ensured.

5. According to the invention, the wall cleaning structure is arranged, and the brush rotates along with the circumferential rotation to scrape off the materials stained on the barrel wall, so that the uniformity of the material components is ensured.

Drawings

FIG. 1 is a first isometric view of a high-intensity self-colored fiber high-efficiency blending apparatus of the present invention;

FIG. 2 is a second isometric view of a high-intensity self-colored fiber high-efficiency blending apparatus of the present invention;

FIG. 3 is a schematic diagram showing the first view linkage of the stirring structure and the turning structure of the high-concentration self-coloring fiber efficient stirring device;

FIG. 4 is a schematic diagram showing the linkage of the stirring structure and the turning structure of the high-efficiency stirring device for high-concentration self-colored fibers at a second view angle;

FIG. 5 is a schematic structural view of a foam breaking structure of a high-concentration self-colored fiber efficient stirring device according to the present invention;

FIG. 6 is a schematic structural view of a stirring structure of a high-concentration self-colored fiber efficient stirring device of the invention;

FIG. 7 is a schematic diagram of the wall cleaning structure of the high-concentration self-colored fiber efficient stirring device;

FIG. 8 is a schematic structural view of a turnover structure of a high-concentration self-colored fiber high-efficiency stirring device of the present invention;

FIG. 9 is a schematic view of the lower part of a stirring barrel of a high-concentration self-coloring fiber efficient stirring device of the invention;

FIG. 10 is a schematic view of the structure of a receiving structure of a high-concentration self-colored fiber high-efficiency stirring device of the present invention;

FIG. 11 is a schematic structural view of a lifting structure of a high-concentration self-colored fiber efficient stirring device of the present invention;

FIG. 12 is an enlarged partial view of area A of FIG. 5 of a high-concentration self-coloring fiber high-efficiency stirring apparatus of the present invention;

FIG. 13 is an enlarged partial view of region B of FIG. 6 of a high-concentration self-coloring fiber high-efficiency stirring apparatus of the present invention;

in the figure: 1. a base, 2, a rest plate, 3, a rest groove, 4, a stirring barrel, 5, a barrel cover, 6, a supporting plate, 7, a first motor, 8, a second motor, 9, a rotating rod, 10, a second gear, 11, a screw, 12, a discharging plate, 13, a striker plate, 14, a first connecting rod, 15, a second connecting rod, 16, a brush, 17, a rotating plate, 18, a connecting gear, 19, a cam, 20, a stirring shaft, 21, a protection box, 22, a turnover shaft, 23, a turnover rod, 24, a connecting rod, 25, a first fixing rod, 26, a first sliding column, 27, a sector gear, 28, a sliding sleeve, 29, a straight rack, 30, a first foam breaking rod, 31, a second foam breaking rod, 32, a supporting plate, 33, a foam breaking ball, 34, a second slide column, 35, a second fixing rod, 36, a lower pressing rod, 37, an upper sliding block, 38, a lower fixing block, 39, a first stirring rod, 40, a second stirring rod, 41, a stirring column, 42, a stirring ball, 43, a connecting disc, 44, a wall cleaning rod, 45, a first driving bevel gear, 46, a first driven bevel gear, 47, a barrel column, 48, a supporting leg, 49, a second driving bevel gear, 50, a second driven bevel gear, 51, a discharge port, 52, a limiting block, 53, a limiting rod, 54, a driving pulley, 55, a driving belt, 56, a driven pulley, 57, a first gear, 58, a screw sleeve, 59, an incomplete gear, 60 and a sliding chute.

Detailed Description

1-13, including base 1, base 1 one end fixedly connected with backup pad 6, base 1's upper end still is provided with agitator 4, and agitator 4's upper end is provided with bung 5, is provided with the stirring structure that can overturn from top to bottom to the material of different degree of depth in the bucket in the agitator 4, stirring structure power connection has the bubble breaking structure that can reciprocate the bubble circumference rotation limit that produces in the material stirring in-process in the bucket, stirring structure still power connection has clear wall structure, and clear wall structure is including the brush 16 that can rotate intermittently while circumference rotation to agitator 4 inner wall, stirring structure is including the (mixing) shaft 20 that rotates with bung 5 inner wall rotation to be connected, and the (mixing) shaft 20 lower extreme is provided with the flip structure that can overturn from top to bottom to the material in the agitator 4, be provided with the lift structure that is connected with bung 5 on the backup pad 6, be provided with on the bung 5 with the flip structure that matches with the lift structure, the flip structure is connected with the agitator 4, still has the brush 16 that holds up the material, and the base is provided with on the base 1 and holds up the slip board and holds up the material, holds up the base and holds up the shelf and has 2.

When the invention is used, the lifting structure is controlled to move the barrel cover 5 upwards, materials are added into the stirring barrel 4, the lifting structure is controlled to work again, the barrel cover 5 is reset, the stirring structure is controlled to work, the stirring structure is utilized to stir the materials with different depths in the stirring barrel 4 at the circumference and turn over the materials at the bottom of the stirring barrel 4 at the circumference, the turning structure is operated at the same time, the materials at the bottom of the stirring barrel 4 are turned at the circumference and turn over the materials at the top and bottom, the two are matched to stir the materials rapidly and efficiently, the wall cleaning structure works, the brush 16 rotates circumferentially and rotates automatically to scrape the materials stained on the barrel wall, the uniformity of the components of the materials is ensured, and the upper end of the materials can generate a large amount of bubbles in the stirring process, so that the heat in the materials can not be dissipated timely, the quality of the materials is influenced, the foam breaking structure works, the air bubble generated at the upper end of the stirring process of materials in the barrel is grabbed in a reciprocating manner while rotating circumferentially, the purpose of breaking open the air bubble is realized, the heat dissipation is ensured, after the stirring is completed, the lifting structure is controlled to work, the barrel cover 5 drives the stirring structure, the overturning structure, the bubble breaking structure and the wall cleaning structure to move upwards, structurally contaminated materials are cleaned, the waste of the materials is ensured, the cost is increased, after the cleaning is completed, the stirring structure is controlled to work again, the stirring structure, the overturning structure, the bubble breaking structure and the wall cleaning structure are dried by water, the next normal use is ensured, and meanwhile, the pouring structure works, the stirring barrel 4 is rotated by taking the bottom of the stirring barrel as a shaft, the materials in the stirring barrel 4 are conveniently poured out, meanwhile, the material receiving barrel is placed in the shelving groove 3 on the shelving plate 2, the position of the material outlet 51 is changed due to the overturning process of the stirring barrel 4, therefore, the position of the placing plate 2 can be changed along with the position of the discharge hole 51, so that the materials can be ensured to fall in the receiving bucket, and the material is effectively prevented from being spilled.

As shown in fig. 3, 4, 6 and 13, the stirring structure further comprises a first motor 7 connected with the barrel cover 5, an output end of the first motor 7 is fixedly connected with the stirring shaft 20, an upper end of the stirring shaft 20 is fixedly connected with a rotating plate 17 and a cam 19 respectively, one end of the rotating plate 17 is provided with a second fixed rod 35, an inner wall of the second fixed rod 35 is slidably connected with a lower pressing rod 36, an upper end of the lower pressing rod 36 is provided with a second sliding column 34 slidably connected with an inner wall of the cam 19, an upper sliding block 37 fixedly connected with the lower pressing rod 36 is slidably connected with two ends of the upper sliding block 37, two ends of the upper sliding block 37 are respectively and rotatably connected with a second stirring rod 40, a lower fixed block 38 corresponding to the upper sliding block 37 is fixedly connected with two ends of the stirring shaft 20, two ends of the lower fixed block 38 are respectively and rotatably connected with a first stirring rod 39, a middle part of the first stirring rod 39 and a second stirring rod 40 are in a cross rotation connection, one end of the first stirring rod 39 and the second stirring rod 40 is provided with a stirring column 41, and two ends of the stirring column 41 are respectively provided with a stirring ball 42.

Preferably, the first motor 7 works, the output end of the first motor 7 drives the stirring shaft 20 to rotate, the stirring shaft 20 drives the turntable and the cam 19 to rotate respectively, the inner wall of the cam 19 is matched with the second sliding column 34 in the rotating process, the lower pressing rod 36 is driven to reciprocate downwards under the limiting action of the second fixing rod 35, the lower pressing rod 36 drives the upper sliding block 37 to reciprocate along the stirring shaft 20, and the upper sliding block 37 drives the second stirring rod 40 to rotate respectively in the fixed position of the lower fixing block 38, so that the included angle between the upper sliding block 37 and the stirring rod is adjusted in a reciprocating manner by matching with the first stirring rod 39, different depths of materials in the stirring barrel 4 can be stirred, the stirring columns 41 are driven to reciprocate respectively in the rotating process of the first stirring rod 39 and the second stirring rod 40, the stirring columns 41 drive the stirring balls 42 to reciprocate to overturn the materials, the high efficiency and the functionality in the stirring process are ensured, and the uniformity of stirring of the materials is improved.

As shown in fig. 3, 4, 5 and 12, the foam breaking structure comprises a first fixing rod 25 fixedly connected with the lower end of a rotating plate 17, a connecting rod 24 is rotatably connected with the lower end of the first fixing rod 25, one end of the connecting rod 24 is provided with a first sliding column 26 slidably connected with the inner wall of a cam 19, the other end of the connecting rod 24 is provided with a sector gear 27, one end of the rotating plate 17 is fixedly connected with a post rod, the post rod is slidably connected with a sliding sleeve 28, one end of the sliding sleeve 28 is fixedly connected with a straight toothed bar 29 meshed with the sector gear 27, the lower end of the post rod is fixedly connected with a supporting disc 32, the lower ends of the sliding sleeve 28 are respectively rotatably connected with a plurality of first foam breaking rods 30, the first foam breaking rods 30 are rotatably connected with a second foam breaking rod 31, the middle part of the second foam breaking rod 31 is rotatably connected with the inner wall of the supporting disc 32, and the lower end of the second foam breaking rod 31 is provided with a foam breaking ball 33.

Preferably, the cam 19 further drives the first sliding column 26 to move up and down in the rotating process, the first sliding column 26 drives the connecting rod 24 to swing in an arc shape by taking the middle of the connecting rod as an axis, the connecting rod 24 drives the sector gear 27 to swing in an arc shape, the straight rack 29 on the sector gear 27 is meshed with the straight rack 29 on the sliding sleeve 28 in the arc swing process of the sector gear 27, the sliding sleeve 28 moves up and down along the post rod, the sliding sleeve 28 drives the plurality of first foam breaking rods 30 at the lower end to rotate, and the first foam breaking rods 30 drive the second foam breaking rods 31 to rotate by taking the middle of the second foam breaking rods as an axis due to the fixed position of the supporting disc 32, the second foam breaking rods 31 drive the foam breaking balls 33 to perform capturing action, the foam breaking balls 33 are utilized to break bubbles at the upper end of materials, the timely dissipation of heat is guaranteed, and the foam breaking balls 33 perform the capturing action and the foam breaking process at different positions at the upper end of the stirring barrel 4 while rotating circumferentially.

As shown in fig. 3, 4 and 7, the wall cleaning structure further comprises a wall cleaning rod 44 rotatably connected with the other end of the rotating plate 17, a brush 16 is arranged on the wall cleaning rod 44, a connecting gear 18 is fixedly connected with the upper end of the wall cleaning rod 44, a connecting disc 43 is arranged at the lower end of the barrel cover 5, and an incomplete gear 59 meshed with the connecting gear 18 is arranged on the connecting disc 43.

Preferably, the rotating plate 17 drives the wall cleaning rod 44 to rotate circumferentially in the rotating process, and the connecting gear 18 and the incomplete gear 59 at the upper end of the wall cleaning rod 44 are meshed intermittently in the rotating process, so that the brush 16 on the wall cleaning rod 44 rotates intermittently while rotating circumferentially, different positions of the brush 16 on the wall cleaning rod 44 are ensured to be contacted with the barrel wall, and a better cleaning effect is achieved on the material stained on the inner wall of the stirring barrel 4.

As shown in fig. 3, 4 and 8, the turnover structure further comprises a protection box 21 connected with the lower end of the stirring shaft 20, a first driving bevel gear 45 fixedly connected with the stirring shaft 20 is arranged in the protection box 21, two ends of the first driving bevel gear 45 are respectively meshed with a first driven bevel gear 46, the first driven bevel gear 46 is fixedly connected with a turnover shaft 22 rotatably connected with the protection box 21, and a plurality of turnover rods 23 are arranged on the turnover shaft 22.

Preferably, the stirring shaft 20 rotates to drive the first driving bevel gear 45 in the protection box 21 to rotate, the first driving bevel gear 45 drives the first driven bevel gears 46 at two ends to rotate respectively, the first driven bevel gear 46 drives the turning shaft 22 to rotate, the turning shaft 22 drives the turning rod 23 to rotate, and the stirring shaft 20 rotates, so that the turning rod 23 rotates circumferentially and simultaneously, materials at the bottom of the stirring barrel 4 can be turned over, material precipitation is prevented, the uniformity of material mixing is influenced, and a pair of supporting legs 48 are further arranged at the bottom of the stirring barrel 4 to support one end of the stirring barrel 4.

As shown in fig. 1, 2 and 11, the lifting structure comprises a second motor 8 fixedly connected with the upper end of the supporting plate 6, the output end of the second motor 8 is fixedly connected with a screw rod 11 rotatably connected with the base 1, and the inner wall of one end of the barrel cover 5 is provided with a screw sleeve 58 in threaded connection with the screw rod 11.

Preferably, when the barrel cover 5 needs to be moved upwards, the second motor 8 can be controlled to work, the output end of the second motor 8 drives the screw rod 11 to rotate, the screw rod 11 is in threaded fit with the threaded sleeve 58 on the inner wall of the barrel cover 5 in the rotating process, the barrel cover 5 is moved upwards, a self-locking function is achieved between the screw rod 11 and the threaded sleeve 58, the barrel cover 5 is effectively prevented from falling, and structurally contaminated materials in the barrel can be cleaned after the barrel cover 5 is moved upwards.

As shown in fig. 1, 2, 9 and 10, the pouring structure comprises a driving pulley 54 fixedly connected with the upper end of the stirring shaft 20, the driving pulley 54 is connected with a driven pulley 56 rotatably connected with the barrel cover 5, the driven pulley 56 is coaxially and fixedly connected with a first gear 57, the supporting rod is rotatably connected with a rotating rod 9, the upper end of the rotating rod 9 is provided with a second gear 10 meshed with the first gear 57, the lower end of the rotating rod 9 is fixedly connected with a second driving bevel gear 49, the second driving bevel gear 49 is meshed with a second driven bevel gear 50, the second driven bevel gear 50 is fixedly connected with a barrel column 47 rotatably connected with the base 1, and the barrel column 47 is fixedly connected with the lower end of the stirring barrel 4.

Preferably, when the barrel cover 5 moves up to the top, the first gear 57 is meshed with the second gear 10, after the material cleaning is completed, the first motor 7 is controlled to work again, the first motor 7 drives the driving pulley 54 to rotate, the driving pulley 54 drives the driven pulley 56 to rotate through the driving belt 55, the driven pulley 56 drives the first gear 57 to rotate, the first gear 57 drives the second gear 10 to rotate, the second gear 10 drives the rotating rod 9 to rotate, the rotating rod 9 drives the second driving bevel gear 49 to rotate, the second driving bevel gear 49 drives the second driven bevel gear 50 to rotate, the second driven bevel gear 50 drives the rotating barrel column 47 to rotate, the rotating barrel column 47 drives the stirring barrel 4 to overturn, and the material in the stirring barrel 4 is conveniently poured out.

As shown in fig. 1, 2, 9 and 10, the receiving structure comprises a baffle plate 13 fixedly connected with the lower end of a discharge hole 51 formed at one end of the stirring barrel 4, two ends of the baffle plate 13 are respectively fixedly connected with a limiting rod 53, the limiting rods 53 are respectively and slidably connected with a limiting block 52, one end of the limiting block 52 is rotatably connected with a first connecting rod 14, the lower end of the first connecting rod 14 is rotatably connected with a base 1, a lower part of the lower end of the first connecting rod 14 is rotatably connected with a second connecting rod 15, the lower end of the second connecting rod 15 is rotatably connected with a rest plate 2, and a chute 60 slidably connected with the rest plate 2 is arranged on the base 1.

Preferably, when the stirring barrel 4 rotates along with the stirring barrel 4 in the process of overturning, the first connecting rod 14 drives the second connecting rod 15 to move towards one end, the second connecting rod 15 drives the shelving plate 2 to slide outwards along the inner wall of the base 1, and meanwhile, the position of the bottom of the first connecting rod 14 is unchanged, so that when the stirring barrel 4 rotates, the upper end of the first connecting rod 14 drives the limiting blocks 52 at two ends of the baffle 13 to move upwards under the limit of the limiting rods 53, the discharge hole 51 of the stirring barrel 4 is opened, materials can flow out from the discharge hole 51 under the bearing of the discharge plate 12, and because the position of the discharge hole 51 changes in the process of rotating the stirring barrel 4, the position of the shelving plate 2 changes along with the position change of the discharge hole 51, the materials can be guaranteed to flow into the receiving barrel in the shelving tank 3 completely, and the material is effectively prevented from being spilled.

The working process of the invention is as follows: when the invention is used, the second motor 8 works, the output end of the second motor 8 drives the screw rod 11 to rotate, the screw rod 11 is in threaded fit with the threaded sleeve 58 on the inner wall of the barrel cover 5 in the rotating process of the screw rod 11, the barrel cover 5 is moved upwards, materials are added into the stirring barrel 4, the second motor 8 is controlled to rotate reversely, and the barrel cover 5 is reset.

The first motor 7 works, the output end of the first motor 7 drives the stirring shaft 20 to rotate, the stirring shaft 20 drives the turntable and the cam 19 to rotate respectively, the inner wall of the cam 19 is matched with the second sliding column 34 in the rotating process, the lower pressing rod 36 is driven to reciprocate downwards under the limiting action of the second fixing rod 35, the lower pressing rod 36 drives the upper sliding block 37 to reciprocate along the stirring shaft 20, and the upper sliding block 37 drives the second stirring rod 40 to rotate respectively due to the fixed position of the lower fixing block 38, so that the included angle between the upper sliding block 37 and the stirring rod is adjusted in a reciprocating manner in cooperation with the first stirring rod 39 in the rotating process of the second stirring rod 40, different depths of materials in the stirring barrel 4 can be stirred, the stirring columns 41 are driven to reciprocate respectively in the rotating process of the first stirring rod 39 and the second stirring rod 40, the stirring columns 41 drive the stirring balls 42 to reciprocate to overturn the materials, the high efficiency and the functionality in the stirring process are ensured, and the uniformity of stirring of the materials is improved.

The in-process of (mixing) shaft 20 rotation drives the rotation of first initiative bevel gear 45 in the protection box 21, and first initiative bevel gear 45 drives the rotation of first driven bevel gear 46 at both ends respectively, and first driven bevel gear 46 drives the rotation of turning shaft 22, and turning shaft 22 drives turning rod 23 rotation, and because (mixing) shaft 20 rotates, consequently turning rod 23 rotates the rotation of circle simultaneously, can overturn the material of agitator 4 bottom, prevents that the material from depositing, influences the homogeneity that the material mixes, cooperates first puddler 39 and second puddler 40 can carry out quick efficient stirring to the material.

The rotating plate 17 drives the wall cleaning rod 44 to rotate circumferentially in the rotating process, and the connecting gear 18 and the incomplete gear 59 at the upper end of the wall cleaning rod 44 are meshed intermittently in the rotating process, so that the brush 16 on the wall cleaning rod 44 rotates intermittently while rotating circumferentially, different positions of the brush 16 on the wall cleaning rod 44 are ensured to be contacted with the barrel wall, and a better cleaning effect is achieved on the material stained on the inner wall of the stirring barrel 4.

And because the upper end of the material can produce a large amount of bubbles in the process of stirring, heat in the material can not be timely dissipated, the quality of the material is influenced, the cam 19 rotates, the in-process drives the first slide column 26 to move up and down, the first slide column 26 drives the connecting rod 24 to swing in an arc mode by taking the middle part of the connecting rod as an axis, the connecting rod 24 drives the sector gear 27 to swing in an arc mode, the straight racks 29 on the sliding sleeve 28 are meshed in the arc swinging process of the sector gear 27, the sliding sleeve 28 moves up and down along the pole is realized, the sliding sleeve 28 drives a plurality of first foam breaking rods 30 at the lower end to rotate, the first foam breaking rods 30 drive the second foam breaking rods 31 to rotate by taking the middle parts of the first foam breaking rods as axes, the second foam breaking rods 31 drive the foam breaking balls 33 to perform grabbing action, the foam breaking treatment on the upper end of the material is guaranteed to dissipate heat timely, and the rotating plate 17 rotates, so that the foam breaking balls 33 perform grabbing action and circumferentially rotate at different positions on the upper end of the stirring barrel 4.

After the stirring is finished, the barrel cover 5 is controlled to move upwards again, the barrel cover 5 drives structural components in the barrel to move upwards synchronously, and materials stained on the structural components are cleaned preferentially, so that the waste of the materials is ensured, and the cost is increased.

After the cleaning is finished, the first motor 7 is controlled to work, and water stains on structural components in the stirring barrel 4 are dried, so that the next normal use is ensured.

The first motor 7 is disconnected, the second motor 8 is controlled to work, the barrel cover 5 is moved to the top, the first gear 57 is meshed with the second gear 10, the first motor 7 is controlled to work, the first motor 7 drives the driving belt pulley 54 to rotate, the driving belt pulley 54 drives the driven belt pulley 56 to rotate through the driving belt 55, the driven belt pulley 56 drives the first gear 57 to rotate, the first gear 57 drives the second gear 10 to rotate, the second gear 10 drives the rotating rod 9 to rotate, the rotating rod 9 drives the second driving bevel gear 49 to rotate, the second driving bevel gear 49 drives the second driven bevel gear 50 to rotate, the second driven bevel gear 50 drives the barrel post 47 to rotate, the barrel post 47 drives the stirring barrel 4 to rotate by taking the bottom of the barrel post as an axis, materials in the stirring barrel 4 are conveniently poured out, and materials in the stirring barrel 4 are conveniently poured out.

When the stirring barrel 4 turns over, the first connecting rod 14 rotates along with the stirring barrel 4, the first connecting rod 14 drives the second connecting rod 15 to move towards one end, the second connecting rod 15 drives the shelving plate 2 to slide outwards along the inner wall of the base 1, and meanwhile, the position of the bottom of the first connecting rod 14 is unchanged, so that when the stirring barrel 4 rotates, the upper end of the first connecting rod 14 drives the limiting blocks 52 at two ends of the baffle 13 to move upwards under the limit of the limiting rods 53, the discharge hole 51 of the stirring barrel 4 is opened, materials can flow out from the discharge hole 51 under the bearing of the discharge plate 12, and because the position of the discharge hole 51 changes in the rotation process of the stirring barrel 4, the position of the shelving plate 2 changes along with the position change of the discharge hole 51 under the pushing action of the second connecting rod 15, the materials can be guaranteed to flow into the receiving barrel in the shelving tank 3 completely, and the material is effectively prevented from being spilled.

Claims

1. A high-efficient agitated vessel of high concentration self-colored fiber, its characterized in that: including base (1), base (1) one end fixedly connected with backup pad (6), the upper end of base (1) still is provided with agitator (4), and the upper end of agitator (4) is provided with bung (5), is provided with in agitator (4) and can carry out the stirring structure of turning over from top to bottom to the material of different degree of depth in the bucket, stirring structure power connection has the bubble broken structure that can go up the bubble that the upper end produced in the material stirring process in the bucket limit circumference rotates the limit reciprocal snatch, stirring structure still power connection has clear wall structure, and clear wall structure is including brush (16) that can rotate limit circumference rotation intermittent type nature to agitator (4) inner wall, stirring structure is including stirring axle (20) that rotates the connection with bung (5) inner wall, and stirring axle (20) lower extreme is provided with can carry out the upset structure of limit circumference rotation limit upset from top to bottom to the material of interior bottom of agitator (4), be provided with on backup pad (6) and bung (5) and be connected with the elevation structure, be provided with on bung (5) and elevation structure matched with the material pouring structure, and connection (2) are connected with base (2) and are laid down structure (1) and are connected with, are still provided with pouring structure (2), the foam breaking structure comprises a first fixed rod (25) fixedly connected with the lower end of a rotating plate (17), a connecting rod (24) is rotationally connected with the lower end of the first fixed rod (25), one end of the connecting rod (24) is provided with a first sliding column (26) in sliding connection with the inner wall of a cam (19), the other end of the connecting rod (24) is provided with a sector gear (27), one end of the rotating plate (17) is fixedly connected with a post rod, the post rod is fixedly connected with a sliding sleeve (28), one end of the sliding sleeve (28) is fixedly connected with a straight tooth bar (29) meshed with the sector gear (27), the lower end of the post rod is fixedly connected with a supporting disc (32), the lower ends of the sliding sleeve (28) are respectively rotationally connected with a plurality of first foam breaking rods (30), the middle part of the second foam breaking rods (31) are rotationally connected with the inner wall of the supporting disc (32), the lower end of the second foam breaking rods (31) is provided with a foam breaking ball (33), the connecting structure comprises a stop block (52) fixedly connected with the lower end of a stirring barrel (4) and the stop block (53), the two ends of the stop block (52) are fixedly connected with the stop blocks (13) respectively, the lower end of the first connecting rod (14) is rotationally connected with the base (1), a second connecting rod (15) is rotationally connected to the upper portion of the lower end of the first connecting rod (14), the lower end of the second connecting rod (15) is rotationally connected with the shelving plate (2), and a sliding groove (60) which is in sliding connection with the shelving plate (2) is arranged on the base (1).

2. The high-efficiency high-concentration self-coloring fiber stirring device according to claim 1, wherein: the stirring structure further comprises a first motor (7) connected with the barrel cover (5), the output end of the first motor (7) is fixedly connected with the stirring shaft (20), the upper end of the stirring shaft (20) is fixedly connected with a rotating plate (17) and a cam (19) respectively, one end of the rotating plate (17) is provided with a second fixing rod (35), the inner wall of the second fixing rod (35) is slidably connected with a lower pressing rod (36), the upper end of the lower pressing rod (36) is provided with a second sliding column (34) slidably connected with the inner wall of the cam (19), the upper end of the stirring shaft (20) is slidably connected with an upper sliding block (37) fixedly connected with the lower pressing rod (36), two ends of the upper sliding block (37) are respectively connected with a second stirring rod (40) in a rotating mode, two ends of the lower fixing block (38) are respectively connected with a first stirring rod (39) in a rotating mode, two ends of the first stirring rod (39) and the second stirring rod (40) are respectively in a cross-rotating mode, and two ends of the first stirring rod (39) and the second stirring rod (40) are respectively provided with stirring balls (41).

3. The high-efficiency high-concentration self-coloring fiber stirring device according to claim 1, wherein: the wall cleaning structure further comprises a wall cleaning rod (44) which is rotationally connected with the other end of the rotating plate (17), a brush (16) is arranged on the wall cleaning rod (44), the upper end of the wall cleaning rod (44) is fixedly connected with a connecting gear (18), the lower end of the barrel cover (5) is provided with a connecting disc (43), and an incomplete gear (59) meshed with the connecting gear (18) is arranged on the connecting disc (43).

4. The high-efficiency high-concentration self-coloring fiber stirring device according to claim 1, wherein: the turnover structure further comprises a protection box (21) connected with the lower end of the stirring shaft (20), a first driving bevel gear (45) fixedly connected with the stirring shaft (20) is arranged in the protection box (21), two ends of the first driving bevel gear (45) are respectively meshed with a first driven bevel gear (46), the first driven bevel gear (46) is fixedly connected with a turnover shaft (22) rotatably connected with the protection box (21), and a plurality of turnover rods (23) are arranged on the turnover shaft (22).

5. The high-efficiency high-concentration self-coloring fiber stirring device according to claim 1, wherein: the lifting structure comprises a second motor (8) fixedly connected with the upper end of the supporting plate (6), the output end of the second motor (8) is fixedly connected with a screw (11) rotationally connected with the base (1), and a threaded sleeve (58) in threaded connection with the screw (11) is arranged on the inner wall of one end of the barrel cover (5).

6. The high-efficiency high-concentration self-coloring fiber stirring device according to claim 1, wherein: the material pouring structure comprises a driving belt wheel (54) fixedly connected with the upper end of a stirring shaft (20), a driven belt wheel (56) rotationally connected with a barrel cover (5) is connected to the driving belt wheel (54), a first gear (57) is coaxially and fixedly connected to the driven belt wheel (56), a rotating rod (9) is rotationally connected to the supporting rod, a second gear (10) meshed with the first gear (57) is arranged at the upper end of the rotating rod (9), a second driving bevel gear (49) is fixedly connected to the lower end of the rotating rod (9), a second driven bevel gear (50) is meshed with the second driving bevel gear (49), a rotary barrel column (47) rotationally connected with a base (1) is fixedly connected to the second driven bevel gear (50), and the rotary barrel column (47) is fixedly connected with the lower end of the stirring barrel (4).