Cooling and discharging device for silica gel mixing mill
By introducing a water pump, heat-conducting plate, and air box structure into the cooling and unloading device of the silicone mixer, combined with a servo motor-driven rotating shaft and discharge shaft, rapid cooling and heat dissipation of silicone are achieved, solving the problem of poor cooling effect of existing devices.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- KUNSHAN TAILOKE SEALING TECHNOLOGY CO LTD
- Filing Date
- 2025-08-01
- Publication Date
- 2026-06-26
AI Technical Summary
The existing silicone mixer cooling and unloading device does not provide sufficient cooling effect for silicone after water cooling, and air cooling is required to enhance the cooling effect.
A cooling and unloading device is designed, which includes a water tank, a water pump, a conduit, a heat dissipation structure, and a fan box. The rotating shaft and the discharge shaft are driven to rotate by a servo motor. Combined with the cooling structure of heat conduction plate and heat sink, rapid cooling is achieved by blowing air from the fan box and circulating cooling water.
This achieves rapid cooling and heat dissipation of the silicone, prevents material blockage, and improves the cooling effect.
Smart Images

Figure CN224408117U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of silicone processing technology, and in particular to a cooling and unloading device for a silicone mixing machine. Background Technology
[0002] Silica gel is a porous material with different particle sizes formed by the appropriate dehydration of silica gel. A silicone mixer is a mechanical device used to mix and plasticize silicone materials. It is mainly used to uniformly mix silicone raw materials with various additives to prepare high-quality silicone products. The silicone mixer breaks the silicone macromolecular chains through the squeezing and shearing action of the rollers, and the various components are evenly distributed, thereby achieving the purpose of mixing. The silicone mixer cooling and unloading device is a key piece of equipment in the rubber industry for cooling and discharging silicone after mixing.
[0003] Modern silicone mixing mill cooling and unloading devices can basically meet people's needs, but some problems still exist, as detailed below:
[0004] When in use, the cooling and unloading device of the silicone mixer may not be able to cool the discharged silicone well enough after water cooling, and the silicone needs to be air-cooled to enhance the cooling effect. Utility Model Content
[0005] The purpose of this invention is to provide a cooling and unloading device for a silicone mixer, in order to solve the problem that existing cooling and unloading devices for silicone mixers are unable to enhance the cooling effect.
[0006] To solve the above-mentioned technical problems, this utility model provides the following technical solution: a cooling and unloading device for a silicone mixing mill, including a base;
[0007] A water tank is installed at the top of the base, a water pump is installed on one side of the top of the water tank, and a conduit is installed at the top of the water pump.
[0008] A bracket is installed at the top of the base, a housing is installed at the top of the bracket, an inlet is installed on one side of the top of the housing, and an outlet is installed on one side of the bottom of the housing.
[0009] A heat dissipation structure is installed on one side of the outer casing. The heat dissipation structure includes a fan box installed on one side of the outer casing, and a connecting shaft installed at the top inside the fan box.
[0010] In use, the silicone material is first loaded into the shell through the inlet. The servo motor then drives the rotating shaft to rotate, which in turn drives the discharge shaft to rotate. The discharge shaft is spiral in shape, and its rotation causes the silicone material inside the shell to move. After the silicone material moves, it is discharged through the outlet. This allows for frequent silicone discharge. Cooling water circulates inside the conduit, which cools the silicone material inside the shell.
[0011] Furthermore, a discharge mechanism is installed inside the housing. The discharge mechanism includes a servo motor installed on one side of the housing and a rotating shaft installed on one side of the servo motor. The discharge mechanism can discharge materials quickly.
[0012] Furthermore, a discharge shaft is installed on the outer side of the rotating shaft. The discharge shaft is spiral in shape and can drive the silicone to move.
[0013] Furthermore, a cooling structure is installed on the outer side of one side of the conduit. The cooling structure includes a heat-conducting plate installed on the outer side of one side of the conduit, a heat sink installed on the outer side of the heat-conducting plate, and heat dissipation holes provided inside the heat sink. The cooling structure can quickly dissipate heat from the silicone.
[0014] Furthermore, the heat sinks are arranged at equal intervals on the outer side of the heat-conducting plate, and the heat sinks are distributed in a ring shape, so that the heat sinks can quickly dissipate heat from the cooling water.
[0015] Furthermore, a first gear is installed on one side of the connecting shaft, and a second gear is provided at the bottom of the first gear. A fan blade is installed on one side of the second gear. The rotation of the first gear will drive the second gear to rotate, and the rotation of the second gear will drive the fan blade to rotate.
[0016] Furthermore, a through hole is provided on one side of the bellows, and the through holes are arranged at equal intervals on one side of the bellows, through which air can be blown.
[0017] The advantages of the silicone mixing mill cooling and unloading device provided by this utility model are: during use, the discharged silicone can be cooled by the heat dissipation structure to improve the cooling effect; the silicone material can be discharged by the discharge mechanism to prevent material discharge blockage; and the cooling water can be quickly cooled by the cooling structure.
[0018] By installing a connecting shaft on one side of the rotating shaft, when the servo motor drives the rotating shaft to rotate, the connecting shaft and the rotating shaft are connected together. The rotation of the rotating shaft will drive the connecting shaft to rotate, and the rotation of the connecting shaft will drive the first gear to rotate. The first gear and the second gear mesh with each other. The rotation of the first gear will drive the second gear to rotate, and the rotation of the second gear will drive the fan blades to rotate. The rotation of the fan blades will blow air out through the through hole, which can quickly cool and dissipate heat from the discharged silicone. This achieves the purpose of enhancing the cooling effect of the silicone mixing machine cooling unloading device.
[0019] By installing a heat-conducting plate at the bottom of one side of the conduit, and the heat-conducting plate and heat sink at the bottom of one side of the conduit being made of brass, the heat-conducting plate can absorb the heat of the cooling water, and then the heat can be quickly dissipated through the heat sink. The heat dissipation holes can increase the surface area of the heat sink, allowing the heat sink to quickly dissipate heat from the cooling water, so that the cooling water can be quickly cooled and circulated. This achieves the purpose of accelerating the cooling speed of the cooling water in the silicone mixer cooling unloading device. Attached Figure Description
[0020] Figure 1 This is a three-dimensional structural schematic diagram of the present invention;
[0021] Figure 2 This is a three-dimensional structural schematic diagram of the present invention;
[0022] Figure 3 This is a three-dimensional cross-sectional structural diagram of the heat dissipation structure of this utility model;
[0023] Figure 4 This is a three-dimensional structural diagram of the cooling structure of this utility model;
[0024] Figure 5 This is a three-dimensional structural diagram of the discharge mechanism of this utility model.
[0025] The following are the annotations in the figure: 1. Outer shell; 2. Discharge mechanism; 201. Servo motor; 202. Rotating shaft; 203. Discharge shaft; 3. Support; 4. Base; 5. Water tank; 6. Water pump; 7. Pipe; 8. Cooling structure; 801. Heat conduction plate; 802. Heat sink; 803. Heat dissipation hole; 9. Heat dissipation structure; 901. First gear; 902. Second gear; 903. Fan blade; 904. Through hole; 905. Connecting shaft; 906. Air box; 10. Outlet; 11. Inlet. Detailed Implementation
[0026] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0027] Please see Figures 1-5 One embodiment of this utility model is a cooling and unloading device for a silicone mixing machine, which includes a base 4.
[0028] A water tank 5 is installed at the top of the base 4. A water pump 6 is installed on one side of the top of the water tank 5. A conduit 7 is installed at the top of the water pump 6. A cooling structure 8 is installed on the outer side of one side of the conduit 7. The cooling structure 8 includes a heat-conducting plate 801 installed on the outer side of one side of the conduit 7. Heat sinks 802 are installed on the outer side of the heat-conducting plate 801. The heat sinks 802 are arranged at equal intervals on the outer side of the heat-conducting plate 801. The heat sinks 802 are distributed in a ring. Heat dissipation holes 803 are provided inside the heat sinks 802.
[0029] See attached document Figure 1 and attached Figure 4 As shown, the operation of the water pump 6 will drive the cooling water inside the water tank 5 to be drawn out. The drawn-out cooling water can enter the inside of the conduit 7. The conduit 7 is wrapped around the surface of the outer shell 1. The cooling water flows inside the conduit 7 and can absorb the heat of the silicone inside the outer shell 1, thus cooling the silicone. Before the conduit 7 circulates back into the water tank 5, the heat-conducting plate 801 and the heat sink 802 at the bottom of one side of the conduit 7 are made of brass. The heat-conducting plate 801 can absorb the heat of the cooling water, and then the heat sink 802 can quickly dissipate the heat. The heat dissipation hole 803 can increase the surface area of the heat sink 802, allowing the heat sink 802 to quickly dissipate the cooling water, so that the cooling water can be quickly cooled and circulated.
[0030] A bracket 3 is installed at the top of the base 4, and a housing 1 is installed at the top of the bracket 3. A discharge mechanism 2 is installed inside the housing 1. The discharge mechanism 2 includes a servo motor 201 installed on one side of the housing 1, a rotating shaft 202 installed on one side of the servo motor 201, and a discharge shaft 203 installed on the outside of the rotating shaft 202. The discharge shaft 203 is spiral in shape.
[0031] A discharge shaft 203 is installed on the outside of the rotating shaft 202. The discharge shaft 203 is spiral in shape.
[0032] See attached document Figure 2 and attached Figure 5 As shown, after the silicone material is loaded into the shell 1 through the inlet 11, the servo motor 201 will drive the rotating shaft 202 to rotate. The rotation of the rotating shaft 202 will drive the discharge shaft 203 to rotate. The discharge shaft 203 is spiral in shape. The rotation of the discharge shaft 203 will drive the silicone material inside the shell 1 to move. After the silicone material moves, it will be discharged through the outlet 10. This allows for frequent discharge of silicone. Cooling water circulates inside the conduit 7, which can cool the silicone material inside the shell 1.
[0033] An inlet 11 is installed on one side of the top of the outer casing 1, and an outlet 10 is installed on one side of the bottom of the outer casing 1.
[0034] A heat dissipation structure 9 is installed on one side of the outer casing 1. The heat dissipation structure 9 includes a fan box 906 installed on one side of the outer casing 1. A through hole 904 is provided on one side of the fan box 906. The through holes 904 are arranged at equal intervals on one side of the fan box 906.
[0035] A connecting shaft 905 is installed at the top of the inside of the bellows 906. A first gear 901 is installed on one side of the connecting shaft 905, and a second gear 902 is provided at the bottom of the first gear 901. A fan blade 903 is installed on one side of the second gear 902.
[0036] See attached document Figure 1-3 As shown, when the servo motor 201 drives the rotating shaft 202 to rotate, the connecting shaft 905 and the rotating shaft 202 are connected together. The rotation of the rotating shaft 202 will drive the connecting shaft 905 to rotate, and the rotation of the connecting shaft 905 will drive the first gear 901 to rotate. The first gear 901 and the second gear 902 mesh with each other. The rotation of the first gear 901 will drive the second gear 902 to rotate, and the rotation of the second gear 902 will drive the fan blade 903 to rotate. The rotation of the fan blade 903 will blow air out through the through hole 904, which can quickly cool and dissipate heat from the discharged silicone.
[0037] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A cooling and unloading device for a silicone mixing mill, including a base (4); Its features are: A water tank (5) is installed at the top of the base (4), a water pump (6) is installed on one side of the top of the water tank (5), and a conduit (7) is installed at the top of the water pump (6). A bracket (3) is installed at the top of the base (4), a shell (1) is installed at the top of the bracket (3), an inlet (11) is installed on one side of the top of the shell (1), and an outlet (10) is installed on one side of the bottom of the shell (1). A heat dissipation structure (9) is installed on one side of the outer shell (1). The heat dissipation structure (9) includes a bellows (906) installed on one side of the outer shell (1). A connecting shaft (905) is installed at the top inside the bellows (906).
2. The silicone mixer cooling and unloading device according to claim 1, characterized in that: The discharge mechanism (2) is installed inside the outer shell (1). The discharge mechanism (2) includes a servo motor (201) installed on one side of the outer shell (1) and a rotating shaft (202) installed on one side of the servo motor (201).
3. The silicone rubber mixer cooling and unloading device according to claim 2, characterized in that: A discharge shaft (203) is installed on the outside of the rotating shaft (202), and the discharge shaft (203) is spiral in shape.
4. The silicone mixer cooling and unloading device according to claim 1, characterized in that: A cooling structure (8) is installed on the outer side of one side of the conduit (7). The cooling structure (8) includes a heat-conducting plate (801) installed on the outer side of one side of the conduit (7), a heat sink (802) installed on the outer side of the heat-conducting plate (801), and heat dissipation holes (803) are provided inside the heat sink (802).
5. The silicone mixer cooling and unloading device according to claim 4, characterized in that: The heat sinks (802) are arranged at equal intervals on the outside of the heat-conducting plate (801), and the heat sinks (802) are distributed in a ring.
6. The silicone rubber mixer cooling and unloading device according to claim 1, characterized in that: A first gear (901) is installed on one side of the connecting shaft (905), and a second gear (902) is provided at the bottom end of the first gear (901). A fan blade (903) is installed on one side of the second gear (902).
7. The silicone rubber mixer cooling and unloading device according to claim 6, characterized in that: The bellows (906) has a through hole (904) on one side, and the through holes (904) are arranged at equal intervals on one side of the bellows (906).