CN116164520B

CN116164520B - Wet production device for calcium stearate

Info

Publication number: CN116164520B
Application number: CN202310463911.7A
Authority: CN
Inventors: 赵浩民; 崔石蕊; 赵学瑞
Original assignee: Shandong Haona New Material Technology Group Co ltd
Current assignee: Shandong Haona New Material Technology Group Co ltd
Priority date: 2023-04-26
Filing date: 2023-04-26
Publication date: 2023-07-11
Anticipated expiration: 2043-04-26
Also published as: CN116164520A

Abstract

The invention belongs to the technical field of calcium stearate drying, and particularly relates to a wet production device for calcium stearate. According to the invention, calcium stearate particles with different diameters can be screened through the rotating sorting plate, and after the separated calcium stearate particles enter the spiral flow passage, the contact time between the separated calcium stearate particles and hot air can be prolonged, the separated calcium stearate particles can be fully dried, and under the condition that the calcium stearate particles stay in the spiral flow passage, the situation of accumulation can be avoided, so that the calcium stearate particles can be fully dried; the separated calcium stearate particles with larger diameters can be discharged from the sorting plate through the auger with the opposite rotation direction of the sorting plate.

Description

Wet production device for calcium stearate

Technical Field

The invention relates to the technical field of calcium stearate drying, in particular to a wet production device for calcium stearate.

Background

Calcium stearate is one of metal soaps of stearic acid, has wide application in the fields of plastics, daily chemistry, paint and the like, and is one of main components of environment-friendly calcium-zinc composite heat stabilizer for polyvinyl chloride.

At present, the production mode of calcium stearate includes dry production and wet production, in wet production, need dissolve the stirring with the raw materials, then after the filter-pressing of plate-and-frame filter press to the feed bin buffering, then put into heating device heating and drying after smashing through the rubbing crusher, at present, current heating and drying device is through heating the drying pot and is dried the material that exposes outside, and the drying pot can only be dried to the material that is exposed, the inside material that is pushed by the outside material hardly contacts steam, thereby it is difficult to dry, and then drying efficiency is low, thereby lead to whole preparation inefficiency, and the calcium stearate particle size of smashing is different, still need sieving to dry after smashing, for this reason, propose a wet production device for calcium stearate.

Disclosure of Invention

The invention provides a wet production device for calcium stearate, which aims to solve the defects in the prior art.

In order to achieve the above purpose, the present invention adopts the following technical scheme: a wet process apparatus for producing for calcium stearate, includes the base, drying mechanism is installed at the top of base, drying mechanism includes the drum, be equipped with separation subassembly and separating mechanism in the drum, separation subassembly is including screening the calcium stearate granule and preventing the accumulational sorting board of calcium stearate granule, separating mechanism is including rotating the auger of installing in the sorting board, the auger is opposite with the rotation direction of sorting board.

Preferably, two sides of the cylinder are respectively and fixedly provided with a second baffle and a first baffle, two ventilation openings which are symmetrically distributed are formed in the first baffle, an electric heater is fixedly arranged on the first baffle, an air inlet and two air outlets are formed in the electric heater, two air outlets on the electric heater are respectively communicated with the corresponding ventilation openings, four supports which are in rectangular distribution are fixedly arranged on the outer side of the cylinder, the bottoms of the four supports are fixedly connected with the top of the base, a first discharge outlet is formed in the bottom of the cylinder, and a plurality of exhaust fans which are in circumferential array distribution penetrate through and are fixedly arranged on the second baffle.

Preferably, the two sides of the sorting plate are respectively and fixedly provided with a first annular frame and a second annular frame, the first annular frame and the second annular frame are hollow, the first annular frame and the second annular frame are both rotationally connected with the inner wall of the cylinder, a tube is fixedly arranged on one side, away from the sorting plate, of the second annular frame, the tube penetrates through the baffle plate and is rotationally connected with the baffle plate, and a baffle plate is fixedly arranged on one side, away from the second annular frame, of the cylinder.

Preferably, the belt pulley II is fixedly sleeved on the outer side of the pipe barrel, the sorting assembly further comprises a motor I fixedly installed on the top of the base, a belt pulley I is fixedly installed on an output shaft of the motor I, and the belt pulley I and the belt pulley II are sleeved with the same synchronous belt I.

Preferably, a plurality of second feed inlets distributed in a circumferential array are formed in the pipe barrel, a feeding mechanism is arranged on the outer side of the pipe barrel and comprises an annular feeding pipe which is rotatably sleeved on the outer side of the pipe barrel, the second feed inlets are all arranged in the annular feeding pipe, a wide-mouth feeding pipe penetrates through the annular feeding pipe and is fixedly arranged on the wide-mouth feeding pipe, and a connecting frame is fixedly arranged on the connecting frame and fixedly connected with the baffle plate.

Preferably, the separation plate is in a nest roll shape, the circle center of the separation plate is a circular cavity, a first feed inlet is arranged at the position, close to the circle center, of the separation plate, a second discharge outlet is arranged at the position, far away from the circle center, of the separation plate, and a spiral flow passage which is communicated with the first feed inlet and the second discharge outlet is arranged on the separation plate.

Preferably, the auger comprises a rotating shaft and a helical blade which are fixedly connected, the helical blade is rotationally connected with the circular cavity, the rotating shaft penetrates through the partition plate and is rotationally connected with the partition plate, the separating mechanism further comprises a belt pulley III fixedly sleeved on the rotating shaft and a motor II fixedly mounted at the top of the base, a belt pulley IV is fixedly mounted on an output shaft of the motor II, and the belt pulley III and the belt pulley IV are sleeved with the same synchronous belt II.

Preferably, the center of the second baffle is fixedly provided with a discharge pipe in a penetrating mode, the auger and the spiral blade extend into the second baffle, and the outer side of the spiral blade is rotationally connected with the inner wall of the discharge pipe.

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

1. according to the invention, calcium stearate particles with different diameters can be screened through the rotating sorting plate, and after the separated calcium stearate particles enter the spiral flow passage, the contact time between the separated calcium stearate particles and hot air can be prolonged, the separated calcium stearate particles can be fully dried, and under the condition that the calcium stearate particles stay in the spiral flow passage, the situation of accumulation can be avoided, so that the calcium stearate particles can be fully dried;

2. the separated calcium stearate particles with larger diameters can be discharged from the sorting plate through the auger with the opposite rotation direction of the sorting plate.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a wet process apparatus for producing calcium stearate according to the present invention;

fig. 2 is a schematic diagram of the overall structure of a wet process apparatus for producing calcium stearate according to the present invention;

FIG. 3 is a schematic diagram showing a drying mechanism in a wet process apparatus for producing calcium stearate according to the present invention;

fig. 4 is a schematic structural view of a second baffle and a plurality of exhaust fans in a wet process device for producing calcium stearate according to the present invention;

FIG. 5 is a schematic diagram of a sorting assembly for use in a wet process apparatus for producing calcium stearate according to the present invention;

FIG. 6 is an enlarged schematic view of the portion A in FIG. 5;

FIG. 7 is a side sectional view of a second ring frame, a tube barrel, a baffle plate and a feeding mechanism in a wet process device for calcium stearate according to the present invention;

FIG. 8 is a side cross-sectional view of a sorting deck in a wet process apparatus for producing calcium stearate according to the present invention;

FIG. 9 is a schematic diagram of the structure of a separating mechanism and a sectional side view of a partial sorting assembly in a wet process apparatus for producing calcium stearate according to the present invention;

fig. 10 is an enlarged schematic view of the portion B in fig. 9.

In the figure: 1. a base; 2. a drying mechanism; 21. a first baffle; 22. a vent; 23. an electric heater; 24. a cylinder; 25. a support; 26. a first discharge hole; 27. a second baffle; 271. a discharge pipe; 28. an exhaust fan; 3. a sorting assembly; 31. an annular frame I; 32. a sorting plate; 321. a circular cavity; 322. a first feeding port; 323. a spiral flow passage; 324. a second discharge hole; 33. a second annular frame; 34. a tube; 341. a second feeding port; 35. a partition plate; 36. a first motor; 37. a first belt pulley; 38. a feeding mechanism; 381. an annular feeding pipe; 382. a wide mouth feed tube; 383. a connecting frame; 39. a belt pulley II; 4. a separation mechanism; 41. an auger; 411. a rotating shaft; 412. a helical blade; 42. a belt pulley III; 43. a second motor; 44. and a belt pulley IV.

Detailed Description

The following description of the embodiments of the present invention will be made more apparent and fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the invention are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 10, the present invention provides a technical solution: a wet process apparatus for producing calcium stearate, including base 1, drying mechanism 2 is installed at the top of base 1, and drying mechanism 2 includes drum 24, is equipped with separation subassembly 3 and separating mechanism 4 in the drum 24, and separation subassembly 3 includes screening calcium stearate granule and prevents the accumulational sorting board 32 of calcium stearate granule, and separating mechanism 4 includes auger 41 of rotation installation in sorting board 32, and auger 41 is opposite with the rotation direction of sorting board 32.

Two sides of the cylinder 24 are fixedly provided with a second baffle 27 and a first baffle 21 respectively, the first baffle 21 is provided with two ventilation openings 22 which are symmetrically distributed, the first baffle 21 is fixedly provided with an electric heater 23, the electric heater 23 is provided with an air inlet and two air outlets, the two air outlets on the electric heater 23 are respectively communicated with the corresponding ventilation openings 22, the outer side of the cylinder 24 is fixedly provided with four supports 25 which are rectangular in distribution, the bottom ends of the four supports 25 are fixedly connected with the top of the base 1, the bottom of the cylinder 24 is provided with a first discharge opening 26, and a plurality of exhaust fans 28 which are distributed in a circumferential array are fixedly arranged on the second baffle 27 in a penetrating manner.

The two sides of the sorting plate 32 are respectively and fixedly provided with a first annular frame 31 and a second annular frame 33, the first annular frame 31 and the second annular frame 33 are hollow, the first annular frame 31 and the second annular frame 33 are both in rotary connection with the inner wall of the cylinder 24, one side of the second annular frame 33, which is far away from the sorting plate 32, is fixedly provided with a pipe barrel 34, the pipe barrel 34 penetrates through the first baffle 21 and is in rotary connection with the first baffle 21, and one side of the cylinder 24, which is far away from the second annular frame 33, is fixedly provided with a baffle 35.

Further, the hollow-out

annular frames

31 and 33 can facilitate air circulation inside the sorting plate 32.

The outside of the tube 34 is fixedly sleeved with a belt pulley II 39, the sorting assembly 3 further comprises a motor I36 fixedly arranged at the top of the base 1, a belt pulley I37 is fixedly arranged on an output shaft of the motor I36, and the belt pulley I37 and the belt pulley II 39 are sleeved with the same synchronous belt I.

Further, the first motor 36 is started to drive the first belt pulley 37 to rotate, the first belt pulley 37 drives the second belt pulley 39 to rotate through the synchronous belt, the second belt pulley 39 drives the pipe barrel 34 to rotate, and the pipe barrel 34 rotates through the second annular frame 33, the sorting plate 32 and the first annular frame 31.

The feeding mechanism 38 is arranged on the outer side of the pipe barrel 34, the feeding mechanism 38 comprises an annular feeding pipe 381 rotationally sleeved on the outer side of the pipe barrel 34, the second feeding holes 341 are all arranged in the annular feeding pipe 381, a wide-mouth feeding pipe 382 is fixedly arranged on the annular feeding pipe 381 in a penetrating mode, a connecting frame 383 is fixedly arranged on the wide-mouth feeding pipe 382, and the connecting frame 383 is fixedly connected with the first baffle 21.

Further, since the connecting frame 383 is fixedly mounted on the first baffle plate 21, the whole feeding mechanism 38 does not rotate, so that when the tube 34 rotates, the calcium stearate particles flowing into the wide-mouth feeding pipe 382 through the wide-mouth feeding pipe 382 enter the tube 34 from the second plurality of feeding ports 341.

The separation plate 32 is in a nest roll shape, a circular cavity 321 is arranged at the center of the separation plate 32, a first feed inlet 322 is arranged at the position, close to the center, of the separation plate 32, a second discharge outlet 324 is arranged at the position, far away from the center, of the separation plate 32, and a spiral flow passage 323 communicated with the first feed inlet 322 and the second discharge outlet 324 is arranged on the separation plate 32.

Further, the sorting plate 32 is made of a screen plate with matrix-type meshes, so that hot air can flow through the sorting plate 32, as shown in fig. 8, under the condition that the sorting plate 32 rotates clockwise, calcium stearate particles in the circular cavity 321 enter the first feeding hole 322, calcium stearate particles with different diameters in the circular cavity 321 can be screened due to the limited width of the first feeding hole 322, and due to the limited width of the spiral flow channel 323, the calcium stearate particles in the spiral flow channel 323 cannot be accumulated, so that the calcium stearate particles in the spiral flow channel 323 can be heated uniformly.

The auger 41 comprises a rotating shaft 411 and a spiral blade 412 which are fixedly connected, the spiral blade 412 is rotationally connected with the circular cavity 321, the rotating shaft 411 penetrates through the partition plate 35 and is rotationally connected with the partition plate 35, the separating mechanism 4 further comprises a belt pulley III 42 fixedly sleeved on the rotating shaft 411 and a motor II 43 fixedly installed on the top of the base 1, a belt pulley IV 44 is fixedly installed on an output shaft of the motor II 43, and the belt pulley III 42 and the belt pulley IV 44 are sleeved with the same synchronous belt II.

Further, the second motor 43 is started to drive the fourth belt pulley 44 to rotate, the fourth belt pulley 44 drives the third belt pulley 42 to rotate through the second synchronous belt, the third belt pulley 42 drives the spiral blade 412 to rotate through the rotating shaft 411, and the rotating spiral blade 412 can convey the calcium stearate particles in the inner circular cavity 321 of the sorting plate 32 from the second annular frame 33 side to the first annular frame 31 side because the rotating direction of the rotating shaft 411 and the sorting plate 32 are opposite, so that the calcium stearate particles with proper diameters in the circular cavity 321 can enter the first feed inlet 322.

The center of the second baffle plate 27 is fixedly provided with a discharge pipe 271 in a penetrating manner, the auger 41 and the spiral blade 412 extend into the second baffle plate 27, and the outer side of the spiral blade 412 is rotatably connected with the inner wall of the discharge pipe 271.

Further, in the case that the rotating shaft 411 drives the spiral blade 412 to rotate, the calcium stearate particles with larger diameters in the circular cavity 321 can be conveyed into the discharge pipe 271, and finally, the calcium stearate particles with larger diameters are discharged from the discharge pipe 271.

In this embodiment: when in use, the calcium stearate particles to be dried are put into the wide-mouth feeding pipe 382, the calcium stearate particles fall into the annular feeding pipe 381 and then enter the pipe barrel 34 through the plurality of second feeding holes 341, and then the calcium stearate particles in the pipe barrel 34 are input into the circular cavity 321 through the auger 41 rotating in the opposite direction;

the electric heater 23 and the exhaust fans 28 are started, the drying hot air generated by the electric heater 23 flows into the cylinder 24 through the two ventilation openings 22, then the drying hot air passes through the annular frame II 33 and enters the sorting plate 32, so that the drying hot air circulates in the circular cavity 321 and the spiral flow passage 323, and finally the moist hot air passes through the annular frame I31 and is exhausted by the exhaust fans 28;

as shown in fig. 8, when the sorting plate 32 rotates clockwise, the calcium stearate particles in the circular cavity 321 enter the spiral flow channel 323 through the first feed inlet 322, but the calcium stearate particles with larger diameters than the first feed inlet 322 cannot enter the first feed inlet 322 because the width of the first feed inlet 322 is limited, so that the calcium stearate particles with different sizes can be screened in the process of rotating the sorting plate 32, the calcium stearate particles with larger diameters in the circular cavity 321 can be discharged from the discharge pipe 271 under the rotation of the auger 41, the calcium stearate particles entering the spiral flow channel 323 are uniformly distributed in the spiral flow channel 323 under the uniform rotation of the sorting plate 32, and the calcium stearate particles in the spiral flow channel 323 are prevented from being accumulated in the spiral flow channel 323 because of the limited width of the spiral flow channel 323, so that the dried calcium stearate particles in the spiral flow channel 323 can be uniformly heated, the dried calcium stearate particles in the spiral flow channel 323 are uniformly, and then discharged from the second discharge port 324 under the effect of discharging the calcium stearate particles from the first discharge port 26 under the continuous rotation of the sorting plate 32.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims

1. Wet process apparatus for producing calcium stearate, comprising a base (1), characterized in that: the drying device is characterized in that a drying mechanism (2) is arranged at the top of the base (1), the drying mechanism (2) comprises a cylinder (24), a sorting assembly (3) and a separating mechanism (4) are arranged in the cylinder (24), the sorting assembly (3) comprises a sorting plate (32) for screening calcium stearate particles and preventing the calcium stearate particles from accumulating, the separating mechanism (4) comprises an auger (41) rotatably arranged in the sorting plate (32), and the rotating directions of the auger (41) and the sorting plate (32) are opposite;

two sides of the cylinder (24) are respectively and fixedly provided with a second baffle (27) and a first baffle (21), two ventilation openings (22) which are symmetrically distributed are formed in the first baffle (21), an electric heater (23) is fixedly arranged on the first baffle (21), an air inlet and two air outlets are formed in the electric heater (23), the two air outlets on the electric heater (23) are respectively communicated with the corresponding ventilation openings (22), four supports (25) which are in rectangular distribution are fixedly arranged on the outer side of the cylinder (24), the bottoms of the four supports (25) are fixedly connected with the top of the base (1), a first discharge opening (26) is formed in the bottom of the cylinder (24), and a plurality of exhaust fans (28) which are distributed in a circumferential array are fixedly arranged on the second baffle (27) in a penetrating manner;

the two sides of the separation plate (32) are respectively and fixedly provided with a first annular frame (31) and a second annular frame (33), the first annular frame (31) and the second annular frame (33) are hollow, the first annular frame (31) and the second annular frame (33) are rotationally connected with the inner wall of the cylinder (24), one side, far away from the separation plate (32), of the second annular frame (33) is fixedly provided with a pipe barrel (34), the pipe barrel (34) penetrates through the first baffle (21) and is rotationally connected with the first baffle (21), and one side, far away from the second annular frame (33), of the cylinder (24) is fixedly provided with a baffle (35);

the sorting plate (32) is in a nest roll shape, a round cavity (321) is formed in the circle center of the sorting plate (32), a first feeding hole (322) is formed in the sorting plate (32) close to the circle center, a second discharging hole (324) is formed in the sorting plate (32) away from the circle center, and a spiral flow passage (323) communicated with the first feeding hole (322) and the second discharging hole (324) is formed in the sorting plate (32).

2. A wet production apparatus for calcium stearate according to claim 1, wherein: the outside fixed cover of bobbin (34) is equipped with belt pulley two (39), select separately subassembly (3) still include fixed mounting motor one (36) at base (1) top, fixed mounting has belt pulley one (37) on the output shaft of motor one (36), cover is equipped with same hold-in range one on belt pulley one (37) and the belt pulley two (39).

3. A wet production apparatus for calcium stearate according to claim 1, wherein: offer a plurality of feed inlets two (341) that are circumference array distribution on bobbin (34), the outside of bobbin (34) is equipped with feed mechanism (38), feed mechanism (38) are including rotating annular material loading pipe (381) of cover outside bobbin (34), and a plurality of feed inlets two (341) all are in annular material loading pipe (381), run through fixed mounting on annular material loading pipe (381) have wide-mouth inlet pipe (382), fixed mounting has link (383) on wide-mouth inlet pipe (382), link (383) and baffle one (21) fixed connection.

4. A wet production apparatus for calcium stearate according to claim 1, wherein: auger (41) are including fixed connection's pivot (411) and helical blade (412), helical blade (412) rotate with round cavity (321) and are connected, pivot (411) run through baffle (35) and rotate with baffle (35) and be connected, separating mechanism (4) still include that the fixed cover is established belt pulley III (42) and fixed mounting on pivot (411) are at motor II (43) at base (1) top, fixed mounting has belt pulley IV (44) on the output shaft of motor II (43), the cover is equipped with same hold-in range II on belt pulley III (42) and belt pulley IV (44).

5. A wet process apparatus for calcium stearate according to claim 4, wherein: the center of the second baffle plate (27) is fixedly provided with a discharge pipe (271) in a penetrating mode, the auger (41) and the spiral blades (412) extend into the second baffle plate (27), and the outer sides of the spiral blades (412) are rotatably connected with the inner wall of the discharge pipe (271).