CN112108062A

CN112108062A - Production and processing method of organic silicon

Info

Publication number: CN112108062A
Application number: CN202011008841.9A
Authority: CN
Inventors: 李新岭; 曲文驰
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-23
Filing date: 2020-09-23
Publication date: 2020-12-22

Abstract

The invention relates to a production and processing method of organic silicon, which adopts an organic silicon production and processing device, wherein the organic silicon production and processing device comprises a processing rack, a heating frame, a first guide plate, a crushing mechanism, a stirring mechanism and a collecting frame, and the heating frame is arranged on the processing rack. The invention can solve the following problems in the production and processing process of organic silicon: in the production and processing process of the traditional organic silicon, the specification of the organic silicon is different in the primary processing process, so that the reject ratio of the product is increased due to the different specification in the subsequent processing and forming process of the organic silicon, and in the production and processing process of the traditional organic silicon, the mixture of the organic silicon and the auxiliary agent needs to be taken out manually or by the existing equipment after the stirring is finished in the stirring process of the organic silicon and the auxiliary agent, so that the production and processing time is greatly prolonged, the efficiency is low, and the yield of the organic silicon production and processing is influenced.

Description

Production and processing method of organic silicon

Technical Field

The invention relates to the field of production and processing of organic silicon, in particular to a production and processing method of organic silicon.

Background

The organic silicon is a compound containing Si-C bonds and at least one organic group directly connected with silicon atoms, has the properties of inorganic materials and organic materials due to the unique structure, has the properties of low surface tension, small viscosity-temperature coefficient, high compressibility, high gas permeability and the like, has the advantages of high and low temperature resistance, electrical insulation, oxidation resistance, stability, hydrophobicity and the like, is widely applied to the industries of aerospace, electronics and electricity, buildings and the like, and the application field is continuously widened along with the continuous increase of the quantity and variety of the organic silicon, so that the organic silicon becomes an irreplaceable and indispensable product system.

At present, the following problems exist in the production and processing processes of organic silicon: in the production and processing process of the traditional organic silicon, the specification of the organic silicon is different in the primary processing process, so that the reject ratio of the product is increased due to the different specification in the subsequent processing and forming process of the organic silicon, and in the production and processing process of the traditional organic silicon, the mixture of the organic silicon and the auxiliary agent needs to be taken out manually or by the existing equipment after the stirring is finished in the stirring process of the organic silicon and the auxiliary agent, so that the production and processing time is greatly prolonged, the efficiency is low, and the yield of the organic silicon production and processing is influenced.

Disclosure of Invention

Technical problem to be solved

The invention provides a production and processing method of organic silicon, which can solve the following problems in the production and processing process of organic silicon: in the production and processing process of the traditional organic silicon, the specification of the organic silicon is different in the primary processing process, so that the reject ratio of the product is increased due to the different specification in the subsequent processing and forming process of the organic silicon, and in the production and processing process of the traditional organic silicon, the mixture of the organic silicon and the auxiliary agent needs to be taken out manually or by the existing equipment after the stirring is finished in the stirring process of the organic silicon and the auxiliary agent, so that the production and processing time is greatly prolonged, the efficiency is low, and the yield of the organic silicon production and processing is influenced.

(II) technical scheme

In order to achieve the purpose, the invention adopts the following technical scheme: the production and processing method of the organic silicon adopts an organic silicon production and processing device, the organic silicon production and processing device comprises a processing rack, a heating frame, a first guide plate, a crushing mechanism, a stirring mechanism and a collecting frame, the heating frame is installed on the processing rack, a first through groove is formed in the side wall of the heating frame, the first guide plate is obliquely installed in the first through groove, one end of the first guide plate is arranged inside the heating frame, the other end of the first guide plate is arranged outside the heating frame, the crushing mechanism is arranged on the outer wall of the heating frame and below the first guide plate, the stirring mechanism is installed on the lower end face of the heating frame, the collecting frame is arranged under the heating frame, and the collecting frame is installed on the processing rack.

Heating frame inside up end and terminal surface have seted up feed inlet and discharge gate respectively, wherein the feed inlet is provided with the slope structure, the apron is installed through the round pin axle in the feed inlet left and right sides, and be connected through the joint mode between the apron, the apron below is provided with the spring beam No. one, spring beam one end is installed on the terminal surface under the apron through the round pin axle, the spring beam other end is installed on the heating frame inner wall through the round pin axle, the feed inlet below is provided with the filter, and the filter slope is installed on the heating frame inner wall, and the filter left side is located directly over the guide plate No. one, be provided with the guide plate No. two under the filter plate, and No. two guide plate ends are located directly over the discharge gate, the stock guide is installed respectively to the discharge gate left and right sides.

The crushing mechanism comprises a crushing frame, a rolling frame, rolling plates, a second spring rod, a movable frame, an electric slider, a limiting rod, a limiting block and a guide groove, wherein the crushing frame is of a vertically transparent structure, the crushing frame is arranged on the outer wall of the heating frame, the crushing frame is arranged under the first guide plate, first sliding grooves are symmetrically formed in the left and right of the inner wall of the crushing frame, the electric slider is arranged in the first sliding grooves in a sliding manner, the movable frame is arranged between the electric sliders, the second spring rod is symmetrically arranged on the left and right of the lower end surface of the movable frame, the rolling plates are arranged on the lower end surface of the second spring rod, the rolling frame is arranged under the rolling plates and is arranged on the inner wall of the crushing frame, the limiting rods are symmetrically arranged at the left and right ends of the rolling plates, the limiting block is arranged right above the limiting rod and is arranged on the lower end surface of the movable frame, the other end of the guide groove penetrates through the heating frame and is arranged in the heating frame, and the guide groove is arranged right above the second guide plate.

Rabbling mechanism including stirring frame, rotation motor, stirring roller, stirring frame, stirring net, link, the branch chain and the vibration branch chain of opening and shutting, wherein link bilateral symmetry slidable mounting on terminal surface under the heating frame, the stirring frame is installed under the link on the terminal surface, the rotation motor passes through the motor cabinet and installs on stirring frame inside terminal surface down, the stirring roller is connected with rotation motor output shaft through the axle sleeve, stirring frame circumference is installed on the stirring roller, is connected through the stirring net between the stirring frame, the branch chain bilateral symmetry that opens and shuts is installed inside the stirring frame, the vibration branch chain sets up in the outside of stirring frame, and the vibration branch chain is installed under the heating frame on the terminal surface.

The method for producing and processing the organic silicon by adopting the organic silicon production and processing device comprises the following steps:

step one, device arrangement: fixing the device on the ground manually, and arranging and adjusting internal mechanisms of the device;

step two, grading treatment: pouring organic silicon and an auxiliary agent into a heating frame manually, heating, and processing the organic silicon into raw materials with uniform specifications through a crushing mechanism;

step three, stirring treatment: the raw materials treated in the second step enter a stirring mechanism, and are stirred and mixed uniformly;

step four, collecting and processing: and (4) collecting the processed organic silicon, and manually placing the organic silicon at a specified position.

Preferably, the second guide plate comprises a guide frame and guide plates, wherein the guide frame is arranged on the inner wall of the heating frame, the guide plates are obliquely arranged on the guide frame from top to bottom, the inclination directions of the adjacent guide plates are opposite, the guide plates are connected end to end, the uppermost guide plate is close to the lower part of the filter plate, the lowermost end of the guide plate at the middle position is positioned at the lower end of the guide groove, the lowermost end of the lowermost guide plate is positioned right above the discharge port, a first groove is formed in the upper end surface of the guide plate, and an inclined stepped structure is arranged in the first groove.

Preferably, the rolling frame is evenly provided with filtering through holes, the inner walls of the left side and the right side of the crushing frame are provided with second sliding grooves, and the rolling frame is clamped inside the second sliding grooves.

Preferably, the branch chain that opens and shuts include division board, No. three spring beam, spacing trapezoidal piece and stripper plate, No. three spring beam one end install on stirring frame inner wall, the No. three spring beam other ends are installed on the stripper plate, the blanking mouth has been seted up on the wall of stirring frame left and right sides, No. three spouts have been seted up on the blanking mouth up end, the division board slides and sets up in No. three spouts, No. two logical grooves have been seted up on the division board, and crisscross setting about No. two logical grooves and No. three logical grooves, No. three logical grooves have been seted up on the stirring frame inner wall, spacing trapezoidal piece slides and sets up at No. three logical inslot, and the stripper plate is connected with spacing trapezoidal piece, wherein spacing trapezoidal piece inclined plane tightly pastes with the division board.

Preferably, the vibration branch chain include vibration frame, driving motor, cam and reset spring, wherein the vibration frame mounting on heating frame lower extreme face right side, driving motor passes through the motor cabinet and installs in the vibration frame, the cam is installed through the ring flange to the driving motor output shaft, and the cam tightly supports and leans on the stirring frame outer wall, reset spring sets up in heating frame lower extreme face left side, reset spring one end is installed on the stirring frame, the reset spring other end is installed on the heating frame.

Preferably, an inclined baffle is installed on the lower end face of the inner part of the stirring frame, and the inclined baffle covers the rotating motor.

(III) advantageous effects

2. In the heating frame designed by the invention, the cover plate is matched with the first spring rod, so that the flow limiting effect on poured organic silicon can be realized, the organic silicon is prevented from falling into the bottom of the heating frame due to too fast pouring of the organic silicon, meanwhile, the second guide plate is provided with the guide plates connected end to end, the organic silicon heating path can be prolonged, the organic silicon is heated more fully, the inclined stepped structure in the guide plates enables the organic silicon to continuously obtain gravitational potential energy to fall downwards, and the organic silicon cannot be blocked in the guide plates.

3. In the crushing mechanism designed by the invention, the rolling plate can carry out secondary treatment on the organic silicon screened by the filter plate through the second spring rod to obtain the organic silicon with the required specification, the rolling plate is matched with the limiting block under the driving of the limiting rod to crush the organic silicon on the rolling frame, the crushed organic silicon falls into the heating frame through the filtering through hole, and the rolling plate can be replaced according to the required specification of the organic silicon.

4. In the opening and closing branched chain designed by the invention, when organic silicon is contacted with the extrusion plate, the extrusion plate drives the limiting trapezoidal block to move outwards through the third spring rod, the opening and closing plate is driven to move upwards in the moving process of the trapezoidal limiting block, and the stirred organic silicon can enter the collecting frame through the blanking port, so that the blockage caused by excessive accumulation of the organic silicon in the stirring frame is avoided, and meanwhile, the complexity and danger of manual material taking can be reduced.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a process flow diagram of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a schematic view of the internal structure of the shredder mechanism of the present invention;

FIG. 4 is a schematic diagram of the internal structure of the switching branch chain of the present invention;

FIG. 5 is an enlarged schematic view of area A of FIG. 2 in accordance with the present invention;

fig. 6 is a schematic view of the internal structure of the guide plate of the present invention.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 6, a method for producing and processing silicone, which adopts a silicone production and processing device, the organic silicon production and processing device comprises a processing rack 1, a heating frame 2, a first guide plate 3, a crushing mechanism 4, a stirring mechanism 5 and a collecting frame 6, heating frame 2 install in processing frame 1, seted up one on the 2 lateral walls of heating frame and led to the groove, the slope of No. one guide plate 3 is installed in one leads to the inslot, 3 one ends of a guide plate set up inside

heating frame

2, 3 other ends of a guide plate set up in heating frame 2 outsidely, the below that lies in a guide plate 3 on the outer wall of heating frame 2 is provided with rubbing crusher structure 4, rabbling mechanism 5 installs on heating frame 2 lower extreme face, collect frame 6 and set up under heating frame 2, and collect frame 6 and install in processing frame 1.

The upper end surface and the lower end surface in the heating frame 2 are respectively provided with a feeding hole and a discharging hole, wherein the feeding hole is arranged in an inclined structure, the left side and the right side of the feeding hole are provided with cover plates 21 through pin shafts, the cover plates 21 are connected in a clamping way, a first spring rod 22 is arranged below the cover plates 21, one end of the first spring rod 22 is arranged on the lower end surface of the cover plate 21 through a pin shaft, the other end of the first spring rod 22 is arranged on the inner wall of the heating frame 2 through a pin shaft, a filter plate 23 is arranged below the feeding hole, the filter plate 23 is obliquely arranged on the inner wall of the heating frame 2, the left side of the filter plate 23 is positioned right above a first guide plate 3, a second guide plate 25 is arranged right below the filter plate 23, the tail end of the second guide plate 25 is positioned right above the discharging hole, when the device works specifically, the organic silicon is poured into the device from the feeding hole manually, in the pouring process of the organic silicon, the cover plate 21 is matched with the first spring rod 22 to limit the flow of the organic silicon, so that the organic silicon is prevented from being blocked due to too fast pouring, and then the organic silicon falls into the bottom of the heating frame 2, meanwhile, in the heating process of the organic silicon, the cover plate 21 can isolate the generated dust inside the heating frame 2, so that the dust is prevented from entering the external environment to cause environmental pollution, one part of the organic silicon falls onto the second guide plate 25 through the filter plate 23 to be heated, the other part of particles with larger specifications fall into the crushing mechanism 4 through the first guide plate 3 through the filter plate 23 to be crushed for the second time, wherein the guide plate 24 is arranged into an inwards inclined triangular structure to limit the organic silicon, so that the organic silicon completely falls into the stirring mechanism 5 through the, so that the organic silicon can not be scattered on the bottom of the heating frame 2.

The second guide plate 25 comprises a guide frame 251 and guide plates 252, wherein the guide frame 251 is installed on the inner wall of the heating frame 2, the guide plates 252 are obliquely installed on the guide frame 251 from top to bottom, the oblique directions of adjacent guide plates 252 are opposite, the guide plates 252 are connected end to end, the uppermost guide plate 252 is close to the lower part of the filter plate 23, the lowermost end of the guide plate 252 at the middle position is positioned at the lower end of the guide groove 410, the lowermost end of the lowermost guide plate 252 is positioned right above the discharge port, the heating path of the organic silicon can be prolonged, the organic silicon is heated more fully, a first groove is formed in the upper end surface of the guide plate 252, an oblique step-shaped structure is arranged in the first groove, the organic silicon can fall down along the guide plates by acquiring gravitational potential energy, and the organic silicon cannot be blocked in the guide plates 252 in the heating process.

The crushing mechanism 4 comprises a crushing frame 41, a rolling frame 42, rolling plates 44, a second spring rod 45, a movable rack 46, electric sliding blocks 47, limiting rods 48, limiting blocks 49 and guide grooves 410, wherein the crushing frame 41 is of a vertically through structure, the crushing frame 41 is installed on the outer wall of the heating frame 2, the crushing frame 41 is arranged under the first guide plate 3, the first sliding grooves are symmetrically formed in the left and right of the inner wall of the crushing frame 41, the electric sliding blocks 47 are slidably arranged in the first sliding grooves, the movable rack 46 is installed between the electric sliding blocks 47, the second spring rod 45 is symmetrically installed on the left and right of the lower end face of the movable rack 46, the rolling plates 44 are installed on the lower end face of the second spring rod 45, the rolling frame 42 is arranged under the rolling plates 44, the rolling frame 42 is installed on the inner wall of the crushing frame 41, the limiting rods 48 are symmetrically installed at the left and right ends of the rolling plates 44, the limiting blocks 49, and the limiting block 49 is installed on the lower end face of the movable frame 46, one end of the guide groove 410 is installed on the lower end face of the crushing frame 41, the other end of the guide groove 410 penetrates through the heating frame 2 and is arranged inside the heating frame 2, and the guide groove 410 is arranged right above the second guide plate 25.

When the crushing mechanism 4 works specifically, organic silicon falls into the crushing frame 41 through the first guide plate 3, the electric slide block 47 is started to drive the rolling plate 44 to roll and crush the organic silicon through the moving rack 46, the second spring rod 45 is extruded and contracted upwards through the rolling plate 44 in the reciprocating movement process of the rolling plate 44, so that the organic silicon on the rolling frame 42 reaches a certain thickness, and when the working thickness is reached, the limiting rod 48 is matched with the limiting block 49, so that the rolling plate 44 does not move upwards any more, and the rolling plate 44 is matched with the rolling frame 42 to grind and crush the organic silicon.

Roll and press and evenly seted up on the frame 42 and filter the through-hole, and seted up No. two spouts on smashing the frame 41 left and right sides inner wall, roll and press the joint of frame 42 inside No. two spouts, according to required organosilicon specification size, change suitable roll and press frame 42, roll and press the joint of frame 42 inside No. two spouts, the organosilicon after grinding is smashed passes through to filter the through-hole and drops into guide slot 410, and it is inside to get into heating frame 2 again.

The stirring mechanism 5 comprises a stirring frame 51, a rotating motor 52, a stirring roller 53, a stirring frame 54, a stirring net 55, a connecting frame 56, an opening and closing branched chain 57 and a vibrating branched chain 58, wherein the connecting frame 56 is arranged on the lower end face of the heating frame 2 in a bilateral symmetry sliding mode, the stirring frame 51 is arranged on the lower end face of the connecting frame 56, the rotating motor 52 is arranged on the lower end face of the inner part of the stirring frame 51 through a motor base, the stirring roller 53 is connected with an output shaft of the rotating motor 52 through a shaft sleeve, the stirring frame 54 is circumferentially arranged on the stirring roller 53, the stirring frames 54 are connected through the stirring net 55, the opening and closing branched chain 57 is arranged inside the stirring frame 51 in a bilateral symmetry mode, the vibrating branched chain 58 is arranged on the outer side of the stirring frame 51, and the.

Stirring mechanism 5 concrete during operation, rotate motor 52 and start to drive stirring roller 53 and rotate, stirring roller 53 rotates the in-process, drives stirring net 55 through stirring frame 54 and stirs organosilicon and auxiliary agent, in the stirring process, organosilicon is discharged from stirring frame 51 through the branch chain 57 that opens and shuts and collects in the frame 6, the use of vibration branch chain 58 can make the stirring process more abundant, organosilicon and the auxiliary agent mixes more evenly.

The inclined baffle is arranged on the lower end face of the inner part of the stirring frame 51 and covers the rotating motor 52, and the inclined baffle can not only prevent organic silicon from being accumulated on the stirring frame 51 to cause blockage when being discharged, but also protect the rotating motor 52 from being interfered by the organic silicon when in work.

The opening and closing branched chain 57 comprises an opening plate 571, a third spring rod 572, a limiting trapezoidal block 573 and a pressing plate 574, one end of the third spring rod 572 is arranged on the inner wall of the stirring frame 51, the other end of the third spring rod 572 is arranged on the pressing plate 574, blanking ports are arranged on the left side wall and the right side wall of the stirring frame 51, a third sliding groove is arranged on the upper end surface of the blanking port, the opening plate 571 is arranged in the third sliding groove in a sliding manner, a second through groove is arranged on the opening plate 571, a third through groove is arranged on the inner wall of the stirring frame 51, the second through groove and the third through groove are arranged in a vertically staggered manner, the limiting trapezoidal block 573 is arranged in the third through groove in a sliding manner, the pressing plate 574 is connected with the limiting trapezoidal block 573, wherein the inclined surface of the limiting trapezoidal block 573 is tightly attached to the opening plate 574, when organosilicon falls into the stirring frame 51, when the organosilicon reaches a certain height, the organosilicon abuts against the pressing plate, in the process that the extrusion plate 574 moves outwards, the limit trapezoidal blocks 573 extrude the cut-off plate 571 upwards through the second through grooves to drive the cut-off plate 571 to move upwards, the blanking port is opened, and the organic silicon falls into the collection frame 6 from the blanking port.

The vibration branched chain 58 comprises a vibration rack 581, a driving motor 582, a cam 583 and a reset spring 584, wherein the vibration rack 581 is installed on the right side of the lower end face of the heating frame 2, the driving motor 582 is installed on the vibration rack 581 through a motor base, the cam 583 is installed on an output shaft of the driving motor 582 through a flange plate, the cam 583 tightly abuts against the outer wall of the stirring frame 51, the reset spring 584 is arranged on the left side of the lower end face of the heating frame 2, one end of the reset spring 584 is installed on the stirring frame 51, the other end of the reset spring 584 is installed on the heating frame 2, in the specific work process, the driving motor 582 is started to drive the cam 583 to rotate, the cam 583 drives the stirring frame 51 to reciprocate in the left-right direction in the rotating process and vibrate and shake organic silicon in the stirring frame 51 through the reset.

step two, grading treatment: pouring organic silicon and an auxiliary agent into the heating frame 2 manually, heating, and processing the organic silicon into raw materials with uniform specifications through the crushing mechanism 4;

step three, stirring treatment: the raw materials treated in the second step enter a stirring mechanism 5, and are stirred and mixed uniformly;

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The production and processing method of the organic silicon adopts an organic silicon production and processing device, the organic silicon production and processing device comprises a processing rack (1), a heating frame (2), a first guide plate (3), a crushing mechanism (4), a stirring mechanism (5) and a collecting frame (6), and the production and processing method is characterized in that: the heating frame (2) is installed on the processing rack (1), a first through groove is formed in the side wall of the heating frame (2), a first guide plate (3) is obliquely installed in the first through groove, one end of the first guide plate (3) is arranged inside the heating frame (2), the other end of the first guide plate (3) is arranged outside the heating frame (2), a crushing mechanism (4) is arranged on the outer wall of the heating frame (2) and below the first guide plate (3), a stirring mechanism (5) is installed on the lower end face of the heating frame (2), a collecting frame (6) is arranged under the heating frame (2), and the collecting frame (6) is installed on the processing rack (1); wherein:

the heating frame (2) is internally provided with a feed inlet and a discharge outlet at the upper end surface and the lower end surface respectively, wherein the feed inlet is arranged in an inclined structure, the left side and the right side of the feed inlet are provided with cover plates (21) through pin shafts, the cover plates (21) are connected in a clamping way, a first spring rod (22) is arranged below the cover plates (21), one end of the first spring rod (22) is arranged on the lower end surface of the cover plates (21) through a pin shaft, the other end of the first spring rod (22) is arranged on the inner wall of the heating frame (2) through a pin shaft, a filter plate (23) is arranged below the feed inlet, the filter plate (23) is obliquely arranged on the inner wall of the heating frame (2), the left side of the filter plate (23) is positioned right above the first guide plate (3), a second guide plate (25) is arranged right below the filter plate, the left side and the right side of the discharge port are respectively provided with a material guide plate (24), and the material guide plates (24) are of inward inclined triangular structures;

the crushing mechanism (4) comprises a crushing frame (41), a rolling frame (42), rolling plates (44), a second spring rod (45), a movable frame (46), electric sliding blocks (47), limiting rods (48), limiting blocks (49) and guide grooves (410), wherein the crushing frame (41) is of a vertically through structure, the crushing frame (41) is installed on the outer wall of the heating frame (2), the crushing frame (41) is arranged under the first guide plate (3), the inner wall of the crushing frame (41) is bilaterally symmetrically provided with first sliding grooves, the electric sliding blocks (47) are slidably arranged in the first sliding grooves, the movable frame (46) is installed between the electric sliding blocks (47), the second spring rods (45) are bilaterally symmetrically installed on the lower end face of the movable frame (46), the rolling plates (44) are installed on the lower end face of the second spring rod (45), the rolling frame (42) is arranged below the rolling plates (44), the rolling frame (42) is arranged on the inner wall of the crushing frame (41), the limiting rods (48) are symmetrically arranged at the left end and the right end of the rolling plate (44), the limiting blocks (49) are arranged right above the limiting rods (48), the limiting blocks (49) are arranged on the lower end face of the movable rack (46), one end of the guide groove (410) is arranged on the lower end face of the crushing frame (41), the other end of the guide groove (410) penetrates through the heating frame (2) to be arranged in the heating frame (2), and the guide groove (410) is arranged right above the second guide plate (25);

the stirring mechanism (5) comprises a stirring frame (51), a rotating motor (52), stirring rollers (53), a stirring frame (54), a stirring net (55), a connecting frame (56), an opening and closing branched chain (57) and a vibrating branched chain (58), wherein the connecting frame (56) is arranged on the lower end face of the heating frame (2) in a bilateral symmetry sliding mode, the stirring frame (51) is arranged on the lower end face of the connecting frame (56), the rotating motor (52) is arranged on the lower end face of the inner part of the stirring frame (51) through a motor base, the stirring rollers (53) are connected with an output shaft of the rotating motor (52) through shaft sleeves, the stirring frame (54) is circumferentially arranged on the stirring rollers (53), the stirring frames (54) are connected through the stirring net (55), the opening and closing branched chains (57) are arranged inside the stirring frame (51) in a bilateral symmetry mode, the vibrating branched chain (58) is arranged on the outer side of the stirring frame (, the vibration branched chain (58) is arranged on the lower end surface of the heating frame (2);

step two, grading treatment: pouring the organic silicon and the auxiliary agent into the heating frame (2) manually, heating, and processing the organic silicon into raw materials with uniform specifications through the crushing mechanism (4);

step three, stirring treatment: the raw materials treated in the second step enter a stirring mechanism (5) and are stirred and mixed uniformly;

2. The method for producing and processing silicone according to claim 1, wherein: the second guide plate (25) comprises a guide frame (251) and guide plates (252), wherein the guide frame (251) is installed on the inner wall of the heating frame (2), the guide plates (252) are obliquely installed on the guide frame (251) from top to bottom, the oblique directions of the adjacent guide plates (252) are opposite, the guide plates (252) are connected end to end, the guide plate (251) at the top is close to the lower part of the filter plate (23), the lowest end of the guide plate (251) at the middle position is located at the lower end of the guide groove (410), the lowest end of the guide plate (251) at the bottom is located right above the discharge hole, a first groove is formed in the upper end face of the guide plate, and an oblique stepped structure is arranged in the first groove.

3. The method for producing and processing silicone according to claim 1, wherein: roll and press frame (42) on evenly seted up and filter the through-hole, and smash and seted up No. two spouts on the frame (41) left and right sides inner wall, roll and press frame (42) joint inside No. two spouts.

4. The method for producing and processing silicone according to claim 1, wherein: the opening and closing branched chain (57) comprises an opening plate (571), a third spring rod (572), a limiting trapezoidal block (573) and a pressing plate (574), one end of the third spring rod (572) is arranged on the inner wall of the stirring frame (51), the other end of the third spring rod (572) is arranged on the extrusion plate (574), the left side wall and the right side wall of the stirring frame (51) are provided with blanking ports, the upper end surface of each blanking port is provided with a third sliding groove, the opening plate (571) is arranged in the third sliding groove in a sliding manner, the opening plate (571) is provided with a second through groove, the inner wall of the stirring frame (51) is provided with a third through groove, the second through groove and the third through groove are staggered up and down, the limit trapezoidal block (573) is arranged in the third through groove in a sliding way, the extrusion plate (574) is connected with the limit trapezoidal block (573), wherein the inclined surface of the limit trapezoidal block (573) is tightly attached to the cut-off plate (571).

5. The method for producing and processing silicone according to claim 1, wherein: vibration branch chain (58) including vibration frame (581), driving motor (582), cam (583) and reset spring (584), wherein vibration frame (581) install on heating frame (2) lower terminal surface right side, driving motor (582) is installed on vibration frame (581) through the motor cabinet, driving motor (582) output shaft installs cam (583) through the ring flange, and cam (583) support and lean on stirring frame (51) outer wall, reset spring (584) sets up on heating frame (2) lower terminal surface left side, reset spring (584) one end is installed on stirring frame (51), reset spring (584) other end is installed on heating frame (2).

6. The method for producing and processing silicone according to claim 1, wherein: the lower end face of the inner part of the stirring frame (51) is provided with an inclined baffle, and the inclined baffle covers the rotating motor (52).