Regenerated rubber production cooling device

By designing a combined structure of sleeves, shelving boxes, and exhaust fans within the heat dissipation box, the problem of poor heat dissipation in recycled rubber cooling devices was solved, achieving efficient rubber cooling and improved stability of cross-linked structures.

CN224446565UActive Publication Date: 2026-07-03朝阳华兴万达新材料有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
朝阳华兴万达新材料有限公司
Filing Date
2025-07-11
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

In existing recycled rubber production cooling devices, the fixed position of the rubber results in poor heat dissipation and affects cooling efficiency.

Method used

A cooling device comprising a heat dissipation box, a rubber support mechanism, and a rubber heat dissipation mechanism is designed. Through a combination structure of a sleeve, a support box, an exhaust fan, and a motor drive, the positioning, rotation, and fan position adjustment of the rubber are achieved, ensuring air circulation and heat dissipation.

Benefits of technology

It improves the heat dissipation efficiency of recycled rubber, ensures the stability of the cross-linked structure, and enhances the cooling effect.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224446565U_ABST
    Figure CN224446565U_ABST
Patent Text Reader

Abstract

The utility model discloses a regenerated rubber production cooling device relates to regenerated rubber production technical field, including heat dissipation box, still include: rubber resting mechanism is set up in the heat dissipation box, and rubber resting mechanism includes the sleeve that sets up in the heat dissipation box, is provided with the mounting shaft in the sleeve, and the fixed sleeve is fixedly sleeved on the mounting shaft, and the resting box is installed on the fixed sleeve, and the sleeve and resting box are respectively set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and are set up and
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of recycled rubber production technology, and in particular to a cooling device for recycled rubber production. Background Technology

[0002] Reclaimed rubber is rubber that has a certain degree of plasticity and can be reused, processed from vulcanized scraps and waste materials in rubber product manufacturing. During the vulcanization process of reclaimed rubber, the molecular activity inside the rubber is relatively intense, and the cross-linking structure forms rapidly, but the stability of the cross-linking structure is poor. Cooling can further stabilize the cross-linking structure, ensuring that the internal structure of the rubber is more robust.

[0003] The prior art patent with publication number CN215151049U discloses a cooling device for the production of recycled rubber. When the device cools the rubber with a fan, the position of the rubber is fixed and different rubbers block each other, which leads to a decrease in the heat dissipation effect of the fan and a longer heat dissipation time. Therefore, a cooling device for the production of recycled rubber is needed to meet the usage requirements. Utility Model Content

[0004] The purpose of this invention is to provide a cooling device for the production of recycled rubber to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a cooling device for recycled rubber production, including a heat dissipation box, and further comprising:

[0006] A rubber support mechanism is provided inside the heat dissipation box. The rubber support mechanism includes a sleeve provided inside the heat dissipation box. An installation shaft is provided inside the sleeve. A fixing sleeve is fixedly sleeved on the installation shaft. A support box is installed on the fixing sleeve. Heat dissipation holes and openings are respectively provided on the sleeve and the support box.

[0007] A rubber heat dissipation mechanism is provided on the heat dissipation box and the rubber support mechanism. The rubber heat dissipation mechanism includes a heat dissipation port opened on the heat dissipation box. An installation plate is movably provided on the outside of the heat dissipation box, and an exhaust fan is installed inside the installation plate.

[0008] Preferably, a support mesh is installed at the bottom of the heat dissipation hole, and a partition plate is installed on the shelf box.

[0009] Preferably, a positioning sleeve is installed on the bottom inner wall of the sleeve, and a positioning block is installed at the bottom end of the mounting shaft, the positioning block being engaged in the positioning sleeve.

[0010] Preferably, a rotating shaft is installed at the bottom of the sleeve, a driven gear is fixedly sleeved on the rotating shaft, a driving gear meshes with the driven gear, a first drive motor is installed on the bottom inner wall of the heat sink, and the driving gear is installed at the output end of the first drive motor.

[0011] Preferably, a support sleeve is installed on the bottom inner wall of the heat sink, and the rotating shaft is rotatably installed inside the support sleeve.

[0012] Preferably, a sliding plate is mounted on the mounting plate, and a guide frame is mounted on the outer wall of the heat sink, with the sliding plate slidably sleeved on the guide frame.

[0013] Preferably, a support plate is installed on the guide frame, a second drive motor is installed on the support plate, a reciprocating screw is installed at the output end of the second drive motor, and the slide plate is screwed onto the reciprocating screw.

[0014] The beneficial effects of this utility model are:

[0015] This utility model allows you to unpack and then hold the rubber from the top of the heat dissipation box, pull the shelf box out from the sleeve, and then place the cooled rubber in the shelf box. Multiple partitions can divide the space inside the shelf box into multiple sections, so that the rubber to be cooled does not interfere with each other. Inserting the positioning block into the positioning sleeve can position the shelf box and heat dissipation holes in the sleeve, thus realizing the placement of the rubber before heat dissipation.

[0016] In this invention, the exhaust fan can extract heat from the rubber through the opening, heat dissipation holes, and exhaust fan rotation. The mounting plate and exhaust fan can move up and down to expand the effective range of the exhaust fan. The rotation of the No. 1 drive motor will drive the rotating shaft to rotate, and the rotating shaft will drive the sleeve and the shelf box to rotate. During heat dissipation, the position of different rubbers can be changed, resulting in a better heat dissipation effect on the rubber. Attached Figure Description

[0017] Figure 1 This is a three-dimensional structural diagram of the cooling device for recycled rubber production proposed in this utility model.

[0018] Figure 2 This is a schematic diagram of the structure of the cooling device for recycled rubber production, including the mounting plate and the exhaust fan, as proposed in this utility model.

[0019] Figure 3 This is a schematic diagram of the drive gear, driven gear, and other structures of the cooling device for recycled rubber production proposed in this utility model.

[0020] Figure 4 This is a schematic diagram of the sleeve, shelf box, and other structures of the cooling device for recycled rubber production proposed in this utility model.

[0021] Figure 5This is a schematic diagram of the supporting mesh, positioning blocks, and other structures of the cooling device for recycled rubber production proposed in this utility model.

[0022] Figure 6 This is a schematic diagram of the guide frame, reciprocating screw, and other structures of the cooling device for recycled rubber production proposed in this utility model.

[0023] In the diagram: 1. Heat dissipation box; 2. Rubber support mechanism; 21. Sleeve; 22. Mounting shaft; 23. Fixing sleeve; 24. Support box; 25. Heat dissipation hole; 26. Through port; 27. Support mesh; 28. Divider plate; 29. ​​Positioning sleeve; 210. Positioning insert; 3. Rubber heat dissipation mechanism; 31. Heat dissipation vent; 32. Mounting plate; 33. Exhaust fan; 34. Rotating shaft; 35. Driven gear; 36. Drive gear; 37. Drive motor No. 1; 38. Support sleeve; 39. Slide plate; 310. Guide frame; 311. Support plate; 312. Drive motor No. 2; 313. Reciprocating screw. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0025] Example:

[0026] like Figure 1-6 As shown, this embodiment provides a cooling device for recycled rubber production, including a heat dissipation box 1 for holding rubber to be cooled. It also includes a rubber holding mechanism 2, disposed within the heat dissipation box 1. The rubber holding mechanism 2 includes a sleeve 21 disposed within the heat dissipation box 1, with an installation shaft 22 disposed within the sleeve 21. A fixing sleeve 23 is fixedly sleeved on the installation shaft 22, and a holding box 24 is mounted on the fixing sleeve 23. The sleeve 21 and the holding box 24 are respectively provided with heat dissipation holes 25 and openings 26. The holding box 24 is pulled out from the sleeve 21, and the cooled rubber is placed inside the holding box 24. The installation shaft 22 and the holding box 24 are then placed back into the sleeve 21. The heat dissipation holes 25 and the openings 26 allow for ventilation within the sleeve 21 and the holding box 24, facilitating air circulation and improving the heat dissipation effect of the rubber.

[0027] To dissipate heat from the rubber, a rubber heat dissipation mechanism 3 is installed on the heat dissipation box 1 and the rubber support mechanism 2. The rubber heat dissipation mechanism 3 includes a heat dissipation port 31 opened on the heat dissipation box 1. An installation plate 32 is movably installed on the outside of the heat dissipation box 1, and an exhaust fan 33 is installed inside the installation plate 32. When the exhaust fan 33 rotates, the heat dissipation port 26, the heat dissipation hole 25, and the exhaust fan 33 can be used to extract the heat emitted by the rubber. The installation plate 32 and the exhaust fan 33 can be moved up and down to expand the effective range of the exhaust fan 33. When dissipating heat from the rubber, the sleeve 21 and the support box 24 can rotate to change the position of different rubbers, resulting in a better heat dissipation effect on the rubber.

[0028] Furthermore, to separate the rubber, a support mesh 27 is installed at the bottom of the heat dissipation hole 25, and a partition plate 28 is installed on the shelf box 24; multiple partition plates 28 can divide the space inside the shelf box 24 into multiple sections, so that the rubber to be cooled does not interfere with each other, and multiple support meshes 27 can allow air circulation between rubbers at different positions, which is beneficial to the heat dissipation of the rubber.

[0029] Furthermore, in order to position the shelving box 24 and the heat dissipation hole 25, a positioning sleeve 29 is installed on the bottom inner wall of the sleeve 21, and a positioning plug 210 is installed at the bottom end of the mounting shaft 22. The positioning plug 210 is engaged in the positioning sleeve 29. When the positioning plug 210 is inserted into the positioning sleeve 29, it can position the shelving box 24 and the heat dissipation hole 25 within the sleeve 21.

[0030] Specifically, to change the position of the rubber during heat dissipation, a rotating shaft 34 is installed at the bottom of the sleeve 21. A driven gear 35 is fixedly sleeved on the rotating shaft 34, and a driving gear 36 meshes with the driven gear 35. A first drive motor 37 is installed on the bottom inner wall of the heat dissipation box 1, and the driving gear 36 is installed at the output end of the first drive motor 37. The rotation of the first drive motor 37 will drive the driving gear 36 to rotate, the rotation of the driving gear 36 will drive the driven gear 35 to rotate, the rotation of the driven gear 35 will drive the rotating shaft 34 to rotate, and the rotation of the rotating shaft 34 will drive the sleeve 21 and the shelf box 24 to rotate, thus changing the position of different rubbers during heat dissipation.

[0031] Furthermore, in order to support the rotating shaft 34, a support sleeve 38 is installed on the bottom inner wall of the heat sink 1, and the rotating shaft 34 is rotatably installed in the support sleeve 38; since the rotating shaft 34 rotates in the support sleeve 38, the support sleeve 38 can support the rotating shaft 34.

[0032] Furthermore, in order to guide the movement of the exhaust fan 33, a sliding plate 39 is installed on the mounting plate 32, and a guide frame 310 is installed on the outer wall of the heat sink 1. The sliding plate 39 is slidably sleeved on the guide frame 310. Since the sliding plate 39 slides on the guide frame 310, it can guide the movement of the mounting plate 32 and the exhaust fan 33, so that the mounting plate 32 and the exhaust fan 33 can only move up and down along the guide frame 310.

[0033] Specifically, to adjust the position of the exhaust fan 33, a support plate 311 is installed on the guide frame 310, and a second drive motor 312 is installed on the support plate 311. A reciprocating screw 313 is installed at the output end of the second drive motor 312, and a sliding plate 39 is screwed onto the reciprocating screw 313. The rotation of the second drive motor 312 will drive the sliding plate 39 to move up and down, which in turn will drive the mounting plate 32 and the exhaust fan 33 to move up and down, thereby adjusting the position of the exhaust fan 33 and expanding the effective range of the exhaust fan 33.

[0034] Working principle: In use, untie 5 and 7, then hold 6 and remove 4 from the top of the heat sink 1. Pull the shelf box 24 out from the sleeve 21, and then place the rubber to be cooled into the shelf box 24. Multiple partitions 28 can divide the space inside the shelf box 24 into multiple sections, ensuring that the rubber to be cooled does not interfere with each other. After the rubber is placed, insert the positioning block 210 into the positioning sleeve 29, and fix 4 to the top of the heat sink 1 using 5 and 7. Start the first drive motor 37, the exhaust fan 33, and the second drive motor 312. The exhaust fan 33 rotates and extracts the heat emitted by the rubber through the port 26, the heat dissipation hole 25, and the exhaust fan 33. The rotation of the second drive motor 312 will drive the slide plate 39 to move up and down, which in turn will drive the mounting plate 32 and the exhaust fan 33 to move up and down, thus expanding the effective range of the exhaust fan 33. The rotation of the first drive motor 37 will drive the drive gear 36 to rotate, which will drive the driven gear 35 to rotate, which will drive the rotating shaft 34 to rotate, which will drive the sleeve 21 and the shelf box 24 to rotate. When dissipating heat from the rubber, the positions of different rubbers can be changed, resulting in a better heat dissipation effect on the rubber.

[0035] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.

Claims

1. Cooling device for the production of reclaimed rubber, comprising a heat sink (1), characterized in that, Also includes: A rubber support mechanism (2) is provided inside the heat dissipation box (1). The rubber support mechanism (2) includes a sleeve (21) provided inside the heat dissipation box (1). An installation shaft (22) is provided inside the sleeve (21). A fixing sleeve (23) is fixedly sleeved on the installation shaft (22). A support box (24) is installed on the fixing sleeve (23). Heat dissipation holes (25) and openings (26) are respectively provided on the sleeve (21) and the support box (24). A rubber heat dissipation mechanism (3) is provided on the heat dissipation box (1) and the rubber support mechanism (2). The rubber heat dissipation mechanism (3) includes a heat dissipation port (31) opened on the heat dissipation box (1). An installation plate (32) is movably provided on the outside of the heat dissipation box (1). An exhaust fan (33) is installed inside the installation plate (32).

2. The cooling device for reclaimed rubber production according to claim 1, characterized in that: A support mesh (27) is installed at the bottom of the heat dissipation hole (25), and a partition plate (28) is installed on the shelf box (24).

3. The cooling device for reclaimed rubber production according to claim 2, characterized in that: A positioning sleeve (29) is installed on the bottom inner wall of the sleeve (21), and a positioning plug (210) is installed at the bottom end of the mounting shaft (22). The positioning plug (210) is engaged in the positioning sleeve (29).

4. The regenerated rubber production cooling device according to claim 1, characterized in that: A rotating shaft (34) is installed at the bottom of the sleeve (21), a driven gear (35) is fixedly sleeved on the rotating shaft (34), a driving gear (36) meshes on the driven gear (35), a first drive motor (37) is installed on the bottom inner wall of the heat sink (1), and the driving gear (36) is installed at the output end of the first drive motor (37).

5. The cooling device for reclaimed rubber production according to claim 4, characterized in that: A support sleeve (38) is installed on the bottom inner wall of the heat sink (1), and the rotating shaft (34) is rotatably installed in the support sleeve (38).

6. The regenerated rubber production cooling device according to claim 1, characterized in that: A sliding plate (39) is installed on the mounting plate (32), and a guide frame (310) is installed on the outer wall of the heat sink (1). The sliding plate (39) is slidably sleeved on the guide frame (310).

7. The cooling device for the production of reclaimed rubber according to claim 6, characterized in that: A support plate (311) is installed on the guide frame (310), a second drive motor (312) is installed on the support plate (311), a reciprocating screw (313) is installed at the output end of the second drive motor (312), and the slide plate (39) is screwed onto the reciprocating screw (313).