A rapid cooling device for epoxy resin production

By combining a spiral tube and a water circulation system, the problem of poor epoxy resin cooling effect was solved, and a highly efficient epoxy resin cooling effect was achieved.

CN224455022UActive Publication Date: 2026-07-03CHIZHOU KECHENG NEW MATERIALS DEV CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHIZHOU KECHENG NEW MATERIALS DEV CO LTD
Filing Date
2025-07-29
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing epoxy resin cooling devices are ineffective and cannot directly and effectively cool epoxy resin.

Method used

The heat removal device consists of a spiral tube, a connecting tube, a drive motor, a driving gear, and a driven gear. The drive motor drives the driving gear to rotate, and the driven gear drives the connecting tube and the spiral tube to rotate. Combined with a water circulation system, the epoxy resin is agitated and cooled.

Benefits of technology

The cooling efficiency of epoxy resin is improved by combining water circulation and agitation, which significantly enhances the cooling effect.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224455022U_ABST
Patent Text Reader

Abstract

This utility model belongs to the field of epoxy resin cooling technology, and in particular, a rapid cooling device for epoxy resin production, including a cooling tank and a water pool. Both the cooling tank and the water pool are equipped with heat removal devices, which include a spiral tube, a connecting pipe, a drive motor, a driving gear, and a driven gear. In this rapid cooling device for epoxy resin production, the epoxy resin is first placed in the cooling tank. Then, a water pump and a circulation pump are started. The water pump draws water, which enters the spiral tube through the connecting pipe on the right, then enters the connecting pipe and the water pump on the left, and is then pumped into the water pool on the left. The circulation pump circulates the water. As the water passes through the spiral tube, it carries away the heat from the epoxy resin. The continuous flow of water in the spiral tube cools the epoxy resin. Then, the drive motor is started to rotate the spiral tube within the cooling tank, agitating the epoxy resin.
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Description

Technical Field

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

[0002] For example, in a rapid cooling device for epoxy resin production disclosed on the Chinese Patent Network (application number: 202320325635.3), in order to accelerate the cooling rate of epoxy resin, the cooling box is rotated to make the epoxy resin inside the cooling box flow inside the box, so as to avoid the epoxy resin from piling up and being unable to cool. Then the entire cooling box is placed in the coolant for cooling. However, this cooling method cannot directly cool the epoxy resin. If the cooling box is only cooled by the coolant, the cooling effect is not good. Utility Model Content

[0003] To address the technical problem of poor cooling effect in existing epoxy adhesive cooling mechanisms, this invention proposes a rapid cooling device for epoxy adhesive production.

[0004] This utility model proposes a rapid cooling device for epoxy resin production, comprising a cooling tank and a water pool. Both the cooling tank and the water pool are equipped with heat removal devices. The heat removal device includes a spiral tube, a connecting tube, a drive motor, a drive gear, and a driven gear. The drive motor controls the rotation of the drive gear, the drive gear drives the driven gear to rotate, the driven gear drives the connecting tube to rotate, and the connecting tube drives the spiral tube to rotate.

[0005] Preferably, the two water pools are located on the left and right sides of the cooling tank, respectively. An installation plate is fixedly installed on the outer surface of the water pool on the right side. The drive motor is fixedly installed inside the installation plate, and the drive gear is fixedly installed on the shaft of the drive motor.

[0006] With the above technical solution, when the drive motor starts, the rotating shaft drives the drive gear to rotate, and the drive motor is stably installed inside the mounting plate.

[0007] Preferably, the cooling tank has a tank cover and a tank body. The tank cover has heat dissipation holes inside and a feed hopper is fixedly installed inside the tank cover. A plate is fixedly installed on the lower surface of the tank cover, and the outer surface of the plate is slidably connected to the upper interior of the tank body.

[0008] Through the above technical solution, the feeding hopper facilitates feeding, the heat dissipation holes facilitate the faster dissipation of heat inside the cooling tank, the gap between the insert plate and the tank body is equipped with a sealing strip to prevent epoxy resin from leaking out of the cooling tank, and horizontal plates are installed on both sides of the tank cover and the tank body. The two horizontal plates are then fixed with bolts to ensure a stable connection between the tank cover and the tank body.

[0009] Preferably, rotating blocks are rotatably connected to the interior of both the left and right ends of the tank, and mounting rings are fixedly installed on the outer surface of the rotating blocks. The outer surface of the mounting rings is rotatably connected to the interior of the tank, and the connecting pipe is fixedly installed inside the rotating blocks.

[0010] With the above technical solution, the mounting ring is locked inside the tank and rotates, ensuring that the rotating block is stably locked inside the tank and rotates. A sealing strip is set in the gap between the mounting ring and the tank to enhance the sealing of the tank and prevent the epoxy resin from leaking out of the tank when cooling. The connecting pipe is locked inside the rotating block and rotates stably.

[0011] Preferably, the spiral tube is fixedly installed between two connecting tubes, with both ends of the spiral tube communicating with the interiors of the two connecting tubes respectively. The driven gear is fixedly installed on the outer surface of the connecting tube located on the right, and the outer surface of the driven gear meshes with the outer surface of the driving gear.

[0012] Through the above technical solution, the driving gear drives the driven gear to rotate, which in turn drives the connecting pipe to rotate, thereby causing the spiral tube to rotate in the cooling tank and agitate the epoxy resin.

[0013] Preferably, a water pump is fixedly installed at the bottom of the water tank on the left, a circulation pipe is fixedly installed between the two water tanks, a circulation pump is fixedly installed at the bottom of the water tank on the right, the inside of the circulation pump is fixedly connected to the right end of the circulation pipe, a fixed pipe is fixedly installed at the right end of the water pump, and the inner side of the fixed pipe is rotatably connected to the outer surface of the left end of the connecting pipe on the left.

[0014] Through the above technical solution, the water pump draws water from the right connecting pipe into the spiral tube, then into the left connecting pipe and the water pump, and then pumps it into the left water tank. The circulation pump can pump the water from the left water tank into the right water tank through the circulation pipe, thus completing the water circulation. When the water passes through the spiral tube, it can carry away the heat of the epoxy resin. The continuous flow of water in the spiral tube cools the epoxy resin. Ice can be added to the water tank for further cooling.

[0015] The beneficial effects of this utility model are as follows:

[0016] By installing a heat removal device, the epoxy resin is first placed in a cooling tank for cooling. Then, a water pump and a circulation pump are started. The water pump draws water from the right connecting pipe into the spiral tube, then into the left connecting pipe and the water pump, and finally into the left water tank. The circulation pump pumps water from the left water tank into the right water tank through the circulation pipe, thus completing the water circulation. As the water passes through the spiral tube, it carries away the heat from the epoxy resin. The continuous flow of water in the spiral tube cools the epoxy resin. Then, the drive motor is started, causing the shaft to drive the drive gear to rotate. The drive gear drives the driven gear to rotate, which in turn rotates the connecting pipe, causing the spiral tube to rotate in the cooling tank, agitating the epoxy resin and enhancing the cooling effect. This achieves the effect of enhancing the cooling effect of the epoxy resin. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of a rapid cooling device for epoxy resin production according to the present invention.

[0018] Figure 2 This is a perspective view of the cooling tank structure of a rapid cooling device for epoxy resin production proposed in this utility model;

[0019] Figure 3 This is a cross-sectional view of the cooling tank structure of a rapid cooling device for epoxy resin production proposed in this utility model;

[0020] Figure 4 This is a perspective view of the connecting pipe structure of a rapid cooling device for epoxy adhesive production proposed in this utility model.

[0021] In the diagram: 1. Cooling tank; 11. Tank lid; 12. Tank body; 13. Heat dissipation hole; 14. Feed hopper; 15. Insert plate; 16. Rotating block; 17. Mounting ring; 2. Water tank; 21. Mounting plate; 22. Water pump; 23. Circulation pipe; 24. Circulation pump; 25. Fixed pipe; 3. Spiral pipe; 4. Connecting pipe; 5. Drive motor; 6. Drive gear; 7. Driven gear. Detailed Implementation

[0022] 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.

[0023] Reference Figures 1-4A rapid cooling device for epoxy resin production includes a cooling tank 1 and a water tank 2. To solve the problem of rapid cooling of epoxy resin and achieve the effect of removing heat from the epoxy resin by using a spiral tube 3, heat removal devices are installed inside both the cooling tank 1 and the water tank 2. The heat removal device includes a spiral tube 3, a connecting pipe 4, a drive motor 5, a drive gear 6, and a driven gear 7. The drive motor 5 controls the rotation of the drive gear 6, which drives the driven gear 7 to rotate. The driven gear 7 drives the connecting pipe 4 to rotate, and the connecting pipe 4 drives the spiral tube 3 to rotate.

[0024] like Figure 1 and Figure 2 As shown, in order to solve the control problem of the spiral tube 3 and achieve the effect of controlling the rotation of the spiral tube 3 with the drive motor 5, two water pools 2 are located on the left and right sides of the cooling tank 1 respectively. The outer surface of the water pool 2 on the right side is fixedly installed with a mounting plate 21. The drive motor 5 is fixedly installed inside the mounting plate 21, and the drive gear 6 is fixedly installed on the shaft of the drive motor 5. When the drive motor 5 starts, the shaft drives the drive gear 6 to rotate. The drive motor 5 is stably installed inside the mounting plate 21.

[0025] like Figure 3 As shown, in order to solve the sealing problem of cooling tank 1 and achieve the effect of sealing the gap between the insert plate 15 and the tank body 12 with a sealing strip, cooling tank 1 has a tank cover 11 and a tank body 12. The inside of the tank cover 11 is provided with heat dissipation holes 13. The inside of the tank cover 11 is fixedly installed with a feed hopper 14. The lower surface of the tank cover 11 is fixedly installed with an insert plate 15. The outer surface of the insert plate 15 is slidably connected to the upper end of the tank body 12. The feed hopper 14 facilitates feeding, and the heat dissipation holes 13 facilitate the faster dissipation of heat inside the cooling tank 1. A sealing strip is provided between the insert plate 15 and the tank body 12 to prevent epoxy resin from leaking out of the cooling tank 1. Horizontal plates are installed on both sides of the tank cover 11 and the tank body 12. The two horizontal plates are then fixed with bolts to make the tank cover 11 and the tank body 12 stably connected.

[0026] like Figure 3 As shown, in order to solve the stability problem of the rotating block 16 and achieve the effect of limiting the rotating block 16 by the mounting ring 17, the rotating blocks 16 are rotatably connected to the inside of both ends of the tank body 12. The mounting ring 17 is fixedly installed on the outer surface of the rotating block 16. The outer surface of the mounting ring 17 is rotatably connected to the inside of the tank body 12. The connecting pipe 4 is fixedly installed inside the rotating block 16. The mounting ring 17 is locked in the tank body 12 and rotates, ensuring that the rotating block 16 is stably locked in the tank body 12 and rotates. A sealing strip is set in the gap between the mounting ring 17 and the tank body 12 to enhance the sealing of the tank body 12 and prevent the epoxy resin from leaking out of the tank body 12 when cooling. The connecting pipe 4 is locked in the rotating block 16 and rotates stably.

[0027] like Figure 3As shown, in order to solve the control problem of the spiral tube 3 and achieve the effect of stable rotation of the spiral tube 3, the spiral tube 3 is fixedly installed between two connecting tubes 4. The two ends of the spiral tube 3 are respectively connected to the interior of the two connecting tubes 4. The driven gear 7 is fixedly installed on the outer surface of the connecting tube 4 located on the right. The outer surface of the driven gear 7 meshes with the outer surface of the driving gear 6. The driving gear 6 drives the driven gear 7 to rotate, which drives the connecting tube 4 to rotate, thereby causing the spiral tube 3 to rotate in the cooling tank 1 and agitate the epoxy resin.

[0028] like Figures 1 to 4 As shown, to solve the water control problem in pool 2 and achieve the effect of circulating water using a pump 22 and a circulation pump 24, a pump 22 is fixedly installed at the bottom of the pool 2 on the left, and a circulation pipe 23 is fixedly installed between the two pools 2. A circulation pump 24 is fixedly installed at the bottom of the pool 2 on the right. The inside of the circulation pump 24 is fixedly connected to the right end of the circulation pipe 23. A fixed pipe 25 is fixedly installed at the right end of the pump 22, and the inner side of the fixed pipe 25 is connected to the outer surface of the left end of the connecting pipe 4 on the left. The water pump 22 draws water from the right connecting pipe 4 into the spiral tube 3, then into the left connecting pipe 4 and the water pump 22, and finally into the left water tank 2. Meanwhile, the circulation pump 24 pumps the water from the left water tank 2 into the right water tank 2 through the circulation pipe 23, thus completing the water circulation. As the water passes through the spiral tube 3, it carries away the heat of the epoxy resin. The continuous flow of water in the spiral tube 3 cools the epoxy resin. Ice can be added to the water tank 2 for further cooling.

[0029] By setting up a heat removal device, when cooling the epoxy resin, the epoxy resin is first placed in the cooling tank 1, and then the water pump 22 and the circulation pump 24 are started. The water pump 22 draws water, which enters the spiral tube 3 from the right connecting pipe 4, then enters the left connecting pipe 4 and the water pump 22, and is then pumped into the left water tank 2. The circulation pump 24 pumps the water from the left water tank 2 into the right water tank 2 through the circulation pipe 23, thus completing the water circulation. When the water passes through the spiral tube 3, it can carry away the heat of the epoxy resin. The continuous flow of water in the spiral tube 3 cools the epoxy resin. Then, the drive motor 5 is started, which drives the shaft to drive the drive gear 6 to rotate. The drive gear 6 drives the driven gear 7 to rotate, which in turn drives the connecting pipe 4 to rotate, thereby causing the spiral tube 3 to rotate in the cooling tank 1, agitating the epoxy resin and enhancing the cooling effect. This achieves the effect of enhancing the cooling effect of the epoxy resin.

[0030] Working principle: When cooling epoxy resin, the epoxy resin is first placed in cooling tank 1. Then, water pump 22 and circulation pump 24 are started. Water pump 22 draws water into spiral tube 3 through connecting pipe 4 on the right, then into connecting pipe 4 on the left and water pump 22, and then into water pool 2 on the left. Meanwhile, circulation pump 24 pumps water from water pool 2 on the left into water pool 2 on the right through circulation pipe 23, thus completing water circulation. When water passes through spiral tube 3, it can carry away the heat of epoxy resin. The continuous flow of water in spiral tube 3 cools the epoxy resin. Then, drive motor 5 is started, causing the shaft to drive the drive gear 6 to rotate. Drive gear 6 drives the driven gear 7 to rotate, which in turn drives connecting pipe 4 to rotate. This causes spiral tube 3 to rotate in cooling tank 1, agitating the epoxy resin and enhancing the cooling effect.

[0031] The above are merely preferred embodiments of this utility model, but the scope of protection of this utility model is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in this utility model, based on the technical solution and inventive concept of this utility model, should be included within the scope of protection of this utility model.

Claims

1. A rapid cooling device for epoxy resin production, comprising a cooling tank (1) and a water pool (2), characterized in that: Both the cooling tank (1) and the water pool (2) are equipped with heat removal devices. The heat removal devices include a spiral tube (3), a connecting pipe (4), a drive motor (5), a drive gear (6), and a driven gear (7). The drive motor (5) controls the drive gear (6) to rotate. The drive gear (6) drives the driven gear (7) to rotate. The driven gear (7) drives the connecting pipe (4) to rotate. The connecting pipe (4) drives the spiral tube (3) to rotate.

2. The rapid cooling device for epoxy resin production according to claim 1, characterized in that: The two water tanks (2) are located on the left and right sides of the cooling tank (1), respectively. The outer surface of the water tank (2) on the right side is fixedly installed with an mounting plate (21). The drive motor (5) is fixedly installed inside the mounting plate (21), and the drive gear (6) is fixedly installed on the shaft of the drive motor (5).

3. The rapid cooling device for epoxy resin production according to claim 1, characterized in that: The cooling tank (1) has a tank cover (11) and a tank body (12). The tank cover (11) has a heat dissipation hole (13) inside. A feed hopper (14) is fixedly installed inside the tank cover (11). A plate (15) is fixedly installed on the lower surface of the tank cover (11). The outer surface of the plate (15) is slidably connected to the upper end of the tank body (12).

4. The rapid cooling device for epoxy resin production according to claim 3, characterized in that: Rotating blocks (16) are rotatably connected to the inside of both the left and right ends of the tank (12). An installation ring (17) is fixedly installed on the outer surface of the rotating block (16). The outer surface of the installation ring (17) is rotatably connected to the inside of the tank (12). The connecting pipe (4) is fixedly installed inside the rotating block (16).

5. The rapid cooling device for epoxy resin production according to claim 1, characterized in that: The spiral tube (3) is fixedly installed between two connecting tubes (4). The two ends of the spiral tube (3) are respectively connected to the interior of the two connecting tubes (4). The driven gear (7) is fixedly installed on the outer surface of the connecting tube (4) located on the right. The outer surface of the driven gear (7) meshes with the outer surface of the driving gear (6).

6. The rapid cooling device for epoxy resin production according to claim 1, characterized in that: A water pump (22) is fixedly installed at the bottom of the water pool (2) on the left side. A circulation pipe (23) is fixedly installed between the two water pools (2). A circulation pump (24) is fixedly installed at the bottom of the water pool (2) on the right side. The inside of the circulation pump (24) is fixedly connected to the right end of the circulation pipe (23). A fixed pipe (25) is fixedly installed at the right end of the water pump (22). The inside of the fixed pipe (25) is rotatably connected to the outer surface of the left end of the connecting pipe (4) on the left side.