A cooling device for mold fitting production
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 江苏佳亭智能科技有限公司
- Filing Date
- 2025-07-07
- Publication Date
- 2026-06-23
AI Technical Summary
Existing mold component cooling devices cannot provide multi-directional cooling, affecting component quality and production efficiency.
A cooling device for mold component production was designed, which uses a parts conveyor belt and multiple cooling components, including mounting piles, metal connecting plates, lifting cylinders, arc-shaped slides, fan mounting plates and fans. The lifting cylinder drives the fan to adjust the airflow direction, thereby achieving multi-directional cooling of the mold components.
It improves the cooling efficiency of mold components, ensuring that all surfaces can dissipate heat fully and cool down quickly to a suitable temperature to meet subsequent production requirements. In addition, the modular design of the device facilitates maintenance.
Smart Images

Figure CN224391833U_ABST
Abstract
Description
Technical Field
[0001] This utility model mainly relates to the technical field of mold component cooling, specifically a cooling device for mold component production. Background Technology
[0002] The cooling system for mold components is a crucial aspect of mold design, directly impacting the injection molding cycle, the molding quality of plastic products, and production efficiency. Using blowers or compressed air for cooling is simple, although its cooling efficiency is lower than water cooling. However, it eliminates the risk of corrosion and is the most cost-effective and widely applicable cooling method.
[0003] According to application number CN202121606292.5, a cooling device for mold parts production is provided, including: a cooling box, a water stain cleaning mechanism on one side of the cooling box, and a blower fixedly connected to the bottom of the cooling box on the side away from the water stain cleaning mechanism. This utility model has the following advantages: the cooled mold parts are guided onto the first absorbent cotton block by the guide inclined plate. When the sensor detects the water stain, the first electric telescopic rod is controlled to move the second absorbent cotton block downward. The first and second absorbent cotton blocks approach and squeeze each other to absorb the water stains on the surface of the mold parts. Then, the mold parts are further dried by the drying fan unit, reducing the subsequent cleaning process and reducing costs; the second electric telescopic rod moves the baffle to facilitate pushing the cooled mold parts away from the top of the cooling box; the push plate facilitates the scraping of debris on the surface of the filter screen.
[0004] In the aforementioned device, the cooling process for mold components cannot be carried out in multiple directions, which results in the components not being cooled effectively and affects their quality. Utility Model Content
[0005] Therefore, the purpose of this utility model is to provide a cooling device for the production of mold parts, so as to solve the technical problems mentioned in the background art.
[0006] To achieve the above objectives, this utility model provides the following technical solution:
[0007] A cooling device for mold component production includes a parts conveyor belt, with parts mounting side plates on both sides of the top of the parts conveyor belt, and multiple cooling components on the top of the parts mounting side plates.
[0008] The cooling component includes a mounting post on the top of the component mounting side plate, a metal connecting plate on one side wall of the mounting post, a lifting cylinder on one side of the metal connecting plate, an arc-shaped sliding groove embedded on one side of the mounting post, a connecting block on the actuating end of the lifting cylinder, a side connecting rod on one end of the connecting block, a fan mounting plate on one end of the side connecting rod, multiple side fans on one side of the fan mounting plate, and multiple top fans on the top of the fan mounting plate.
[0009] Preferably, the bottom of the mounting pile is provided with a through groove, which is located at the top of the parts conveyor belt.
[0010] Preferably, a limiting metal block is provided on one side wall of the telescopic cylinder, and the limiting metal block is rotatably connected to the side wall of the metal connecting plate.
[0011] Preferably, a slider is slidably connected to the inner wall of the arc-shaped groove, and one end of the slider is rotatably connected to the inner wall of the other end of the connecting block.
[0012] Preferably, one end of the fan mounting plate is provided with an S-shaped metal plate, the other end of the fan mounting plate is provided with an L-shaped straight plate, and the top of the L-shaped straight plate is provided with a horizontal connecting plate.
[0013] Preferably, the S-shaped metal plate is connected to the side wall of the top fan, the top fan is inclined, and the L-shaped straight plate is connected to the side wall of the side fan.
[0014] Preferably, the side wall of the parts conveyor belt is provided with a drive motor, and the bottom of the parts conveyor belt is provided with multiple support frames.
[0015] In summary, this technical solution has the following main advantages:
[0016] In this invention, the top of the mold component can be precisely cooled, removing the heat accumulated on the top. Through a multi-directional cooling layout, all surfaces of the mold component can be fully cooled, greatly improving cooling efficiency and ensuring that the mold component can be quickly cooled to a suitable temperature to meet the requirements of subsequent production processes. Furthermore, the device can adjust the blowing direction of the fan according to the actual situation, so that the airflow can act more precisely on the mold component, improving the targeting and effect of cooling.
[0017] Meanwhile, the device adopts a modular design and a reasonable spatial layout, with clear and unambiguous connections between various components; when the device malfunctions, maintenance personnel can quickly locate the problem and carry out targeted repairs or replacements. Attached Figure Description
[0018] Figure 1 This is an isometric view of the overall structure of this utility model;
[0019] Figure 2 Axonometric view of the cooling component structure of this utility model Figure 1 ;
[0020] Figure 3 Axonometric view of the cooling component structure of this utility model Figure 2 ;
[0021] Figure 4 This is an isometric view of a portion of the cooling component of this utility model;
[0022] Figure 5 This is an isometric drawing of the specific structure of the mounting pile, the telescopic cylinder, and the fan mounting plate of this utility model.
[0023] Figure descriptions: 10. Parts conveyor belt; 11. Component mounting side plate; 20. Cooling component; 21. Mounting pile; 22. Metal connecting plate; 23. Lifting cylinder; 24. Arc-shaped chute; 25. Connecting block; 26. Side connecting support rod; 27. Fan mounting plate; 28. Side fan; 29. Top fan; 211. Through groove; 231. Limiting metal block; 241. Slider; 271. S-shaped metal plate; 272. L-shaped straight plate; 273. Horizontal connecting plate; 12. Drive motor; 13. Support frame. Detailed Implementation
[0024] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.
[0025] Example
[0026] like Figures 1 to 5 As shown, a cooling device for mold component production includes a parts conveyor belt 10, parts mounting side plates 11 on both sides of the top of the parts conveyor belt 10, and multiple cooling components 20 on the top of the parts mounting side plates 11.
[0027] The cooling component 20 includes a mounting post 21 on the top of the component mounting side plate 11, a metal connecting plate 22 on one side wall of the mounting post 21, a lifting cylinder 23 on one side of the metal connecting plate 22, an arc-shaped sliding groove 24 embedded on one side of the mounting post 21, a connecting block 25 on the actuating end of the lifting cylinder 23, a side connecting support rod 26 on one end of the connecting block 25, a fan mounting plate 27 on one end of the side connecting support rod 26, a plurality of side fans 28 on one side of the fan mounting plate 27, and a plurality of top fans 29 on the top of the fan mounting plate 27.
[0028] The bottom of the mounting pile 21 is provided with a through groove 211, which is located at the top of the parts conveyor belt 10.
[0029] The lifting cylinder 23 has a limiting metal block 231 on one side wall, and the limiting metal block 231 is rotatably connected to the side wall of the metal connecting plate 22.
[0030] A slider 241 is slidably connected to the inner wall of the arc-shaped groove 24. One end of the slider 241 is rotatably connected to the inner wall of the other end of the connecting block 25.
[0031] One end of the fan mounting plate 27 is provided with an S-shaped metal plate 271, and the other end of the fan mounting plate 27 is provided with an L-shaped straight plate 272. The top of the L-shaped straight plate 272 is provided with a horizontal connecting plate 273.
[0032] The S-shaped metal plate 271 is connected to the side wall of the top fan 29, the top fan 29 is set at an angle, and the L-shaped straight plate 272 is connected to the side wall of the side fan 28.
[0033] The side wall of the parts conveyor belt 10 is equipped with a drive motor 12, and the bottom of the parts conveyor belt 10 is equipped with multiple support frames 13.
[0034] It should be noted that in this embodiment, the overall structure is arranged around the parts conveyor belt 10; the parts conveyor belt 10 is the core component for conveying mold parts, and a drive motor 12 is installed on its side wall. The drive motor 12 provides power so that the parts conveyor belt 10 can operate continuously and stably, realizing the conveying of mold parts on the production line.
[0035] Multiple support frames 13 are provided at the bottom of the parts conveyor belt 10. The support frames 13 are evenly distributed around the bottom of the parts conveyor belt 10 to provide stable support for the parts conveyor belt 10, ensuring that it remains stable during operation and avoiding the impact of shaking on the conveying accuracy of mold parts.
[0036] On both sides of the top of the parts conveyor belt 10, symmetrical component mounting side plates 11 are arranged; the component mounting side plates 11 serve to fix and support the cooling component 20, provide a stable mounting platform for the cooling component 20, and ensure that the cooling component 20 can effectively cool the mold parts passing by in a suitable position.
[0037] Multiple mounting posts 21 are provided on the top of the component mounting side plate 11. The bottom of the mounting posts 21 is provided with a through groove 211, which is located on the top of the component conveyor belt 10. This design ensures that the mounting posts 21 can maintain their own stability without obstructing the normal operation of the component conveyor belt 10. The existence of the through groove 211 also provides space for some necessary lines or airflow channels.
[0038] A metal connecting plate 22 is fixed to one side wall of the mounting pile 21, which provides an installation base for the telescopic cylinder 23. A limiting metal block 231 is set on one side wall of the telescopic cylinder 23, and the limiting metal block 231 is rotatably connected to the side wall of the metal connecting plate 22. This rotatable connection allows the telescopic cylinder 23 to have a certain degree of freedom of movement when working, while the limiting metal block 231 ensures that the telescopic cylinder 23 will not shake at will, thus ensuring its working stability.
[0039] A connecting block 25 is provided at the actuator end of the telescopic cylinder 23. One end of the connecting block 25 is fixedly connected to the actuator end of the telescopic cylinder 23, and the other end is connected to one end of the side connecting support rod 26. The side connecting support rod 26 serves to connect and support the fan mounting plate 27, and its other end is fixedly connected to the fan mounting plate 27.
[0040] An arc-shaped groove 24 is embedded on one side of the mounting pile 21. A slider 241 is slidably connected to the inner wall of the arc-shaped groove 24. One end of the slider 241 is rotatably connected to the inner wall of the other end of the connecting block 25. When the lifting cylinder 23 is working, its actuator pushes the connecting block 25 to move. The connecting block 25 adjusts the angle of the fan mounting plate 27 by sliding the slider 241 in the arc-shaped groove 24. This design allows the fan mounting plate 27 to flexibly adjust the airflow direction of the fan according to different cooling needs, thereby improving the cooling effect.
[0041] One end of the fan mounting plate 27 is provided with an S-shaped metal plate 271, and the other end is provided with an L-shaped straight plate 272. The top of the L-shaped straight plate 272 is provided with a horizontal connecting plate 273. The S-shaped metal plate 271 is connected to the side wall of the top fan 29. The top fan 29 is set at an angle. This angled setting allows the airflow generated by the top fan 29 to better cover the top area of the mold parts, thereby improving the top cooling efficiency.
[0042] The L-shaped straight plate 272 is connected to the side wall of the side fan 28. The side fan 28 can cool the side of the mold parts. In conjunction with the top fan 29, it can achieve multi-directional cooling of the mold parts.
[0043] The working principle of this utility model is as follows:
[0044] When the mold components move along the parts conveyor belt 10 to the area below the cooling component 20, the drive motor 12 drives the parts conveyor belt 10 to run continuously, ensuring that the mold components can pass smoothly through the cooling area; the lifting cylinder 23 starts to work according to the preset program or the information fed back by the sensor. The lifting cylinder 23 is equipped with the necessary air pump, air circuit, control element and related circuit, which are conventional existing technology and will not be described in detail.
[0045] The actuator drives the connecting block 25 to move, and the connecting block 25 slides within the arc-shaped groove 24 via the slider 241, causing the fan mounting plate 27 to adjust to a suitable angle. The top fan 29 and the side fan 28 start simultaneously. The inclined airflow generated by the top fan 29 blows over the top of the mold component, carrying away the heat from the top of the mold component; the airflow generated by the side fan 28 blows over the side of the mold component, cooling the side of the mold component. Through the coordinated work of the top fan 29 and the side fan 28, the temperature of the mold component can be quickly reduced, the cooling efficiency can be improved, and the quality of the mold component in subsequent production stages can be guaranteed.
[0046] The above embodiments are only for illustrating the technical concept of this utility model and should not be construed as limiting the scope of protection of this utility model. Any modifications made to the technical solution based on the technical concept proposed by this utility model shall fall within the scope of protection of this utility model.
Claims
1. A cooling device for mold component production, comprising a parts conveyor belt (10), characterized in that... The top two sides of the part conveyor belt (10) are provided with part placement side plates (11), and the top of the part placement side plates (11) is provided with multiple cooling components (20); The cooling component (20) includes a mounting post (21) on the top of the component mounting side plate (11), a metal connecting plate (22) on one side wall of the mounting post (21), a lifting cylinder (23) on one side of the metal connecting plate (22), an arc-shaped sliding groove (24) embedded on one side of the mounting post (21), a connecting block (25) on the actuating end of the lifting cylinder (23), a side connecting support rod (26) on one end of the connecting block (25), a fan mounting plate (27) on one end of the side connecting support rod (26), a plurality of side fans (28) on one side of the fan mounting plate (27), and a plurality of top fans (29) on the top of the fan mounting plate (27).
2. The cooling device for mold component production according to claim 1, characterized in that, The bottom of the mounting pile (21) is provided with a through groove (211), which is located at the top of the parts conveyor belt (10).
3. The cooling device for mold component production according to claim 1, characterized in that, The lifting cylinder (23) has a limiting metal block (231) on one side wall, and the limiting metal block (231) is rotatably connected to the side wall of the metal connecting plate (22).
4. A cooling device for mold component production according to claim 1, characterized in that, The inner wall of the arc-shaped groove (24) is slidably connected to a slider (241), and one end of the slider (241) is rotatably connected to the inner wall of the other end of the connecting block (25).
5. A cooling device for mold component production according to claim 1, characterized in that, The fan mounting plate (27) has an S-shaped metal plate (271) at one end and an L-shaped straight plate (272) at the other end. The L-shaped straight plate (272) has a horizontal connecting plate (273) at the top.
6. A cooling device for mold component production according to claim 5, characterized in that, The S-shaped metal plate (271) is connected to the side wall of the top fan (29), the top fan (29) is inclined, and the L-shaped straight plate (272) is connected to the side wall of the side fan (28).
7. A cooling device for mold component production according to claim 1, characterized in that, The side wall of the parts conveyor belt (10) is provided with a drive motor (12), and the bottom of the parts conveyor belt (10) is provided with multiple support frames (13).