阅读说明：本技术 一种球磨生产车间 (Ball mill workshop ) 是由 颜志仁 陆丹萍 于 2020-10-31 设计创作，主要内容包括：本申请涉及人工牛黄生产技术领域,尤其是一种球磨生产车间,其包括球磨机构、筛分机构和真空泵,球磨机构连通于筛分机构；真空泵连通于筛分机构；球磨机构包括支撑座、球磨罐体、驱动组件和收集壳体,收集壳体固定连接于支撑座之间；球磨罐体转动连接于支撑座之间且位于收集壳体内部；收集壳体开设有填料开口；驱动组件固定连接于球磨罐体,用于驱动球磨罐体绕自身轴向转动；支撑座上固定连接有集尘机构；球磨罐体开设有进料口；进料口可拆卸连接有孔板；进料口可拆卸连接有盖板；盖板盖设于孔板上部。本申请具有球磨操作更为省时省力,提升作业车间空气质量,提升原材料的利用率的效果。(The application relates to the technical field of artificial bezoar production, in particular to a ball milling production workshop, which comprises a ball milling mechanism, a screening mechanism and a vacuum pump, wherein the ball milling mechanism is communicated with the screening mechanism; the vacuum pump is communicated with the screening mechanism; the ball milling mechanism comprises supporting seats, a ball milling tank body, a driving assembly and a collecting shell, and the collecting shell is fixedly connected between the supporting seats; the ball milling tank body is rotatably connected between the supporting seats and is positioned in the collecting shell; the collecting shell is provided with a filler opening; the driving assembly is fixedly connected with the ball milling tank body and used for driving the ball milling tank body to rotate around the self axial direction; the supporting seat is fixedly connected with a dust collecting mechanism; the ball milling tank body is provided with a feed inlet; the feed inlet is detachably connected with a pore plate; the feed inlet is detachably connected with a cover plate; the cover plate is arranged on the upper part of the pore plate. This application has ball-milling operation more labour saving and time saving, promotes job shop air quality, promotes the effect of the utilization ratio of raw and other materials.)

1. A ball mill production plant comprising a production chamber (16), characterized in that: the ball milling device also comprises a ball milling mechanism (1) and a screening mechanism (2) which are arranged in the production chamber (16), wherein the ball milling mechanism (1) is communicated with the screening mechanism (2); the screening mechanism (2) is communicated with a vacuum pump (3); the production chamber (16) is communicated with a constant temperature and humidity mechanism (81); the ball milling mechanism (1) comprises supporting seats (11), a ball milling tank body (12), a driving assembly (13) and a collecting shell (14), wherein the collecting shell (14) is fixedly connected between the supporting seats (11); the ball milling tank body (12) is rotatably connected between the supporting seats (11) and is positioned in the collecting shell (14); the collecting shell (14) is provided with a filler opening (141); the driving component (13) is fixedly connected to the ball milling tank body (12) and is used for driving the ball milling tank body (12) to rotate around the self axial direction; the supporting seat (11) is fixedly connected with a dust collecting component (5); the ball milling tank body (12) is provided with a feeding hole (121); the feed inlet (121) is provided with a sealing mechanism (1200) for controlling the material to enter and exit.

2. A ball mill production plant according to claim 1, characterised in that: the ball milling mechanism (1) further comprises a lifting platform (10), and the supporting seat (11) is fixedly connected to the lifting platform (10); the bottom of the collecting shell (14) is funnel-shaped and is fixedly connected with the lifting platform (10); the center of the bottom of the collecting shell (14) is communicated with a discharge pipe (15); one end of the discharge pipe (15) is communicated with the bottom of the collecting shell (14) and the other end is communicated with the screening mechanism (2).

3. A ball mill production plant according to claim 2, characterized in that: the screening mechanism (2) comprises a collecting box body (21), a first screening assembly (22), a second screening assembly (23) and a collecting pipe fitting (24), wherein the first screening assembly (22) is communicated with the top of the collecting box body (21); one end of the first screen assembly (22) is communicated with the top of the collection box body (21) and the other end is communicated with the second screen assembly (23); the second screen assembly (23) end is connected to the first screen assembly (22) and the other end is connected to the collection pipe (24); the discharge pipe (15) is communicated with the peripheral side of the collecting pipe (24); the vacuum pump (3) is communicated with a first vacuum tube (31); one end of the first vacuum tube (31) is communicated with the air exhaust end of the vacuum pump (3) and the other end is communicated with the top of the collection box body (21).

4. A ball mill production plant according to claim 3, characterized in that: the first screen assembly (22) comprises a first outer shell (221) and a first titanium rod filter (222), and the air inlet end of the first outer shell (221) is hermetically connected with a first main conveying pipe (223); a plurality of first conveying branch pipes (224) are fixedly communicated with the first main conveying pipe (223); one end of the first conveying branch pipe (224) is fixedly communicated with the first main conveying pipe (223) and the other end is communicated with the first titanium rod filter (222); the second screen assembly (23) comprises a second pipe shell (231) and a folding filter (232), one end of the second pipe shell (231) is communicated with the first outer shell (221), and the other end of the second pipe shell is communicated with the collecting pipe fitting (24); the air inlet end of the second pipe shell (231) is connected with a second main conveying pipe (233) in a sealing way; a plurality of second conveying branch pipes (234) are fixedly communicated with the second main conveying pipe (233); one end of the second conveying branch pipe (234) is fixedly communicated with the second main conveying pipe (233) and the other end is communicated with the folding filter (232).

5. A ball mill production plant according to claim 3, characterized in that: the bottom of the collecting box body (21) is funnel-shaped; the center of the bottom of the collection box body (21) is communicated with a discharge pipe fitting (4); the discharging pipe fitting (4) is fixedly communicated with an electromagnetic valve (41); the side wall of the discharging pipe fitting (4) is fixedly connected with a micro bin wall type vibrator (42); one end of the discharging pipe fitting (4) is communicated with the center of the bottom of the collecting box body (21) and the other end is communicated with a guiding hose (43).

6. A ball mill production plant according to claim 3, characterized in that: the dust collecting component (5) is fixedly connected to the supporting seat (11) and is positioned at the upper part of the ball milling tank body (12); the dust collection component (5) comprises a dust collection cover (51), and the dust collection cover (51) is fixedly connected to the supporting seat (11) and is positioned at the upper part of the ball milling tank body (12); the top of the dust collection cover (51) is communicated with a standby filtering mechanism (6); the standby filtering mechanism (6) is communicated with the vacuum pump (3).

7. A ball mill production plant according to claim 6, characterised in that: the standby filtering mechanism (6) comprises an outer shell (61) and a second titanium rod filter (62), and the air inlet end of the outer shell (61) is hermetically connected with a third main conveying pipe (63); the third main conveying pipe (63) is positioned inside the outer shell (61); a filter screen (631) is arranged in the third main conveying pipe (63); a plurality of third conveying branch pipes (64) are fixedly communicated with the third main conveying pipe (63); one end of the third conveying branch pipe (64) is fixedly communicated with the third main conveying pipe (63), and the other end of the third conveying branch pipe is communicated with the second titanium rod filter (62); the third main conveying pipe (63) is communicated with a standby conveying pipe (65); one end of the standby material conveying pipe (65) is communicated with the third main conveying pipe (63), and the other end of the standby material conveying pipe is communicated with the periphery of the collecting pipe fitting (24); the outer shell (61) is fixedly connected with a second vacuum tube (32); one end of the second vacuum tube (32) is communicated with the vacuum pump (3) and the other end is communicated with the upper part of the peripheral side of the outer shell (61).

8. A ball mill production plant according to claim 7, characterized in that: a three-way pipe (7) is fixedly communicated with the peripheral side of the collecting pipe fitting (24); the three-way pipe (7) is communicated with the dust hood (51) through a gas pipe (52); the three-way pipe (7) is communicated with a standby material conveying pipe (65); a first control valve (8) is arranged on the pipe section of the three-way pipe (7) communicated with the gas conveying pipe (52); and a second control valve (80) is arranged on the section of the three-way pipe (7) communicated with the standby material conveying pipe (65).

9. A ball mill production plant according to claim 1, characterised in that: the constant temperature and humidity mechanism (81) comprises an air outlet cover (811), an air suction fan (812), an air inlet cover (813) and a constant temperature and humidity machine (814), wherein the air outlet cover (811) is fixedly connected to the top of the production chamber (16); the exhaust fan (812) is communicated with the exhaust cover (811) and is arranged outside the production chamber (16); the air inlet hood (813) is fixedly connected to the top of the production chamber (16); the constant temperature and humidity machine (814) is communicated with the air inlet hood (813) and is arranged outside the production chamber (16).

Technical Field

The application relates to the technical field of artificial bezoar production, in particular to a ball mill production workshop.

Background

The ingredients involved in the production and preparation of the artificial bezoar comprise taurine, cholesterol, zinc sulfate, calcium gluconate, ox gall powder, corn starch and the like. The quality of the finally prepared calculus bovis factitius is influenced by the ingredient particle size of the calculus bovis factitius, so that the calculus bovis factitius needs to be subjected to ball milling and screening.

Referring to fig. 1, a conventional ball mill production workshop includes two installation seats 9 spaced from each other, a ball mill tank 91 is rotatably connected to the installation seats 9, and a plurality of grinding balls 910 are loaded on the ball mill tank 91. The ball milling tank 91 is connected with a driving device 92 for driving the ball milling tank 91 to rotate around the self axial direction. The ball-milling jar body 9 both ends center welding has pivot 93, and the embedded bearing 94 that is equipped with of mount pad 9, pivot 93 rotate to be connected in bearing 94. One end of the ball milling tank body 91 is circumferentially and fixedly connected with a transmission gear 913. The driving device 92 includes a driving motor 921 fixed on the ground, an output shaft of the driving motor 921 is circumferentially and fixedly connected with a driving gear 922, and the driving gear 922 is meshed with a transmission gear 913. The ball milling tank body 91 is circumferentially provided with a material inlet 911; the material inlet 911 is sealed by a sealing cover 912.

The above prior art solutions have the following drawbacks: after the ball milling is completed by adopting the prior art, the artificial bezoar ingredients in the ball milling tank body need to be manually taken out and put into a screening device for screening. The prior art is time-consuming and labor-consuming, and easily causes a large amount of dust in the air, influences the quality of the operation environment and reduces the utilization rate of raw materials.

Disclosure of Invention

In order to solve current ball-milling operation and waste time and energy, easily make and appear a large amount of dusts in the air, influence the problem of operation environmental quality and the utilization ratio that reduces raw and other materials, this application aim at provides a ball-milling workshop.

The application purpose of the application is realized by the following technical scheme: a ball milling production workshop, the production room also includes ball milling mechanism, sifting mechanism that set up in the production room, the ball milling mechanism connects to sifting mechanism; the screening mechanism is communicated with a vacuum pump; the production chamber is communicated with a constant temperature and humidity mechanism; the ball milling mechanism comprises supporting seats, a ball milling tank body, a driving assembly and a collecting shell, and the collecting shell is fixedly connected between the supporting seats; the ball milling tank body is rotatably connected between the supporting seats and is positioned in the collecting shell; the collecting shell is provided with a filler opening; the driving assembly is fixedly connected with the ball milling tank body and used for driving the ball milling tank body to rotate around the self axial direction; the supporting seat is fixedly connected with a dust collecting component; the ball milling tank body is provided with a feed inlet; the feed inlet is provided with a closing mechanism for controlling the material to enter and exit.

Through adopting above-mentioned technical scheme, open earlier apron and orifice plate and pack into ball-milling jar body with artifical bezoar preparation material, cover orifice plate and apron and carry out the ball-milling operation, open the apron after the ball-milling is accomplished, make the material that the ball-milling was accomplished flow to screening mechanism and sieve under the effect of vacuum pump and obtain the target material, and material flow direction screening mechanism in-process, the material of collection dirt subassembly adsorbability in the excessive air, guarantee operation sanitation, therefore, adopt this application can make ball-milling and screening operation save time and laborsaving, can promote job shop air quality, promote the effect of the utilization ratio of raw and other materials.

Preferably, the ball milling mechanism further comprises a lifting platform, and the supporting seat is fixedly connected to the lifting platform; the bottom of the collecting shell is funnel-shaped and is fixedly connected with the lifting platform; the center of the bottom of the collecting shell is communicated with a discharge pipe; one end of the discharge pipe is communicated with the bottom of the collecting shell, and the other end of the discharge pipe is communicated with the screening mechanism.

Through adopting above-mentioned technical scheme, under the effect of lifting platform, the material can flow to screening mechanism more fast under gravity and vacuum effect, promotes material transfer efficiency.

Preferably, the screening mechanism comprises a collecting box body, a first screening assembly, a second screening assembly and a collecting pipe, wherein the first screening assembly is communicated with the top of the collecting box body; one end of the first screening component is communicated with the top of the collecting box body, and the other end of the first screening component is communicated with the second screening component; the end of the second screen assembly is communicated with the first screen assembly, and the other end of the second screen assembly is communicated with the collecting pipe fitting; the discharge pipe is communicated with the periphery of the collecting pipe; the vacuum pump is communicated with a first vacuum tube; one end of the first vacuum tube is communicated with the air exhaust end of the vacuum pump, and the other end of the first vacuum tube is communicated with the top of the collecting box body.

Through adopting above-mentioned technical scheme, under the vacuum effect, the material collects the flow direction second screening subassembly through collecting the pipe fitting earlier and sieves, and the first screening subassembly that flows out sieves again, and the material that accomplishes the screening flows to the storage of collecting in the box and treats the transportation, can comparatively effectively sieve the material, guarantees the quality of the artificial bezoar of production.

Preferably, the first screen assembly comprises a first outer shell and a first titanium rod filter, and the air inlet end of the first outer shell is hermetically connected with a first main conveying pipe; the first main conveying pipe is fixedly communicated with a plurality of first conveying branch pipes; one end of the first conveying branch pipe is fixedly communicated with the first main conveying pipe, and the other end of the first conveying branch pipe is communicated with the first titanium rod filter; the second screening assembly comprises a second pipe shell and a folding filter, wherein one end of the second pipe shell is communicated with the first outer shell, and the other end of the second pipe shell is communicated with the collecting pipe fitting; the air inlet end of the second pipe shell is connected with a second main conveying pipe in a sealing mode; the second main conveying pipe is fixedly communicated with a plurality of second conveying branch pipes; one end of the second conveying branch pipe is fixedly communicated with the second main conveying pipe, and the other end of the second conveying branch pipe is communicated with the folding filter.

Through adopting above-mentioned technical scheme, under the double filtration of folding filter and first titanium stick filter, can comparatively effectively sieve the material, guarantee the quality of the artificial bezoar of production.

Preferably, the bottom of the collecting box body is funnel-shaped; the center of the bottom of the collecting box body is communicated with a discharging pipe fitting; the discharge pipe is fixedly communicated with an electromagnetic valve; the side wall of the discharge pipe is fixedly connected with a micro bin wall type vibrator; one end of the discharge pipe is communicated with the center of the bottom of the collecting box body, and the other end of the discharge pipe is communicated with a guide hose.

Through adopting above-mentioned technical scheme, miniature bulkhead formula vibrator can prevent that the discharging pipe from blockking up, can guarantee the discharging efficiency of discharging pipe.

Preferably, the dust collecting assembly is fixedly connected to the supporting seat and is positioned at the upper part of the ball milling tank body; the dust collecting component comprises a dust collecting cover which is fixedly connected with the supporting seat and is positioned at the upper part of the ball milling tank body; the top of the dust collection cover is communicated with a standby filtering mechanism; the standby filtering mechanism is communicated with the vacuum pump.

By adopting the technical scheme, the overflowing materials can be effectively collected, and the sanitation of the operation environment is ensured; and the air flow that collects is to reserve filter mechanism, can retrieve the material that overflows scattered, promotes the utilization ratio of raw and other materials.

Preferably, the standby filtering mechanism comprises an outer shell and a second titanium rod filter, and the air inlet end of the outer shell is hermetically connected with a third main conveying pipe; the third main conveying pipe is positioned inside the outer shell; a first filter screen is arranged in the third main conveying pipe; the third main conveying pipe is fixedly communicated with a plurality of third conveying branch pipes; one end of the third conveying branch pipe is fixedly communicated with the third main conveying pipe, and the other end of the third conveying branch pipe is communicated with the second titanium rod filter; the third main conveying pipe is communicated with a standby conveying pipe; one end of the standby conveying pipe is communicated with the third main conveying pipe, and the other end of the standby conveying pipe is communicated with the periphery of the collecting pipe fitting; the outer shell is fixedly connected with a second vacuum tube; one end of the second vacuum tube is communicated with the vacuum pump and the other end is communicated with the upper part of the peripheral side of the outer shell.

By adopting the technical scheme, when the screening mechanism breaks down and needs to be maintained, the standby filtering mechanism can be used for carrying out temporary screening treatment, so that continuous production is ensured; and can be used for collecting the materials overflowing into the air, and the utilization rate of the raw materials is improved.

Preferably, the periphery of the collecting pipe fitting is fixedly communicated with a three-way pipe; the three-way pipe is communicated with the dust hood through a gas pipe; the three-way pipe is communicated with the standby conveying pipe; the three-way pipe section communicated with the gas pipe is provided with a first control valve; and the three-way pipe section communicated with the standby conveying pipe is provided with a second control valve.

By adopting the technical scheme, when the screening mechanism operates, the second control valve is closed; when the screening mechanism needs to be overhauled, the second control valve is opened, and the standby filtering mechanism and the screening mechanism can be controlled to work simply and effectively; when dust collection treatment is needed, the first control valve is opened, and when ball milling operation is carried out, the first control valve is closed, so that the work of the dust collection assembly can be controlled simply and effectively; meanwhile, the maintenance is convenient.

Preferably, the constant temperature and humidity mechanism comprises an air outlet cover, an air exhaust fan, an air inlet cover and a constant temperature and humidity machine, wherein the air outlet cover is fixedly connected to the top of the production chamber; the air exhaust fan is communicated with the air outlet cover and is arranged outside the production chamber; the air inlet cover is fixedly connected to the top of the production chamber; the constant temperature and humidity machine is communicated with the air inlet cover and is arranged outside the production chamber.

By adopting the technical scheme, a constant-temperature and constant-humidity production environment is created, and the quality of the produced artificial bezoar is ensured.

In summary, the present application has the following advantages:

1. this application has ball-milling and screening operation and can go on together for ball-milling and screening operation are labour saving and time saving more.

2. This application is used to collection dirt subassembly and reserve filter mechanism, can promote job shop air quality and promote the utilization ratio of raw and other materials.

Drawings

Fig. 1 is a schematic view of a structure of a ball milling apparatus according to the related art.

Fig. 2 is a schematic view of the overall structure of embodiment 1 in the present application.

Fig. 3 is a schematic structural view of a ball mill mechanism and a dust collecting assembly in embodiment 1 of the present application.

Fig. 4 is a schematic structural view of a sieving mechanism in embodiment 1 of the present application.

Fig. 5 is a schematic structural view of a first filter member according to example 1 of the present application.

FIG. 6 is a schematic view showing a connection structure between a backup filter mechanism and a vacuum pump in example 1 of this application.

Fig. 7 is a schematic structural diagram of the ball milling mechanism, the blanking mechanism and the dust collecting assembly in embodiment 2 of the present application.

Fig. 8 is a partial enlarged view at a in fig. 7.

Fig. 9 is a schematic structural view of the closing mechanism in the closed state in embodiment 2 of the present application.

In the figure, 1, a ball milling mechanism; 10. lifting the platform; 100. a ladder; 11. a supporting seat; 12. ball milling a tank body; 120. driving the belt pulley; 1200. a sealing mechanism; 121. a feed inlet; 122. an orifice plate; 123. a cover plate; 1231. a first seal plate; 1232. a second seal plate; 1233. a first chute; 12331. a first moving slot; 12332. a first slide bar; 12333. a first slider; 12334. a first thread groove; 1234. a second chute; 12341. a second moving slot; 12342. a second slide bar; 12343. a second slider; 12344. a second thread groove; 1235. caulking grooves; 1236. connecting columns; 124. a first fixing member; 1240. a first fixed block; 1241. a first screw; 125. a second fixing member; 1250. a second fixed block; 1251. a second screw; 13. a drive assembly; 131. a drive motor; 132. a drive pulley; 133. a belt; 14. a collection housing; 15. a discharge pipe; 16. a production room; 2. a screening mechanism; 20. a lifting block; 21. a collection box body; 22. a first screen assembly; 221. a first outer case; 222. a first titanium rod filter; 223. a first main transport pipe; 224. a first conveying branch pipe; 23. a second screen assembly; 231. a second tube housing; 232. folding the filter; 233. a second main conveying pipe; 234. a second conveying branch pipe; 24. collecting the pipe fittings; 3. a vacuum pump; 31. a first vacuum tube; 311. a first filter member; 312. a filter mesh sheet; 313. a non-woven fabric layer; 314. a bamboo charcoal fiber felt layer; 32. a second vacuum tube; 321. a second filter member; 4. a discharge pipe fitting; 41. an electromagnetic valve; 42. a micro silo-wall vibrator; 43. a lead-out hose; 5. a dust collection assembly; 51. a dust collection cover; 510. air holes are formed; 511. a dust collecting head; 52. a gas delivery pipe; 6. a standby filtering mechanism; 61. an outer housing; 62. a second titanium rod filter; 63. a third main delivery pipe; 631. a filter screen; 64. a third conveying branch pipe; 65. a delivery pipe; 7. a three-way pipe; 8. a first control valve; 80. a second control valve; 81. a constant temperature and humidity mechanism; 811. an air outlet cover; 812. an air extracting fan; 813. an air intake hood; 814. a constant temperature and humidity machine; 815. an air supply pipe; 816. a gas delivery pipe; 9. a mounting seat; 91. ball milling a tank body; 910. grinding balls; 911. a material inlet; 912. sealing the cover; 913. a transmission gear; 92. a drive device; 921. a drive motor; 922. a driving gear; 93. a rotating shaft; 94. and a bearing.

Detailed Description

The present application is described in further detail below with reference to figures 2-9 and examples.

Example 1:

referring to fig. 2, for a ball milling workshop that this application disclosed, including production room 16, be provided with ball-milling mechanism 1 in the production room 16, ball-milling mechanism 1 intercommunication has screening mechanism 2. The screening mechanism 2 is communicated with a vacuum pump 3, and the vacuum pump 3 is preferably a screw type vacuum pump. In order to ensure the sanitation of the working environment, the ball milling mechanism 1 is provided with a dust collecting component 5. In order to recover the materials overflowed to the air, the dust collection assembly 5 is communicated with a standby filtering mechanism 6 communicated with the vacuum pump 3. The standby filtering mechanism 6 is communicated with the screening mechanism 2, and when the screening mechanism 2 needs to be overhauled, the standby filtering mechanism 6 can screen materials, so that continuous production can be guaranteed.

Referring to fig. 2, in order to create a constant temperature and humidity production environment and ensure the quality of the produced calculus bovis factitius, the production chamber 16 is communicated with a constant temperature and humidity mechanism 81. The constant temperature and humidity mechanism 81 comprises an air outlet cover 811, an air suction fan 812, an air inlet cover 813 and a constant temperature and humidity machine 814, wherein the air outlet cover 811 is fixedly connected to the top of the production chamber 16, and the air suction fan 812 is communicated with the air outlet cover 811 and is arranged outside the production chamber 16. The air outlet cover 811 is communicated with the suction fan 812 through an air supply pipe 815. The air inlet hood 813 is fixedly connected to the top of the production chamber 16, and the constant temperature and humidity machine 814 is communicated with the air inlet hood 813 and is arranged outside the production chamber 16. The air inlet hood 813 is communicated with the constant temperature and humidity machine 814 through an air delivery pipe 816.

Referring to fig. 2 and 3, the ball milling mechanism 1 includes a lifting platform 10, and the lifting platform 10 is mounted with a ladder 100 for an operator to climb. Two supporting seats 11 are welded on the lifting platform 10 and are spaced from each other. The supporting seat 11 is rotatably connected with a ball milling tank 12, and grinding balls for ball milling materials are loaded in the ball milling tank 12. The rotating shaft of the ball milling tank body 12 is rotatably connected to the supporting seat 11. The rotating shaft of the ball milling tank body 12 is fixedly connected with a driving component 13. The driving assembly 13 includes a driving motor 131, and a driving pulley 132 is fixedly connected to an output shaft of the driving motor 131 in a circumferential direction. A driving belt pulley 120 is fixedly connected to the circumferential direction of the rotating shaft of the ball mill pot 12, and a belt 133 is sleeved between the driving belt pulley 132 and the driving belt pulley 120.

Referring to fig. 2 and 3, the lifting platform 10 is provided with a collection housing 14, and the side wall of the collection housing 14 is fixedly connected between the support bases 11. The ball mill pot 12 is rotatably connected between the support bases 11 and is located inside the collecting case 14. The collection housing 14 is opened with a filler opening 141 for feeding the material. The outer wall of the ball milling tank body 12 is circumferentially provided with a feeding hole 121. The feed port 121 is provided with a closing mechanism 1200. The closing mechanism 1200 includes an orifice plate 122 fixedly connected to the feed inlet 121 by bolts, and the aperture of the orifice plate 122 is 12mm, so as to allow the material subjected to ball milling to flow into the collecting housing 14, and the grinding balls are retained in the ball milling tank 12. The feed inlet 121 is fixedly connected with a cover plate 123 through bolts, and the cover plate 123 is arranged on the upper portion of the orifice plate 122 in a covering mode and prevents materials from flowing out during ball milling operation. The bottom of the collecting shell 14 is a funnel, and the center of the bottom of the collecting shell 14 is communicated with a discharge pipe 15. Discharging pipe 15 one end is fixed to be communicated in collecting 14 bottom centers of casing department and the other end communicates in screening mechanism 2, and the material that will accomplish the ball-milling is transported to screening mechanism 2 and is sieved the processing, has saved manual operation and has transported the operation, can promote raw and other materials utilization ratio and promote whole production efficiency.

Referring to fig. 2 and 4, the screening mechanism 2 includes a collecting box 21 placed on the ground, a lifting block 20 is fixedly connected to the lower surface of the collecting box 21, and universal wheels are mounted on the lower surface of the lifting block 20 to facilitate movement of the collecting box 21. The bottom surface in the collection box body 21 is funnel-shaped, and the center of the bottom of the collection box body 21 is communicated with a discharge pipe fitting 4. One end of the discharging pipe fitting 4 is fixedly communicated with the center of the bottom of the collecting box body 21, and the other end of the discharging pipe fitting is sleeved with a guiding hose 43. The sleeve joint of the discharging pipe fitting 4 and the guiding hose 43 is reinforced by a pipeline connecting piece, so that the discharging pipe fitting and the guiding hose are prevented from falling off. In order to ensure the discharging efficiency of the discharging pipe fitting 4, the discharging pipe fitting 4 is fixedly communicated with an electromagnetic valve 41, and the side wall of the discharging pipe fitting 4 is fixedly connected with a micro bin wall type vibrator 42.

Referring to fig. 5, the vacuum pump 3 is connected to a first vacuum tube 31, one end of the first vacuum tube 31 is fixedly connected to the suction end of the vacuum pump 3, and the other end is fixedly connected to the top of the collection box 21. The first vacuum tube 31 is fixedly communicated with one end of the top of the collecting box 21 and is provided with a first filtering piece 311. The first filter member 311 includes two filter mesh sheets 312, and the filter mesh sheets 312 are 600 mesh filter screens. The filter mesh 312 is circumferentially wrapped with a non-woven layer 313. The bamboo charcoal fiber felt layer 314 is filled between the two filter mesh sheets 312, so that the material is effectively prevented from flowing to the vacuum pump 3, and the normal operation of the vacuum pump 3 is ensured.

Referring to FIG. 4, a first screen assembly 22 is fixedly attached to the top of collection box 21 by a flange. First screen assembly 22 includes a first outer housing 221 in communication with the top of collection box 21, with an inlet end of first outer housing 221 fixedly and sealingly connected with a first primary duct 223. The first main conveying pipe 223 is welded and communicated with a plurality of first conveying branch pipes 224, one end of each first conveying branch pipe 224 is welded and communicated with the first main conveying pipe 223, the other end of each first conveying branch pipe 224 is communicated with a first titanium rod filter 222, and the first titanium rod filters 222 are located in the first outer shell 221.

Referring to fig. 4, the end of first outer housing 221 facing away from collection box 21 is fixedly attached to second screen assembly 23 by a flange. Second screen assemblies 23 include a second tube housing 231 fixedly attached to first outer housing 221 by a flange, and a second main feed tube 233 fixedly and sealingly attached to an inlet end of second tube housing 231. A plurality of second delivery branch pipes 234 are welded and communicated with the second main delivery pipe 233. One end of the second delivery branch pipe 234 is welded and communicated with the second main delivery pipe 233, and the other end is communicated with the folding filter 232 positioned in the second pipe shell 231.

Referring to fig. 4 and fig. 2, the end of the second pipe housing 231 facing away from the collecting tank 21 is fixedly connected with a collecting pipe 24 through a flange, and the discharging pipe 15 is communicated with the upper part of the collecting pipe 24. A three-way pipe 7 is fixedly communicated with the peripheral side of the collecting pipe fitting 24; the three-way pipe 7 is communicated with the dust collection component 5, and the three-way pipe 7 is communicated with the standby filtering mechanism 6. A first control valve 8, preferably a ball valve, is fixedly communicated with the pipe section of the three-way pipe 7 communicated with the gas conveying pipe 52; the section of the three-way pipe 7 communicated with the standby material conveying pipe 65 is fixedly communicated with a second control valve 80, preferably a ball valve.

Referring to fig. 2 and 3, the dust collecting assembly 5 is fixedly connected to the supporting base 11 and located on the upper portion of the ball milling tank 12, and is used for recovering powder materials overflowed and scattered in the air after ball milling is completed, so that the quality of the operation environment is ensured. The dust collecting assembly 5 comprises a dust collecting cover 51, and the top of the dust collecting cover 51 is provided with a vent 510. The dust collecting cover 51 is welded to the side surface of the supporting base 11 and is located at the upper part of the ball mill tank 12. The top of the dust collecting cover 51 is fixedly connected with a dust collecting head 511, the air holes 510 are communicated with the dust collecting head 511, and the dust collecting head 511 is in the shape of a circular ring column with one closed end. The opening end of the dust collecting head 511 is welded on the upper surface of the dust collecting cover 51, and the closed end of the dust collecting cover 51 is fixedly communicated with the air pipe 52. One end of the air pipe 52 is communicated with the dust collecting head 511 and the other end is communicated with the spare filtering mechanism 6.

Referring to fig. 6, the backup filter mechanism 6 includes an outer case 61, and a third main duct 63 is fixedly and sealingly connected to an inlet end of the outer case 61, the third main duct 63 being located inside the outer case 61. A filter screen 631 is fixedly connected to the inner wall of the third main conveying pipe 63. The third main conveying pipe 63 is communicated with a plurality of third conveying branch pipes 64 in a welding mode, and the third conveying branch pipes 64 are fixedly communicated with a second titanium rod filter 62. The third main conveying pipe 63 is communicated with a standby conveying pipe 65, one end of the standby conveying pipe 65 is communicated with the three-way pipe 7, and the other end of the standby conveying pipe 65 is communicated with the third main conveying pipe 63. The upper part of the side wall of the outer shell 61 is fixedly communicated with a second vacuum tube 32. One end of the second vacuum tube 32 is fixedly communicated with the air exhaust end of the vacuum pump 3, and the other end is communicated with the upper part of the side wall of the outer shell 61. A second filtering member 321 with the same structure as the first filtering member 311 is arranged in the second vacuum tube 32 to prevent the material from entering the vacuum pump 3 and affecting the normal use of the present application.

Example two:

the difference between the second embodiment and the first embodiment is that: referring to fig. 7 and 8, the sealing mechanism 1200 includes the aperture plate 122, a first sealing plate 1231 capable of sliding axially along the ball milling pot 12, and a second sealing plate 1232 capable of sliding axially along the ball milling pot 12, where the first sealing plate 1231 and the second sealing plate 1232 can cooperate to form a sealing plate covering the upper portion of the aperture plate 122, so as to ensure that the material is always in the ball milling pot 12 during the ball milling operation.

Referring to fig. 7 and 8, the specific implementation structure is as follows: the side wall of the feeding port 121 is axially provided with a first sliding groove 1233 along the ball milling pot 12, and the first sealing plate 1231 can axially slide along the ball milling pot 12 in the first sliding groove 1233. The sidewall of the feed port 121 is provided with a second chute 1234 along the axial direction of the bowl 12, and the second sealing plate 1232 can slide along the axial direction of the bowl 12 in the second chute 1234.

Referring to fig. 7 and 8, in order to ensure that the first sealing plate 1231 and the second sealing plate 1232 are stably connected during the ball milling operation, two caulking grooves 1235 spaced from each other are formed in the bottom surface of the first sealing plate 1231, and a connecting column 1236 capable of being embedded in the caulking grooves 1235 is formed in the bottom surface of the second sealing plate 1232.

Referring to fig. 8, in order to facilitate the movement of the first closing plate 1231 and the second closing plate 1232, the first moving groove 12331 is formed in the outer surface of the bowl 12 along the axial direction of the bowl 12 in the circumferential direction, and the first sliding groove 1233 is communicated with the first moving groove 12331. The outer surface of the ball milling pot 12 is circumferentially provided with a second moving groove 12341 along the axial direction of the ball milling pot 12, and the second moving groove 12341 is communicated with the second sliding groove 1234. A first slide bar 12332 is fixedly connected to a side of the upper surface of the first sealing plate 1231 facing away from the feed opening 121, and the first slide bar 12332 can slide in the first moving groove 12331. The end of the first slide bar 12332 opposite to the first sealing plate 1231 is fixedly connected with a first slide block 12333, and the lower surface of the first slide block 12333 abuts against the outer surface of the ball mill pot 12. A second sliding rod 12342 is fixedly connected to an upper surface of the second sealing plate 1232, and the second sliding rod 12342 can slide in the second moving groove 12341. A second slide block 12343 is fixedly connected to a rod end of the second slide bar 12342 facing away from the second sealing plate 1232, and a lower surface of the second slide block 12343 abuts against an outer surface of the ball milling pot 12. When the sealing mechanism 1200 is required to be closed for performing the ball milling operation, the second slider 12343 and the first slider 12333 are controlled to control the opposite directions of the first sealing plate 1231 and the second sealing plate 1232, so that the connecting column 1236 of the second sealing plate 1232 is engaged with the insertion groove 1235 of the first sealing plate 1231.

Referring to fig. 8, in order to prevent the first closing plate 1231 and the second closing plate 1232 from being loosely coupled, the outer surface of the bowl 12 is provided with a first fixing member 124 for fixing the position of the first closing plate 1231; the outer surface of the ball milling pot 12 is provided with a second fixing member 125 for fixing the position of the second sealing plate 1232.

Referring to fig. 8 and 9, the first fixture 124 includes a first fixture block 1240, and the first fixture block 1240 is welded to the outer surface of the ball mill body 12 and is located at the circumferential direction of the feed opening 121. The first fixing block 1240 is in threaded connection with a first screw 1241, and the moving direction of the first screw 1241 is perpendicular to the sliding direction of the first sealing plate 1231. The first slider 12333 is circumferentially provided with a first thread groove 12334 facing the first screw 1241, and the central axis of the first thread groove 12334 is collinear with the central axis of the first screw 1241. When the closing mechanism 1200 is closed for performing the ball milling operation, the first screw 1241 may be screwed into the first screw groove 12334, so as to fix the position of the first sealing plate 1231.

Referring to fig. 8 and 9, the second fixing member 125 includes a second fixing block 1250, and the second fixing block 1250 is fixedly attached to the outer surface of the ball mill body 12 and located at the circumferential direction of the feed opening 121. The second fixing block 1250 is in threaded connection with a second screw 1251, and the moving direction of the second screw 1251 is perpendicular to the sliding direction of the second closing plate 1232. A second thread groove 12344 is formed around the second slider 12343, and a central axis of the second thread groove 12344 is collinear with a central axis of the second screw 1251. When closing mechanism 1200 carries out ball-milling operation, second screw 1251 can be fixed with second thread groove 12344 screw thread, realizes the fixed of second shrouding 1232 position to guarantee that ball-milling operation can go on by the safety and stability.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.