Organic solvent stirring processing device

By using a servo motor-driven stirring rack and rotating plate for autonomous rotation, combined with a feeding and cleaning mechanism, the problem of poor organic solvent stirring effect in existing technologies is solved, achieving efficient organic solvent turbulence stirring and quality assurance.

CN117018912BActive Publication Date: 2026-06-23GANZHOU ZHONGNENG IND CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
GANZHOU ZHONGNENG IND CO LTD
Filing Date
2023-09-21
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

In the prior art, the blades of the organic solvent stirring device rotate adaptively with the solvent flow, resulting in poor turbulence stirring effect.

Method used

The mixing rack and rotating plate are driven by a servo motor. The rotating plate rotates autonomously through the meshing of bevel gears and bevel gear discs. Combined with the material feeding and cleaning mechanism, the mixing effect is improved.

Benefits of technology

It achieves efficient turbulent stirring of organic solvents, ensuring that all solvents are stirred and preventing precipitation, thus improving the stirring quality.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to a processing device, in particular to an organic solvent stirring processing device. The application aims to design an organic solvent stirring processing device which can rotate autonomously to disturb the flow of organic solvent and improve the stirring effect of the organic solvent. The organic solvent stirring processing device comprises a support frame, a shell and a feeding hopper, the inner side of the support frame is fixedly connected with the shell in the circumferential direction, and the middle of the top of the shell is fixedly penetrated with the feeding hopper. The application pours the appropriate amount of organic solvent into the shell through the feeding hopper, the organic solvent contacts the stirring and rotating plate, then the servo motor is started to drive the stirring frame to rotate, the stirring frame rotates to stir the organic solvent, and the stirring frame also drives the rotating plate to rotate through the horizontal shaft, the rotating plate rotates through the bevel gear and the bevel gear plate, the rotating plate rotates to disturb the flow of the organic solvent, and the organic solvent can be better stirred, so that the stirring effect is improved.
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Description

Technical Field

[0001] This invention relates to a processing apparatus, and more particularly to an organic solvent stirring processing apparatus. Background Technology

[0002] Organic solvents are a large class of organic compounds that are widely used in daily life and production. They have small molecular weights and are found in coatings, adhesives, paints and cleaning agents. During the processing of organic solvents, they need to be stirred in order to improve their performance.

[0003] Chinese patent CN215782928U discloses an organic solvent stirring device, comprising a main body consisting of a housing and a top cover. A motor is mounted on the upper surface of the top cover, and a rotating shaft extending vertically downward to the bottom of the housing is mounted on the output end of the motor. Several sets of blades are arranged vertically at intervals on the rotating shaft, with multiple blades in each set spirally arranged at intervals around the circumference of the rotating shaft. A stirring frame is mounted on the rotating shaft and outside the blade sets. The inner wall of the stirring frame is connected to the end of some blades away from the rotating shaft. At least two stirring spoons are mounted on the outside of the stirring frame, one at the upper end and the other at the lower end. Although the above patent can stir organic solvents, the blades rotate adaptively with the flow of organic solvent and cannot rotate autonomously, which affects the effect of turbulent stirring of organic solvents.

[0004] The present invention aims to solve the problems existing in the above-mentioned patents. To this end, an organic solvent stirring and processing device is proposed that can autonomously rotate to turbulently stir organic solvents and improve the turbulent stirring effect of organic solvents. Summary of the Invention

[0005] To overcome the shortcomings of the aforementioned patents, which, although capable of stirring organic solvents, have blades that rotate adaptively with the flow of the organic solvent and cannot rotate autonomously, thus affecting the effect of turbulent stirring of the organic solvent, this invention provides an organic solvent stirring and processing device that can rotate autonomously to turbulently stir organic solvents, thereby improving the effect of turbulent stirring of organic solvents.

[0006] This invention is achieved through the following technical means:

[0007] An organic solvent stirring and processing device includes a support frame, a discharge pipe, a servo motor, a stirring frame, a housing, and a feed hopper. The housing is fixedly connected to the inner side of the support frame along the circumferential direction. The feed hopper is fixedly connected to the middle of the top of the housing. The stirring frame for stirring the organic solvent is rotatably connected to the middle of the bottom of the housing. The servo motor is fixedly connected to the rear side of the bottom of the housing. The output shaft of the servo motor is fixedly connected to the bottom end of the stirring frame. The discharge pipe is connected to the front side of the bottom of the housing. The device also includes a stirring mechanism and a driving mechanism. The stirring frame is provided with a stirring mechanism for turbulent stirring of the organic solvent. The upper part of the inner side of the housing is provided with a driving mechanism for driving the stirring mechanism to rotate.

[0008] Further explanation: The mixing mechanism includes horizontal shafts, rotating plates, and toothed belt assemblies. Five sets of horizontal shafts are evenly spaced circumferentially and rotated through the mixing frame. Each set of horizontal shafts consists of two shafts. A rotating plate for stirring the organic solvent is fixedly installed in the middle of each horizontal shaft. A toothed belt assembly is connected between the outer sides of the five horizontal shafts on each side.

[0009] Further explanation: The drive mechanism includes a fixed frame, a bevel gear disk and bevel gears. The bevel gears are fixedly mounted on the outer sides of the five uppermost horizontal shafts. The fixed frame is fixedly connected to the upper part of the inner side of the housing. The bevel gear disk for driving the bevel gears to rotate is fixedly connected to the bottom of the fixed frame along the circumferential direction. The bevel gear disk meshes with the bevel gears.

[0010] Further explanation includes a material-dispensing mechanism for further agitating the organic solvent. The material-dispensing mechanism includes guide rods, elliptical groove rods, dispensing plates, and a transmission assembly. Four sets of guide rods are fixedly connected at even intervals between the top and bottom of the housing, with two guide rods in each set. A dispensing plate for further agitating the organic solvent inside the housing is slidably mounted between the two guide rods in each set. Four elliptical groove rods are rotatably connected at even intervals along the circumference between the top and bottom of the housing to drive the dispensing plates to move up and down. The grooves of the four elliptical groove rods contact the inner sides of the four dispensing plates respectively. The lower part of the elliptical groove rod on the left rear side is driven to the lower part of the stirring frame by a synchronous belt assembly. A transmission assembly is connected between the bottom ends of the four elliptical groove rods.

[0011] Further explanation includes a cleaning mechanism for scraping off organic solvents adhering to the inner wall of the housing. The cleaning mechanism includes a sliding plate, a column spring, a scraper, and a magnetic suction plate. A sliding plate is slidably mounted between each pair of guide rods corresponding to the four sides of the housing. A scraper for scraping off organic solvents adhering to the inner wall of the housing is fixed between the outer sides of the four sliding plates. The scraper contacts the inner wall of the housing. The inner side of the scraper is made of iron. Two column springs mounted on the guide rods are connected between the top of the four sliding plates and the top of the housing. A magnetic suction plate for driving the scraper to move downwards is fixed in the middle of the top of each of the four scraping plates.

[0012] Further explanation includes heating plates, with heating plates embedded and fixed to the center of each of the four outer sides of the housing for heating the housing.

[0013] Further explanation includes a cover plate and magnetic blocks. A cover plate is placed on top of the feed hopper to block foreign debris, and magnetic blocks are symmetrically fixed to the bottom of the cover plate, with the magnetic blocks in magnetic contact with the feed hopper.

[0014] Further explanation includes the presence of heat insulation covers, with heat insulation covers fixed to the center of each of the four outer sides of the casing, and four heating plates located inside the four heat insulation covers respectively.

[0015] The significant advancement of this invention lies in:

[0016] 1. Pour an appropriate amount of organic solvent into the shell through the feed hopper. The organic solvent comes into contact with the stirring and rotating plate. Then, start the servo motor to drive the stirring frame to rotate. The stirring frame rotates to stir the organic solvent. The stirring frame also drives the rotating plate to rotate through the horizontal shaft. The rotating plate rotates through the bevel gear and bevel tooth disk. The rotation of the rotating plate turbulently stirs the organic solvent, which can better stir the organic solvent and thus improve the stirring effect.

[0017] 2. Under the action of the feeding mechanism, whenever the stirring rack stirs the organic solvent, the feeding mechanism can further agitate the organic solvent, thereby further improving the stirring effect of the organic solvent.

[0018] 3. Under the action of the cleaning mechanism, whenever the scraper moves up and down, the cleaning mechanism can scrape off the organic solvents adhering to the inner wall of the housing, thereby ensuring that all the organic solvents can be stirred. Attached Figure Description

[0019] Figure 1 This is a three-dimensional structural diagram of the present invention.

[0020] Figure 2 This is a partial cross-sectional view of the housing of the present invention.

[0021] Figure 3 This is a three-dimensional structural diagram of the stirring rack of the present invention.

[0022] Figure 4 This is a three-dimensional structural diagram of the mixing mechanism of the present invention.

[0023] Figure 5 This is an enlarged schematic diagram of part A of the present invention.

[0024] Figure 6 This is a three-dimensional structural diagram of the driving mechanism of the present invention.

[0025] Figure 7 This is a three-dimensional structural diagram of the feeding mechanism of the present invention.

[0026] Figure 8 This is a three-dimensional structural diagram of the cleaning mechanism of the present invention.

[0027] Figure 9 This is a three-dimensional structural diagram of the heating plate of the present invention.

[0028] Figure 10 This is a three-dimensional structural diagram of the cover plate of the present invention.

[0029] In the attached diagram, the following are the reference numerals: 1-support frame, 2-discharge pipe, 21-servo motor, 22-mixing frame, 3-shell, 31-feed hopper, 4-mixing mechanism, 41-horizontal shaft, 42-rotating plate, 43-toothed belt assembly, 5-drive mechanism, 51-fixed frame, 52-bevel gear disc, 53-bevel gear, 6-push material mechanism, 61-guide rod, 62-elliptical groove rod, 63-push material plate, 64-transmission assembly, 7-cleaning mechanism, 71-sliding plate, 72-column spring, 73-scraper, 74-magnetic plate, 8-heating plate, 81-heat insulation cover, 9-cover plate, 91-magnetic block. Detailed Implementation

[0030] First, it should be noted that in different described embodiments, the same components are given the same reference numerals or the same component names. The disclosure contained throughout this specification can be applied semantically to the same components having the same reference numerals or the same component names. The location descriptions selected in the specification, such as upper, lower, and lateral, also refer to the directly described and illustrated figures and are semantically applied to the new location when the location changes.

[0031] Example 1

[0032] An organic solvent stirring and processing apparatus includes a support frame 1, a discharge pipe 2, a servo motor 21, a stirring frame 22, a housing 3, a feed hopper 31, a stirring mechanism 4, and a drive mechanism 5. (See also...) Figures 1-6 As shown, a housing 3 is installed on the inner side of the support frame 1 by welding along the circumference. A feed hopper 31 is fixedly connected to the middle of the top of the housing 3, and a stirring frame 22 is rotatably connected to the middle of the bottom of the housing 3. When the stirring frame 22 rotates, it can stir the organic solvent. A servo motor 21 is installed on the rear side of the bottom of the housing 3 by bolt connection. The output shaft of the servo motor 21 is fixedly connected to the bottom end of the stirring frame 22. A discharge pipe 2 is connected to the front side of the bottom of the housing 3. A stirring mechanism 4 is provided on the stirring frame 22. When the stirring mechanism 4 operates, it can turbulently stir the organic solvent. A drive mechanism 5 is provided on the upper part of the inner side of the housing 3. When the drive mechanism 5 operates, it can drive the stirring mechanism 4 to rotate.

[0033] The mixing mechanism 4 includes a horizontal shaft 41, a rotating plate 42, and a toothed belt assembly 43. Please refer to [link / reference]. Figure 2 , Figure 4 and Figure 5 As shown, five sets of horizontal shafts 41 are evenly spaced circumferentially on the stirring rack 22. Each set of horizontal shafts 41 consists of two shafts. A rotating plate 42 is fixedly mounted in the middle of each horizontal shaft 41. When the rotating plate 42 rotates, it can turbulently stir the organic solvent. A toothed belt assembly 43 is connected between the outer sides of the five horizontal shafts 41 on each side. The toothed belt assembly 43 consists of five grooved pulleys and a toothed belt. The five grooved pulleys are fixedly mounted on the outer sides of the five horizontal shafts 41, and the toothed belt is wound between the five grooved pulleys.

[0034] The drive mechanism 5 includes a fixed frame 51, a bevel gear disc 52, and a bevel gear 53. Please refer to [link / reference]. Figure 2 and Figure 6 As shown, bevel gears 53 are fixedly mounted on the outer sides of the top five horizontal shafts 41. A fixed frame 51 is installed on the upper inner side of the housing 3 by welding. A bevel gear disk 52 is fixedly connected to the bottom of the fixed frame 51 along the circumference. The bevel gear disk 52 meshes with the bevel gears 53. When the bevel gears 53 rotate, the bevel gear disk 52 can drive the bevel gears 53 to rotate.

[0035] First, an appropriate amount of organic solvent is poured into the feed hopper 31. The organic solvent in the feed hopper 31 flows into the housing 3 and contacts the stirring rack 22 and the rotating plate 42. Then, the servo motor 21 is started to drive the stirring rack 22 to rotate. The rotation of the stirring rack 22 stirs the organic solvent. At the same time, the rotation of the stirring rack 22 drives the horizontal shaft 41 to rotate, which in turn drives the rotating plate 42 to rotate. The rotation of the horizontal shaft 41 drives the bevel gear 53 to rotate, which in turn drives the bevel gear disk 52 to rotate. The rotation of the bevel gear 53 drives the horizontal shaft 41 to rotate, which in turn drives the rotating plate 42 to rotate. The rotation of the rotating plate 42 turbulently stirs the organic solvent, thus improving its agitation. The stirring effect is better. After the organic solvent is stirred, the servo motor 21 is turned off, the stirring rack 22 stops rotating, the stirring rack 22 stops driving the horizontal shaft 41 to rotate, the horizontal shaft 41 stops driving the bevel gear 53 and the rotating plate 42 to rotate, the bevel gear 53 stops rotating through the bevel gear disk 52, and the rotating plate 42 also stops rotating. The collection container can then be placed under the discharge pipe 2, and the discharge pipe 2 is turned on. The stirred organic solvent in the discharge pipe 2 is discharged through the discharge pipe 2 and falls into the collection container. After all the stirred organic solvent has been discharged, the discharge pipe 2 is turned off, and the collection container is picked up for further processing of the organic solvent. In this way, the organic solvent is stirred by the autonomous rotation of the rotating plate 42, which turbulences the flow, thus improving the stirring effect.

[0036] Example 2

[0037] Based on Embodiment 1, a material feeding mechanism 6 is also included. The material feeding mechanism 6 includes a guide rod 61, an elliptical groove rod 62, a material feeding plate 63, and a transmission assembly 64. Please refer to [link to previous document]. Figure 2 and Figure 7 As shown, four sets of guide rods 61 are fixedly connected at even intervals between the top and bottom of the shell 3. Each set of guide rods 61 consists of two rods. A material-pulling plate 63 is slidably mounted between the two guide rods 61 in each set. When the material-pulling plate 63 moves up and down, it can further agitate the organic solvent inside the shell 3. Four elliptical groove rods 62 are rotatably connected at even intervals along the circumference between the top and bottom of the shell 3. The grooves of the four elliptical groove rods 62 are respectively in contact with the inner side of the four material-pulling plates 63. When the elliptical groove rods 62 rotate, they can drive the material-pulling plates 63 to move up and down. The lower part of the elliptical groove rod 62 on the left rear side is connected to the lower part of the stirring frame 22 through a synchronous belt assembly. A transmission assembly 64 is connected between the bottom ends of the four elliptical groove rods 62. The transmission assembly 64 consists of three pulleys and a flat belt. The four pulleys are fixedly mounted on the bottom ends of the four elliptical groove rods 62, and the flat belt is wound between the four pulleys.

[0038] It also includes a cleaning mechanism 7, which comprises a sliding plate 71, a column spring 72, a scraper 73, and a magnetic suction plate 74. Please refer to [link / reference]. Figure 2 and Figure 8 As shown, a sliding plate 71 is slidably mounted between each pair of guide rods 61 corresponding to the four sides of the housing 3. A scraper 73 is fixed between the outer sides of the four sliding plates 71. The scraper 73 is in contact with the inner wall of the housing 3. When the scraper 73 moves up and down, it can scrape off the organic solvent adhering to the inner wall of the housing 3. The inner side of the scraper 73 is made of iron. Two column springs 72 mounted on the guide rods 61 are connected between the top of the four sliding plates 71 and the top of the inner wall of the housing 3. A magnetic suction plate 74 is fixed in the middle of the top of each of the four material feeding plates 63. When the magnetic suction plate 74 is reset, it can drive the scraper 73 to move downward.

[0039] When the servo motor 21 starts and drives the stirring rack 22 to stir the organic solvent, the rotation of the stirring rack 22 also drives the left rear elliptical groove rod 62 to rotate via the synchronous belt assembly. The rotation of the left rear elliptical groove rod 62 drives the remaining three elliptical groove rods 62 to rotate via the transmission assembly 64. The rotation of the four elliptical groove rods 62 drives the four material-pulling plates 63 to move up and down, further agitating the organic solvent. After the organic solvent is stirred, the servo motor 21 is turned off, the stirring rack 22 stops driving the left rear elliptical groove rod 62 to rotate via the synchronous belt assembly, the remaining three elliptical groove rods 62 also stop rotating, and the four elliptical groove rods 62 stop driving the four material-pulling plates 63 to move up and down. In this way, the organic solvent can be further stirred, thereby further improving the stirring effect of the organic solvent.

[0040] When the four material-pulling plates 63 move up and down, they also drive the four magnetic suction plates 74 to move up and down. When the magnetic suction plates 74 move upward and contact the scraper 73, they attract the scraper 73. Then, when the magnetic suction plates 74 move downward, they drive the scraper 73 downward. The downward movement of the scraper 73 drives the sliding plate 71 downward, stretching the column spring 72. The downward movement of the scraper 73 scrapes off the organic solvent adhering to the inner wall of the housing 3. The scraped organic solvent is stirred by the stirring frame 22. When the column spring 72 is stretched to its maximum... During the long stroke, the column spring 72 stops moving downwards, causing the sliding plate 71 to stop moving downwards. The sliding plate 71 causes the scraper 73 to stop moving downwards, while the magnetic plate 74 continues to move downwards and disengages from the scraper 73. Due to the action of the column spring 72, the sliding plate 71 moves upwards to reset, causing the scraper 73 to move upwards to reset. The scraper 73 resets and scrapes off the organic solvent adhering to the inner wall of the housing 3 again. This process is repeated, continuously scraping off and stirring the organic solvent inside the housing 3, thus ensuring that all the organic solvent can be stirred.

[0041] Example 3

[0042] Based on Embodiments 1 and 2, it also includes a heating plate 8 and a heat insulation cover 81. Please refer to [link / reference]. Figure 9 As shown, heating plates 8 are embedded and fixed in the middle of the four outer sides of the housing 3. When the heating plates 8 are activated, they can heat the housing 3. Heat insulation covers 81 are fixed in the middle of the four outer sides of the housing 3, and the four heating plates 8 are located in the four heat insulation covers 81 respectively.

[0043] It also includes a cover plate 9 and a magnet 91, please refer to Figure 10 As shown, a cover plate 9 is placed on the top of the feed hopper 31. The cover plate 9 can block foreign debris. Magnetic blocks 91 are symmetrically fixed to the bottom of the cover plate 9, and the magnetic blocks 91 are in magnetic contact with the feed hopper 31.

[0044] When the stirring rack 22 rotates to stir the organic solvent, the heating plate 8 is activated to heat the housing 3. Heating the housing 3 also heats the organic solvent, making it more fluid. The stirring rack 22 continues to stir the heated organic solvent. The heat shield 81 prevents operators from being burned by contact with the heating plate 8. Once all the organic solvent has been stirred and drained, the heating plate 8 is turned off, ceasing to heat the housing 3. This prevents the organic solvent from solidifying and settling, thus ensuring effective stirring and guaranteeing optimal stirring results.

[0045] When it is necessary to pour organic solvent into the feed hopper 31, remove the cover plate 9 from the feed hopper 31. Removing the cover plate 9 causes the magnetic block 91 to disengage from the feed hopper 31. Then, pour an appropriate amount of organic solvent into the feed hopper 31, causing the organic solvent to fall into the housing 3. Afterward, replace the cover plate 9 onto the feed hopper 31, and the magnetic block 91 will magnetically contact the feed hopper 31 to secure the cover plate 9. This prevents foreign matter from falling through the feed hopper 31 and mixing with the organic solvent, thus ensuring the quality of the organic solvent.

[0046] Finally, it is necessary to note that the above content is only used to help understand the technical solution of the present invention and should not be construed as a limitation on the scope of protection of the present invention; any non-essential improvements and adjustments made by those skilled in the art based on the above content of the present invention are all within the scope of protection claimed by the present invention.

Claims

1. An organic solvent stirring and processing device, comprising a support frame (1), a discharge pipe (2), a servo motor (21), a stirring frame (22), a housing (3), and a feed hopper (31), wherein the housing (3) is fixedly connected to the inner side of the support frame (1) along the circumferential direction, the feed hopper (31) is fixedly connected to the middle of the top of the housing (3), the stirring frame (22) for stirring the organic solvent is rotatably connected to the middle of the bottom of the housing (3), the servo motor (21) is fixedly connected to the rear side of the bottom of the housing (3), the output shaft of the servo motor (21) is fixedly connected to the bottom end of the stirring frame (22), and the discharge pipe (2) is connected to the front side of the bottom of the housing (3), characterized in that, It also includes a stirring mechanism (4) and a driving mechanism (5). The stirring frame (22) is provided with a stirring mechanism (4) for stirring the organic solvent. The upper inner side of the housing (3) is provided with a driving mechanism (5) for rotating the stirring mechanism (4). The mixing mechanism (4) includes a horizontal shaft (41), a rotating plate (42) and a toothed belt assembly (43). Five sets of horizontal shafts (41) are evenly spaced around the stirring frame (22) and rotated. Each set of horizontal shafts (41) has two shafts. A rotating plate (42) for stirring the organic solvent is fixedly installed in the middle of each horizontal shaft (41). A toothed belt assembly (43) is connected between the outer sides of the five horizontal shafts (41) on each side. The drive mechanism (5) includes a fixed frame (51), a bevel gear disc (52) and a bevel gear (53). The bevel gear (53) is fixedly mounted on the outer side of the five horizontal shafts (41) at the top. The fixed frame (51) is fixedly connected to the upper part of the inner side of the housing (3). The bevel gear disc (52) for driving the bevel gear (53) to rotate is fixedly connected to the bottom of the fixed frame (51) along the circumferential direction. The bevel gear disc (52) meshes with the bevel gear (53). It also includes a material feeding mechanism (6) for further agitating the organic solvent. The material feeding mechanism (6) includes guide rods (61), elliptical groove rods (62), feeding plates (63) and transmission components (64). Four sets of guide rods (61) are fixedly connected at even intervals between the top and bottom of the housing (3). There are two guide rods in each set. A feeding plate (63) for further agitating the organic solvent in the housing (3) is slidably fitted between the two guide rods (61). Four elliptical groove rods (62) for driving the feeding plate (63) to move up and down are rotated at even intervals along the circumference between the top and bottom of the housing (3). The grooves of the four elliptical groove rods (62) are in contact with the inner side of the four feeding plates (63). The lower part of the elliptical groove rod (62) on the left rear side is driven by a synchronous belt assembly to the lower part of the stirring frame (22). The transmission components (64) are connected between the bottom ends of the four elliptical groove rods (62). It also includes a cleaning mechanism (7) for scraping off organic solvents adhering to the inner wall of the housing (3). The cleaning mechanism (7) includes a sliding plate (71), a column spring (72), a scraper (73) and a magnetic plate (74). A sliding plate (71) is slidably mounted between each pair of guide rods (61) corresponding to the four sides of the housing (3). A scraper (73) for scraping off organic solvents adhering to the inner wall of the housing (3) is fixed between the outer sides of the four sliding plates (71). The scraper (73) contacts the inner wall of the housing (3). The inner side of the scraper (73) is made of iron. Two column springs (72) mounted on the guide rods (61) are connected between the top of the four sliding plates (71) and the top of the inner wall of the housing (3). A magnetic plate (74) for driving the scraper (73) to move downward is fixed in the middle of the top of the four scraper plates (63).

2. The organic solvent stirring and processing apparatus as described in claim 1, characterized in that, It also includes a heating plate (8), and the heating plate (8) for heating the housing (3) is embedded and fixed in the middle of the four sides of the housing (3).

3. The organic solvent stirring and processing apparatus as described in claim 2, characterized in that, It also includes a cover plate (9) and a magnetic block (91). The top of the feed hopper (31) is covered with a cover plate (9) to block foreign debris. The bottom of the cover plate (9) is symmetrically fixed with magnetic blocks (91), and the magnetic blocks (91) are in magnetic contact with the feed hopper (31).

4. The organic solvent stirring and processing apparatus as described in claim 3, characterized in that, It also includes a heat shield (81), and the heat shield (81) is fixed to the middle of the four sides of the shell (3). The four heating plates (8) are located in the four heat shields (81).