A plastic product production recycled plastic particle anti-blocking device

By designing a roller and vibration mechanism to process recycled plastic granules, the problem of granule clumping was solved, product quality and production efficiency were improved, energy consumption and costs were reduced, and the concept of environmentally friendly and energy-saving production was in line with the goal of environmental protection and energy conservation.

CN122165556APending Publication Date: 2026-06-09CHENGDU DONGSHENG PACKING MATERIAL CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
CHENGDU DONGSHENG PACKING MATERIAL CO LTD
Filing Date
2026-05-11
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In existing technologies, recycled plastic pellets are prone to clumping during storage and transportation, resulting in low production efficiency, increased costs, and uneven product quality. Traditional methods such as manual crushing are inefficient, mechanical stirring is energy-intensive, and adding anti-caking agents may introduce chemical substances that threaten environmental performance.

Method used

Design a device for preventing recycled plastic granules from caking in plastic product manufacturing. It adopts a combination of agitator rollers and vibration mechanism to process recycled plastic granules through strong agitation and fine vibration, avoiding the use of chemical anti-caking agents. The device has a simple structure and is easy to maintain.

Benefits of technology

It improves the surface smoothness and strength of products, reduces labor intensity and energy consumption, meets environmental protection and energy-saving production requirements, and enhances production efficiency and enterprise competitiveness.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN122165556A_ABST
    Figure CN122165556A_ABST
Patent Text Reader

Abstract

The application provides a regenerated plastic particle anti-blocking equipment for plastic product production, and belongs to the technical field of plastic product production, and comprises a supporting mechanism, an adjusting mechanism is arranged on the top surface of the supporting mechanism, a processing mechanism is horizontally arranged at the top end of the adjusting mechanism, a feeding mechanism is fixedly connected to the top surface of the processing mechanism in a symmetrical mode, and a vibrating mechanism is fixedly installed on one side of the processing mechanism in a symmetrical mode. The application helps to improve the production automation level and product quality stability of enterprises, and enhances the market competitiveness of enterprises. Meanwhile, the environment-friendly and energy-saving production mode meets the sustainable development strategy requirements of modern enterprises, and helps to improve the social image and brand value of enterprises. The equipment has high automation, and manual intervention is not needed in the whole process from feeding, anti-blocking treatment to material discharge, so that the production efficiency is greatly improved. Meanwhile, the equipment has high processing capacity, and can meet the demand of large-scale continuous production.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention relates to the field of plastic product manufacturing technology, and more specifically, to a device for preventing the agglomeration of recycled plastic granules in plastic product manufacturing. Background Technology

[0002] Recycled plastic granules are an important raw material widely used in the production of various plastic products. However, during storage and transportation, recycled plastic granules are prone to clumping due to changes in environmental humidity and temperature, as well as the mutual compression and friction between the granules. Clumped recycled plastic granules not only affect production efficiency and increase production costs, but may also adversely affect the quality of the final product, such as uneven surface and inconsistent strength.

[0003] Traditional methods for addressing the clumping problem of recycled plastic pellets mainly include manual crushing, mechanical mixing, and adding anti-caking agents. However, these methods all have significant drawbacks. Manual crushing is inefficient, labor-intensive, and it is difficult to ensure consistent crushing results; while mechanical mixing can alleviate clumping to some extent, the equipment is complex, energy-intensive, and may adversely affect the physical properties of the pellets; adding anti-caking agents may introduce new chemical substances, posing a potential threat to the environmental and performance characteristics of the product. Summary of the Invention

[0004] The purpose of this invention is to address the problem of caking in recycled plastic granules, which is mainly solved by traditional methods such as manual crushing, mechanical mixing, and adding anti-caking agents. However, these methods all have significant drawbacks. Manual crushing is inefficient, labor-intensive, and it is difficult to ensure consistent crushing results; mechanical mixing can alleviate the caking problem to some extent, but the equipment is complex, energy-intensive, and may adversely affect the physical properties of the granules; adding anti-caking agents may introduce new chemical substances, posing a potential threat to the environmental performance and usability of the product. Therefore, this invention proposes an anti-caking device for recycled plastic granules used in the production of plastic products.

[0005] To achieve the above-mentioned objectives, the present invention provides the following technical solution: It is applied to plastic product manufacturing equipment to improve the above-mentioned problems.

[0006] The present invention is as follows: The system includes a support mechanism, an adjustment mechanism mounted on the top surface of the support mechanism, a processing mechanism horizontally mounted at the top of the adjustment mechanism, a feeding mechanism symmetrically and fixedly connected to the top surface of the processing mechanism, and a vibration mechanism symmetrically and fixedly mounted on one side of the processing mechanism. The support mechanism includes a support base plate, a control main box is fixedly installed on the top surface of the support base plate, a control panel is fixedly installed on one side of the control main box, and traction end blocks are horizontally and symmetrically welded to both ends of the support base plate. The adjustment mechanism includes a telescopic upright, an adjustment cylinder is vertically fixed to the side of the telescopic upright, an inner connecting block is horizontally welded between the sides of the telescopic upright, and inclined cylinders are symmetrically connected to both ends of the inner connecting block; The processing mechanism includes a main processing box, a bottom mating block symmetrically and fixedly connected to the bottom surface of the main processing box, a central connecting block horizontally and fixedly welded to the center line of the bottom surface of the main processing box, a mating side box vertically and fixedly connected to the center of one side of the main processing box, a transmission motor fixedly connected to the side of the mating side box, sealing end plates vertically snapped into the inner sides of the two open ends of the main processing box, flipping end shafts symmetrically inserted into both ends of the central connecting block, top through slots symmetrically opened near both ends on the top surface of the main processing box, a transmission gear provided on the inner side of the mating side box, a swivel roller symmetrically provided at the center of the inner side of the main processing box, a main connecting shaft fixedly connected to both ends of the swivel roller, one end of the main connecting shaft fixedly connected to the center of the transmission gear, and guide inner blocks symmetrically and fixedly welded to the top and bottom surfaces of the inner side of the main processing box. The feeding mechanism includes a feeding hopper, and a top cover is hinged to the top opening of the feeding hopper; The vibration mechanism includes an inner support plate, which is symmetrically and fixedly connected to the side of the main processing box. Connecting springs are symmetrically and evenly fixedly connected to the four corners of the side of the inner support plate. A mating plate is fixedly connected to one end of each connecting spring. A vibrator is fixedly installed on one side of the mating plate. A vibration rod is connected to the output end of the vibrator. An inner support rod is fixedly connected to one end of the vibration rod. A bent rod is evenly welded to one side of the inner support rod. A branch rod is evenly welded to the side of the inner support rod away from the bent rod.

[0007] As a preferred technical solution of the present invention, the four corners of the support base plate are symmetrically and fixedly connected with movable wheels, the sides of the movable wheels are provided with braking structures, one side of the support base plate is vertically and fixedly connected with a support column, the top surface of the traction end block is provided with a connecting hole, the traction end block is connected to an external traction vehicle through the connecting hole, the bottom end of the telescopic pole is horizontally welded with a mounting base plate, the top surface of the mounting base plate is symmetrically provided with mounting connecting holes, the bottom surface of the control main box is provided with a bottom locking hole, and the top of the support column is fixedly connected with a rotating locking block, which is locked into the inner side of the bottom locking hole.

[0008] As a preferred technical solution of the present invention, the inner connecting block has end slots symmetrically opened at both ends, the inclined cylinder has connecting shafts symmetrically inserted at both ends, the telescopic upright has a side locking hole at the top side, the inner side of the side locking hole is fixedly locked with a fixed bearing, the top cover is connected with a stabilizing buckle, the inner support plate has a through hole at the center of the side, and the inner side of the through hole is fixedly locked with an isolation rubber ring.

[0009] As a preferred technical solution of the present invention, a maintenance slot is provided on one side of the main processing box, and a sealing cover plate is bolted to the inner side of the maintenance slot. Positioning screws are symmetrically threaded to both ends of the main processing box. Limiting grooves are provided on the inner sides of the two openings of the main processing box. Top through slots are provided at both ends of the top surface of the main processing box. Through screw holes are provided at the center of the top surface of both ends of the main processing box. The positioning screws are threaded to the inner side of the through screw holes, and the extended ends are pressed to the side of the sealing end plate. Bottom screw holes are uniformly provided on the bottom surface of the main processing box.

[0010] As a preferred technical solution of the present invention, the adjustment mechanism is vertically and symmetrically fixedly connected at the center of the top surface of the support mechanism. The plastic particles are fed into the interior of the processing mechanism through the feeding mechanism on the top surface. There are two vibration mechanisms, and the two vibration mechanisms are symmetrically and fixedly connected on the side of the processing mechanism near both ends.

[0011] As a preferred technical solution of the present invention, the control main box is installed on the side of the support base plate via a support column, and a control device is provided on the inner side of the control main box. The control panel is electrically connected to the internal control device of the control main box. There are two traction end blocks, and the two traction end blocks are symmetrically and fixedly connected at the center of both ends of the support base plate.

[0012] As a preferred technical solution of the present invention, there are two telescopic poles, and the two telescopic poles are arranged in parallel with each other. The bottom end of the telescopic pole is fixedly installed at the center of both sides of the top surface of the supporting base plate through the mounting base plate. The inner connecting block is fixedly connected to the top of the sleeve of the telescopic pole. The inclined cylinders are all connected to the inner side of the groove of the end slot and the bottom mating block through the connecting shafts at both ends.

[0013] As a preferred technical solution of the present invention, the main processing box is a box structure with open ends, and the main processing box is connected to the top of the telescopic uprights by a flip-type connection of the middle connecting block on the bottom surface. The bottom mating block is symmetrically fixedly set at the center line of the bottom surface of the main processing box near both ends. The output end of the transmission motor is extended and fixedly connected to one end of a main connecting shaft. The top end of the sealing end plate is inserted through and inserted into the inner side of the top through groove, and the sealing end plate is sealed at the two open ends of the main processing box.

[0014] As a preferred technical solution of the present invention, one end of the flipping end shaft is horizontally fixedly inserted into the inner side of the fixed bearing, the transmission gears are all fixedly connected to the outer side of the main connecting shaft, and the transmission gears are toothed to each other, the agitator rollers are stacked and arranged in parallel at the inner center of the main processing box, and the outer side of the agitator rollers is uniformly provided with staggered column structures, the guide inner blocks are symmetrically arranged on both sides near the agitator rollers, the bottom opening of the feeding hopper is fixedly connected to the top opening of the top through groove to maintain communication, the mating plate and the inner support plate are arranged in parallel, one end of the vibration rod extends and is inserted into the inner side of the main processing box, the inner support rods are parallel and symmetrically arranged on both sides of the agitator rollers, one end of the bending rod extends to the inner side of the top through groove, and the branch rod extends horizontally and is arranged near the agitator rollers.

[0015] Compared with the prior art, the beneficial effects of the present invention are as follows: In the solution of this invention: 1. Through the powerful agitation of the set-up agitator rollers and the precise vibration of the vibration mechanism, the clumps in the recycled plastic granules are effectively broken up, ensuring the uniformity and consistency of the material. This helps improve the surface smoothness and strength of the final product, guaranteeing product quality. This invention does not use any chemical anti-caking agents, avoiding environmental pollution and potential impacts on product performance from chemical substances. Furthermore, the equipment uses a mechanical processing method, requiring no additional energy consumption such as heating, aligning with environmentally friendly and energy-saving production principles.

[0016] 2. The equipment boasts a simple and rational structure, facilitating maintenance and upkeep, thus reducing equipment failure rates and repair costs. Simultaneously, automated processing eliminates tedious manual crushing processes, lowering labor intensity and costs. Furthermore, the equipment's low energy consumption and stable, reliable operation further reduce production costs. The equipment's height and tilt angle can be flexibly adjusted to meet the processing requirements of different production lines and materials. Moreover, the equipment is easily movable, allowing for rapid adaptation to changes in production site layouts.

[0017] 3. The application of this invention helps improve the level of production automation and product quality stability in enterprises, thereby enhancing their market competitiveness. Simultaneously, the environmentally friendly and energy-saving production method aligns with the sustainable development strategies of modern enterprises, contributing to improved social image and brand value. The equipment boasts a high degree of automation, requiring no manual intervention from material feeding and anti-caking treatment to material discharge, significantly improving production efficiency. Furthermore, the equipment has a strong processing capacity, meeting the demands of large-scale continuous production. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall three-dimensional separate internal connection structure provided by the present invention; Figure 2 This is a schematic diagram of the overall three-dimensional front view structure provided by the present invention; Figure 3 This is a schematic diagram of the overall three-dimensional bottom-view connection structure provided by the present invention; Figure 4 This is a schematic diagram of the overall three-dimensional top view connection structure provided by the present invention; Figure 5 This is a schematic diagram of the overall three-dimensional back-view connection structure provided by the present invention; Figure 6 This is a schematic diagram of the overall three-dimensional back-side top-view connection structure provided by the present invention; Figure 7 This is a schematic diagram of the overall back-separated upward-view connection structure provided by the present invention; Figure 8 This is a schematic diagram of the overall front view, separate top view, and connected structure provided by the present invention; Figure 9 This is a schematic diagram of the overall separate internal bottom-view connection structure provided by the present invention; Figure 10 This is a schematic diagram of the overall internal side view connection structure provided by the present invention; Figure 11 This is a bottom view of the internal connection structure of the main processing box provided by the present invention; Figure 12 This is a schematic diagram of the back connection structure of the main processing box provided by the present invention; Figure 13 This is a top view of the internal structure of the main processing box provided by the present invention.

[0019] The image shows: 1. Support Mechanism; 101. Support Base Plate; 102. Casters; 103. Support Column; 104. Control Main Box; 105. Control Panel; 106. Traction End Block; 107. Connecting Hole; 108. Mounting Base Plate; 109. Mounting Connection Hole; 110. Bottom Locking Hole; 111. Rotating Locking Block; 2. Adjustment Mechanism; 201. Telescopic Upright; 202. Adjusting Cylinder; 203. Inner Connecting Block; 204. End Locking Slot; 205. Inclined Cylinder; 206. Connecting Shaft; 207. Side Locking Hole; 208. Fixed Bearing; 3. Processing Mechanism; 301. Main Processing Box; 302. Maintenance Slot; 303. Sealing Cover Plate; 304. Bottom Fitting Block; 305. Middle Connecting Block; 306. Fitting Block 307. Side box; 308. Transmission motor; 309. Sealing end plate; 310. Positioning screw; 311. Limiting inner groove; 312. Top through groove; 313. Through screw hole; 314. Flipping end shaft; 315. Bottom screw hole; 316. Top through groove; 317. Transmission gear; 318. Main connecting shaft; 319. Guide inner block; 4. Actuating roller; 401. Feeding mechanism; 402. Feeding hopper; 403. Top cover; 404. Stabilizing strip; 5. Vibration mechanism; 501. Inner support plate; 502. Connecting spring; 503. Mating plate; 504. Vibrator; 505. Through hole; 506. Isolation rubber ring; 507. Vibration rod; 508. Inner support rod; 509. Bending rod; 510. Branch rod. Detailed Implementation

[0020] To make the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Example

[0021] like Figures 1-13 As shown, the present invention provides a technical solution: a device for preventing the agglomeration of recycled plastic granules in the production of plastic products, comprising a support mechanism 1, an adjustment mechanism 2 installed on the top surface of the support mechanism 1, a processing mechanism 3 horizontally arranged at the top of the adjustment mechanism 2, a feeding mechanism 4 symmetrically fixedly connected to the top surface of the processing mechanism 3, and a vibration mechanism 5 symmetrically fixedly installed on one side of the processing mechanism 3. The adjustment mechanism 2 is vertically symmetrically fixedly connected at the center of the top surface of the support mechanism 1. Plastic granules are fed into the interior of the processing mechanism 3 through the feeding mechanism 4 on the top surface. There are two vibration mechanisms 5, and the two vibration mechanisms 5 are symmetrically fixedly connected and arranged on the side of the processing mechanism 3 near both ends. The support mechanism 1 includes a support base plate 101. A control main box 104 is fixedly installed on the top surface of the support base plate 101. A control panel 105 is fixedly installed on one side of the control main box 104. Traction end blocks 106 are horizontally and symmetrically welded to both ends of the support base plate 101. Moving wheels 102 are symmetrically and fixedly connected to the bottom surfaces of the four corners of the support base plate 101. A braking structure is provided on the side of the moving wheels 102. A support column 103 is vertically fixedly connected to one side of the support base plate 101. A connection hole 107 is opened on the top surface of the traction end block 106. The control main box 104 is installed on the side of the support base plate 101 through the support column 103. A control device is provided on the side. The control panel 105 is electrically connected to the internal control device of the control main box 104. There are two traction end blocks 106, and the two traction end blocks 106 are symmetrically fixedly connected to the center positions of both ends of the support base plate 101. The traction end blocks 106 are connected to the external tractor through the connection hole 107. The bottom end of the telescopic pole 201 is horizontally welded with a mounting base plate 108. The top surface of the mounting base plate 108 is symmetrically provided with mounting connection holes 109. The bottom surface of the control main box 104 is provided with a bottom locking hole 110. The top end of the support column 103 is fixedly connected with a rotating locking block 111, which is locked in place on the inner side of the bottom locking hole 110.

[0022] The support mechanism 1 provides stable support for the equipment. The support base plate 101 is made of sturdy materials and can withstand the weight of the equipment and various forces generated during processing. The braking structure on the side of the casters 102 ensures the stability of the equipment when it is in a fixed position and prevents the equipment from moving during use. Example

[0023] like Figures 1-13 As shown, the present invention provides a technical solution: a device for preventing the agglomeration of recycled plastic granules in the production of plastic products, comprising a support mechanism 1, an adjustment mechanism 2 installed on the top surface of the support mechanism 1, a processing mechanism 3 horizontally arranged at the top of the adjustment mechanism 2, a feeding mechanism 4 symmetrically fixedly connected to the top surface of the processing mechanism 3, and a vibration mechanism 5 symmetrically fixedly installed on one side of the processing mechanism 3. The adjustment mechanism 2 is vertically symmetrically fixedly connected at the center of the top surface of the support mechanism 1. Plastic granules are fed into the interior of the processing mechanism 3 through the feeding mechanism 4 on the top surface. There are two vibration mechanisms 5, and the two vibration mechanisms 5 are symmetrically fixedly connected and arranged on the side of the processing mechanism 3 near both ends. The support mechanism 1 includes a support base plate 101. A control main box 104 is fixedly installed on the top surface of the support base plate 101. A control panel 105 is fixedly installed on one side of the control main box 104. Traction end blocks 106 are horizontally and symmetrically welded to both ends of the support base plate 101. Moving wheels 102 are symmetrically and fixedly connected to the bottom surfaces of the four corners of the support base plate 101. A braking structure is provided on the side of the moving wheels 102. A support column 103 is vertically fixedly connected to one side of the support base plate 101. A connection hole 107 is opened on the top surface of the traction end block 106. The control main box 104 is installed on the side of the support base plate 101 through the support column 103. A control device is provided on the side. The control panel 105 is electrically connected to the internal control device of the control box 104. There are two traction end blocks 106, and the two traction end blocks 106 are symmetrically fixedly connected to the center positions of both ends of the support base plate 101. The traction end blocks 106 are connected to the external traction vehicle through the connection hole 107. The bottom end of the telescopic pole 201 is horizontally welded with a mounting base plate 108. The top surface of the mounting base plate 108 is symmetrically provided with mounting connection holes 109. The bottom surface of the control box 104 is provided with a bottom locking hole 110. The top end of the support column 103 is fixedly connected with a rotating locking block 111, and the rotating locking block 111 is locked in the inner side of the bottom locking hole 110. The adjustment mechanism 2 includes a telescopic upright 201. An adjusting cylinder 202 is vertically fixed to the side of each telescopic upright 201. An inner connecting block 203 is horizontally welded to the side of each telescopic upright 201. An inclined cylinder 205 is symmetrically connected to both ends of the inner connecting block 203. End slots 204 are symmetrically opened at the center of both ends of the inner connecting block 203. Connecting shafts 206 are symmetrically inserted into both ends of the inclined cylinders 205. There are two telescopic uprights 201, and the two telescopic uprights 201 are arranged parallel to each other. The bottom end of the telescopic pole 201 is fixedly installed at the center of both sides of the top surface of the support base plate 101 via the mounting base plate 108. The inner connecting block 203 is fixedly connected to the top of the sleeve of the telescopic pole 201. The inclined cylinders 205 are all connected to the inner side of the groove of the end slot 204 and the bottom mating block 304 via the connecting shafts 206 at both ends. The top of the side of the telescopic pole 201 is provided with a side locking hole 207, and a fixed bearing 208 is fixedly engaged on the inner side of the side locking hole 207.

[0024] The telescopic pole 201 can be extended or retracted by the adjusting cylinder 202 in the adjusting mechanism 2, thereby achieving height adjustment of the processing mechanism 3. In different production environments, such as different workshop heights and different equipment layouts, the equipment can be adjusted to a suitable height according to actual needs, facilitating its use in conjunction with other production equipment. Example

[0025] like Figures 1-13As shown, the present invention provides a technical solution: a device for preventing the agglomeration of recycled plastic granules in the production of plastic products, comprising a support mechanism 1, an adjustment mechanism 2 installed on the top surface of the support mechanism 1, a processing mechanism 3 horizontally arranged at the top of the adjustment mechanism 2, a feeding mechanism 4 symmetrically fixedly connected to the top surface of the processing mechanism 3, and a vibration mechanism 5 symmetrically fixedly installed on one side of the processing mechanism 3. The adjustment mechanism 2 is vertically symmetrically fixedly connected at the center of the top surface of the support mechanism 1. Plastic granules are fed into the interior of the processing mechanism 3 through the feeding mechanism 4 on the top surface. There are two vibration mechanisms 5, and the two vibration mechanisms 5 are symmetrically fixedly connected and arranged on the side of the processing mechanism 3 near both ends. The support mechanism 1 includes a support base plate 101. A control main box 104 is fixedly installed on the top surface of the support base plate 101. A control panel 105 is fixedly installed on one side of the control main box 104. Traction end blocks 106 are horizontally and symmetrically welded to both ends of the support base plate 101. Moving wheels 102 are symmetrically and fixedly connected to the bottom surfaces of the four corners of the support base plate 101. A braking structure is provided on the side of the moving wheels 102. A support column 103 is vertically fixedly connected to one side of the support base plate 101. A connection hole 107 is opened on the top surface of the traction end block 106. The control main box 104 is installed on the side of the support base plate 101 through the support column 103. A control device is provided on the side. The control panel 105 is electrically connected to the internal control device of the control box 104. There are two traction end blocks 106, and the two traction end blocks 106 are symmetrically fixedly connected to the center positions of both ends of the support base plate 101. The traction end blocks 106 are connected to the external traction vehicle through the connection hole 107. The bottom end of the telescopic pole 201 is horizontally welded with a mounting base plate 108. The top surface of the mounting base plate 108 is symmetrically provided with mounting connection holes 109. The bottom surface of the control box 104 is provided with a bottom locking hole 110. The top end of the support column 103 is fixedly connected with a rotating locking block 111, and the rotating locking block 111 is locked in the inner side of the bottom locking hole 110. The adjustment mechanism 2 includes a telescopic upright 201. An adjusting cylinder 202 is vertically fixed to the side of each telescopic upright 201. An inner connecting block 203 is horizontally welded to the side of each telescopic upright 201. An inclined cylinder 205 is symmetrically connected to both ends of the inner connecting block 203. End slots 204 are symmetrically opened at the center of both ends of the inner connecting block 203. Connecting shafts 206 are symmetrically inserted into both ends of the inclined cylinders 205. There are two telescopic uprights 201, and the two telescopic uprights 201 are arranged parallel to each other. The bottom end of the telescopic pole 201 is fixedly installed at the center of both sides of the top surface of the support base plate 101 via the mounting base plate 108. The inner connecting block 203 is fixedly connected to the top of the sleeve of the telescopic pole 201. The inclined cylinders 205 are all connected to the inner side of the groove of the end slot 204 and the bottom mating block 304 via the connecting shafts 206 at both ends. The top of the side of the telescopic pole 201 is provided with a side locking hole 207, and a fixed bearing 208 is fixedly engaged on the inner side of the side locking hole 207. The processing mechanism 3 includes a main processing box 301. A bottom mating block 304 is symmetrically and fixedly connected to the bottom surface of the main processing box 301. A central connecting block 305 is horizontally and fixedly welded to the center line of the bottom surface of the main processing box 301. A mating side box 306 is vertically and fixedly connected to the center of one side of the main processing box 301. A transmission motor 307 is fixedly connected to the side of the mating side box 306. Sealing end plates 308 are vertically snapped onto the inner sides of the two open ends of the main processing box 301. Tilting end shafts 313 are symmetrically inserted into both ends of the central connecting block 305. A maintenance slot 302 is provided on one side of the main processing box 301. A sealing cover plate 303 is bolted to the inner side of the maintenance slot 302. The processing box 301 has symmetrically threaded positioning screws 309 at both ends. Limiting grooves 310 are formed on the inner sides of the two openings of the main processing box 301. Top through grooves 311 are formed at both ends of the top surface of the main processing box 301. The main processing box 301 is a box structure with openings at both ends. The main processing box 301 is connected to the top of the telescopic uprights 201 via a flip-type connection using a central connecting block 305 on the bottom surface. Bottom mating blocks 304 are symmetrically fixed at the center line of the bottom surface of the main processing box 301 near both ends. The output end of the transmission motor 307 is extended and fixedly connected to one end of a main connecting shaft 317. The top end of the sealing end plate 308 is inserted through the top through groove. The inner side of 311, and the sealing end plate 308 is sealed at the two open ends of the main processing box 301. The center of the top surface of both ends of the main processing box 301 is provided with through screw holes 312. The positioning screw 309 is threadedly connected to the inner side of the through screw hole 312, and the extension end is pressed at the side position of the sealing end plate 308. The bottom surface of the main processing box 301 is evenly provided with bottom screw holes 314. The top surface of the main processing box 301 is symmetrically provided with top through grooves 315 near both ends. The inner side of the side box 306 is provided with a transmission gear 316. The center of the inner side of the main processing box 301 is symmetrically provided with a moving roller 319. The two ends of the moving roller 319 are fixedly connected with the main connecting shaft 31. 7. One end of the main connecting shaft 317 is fixedly connected to the center of the transmission gear 316. The inner top and bottom surfaces of the main processing box 301 are symmetrically welded with guide blocks 318. One end of the flipping end shaft 313 is horizontally fixedly inserted into the inner side of the fixed bearing 208. The transmission gears 316 are all fixedly connected to the outer side of the main connecting shaft 317, and the transmission gears 316 are toothed to each other. The agitator rollers 319 are arranged in parallel and stacked on the inner center of the main processing box 301, and the outer side of the agitator rollers 319 is uniformly provided with staggered column structures. The guide blocks 318 are symmetrically arranged on both sides near the agitator rollers 319.

[0026] Through the telescopic cooperation of the inclined cylinder 205, the main processing box 301 of the processing mechanism 3 can be tilted at the top of the telescopic upright 201. This angle adjustment function makes the equipment more flexible and convenient in operations such as feeding, processing, and discharging. For example, when feeding, the end holding the material can be flipped upwards for easy feeding; during processing, the angle can be adjusted as needed to allow the plastic granules to circulate better within the main processing box 301, improving the processing effect. Example

[0027] like Figures 1-13 As shown, the present invention provides a technical solution: a device for preventing the agglomeration of recycled plastic granules in the production of plastic products, comprising a support mechanism 1, an adjustment mechanism 2 installed on the top surface of the support mechanism 1, a processing mechanism 3 horizontally arranged at the top of the adjustment mechanism 2, a feeding mechanism 4 symmetrically fixedly connected to the top surface of the processing mechanism 3, and a vibration mechanism 5 symmetrically fixedly installed on one side of the processing mechanism 3. The adjustment mechanism 2 is vertically symmetrically fixedly connected at the center of the top surface of the support mechanism 1. Plastic granules are fed into the interior of the processing mechanism 3 through the feeding mechanism 4 on the top surface. There are two vibration mechanisms 5, and the two vibration mechanisms 5 are symmetrically fixedly connected and arranged on the side of the processing mechanism 3 near both ends. The support mechanism 1 includes a support base plate 101. A control main box 104 is fixedly installed on the top surface of the support base plate 101. A control panel 105 is fixedly installed on one side of the control main box 104. Traction end blocks 106 are horizontally and symmetrically welded to both ends of the support base plate 101. Moving wheels 102 are symmetrically and fixedly connected to the bottom surfaces of the four corners of the support base plate 101. A braking structure is provided on the side of the moving wheels 102. A support column 103 is vertically fixedly connected to one side of the support base plate 101. A connection hole 107 is opened on the top surface of the traction end block 106. The control main box 104 is installed on the side of the support base plate 101 through the support column 103. A control device is provided on the side. The control panel 105 is electrically connected to the internal control device of the control box 104. There are two traction end blocks 106, and the two traction end blocks 106 are symmetrically fixedly connected to the center positions of both ends of the support base plate 101. The traction end blocks 106 are connected to the external traction vehicle through the connection hole 107. The bottom end of the telescopic pole 201 is horizontally welded with a mounting base plate 108. The top surface of the mounting base plate 108 is symmetrically provided with mounting connection holes 109. The bottom surface of the control box 104 is provided with a bottom locking hole 110. The top end of the support column 103 is fixedly connected with a rotating locking block 111, and the rotating locking block 111 is locked in the inner side of the bottom locking hole 110. The adjustment mechanism 2 includes a telescopic upright 201. An adjusting cylinder 202 is vertically fixed to the side of each telescopic upright 201. An inner connecting block 203 is horizontally welded to the side of each telescopic upright 201. An inclined cylinder 205 is symmetrically connected to both ends of the inner connecting block 203. End slots 204 are symmetrically opened at the center of both ends of the inner connecting block 203. Connecting shafts 206 are symmetrically inserted into both ends of the inclined cylinders 205. There are two telescopic uprights 201, and the two telescopic uprights 201 are arranged parallel to each other. The bottom end of the telescopic pole 201 is fixedly installed at the center of both sides of the top surface of the support base plate 101 via the mounting base plate 108. The inner connecting block 203 is fixedly connected to the top of the sleeve of the telescopic pole 201. The inclined cylinders 205 are all connected to the inner side of the groove of the end slot 204 and the bottom mating block 304 via the connecting shafts 206 at both ends. The top of the side of the telescopic pole 201 is provided with a side locking hole 207, and a fixed bearing 208 is fixedly engaged on the inner side of the side locking hole 207. The processing mechanism 3 includes a main processing box 301. A bottom mating block 304 is symmetrically and fixedly connected to the bottom surface of the main processing box 301. A central connecting block 305 is horizontally and fixedly welded to the center line of the bottom surface of the main processing box 301. A mating side box 306 is vertically and fixedly connected to the center of one side of the main processing box 301. A transmission motor 307 is fixedly connected to the side of the mating side box 306. Sealing end plates 308 are vertically snapped onto the inner sides of the two open ends of the main processing box 301. Tilting end shafts 313 are symmetrically inserted into both ends of the central connecting block 305. A maintenance slot 302 is provided on one side of the main processing box 301. A sealing cover plate 303 is bolted to the inner side of the maintenance slot 302. The processing box 301 has symmetrically threaded positioning screws 309 at both ends. Limiting grooves 310 are formed on the inner sides of the two openings of the main processing box 301. Top through grooves 311 are formed at both ends of the top surface of the main processing box 301. The main processing box 301 is a box structure with openings at both ends. The main processing box 301 is connected to the top of the telescopic uprights 201 via a flip-type connection using a central connecting block 305 on the bottom surface. Bottom mating blocks 304 are symmetrically fixed at the center line of the bottom surface of the main processing box 301 near both ends. The output end of the transmission motor 307 is extended and fixedly connected to one end of a main connecting shaft 317. The top end of the sealing end plate 308 is inserted through the top through groove. The inner side of 311, and the sealing end plate 308 is sealed at the two open ends of the main processing box 301. The center of the top surface of both ends of the main processing box 301 is provided with through screw holes 312. The positioning screw 309 is threadedly connected to the inner side of the through screw hole 312, and the extension end is pressed at the side position of the sealing end plate 308. The bottom surface of the main processing box 301 is evenly provided with bottom screw holes 314. The top surface of the main processing box 301 is symmetrically provided with top through grooves 315 near both ends. The inner side of the side box 306 is provided with a transmission gear 316. The center of the inner side of the main processing box 301 is symmetrically provided with a moving roller 319. The two ends of the moving roller 319 are fixedly connected with the main connecting shaft 31. 7. One end of the main connecting shaft 317 is fixedly connected to the center of the transmission gear 316. The inner top and bottom surfaces of the main processing box 301 are symmetrically fixedly welded with guide inner blocks 318. One end of the flipping end shaft 313 is horizontally fixedly inserted into the inner side of the fixed bearing 208. The transmission gears 316 are all fixedly connected to the outer side of the main connecting shaft 317, and the transmission gears 316 are toothed to each other. The agitator rollers 319 are stacked and arranged in parallel at the center of the inner side of the main processing box 301, and the outer side of the agitator rollers 319 is uniformly provided with staggered column structures. The guide inner blocks 318 are symmetrically arranged on both sides near the agitator rollers 319. The feeding mechanism 4 includes a feeding hopper 401, a top cover 402 is hinged to the top opening of the feeding hopper 401, the bottom opening of the feeding hopper 401 is fixedly connected to the top opening of the top through groove 315 to maintain communication, and a stabilizing buckle 403 is provided on the side of the top cover 402.

[0028] The ease of disassembly and installation facilitates equipment maintenance. For example, when the agitator roller 319 or the vibration mechanism 5 malfunctions, the relevant components can be easily disassembled for repair or replacement. A maintenance slot 302 on one side of the main processing box 301 is bolted to a sealing cover 303. When internal components of the main processing box 301 need repair, only the sealing cover 303 needs to be opened for maintenance, eliminating the need for extensive disassembly of the entire equipment and saving maintenance time and costs. Example

[0029] like Figures 1-13 As shown, the present invention provides a technical solution: a device for preventing the agglomeration of recycled plastic granules in the production of plastic products, comprising a support mechanism 1, an adjustment mechanism 2 installed on the top surface of the support mechanism 1, a processing mechanism 3 horizontally arranged at the top of the adjustment mechanism 2, a feeding mechanism 4 symmetrically fixedly connected to the top surface of the processing mechanism 3, and a vibration mechanism 5 symmetrically fixedly installed on one side of the processing mechanism 3. The adjustment mechanism 2 is vertically symmetrically fixedly connected at the center of the top surface of the support mechanism 1. Plastic granules are fed into the interior of the processing mechanism 3 through the feeding mechanism 4 on the top surface. There are two vibration mechanisms 5, and the two vibration mechanisms 5 are symmetrically fixedly connected and arranged on the side of the processing mechanism 3 near both ends. The support mechanism 1 includes a support base plate 101. A control main box 104 is fixedly installed on the top surface of the support base plate 101. A control panel 105 is fixedly installed on one side of the control main box 104. Traction end blocks 106 are horizontally and symmetrically welded to both ends of the support base plate 101. Moving wheels 102 are symmetrically and fixedly connected to the bottom surfaces of the four corners of the support base plate 101. A braking structure is provided on the side of the moving wheels 102. A support column 103 is vertically fixedly connected to one side of the support base plate 101. A connection hole 107 is opened on the top surface of the traction end block 106. The control main box 104 is installed on the side of the support base plate 101 through the support column 103. A control device is provided on the side. The control panel 105 is electrically connected to the internal control device of the control box 104. There are two traction end blocks 106, and the two traction end blocks 106 are symmetrically fixedly connected to the center positions of both ends of the support base plate 101. The traction end blocks 106 are connected to the external traction vehicle through the connection hole 107. The bottom end of the telescopic pole 201 is horizontally welded with a mounting base plate 108. The top surface of the mounting base plate 108 is symmetrically provided with mounting connection holes 109. The bottom surface of the control box 104 is provided with a bottom locking hole 110. The top end of the support column 103 is fixedly connected with a rotating locking block 111, and the rotating locking block 111 is locked in the inner side of the bottom locking hole 110. The adjustment mechanism 2 includes a telescopic upright 201. An adjusting cylinder 202 is vertically fixed to the side of each telescopic upright 201. An inner connecting block 203 is horizontally welded to the side of each telescopic upright 201. An inclined cylinder 205 is symmetrically connected to both ends of the inner connecting block 203. End slots 204 are symmetrically opened at the center of both ends of the inner connecting block 203. Connecting shafts 206 are symmetrically inserted into both ends of the inclined cylinders 205. There are two telescopic uprights 201, and the two telescopic uprights 201 are arranged parallel to each other. The bottom end of the telescopic pole 201 is fixedly installed at the center of both sides of the top surface of the support base plate 101 via the mounting base plate 108. The inner connecting block 203 is fixedly connected to the top of the sleeve of the telescopic pole 201. The inclined cylinders 205 are all connected to the inner side of the groove of the end slot 204 and the bottom mating block 304 via the connecting shafts 206 at both ends. The top of the side of the telescopic pole 201 is provided with a side locking hole 207, and a fixed bearing 208 is fixedly engaged on the inner side of the side locking hole 207. The processing mechanism 3 includes a main processing box 301. A bottom mating block 304 is symmetrically and fixedly connected to the bottom surface of the main processing box 301. A central connecting block 305 is horizontally and fixedly welded to the center line of the bottom surface of the main processing box 301. A mating side box 306 is vertically and fixedly connected to the center of one side of the main processing box 301. A transmission motor 307 is fixedly connected to the side of the mating side box 306. Sealing end plates 308 are vertically snapped onto the inner sides of the two open ends of the main processing box 301. Tilting end shafts 313 are symmetrically inserted into both ends of the central connecting block 305. A maintenance slot 302 is provided on one side of the main processing box 301. A sealing cover plate 303 is bolted to the inner side of the maintenance slot 302. The processing box 301 has symmetrically threaded positioning screws 309 at both ends. Limiting grooves 310 are formed on the inner sides of the two openings of the main processing box 301. Top through grooves 311 are formed at both ends of the top surface of the main processing box 301. The main processing box 301 is a box structure with openings at both ends. The main processing box 301 is connected to the top of the telescopic uprights 201 via a flip-type connection using a central connecting block 305 on the bottom surface. Bottom mating blocks 304 are symmetrically fixed at the center line of the bottom surface of the main processing box 301 near both ends. The output end of the transmission motor 307 is extended and fixedly connected to one end of a main connecting shaft 317. The top end of the sealing end plate 308 is inserted through the top through groove. The inner side of 311, and the sealing end plate 308 is sealed at the two open ends of the main processing box 301. The center of the top surface of both ends of the main processing box 301 is provided with through screw holes 312. The positioning screw 309 is threadedly connected to the inner side of the through screw hole 312, and the extension end is pressed at the side position of the sealing end plate 308. The bottom surface of the main processing box 301 is evenly provided with bottom screw holes 314. The top surface of the main processing box 301 is symmetrically provided with top through grooves 315 near both ends. The inner side of the side box 306 is provided with a transmission gear 316. The center of the inner side of the main processing box 301 is symmetrically provided with a moving roller 319. The two ends of the moving roller 319 are fixedly connected with the main connecting shaft 31. 7. One end of the main connecting shaft 317 is fixedly connected to the center of the transmission gear 316. The inner top and bottom surfaces of the main processing box 301 are symmetrically fixedly welded with guide inner blocks 318. One end of the flipping end shaft 313 is horizontally fixedly inserted into the inner side of the fixed bearing 208. The transmission gears 316 are all fixedly connected to the outer side of the main connecting shaft 317, and the transmission gears 316 are toothed to each other. The agitator rollers 319 are stacked and arranged in parallel at the center of the inner side of the main processing box 301, and the outer side of the agitator rollers 319 is uniformly provided with staggered column structures. The guide inner blocks 318 are symmetrically arranged on both sides near the agitator rollers 319. The feeding mechanism 4 includes a feeding hopper 401, a top cover 402 is hinged to the top opening of the feeding hopper 401, the bottom opening of the feeding hopper 401 is fixedly connected to the top opening of the top through groove 315 to maintain communication, and a stabilizing buckle 403 is connected to the side of the top cover 402. The vibration mechanism 5 includes an inner support plate 501, which is symmetrically and fixedly connected to the side of the main processing box 301. Connecting springs 502 are symmetrically and evenly fixedly connected to the four corners of the side of the inner support plate 501. A mating plate 503 is fixedly connected to one end of each connecting spring 502. A vibrator 504 is fixedly installed on one side of the mating plate 503. A through hole 505 is opened at the center of the side of the inner support plate 501. An isolation rubber ring 506 is fixedly snapped into the inner side of the through hole 505. A vibration rod 507 is connected to the output end of the vibrator 504. One end of the vibration rod 507 is fixedly... An inner support rod 508 is fixedly connected. A bent rod 509 is evenly welded to one side of the inner support rod 508. A branch rod 510 is evenly welded to the side of the inner support rod 508 away from the bent rod 509. The mating plate 503 and the inner support plate 501 are arranged in parallel with each other. One end of the vibration rod 507 extends and is inserted into the inner side of the main processing box 301. The inner support rod 508 is arranged parallel and symmetrically on both sides of the agitator roller 319. One end of the bent rod 509 extends to the inner side of the top through groove 315. The branch rod 510 extends horizontally and is located near the agitator roller 319.

[0030] The bending rod 509 and branch rod 510 in the vibration mechanism 5 generate high-frequency vibration under the drive of the vibrator 504, which can further vibrate and disperse the material. Especially for some plastic particles with more severe agglomeration, this dual treatment method can ensure that the agglomeration is completely broken up, so that the plastic particles are restored to a loose state, which meets the requirements of subsequent plastic product production, effectively improves product quality, and reduces quality problems such as material shortage and surface defects caused by agglomeration.

[0031] Working Principle: The equipment moves flexibly via the casters 102 at the bottom of the support base plate 101, facilitating adjustments to its position according to production needs. Once in position, the casters are secured using a braking mechanism to ensure stability. For long-distance movement or relocation, the equipment can be connected to an external traction vehicle via the connection hole 107 on the traction end block 106 for overall traction. Based on the actual height requirements of the production line, the adjusting cylinder 202 in the adjusting mechanism 2 is activated via the control panel 105. The adjusting cylinder 202 drives the telescopic upright 201 to extend and retract, thereby adjusting the main processing box 301 at the top to the specified height to meet the docking requirements of different production lines. The top cover 402 in the feeding mechanism 4 is opened, and the recycled plastic granules to be processed are fed into the main processing box 301 through the feeding hopper 401. After feeding, the top cover 402 is closed, and the stabilizing strip 403 is fastened to prevent material leakage and the entry of external impurities. The extension and retraction of the inclined cylinder 205 is controlled via the control panel 105 according to material processing needs. The inclined cylinder 205 is connected to the bottom mating block 304 at the bottom of the main processing box 301 via the connecting shaft 206, driving the main processing box 301 to tilt at the top of the telescopic upright 201, so that the end containing the material flips upward, facilitating subsequent processing operations. The transmission motor 307 in the mating side box 306 is activated, driving the transmission gear 316 to rotate via the main connecting shaft 317, which in turn drives the agitator roller 319 to rotate. The staggered column structure evenly arranged on the outer side of the agitator roller 319 powerfully agitates the falling plastic granules, effectively breaking up clumps of material. Simultaneously, the vibrator 504 in the vibration mechanism 5 is activated, transmitting vibration energy to the inner support rod 508 via the vibration rod 507. The bent rod 509 on one side of the inner support rod 508 extends to the inside of the top passage 315 below the feeding hopper 401, and performs initial vibration to disperse the material entering the main processing box 301; the branch rod 510 on the other side extends horizontally between the agitator rollers 319, and further vibrates and refines the material processed by the agitator rollers, ensuring that the material is completely dispersed. By repeatedly adjusting the tilt angle of the main processing box 301 and starting the coordinated work of the agitator rollers 319 and the vibration mechanism 5, the plastic particles are circulated and vibrated to disperse within the main processing box 301. After processing, the sealing end plate 308 is loosened by rotating the positioning screw 309, pushing the sealing end plate 308 to open one end opening of the main processing box 301, and the processed plastic particles are smoothly discharged to the next production stage.

[0032] All technical features in this embodiment can be freely combined according to actual needs.

[0033] The above embodiments are preferred implementations of the present invention. In addition, the present invention can be implemented in other ways. Any obvious substitutions without departing from the concept of the present technical solution are within the protection scope of the present invention.

[0034] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0035] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A device for preventing the agglomeration of recycled plastic granules in the production of plastic products, comprising a support mechanism (1), characterized in that, An adjustment mechanism (2) is installed on the top surface of the support mechanism (1), and a processing mechanism (3) is horizontally installed at the top of the adjustment mechanism (2). A feeding mechanism (4) is symmetrically and fixedly connected to the top surface of the processing mechanism (3), and a vibration mechanism (5) is symmetrically and fixedly installed on one side of the processing mechanism (3). The support mechanism (1) includes a support base plate (101), a control main box (104) is fixedly installed on the top surface of the support base plate (101), a control panel (105) is fixedly installed on one side of the control main box (104), and traction end blocks (106) are horizontally and symmetrically welded to both ends of the support base plate (101). The adjustment mechanism (2) includes a telescopic upright (201), an adjustment cylinder (202) is vertically fixedly connected to the side of the telescopic upright (201), and an inner connecting block (203) is horizontally welded between the sides of the telescopic upright (201). An inclined cylinder (205) is symmetrically connected to both ends of the inner connecting block (203). The processing mechanism (3) includes a main processing box (301). A bottom mating block (304) is symmetrically and fixedly connected to the bottom surface of the main processing box (301). A central connecting block (305) is horizontally and fixedly welded to the center line of the bottom surface of the main processing box (301). A mating side box (306) is vertically and fixedly connected to the center of one side of the main processing box (301). A transmission motor (307) is fixedly connected to the side of the mating side box (306). Sealing end plates (308) are vertically snapped into the inner sides of the two open ends of the main processing box (301). The two ends of the central connecting block (305) are symmetrical. A flip-end shaft (313) is inserted into the main processing box (301). A top through groove (315) is symmetrically opened on the top surface of the main processing box (301) near both ends. A transmission gear (316) is provided on the inner side of the mating side box (306). A push roller (319) is symmetrically arranged at the center of the inner side of the main processing box (301). A main connecting shaft (317) is fixedly connected to both ends of the push roller (319). One end of the main connecting shaft (317) is fixedly connected to the center of the transmission gear (316). A guide inner block (318) is symmetrically fixedly welded to the top and bottom surfaces of the inner side of the main processing box (301). The feeding mechanism (4) includes a feeding hopper (401), and the top opening end of the feeding hopper (401) is hinged to a top cover (402). The vibration mechanism (5) includes an inner support plate (501), which is symmetrically and fixedly connected to the side of the main processing box (301). Connecting springs (502) are symmetrically and evenly fixedly connected to the four corners of the side of the inner support plate (501). A mating plate (503) is fixedly connected to one end of the connecting spring (502). A vibrator (504) is fixedly installed on one side of the mating plate (503). A vibration rod (507) is connected to the output end of the vibrator (504). An inner support rod (508) is fixedly connected to one end of the vibration rod (507). A bending rod (509) is evenly welded to one side of the inner support rod (508). A branch rod (510) is evenly welded to the side of the inner support rod (508) away from the bending rod (509).

2. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, The four corners of the support base plate (101) are symmetrically fixedly connected with moving wheels (102). The moving wheels (102) are provided with a braking structure on the side. The support base plate (101) is vertically fixedly connected with a support column (103) on one side. The top surface of the traction end block (106) is provided with a connection hole (107). The traction end block (106) is connected to the external traction vehicle through the connection hole (107). The bottom end of the telescopic pole (201) is horizontally welded with an installation base plate (108). The top surface of the installation base plate (108) is symmetrically provided with an installation connection hole (109). The bottom surface of the control main box (104) is provided with a bottom locking hole (110). The top of the support column (103) is fixedly connected with a rotating locking block (111). The rotating locking block (111) is locked in place on the inner side of the bottom locking hole (110).

3. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, The inner connecting block (203) has end slots (204) symmetrically opened at both ends. The inclined cylinder (205) has connecting shafts (206) symmetrically inserted at both ends. The telescopic pole (201) has a side locking hole (207) at the top side. The inner side of the side locking hole (207) is fixedly locked with a fixed bearing (208). The top cover (402) is connected with a stabilizing buckle (403). The inner support plate (501) has a through hole (505) at the center of its side. The inner side of the through hole (505) is fixedly locked with an isolation rubber ring (506).

4. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, A maintenance slot (302) is provided on one side of the main processing box (301). A sealing cover plate (303) is bolted to the inner side of the maintenance slot (302). Positioning screws (309) are symmetrically threaded to both ends of the main processing box (301). Limiting grooves (310) are provided on the inner side of the two openings of the main processing box (301). Top through slots (311) are provided at both ends of the top surface of the main processing box (301). Through screw holes (312) are provided at the center of the top surface of both ends of the main processing box (301). The positioning screw (309) is threaded to the inner side of the through screw hole (312), and its extension end is pressed to the side of the sealing end plate (308). Bottom screw holes (314) are evenly provided on the bottom surface of the main processing box (301).

5. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, The adjustment mechanism (2) is vertically and symmetrically fixedly connected to the center of the top surface of the support mechanism (1). Plastic particles are fed into the interior of the processing mechanism (3) through the feeding mechanism (4) on the top surface. There are two vibration mechanisms (5), and the two vibration mechanisms (5) are symmetrically and fixedly connected to the sides of the processing mechanism (3) near both ends.

6. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, The control box (104) is installed on the side of the support base plate (101) via the support column (103), and the control device is provided on the inner side of the control box (104). The control panel (105) is electrically connected to the internal control device of the control box (104). There are two traction end blocks (106), and the two traction end blocks (106) are symmetrically fixedly connected at the center of both ends of the support base plate (101).

7. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, There are two telescopic poles (201), and the two telescopic poles (201) are arranged in parallel to each other. The bottom end of the telescopic pole (201) is fixedly installed on the center position of the two sides of the top surface of the support base plate (101) through the mounting base plate (108). The inner connecting block (203) is fixedly connected to the top end of the sleeve of the telescopic pole (201). The inclined cylinders (205) are all connected to the inner side of the groove of the end slot (204) and the bottom mating block (304) through the connecting shafts (206) at both ends.

8. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, The main processing box (301) is a box structure with open ends. The main processing box (301) is connected to the top of the telescopic uprights (201) by a flip-type connection of the middle connecting block (305) on the bottom surface. The bottom mating block (304) is symmetrically fixed on the bottom center line of the main processing box (301) near both ends. The output end of the transmission motor (307) is extended and fixedly connected to one end of a main connecting shaft (317). The top end of the sealing end plate (308) is inserted through and installed on the inner side of the top through groove (311), and the sealing end plate (308) is sealed at the two open ends of the main processing box (301).

9. The anti-caking device for recycled plastic granules used in the production of plastic products according to claim 1, characterized in that, One end of the flipping end shaft (313) is horizontally fixedly inserted into the inner side of the fixed bearing (208). The transmission gears (316) are all fixedly connected to the outer side of the main connecting shaft (317), and the transmission gears (316) are toothed to each other. The agitator rollers (319) are arranged in parallel and stacked on the inner center of the main processing box (301), and the outer side of the agitator rollers (319) is uniformly provided with staggered column structures. The guide blocks (318) are symmetrically arranged on both sides near the agitator rollers (319). The bottom opening of the feeding hopper (401) is fixedly connected to the top opening of the top through groove (315) to maintain communication. The mating plate (503) and the inner support plate (501) are arranged in parallel with each other. One end of the vibrating rod (507) is inserted into the inner side of the main processing box (301). The inner support rod (508) is arranged in parallel and symmetrically on both sides of the actuating roller (319). One end of the bending rod (509) extends to the inner side of the top through groove (315). The branch rod (510) extends horizontally and is arranged near the actuating roller (319).