A cooling device for mining cable production
By designing a cooling and drying component for mining cable production, the problem of residual moisture on the material surface and resource waste has been solved, achieving efficient cooling and drying, improving production efficiency and saving water resources.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI KEYUAN CABLE GRP CO LTD
- Filing Date
- 2025-07-04
- Publication Date
- 2026-07-14
AI Technical Summary
Existing cooling devices for mining cable production use water cooling, which easily leaves moisture on the surface of materials, affecting subsequent processing and resulting in the ineffective recycling of water resources and waste.
A cooling device for mining cable production, comprising a cooling component and a drying component, was designed. The device utilizes a water pump to recycle water resources and employs a drying component to rapidly dry the material surface. By combining inclined block and airflow drying technologies, the device improves cooling and drying efficiency.
This technology enables rapid cooling and drying of materials, improving production efficiency and product quality while conserving water resources and achieving water recycling.
Smart Images

Figure CN224489988U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of mining cable production equipment, and in particular to a cooling device for mining cable production. Background Technology
[0002] Cooling devices in mining cable production are key equipment in cable production lines, primarily used for rapidly cooling the insulation and sheath layers of extruded cables. Their core function is to control the flow rate, temperature, and contact method of the cooling medium (such as water or air) to quickly solidify and shape the cable material at high temperatures, ensuring that the cable's physical and electrical properties meet standard requirements. The material extruded from the extruder is at a high temperature and needs timely cooling and shaping because cable insulation and sheath layers are typically made of polymers such as plastics (e.g., polyethylene, polyvinyl chloride) or rubber, which are melted and extruded at high temperatures. Cooling allows the molten material to solidify rapidly, preventing deformation, adhesion, or structural instability caused by excessively high temperatures.
[0003] Currently, most existing cooling devices use water cooling. After the cable insulation and sheath layers are extruded, they are directly immersed in flowing cold water when passing through a water tank. The high specific heat capacity of water is used to quickly remove heat. However, this method makes it easy for moisture to remain on the surface of the material, which not only affects subsequent processing, but also prevents the effective recycling of the moisture, resulting in a waste of water resources. Utility Model Content
[0004] To solve the above-mentioned technical problems, this utility model provides a cooling device for the production of mining cables.
[0005] This utility model is achieved using the following technical solution: a cooling device for producing mining cables, comprising an extruder body for producing cables, a cooling component capable of rapidly cooling the extruded material on one side of the extruder body, and a drying component capable of rapidly drying the surface of the material on one side of the cooling component, the cooling component comprising a cooling box disposed on one side of the extrusion port of the extruder body, a water storage tank disposed at the bottom of the cooling box, a water pump disposed on one side of the water storage tank, an inlet pipe fixedly connected to the inlet end of the water pump, an outlet pipe fixedly connected to the outlet end of the water pump, one end of the inlet pipe fixedly connected to the bottom of one side of the water storage tank, and one end of the outlet pipe fixedly connected to one side of the cooling box.
[0006] Through the above technical solution, the water pump draws water from the water storage tank and delivers it to the cooling box through the water outlet pipe to cool the extruded material. The cooled water then flows back to the water storage tank, realizing the recycling of water resources and improving cooling efficiency.
[0007] As a further improvement to the above solution, an inclined block arranged in a right-angled triangle is fixedly installed at one end inside the cooling box, and one right-angled side of the inclined block is in contact with the inner wall of the cooling box.
[0008] Through the above technical solution, the tilting block can change the moving position of the extruded material, making it easier for the material to come out of the cooling box.
[0009] As a further improvement to the above solution, the bottom side of the cooling box has two symmetrically arranged first collection ports, and the top of the water storage tank has two symmetrically arranged second collection ports, with each first collection port connected to the adjacent second collection port.
[0010] Through the above technical solution, the water in the cooling box flows back to the water storage tank through the first collection port and the second collection port, ensuring the recycling of water resources.
[0011] As a further improvement to the above solution, the drying assembly includes a drying cylinder fixedly installed on one side of the cooling box. An installation port is opened on one side of the drying cylinder, and an installation box is fixedly installed on the installation port. A drive motor is fixedly installed inside the installation box, and a rotating rod is fixedly installed on the output end of the drive motor. Multiple fan blades arranged in a ring array are fixedly installed on the cylindrical surface of the rotating rod.
[0012] The above technical solution drives the motor to rotate the rotating rod and fan blades, generating airflow to dry the surface of the cooled material, thereby improving drying efficiency.
[0013] As a further improvement to the above solution, a collection groove is provided on the bottom side of the inner cavity of the drying cylinder, a third collection port is provided on the bottom of the inner wall of the collection groove, and a fourth collection port is provided on one side of the top of the water storage tank, with the third collection port and the fourth collection port connected together.
[0014] Through the above technical solution, during the drying process, the water blown away by the wind gathers in the collection tank, and then flows back to the water storage tank through the collection tank, the third collection port and the fourth collection port, further realizing the recycling of water resources.
[0015] As a further improvement to the above solution, a support plate is fixedly installed at the bottom of the water storage tank, and multiple support rods are fixedly installed at the top of the support plate. The top of each support rod is fixedly installed to a cooling box or a drying cylinder, and the water pump is fixedly installed at the top of the support plate.
[0016] Through the above technical solution, the support plate and support rod provide support and fixation for the cooling box, drying cylinder and water pump, ensuring the stability of the device.
[0017] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0018] This invention enables rapid cooling and drying of extruded materials by incorporating cooling and drying components, thereby improving production efficiency and product quality. Simultaneously, the inclusion of a water storage tank, water pump, inlet pipe, and outlet pipe facilitates water recycling, conserving water resources. Attached Figure Description
[0019] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0020] Figure 2 This is a schematic diagram of the structure of the present invention with a cooling component;
[0021] Figure 3 This is a cross-sectional structural diagram of the present invention, which includes a drying box and a water storage tank.
[0022] Explanation of key symbols:
[0023] 1. Extruder body; 201. Cooling box; 202. Water storage tank; 203. Water pump; 204. Water inlet pipe; 205. Water outlet pipe; 301. Drying cylinder; 302. Mounting box; 303. Drive motor; 304. Rotating rod; 305. Fan blade; 4. Inclined block; 5. First collection port; 6. Second collection port; 7. Collection trough; 8. Third collection port; 9. Fourth collection port; 10. Support plate; 11. Support rod. Detailed Implementation
[0024] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. It should be noted that, without conflict, the various embodiments or technical features described below can be arbitrarily combined to form new embodiments.
[0025] Please combine Figures 1-3 This embodiment of a cooling device for producing mining cables includes an extruder body 1 for producing cables. One side of the extruder body 1 is provided with a cooling component that can rapidly cool the extruded material, and one side of the cooling component is provided with a drying component that can rapidly dry the surface of the material.
[0026] The cooling assembly includes a cooling box 201 disposed on one side of the extrusion port of the extruder body 1. A water storage tank 202 is provided at the bottom of the cooling box 201. A water pump 203 is provided on one side of the water storage tank 202. The water inlet end of the water pump 203 is fixedly connected to a water inlet pipe 204, and the water outlet end of the water pump 203 is fixedly connected to a water outlet pipe 205. One end of the water inlet pipe 204 is fixedly connected to the bottom of one side of the water storage tank 202, and one end of the water outlet pipe 205 is fixedly connected to one side of the cooling box 201.
[0027] The water pump 203 draws water from the water storage tank 202 and delivers it to the cooling box 201 through the water outlet pipe 205 to cool the extruded material. The cooled water then flows back to the water storage tank 202, realizing the recycling of water resources and improving cooling efficiency.
[0028] An inclined block 4 arranged in a right-angled triangle is fixedly installed at one end inside the cooling box 201, and the right-angled side of one side of the inclined block 4 is in contact with the inner wall of the cooling box 201.
[0029] The tilting block 4 can change the movement position of the extruded material, making it easier for the material to come out of the cooling box 201.
[0030] The cooling box 201 has two symmetrically arranged first collection ports 5 on its bottom side, and the water storage tank 202 has two symmetrically arranged second collection ports 6 on its top side. Each first collection port 5 is connected to the adjacent second collection port 6.
[0031] Water in the cooling box 201 flows back to the water storage tank 202 through the first collection port 5 and the second collection port 6, ensuring the recycling of water resources.
[0032] The drying assembly includes a drying cylinder 301 fixedly installed on one side of the cooling box 201. A mounting port is provided on one side of the drying cylinder 301, and a mounting box 302 is fixedly installed on the mounting port. A drive motor 303 is fixedly installed inside the mounting box 302. A rotating rod 304 is fixedly installed on the output end of the drive motor 303. Multiple fan blades 305 arranged in a ring array are fixedly installed on the cylindrical surface of the rotating rod 304.
[0033] The drive motor 303 drives the rotating rod 304 and the fan blade 305 to rotate, generating airflow to dry the surface of the cooled material and improve drying efficiency.
[0034] A collection trough 7 is provided on the bottom side of the inner cavity of the drying cylinder 301. A third collection port 8 is provided on the bottom of the inner wall of the collection trough 7. A fourth collection port 9 is provided on one side of the top of the water storage tank 202. The third collection port 8 and the fourth collection port 9 are connected.
[0035] During the drying process, the water blown away by the wind gathers in the collection tank 7, and flows back to the water storage tank 202 through the collection tank 7, the third collection port 8 and the fourth collection port 9, further realizing the recycling of water resources.
[0036] A support plate 10 is fixedly installed at the bottom of the water storage tank 202, and multiple support rods 11 are fixedly installed at the top of the support plate 10. The top of each support rod 11 is fixedly installed to the cooling box 201 or the drying cylinder 301. The water pump 203 is fixedly installed at the top of the support plate 10.
[0037] The support plate 10 and support rod 11 provide support and fixation for the cooling box 201, drying cylinder 301 and water pump 203, ensuring the stability of the device.
[0038] The implementation principle of a cooling device for producing mining cables in this embodiment is as follows: the material extruded from the extruder body 1 enters the cooling box 201, and the water pump 203 draws water from the water storage tank 202 and delivers it to the cooling box 201 through the water outlet pipe 205 to cool the material.
[0039] The cooled water flows back to the water storage tank 202 through the first collection port 5 and the second collection port 6.
[0040] When the cooled material moves, it will be lifted by the tilting block 4 to avoid being blocked by the inner wall of the cooling box 201 and unable to move into the drying cylinder 301. After the material enters the drying cylinder 301, the drive motor 303 drives the rotating rod 304 and the fan blade 305 to rotate, generating airflow to dry the surface of the material.
[0041] During the drying process, the wind will blow the water remaining on the surface of the material and the water remaining at the bottom of the inner cavity of the drying cylinder 301 together, and blow the water to one side of the collection tank 7 to collect it. The collected water flows back to the water storage tank 202 through the collection tank 7, the third collection port 8 and the fourth collection port 9, realizing the recycling of water resources.
[0042] The support plate 10 and the support rod 11 provide support and fixation for the entire device, ensuring its stable operation.
[0043] Furthermore, due to the large size of the water storage tank 202, it is difficult for the water circulating inside to be heated to a very high temperature by the heat of the material.
[0044] The above embodiments are merely preferred embodiments of this utility model and should not be construed as limiting the scope of protection of this utility model. Any non-substantial changes and substitutions made by those skilled in the art based on this utility model shall fall within the scope of protection claimed by this utility model.
Claims
1. A cooling device for producing mining cables, comprising an extruder body (1) for producing cables, characterized in that, The extruder body (1) is provided with a cooling component on one side that can rapidly cool the extruded material, and a drying component on one side that can rapidly dry the surface of the material. The cooling component includes a cooling box (201) located on one side of the extrusion port of the extruder body (1). A water storage tank (202) is located at the bottom of the cooling box (201). A water pump (203) is located on one side of the water storage tank (202). The water inlet end of the water pump (203) is fixedly connected to a water inlet pipe (204), and the water outlet end of the water pump (203) is fixedly connected to a water outlet pipe (205). One end of the water inlet pipe (204) is fixedly connected to the bottom of one side of the water storage tank (202), and one end of the water outlet pipe (205) is fixedly connected to one side of the cooling box (201).
2. The cooling device for mining cable production as described in claim 1, characterized in that, An inclined block (4) arranged in a right-angled triangle is fixedly installed at one end inside the cooling box (201), and the right-angled side of the inclined block (4) is in contact with the inner wall of the cooling box (201).
3. The cooling device for mining cable production as described in claim 1, characterized in that, The cooling box (201) has two symmetrically arranged first collection ports (5) on its bottom side, and the water storage tank (202) has two symmetrically arranged second collection ports (6) on its top. Each first collection port (5) is connected to the adjacent second collection port (6).
4. The cooling device for mining cable production as described in claim 1, characterized in that, The drying assembly includes a drying cylinder (301) fixedly installed on one side of the cooling box (201). The drying cylinder (301) has an installation port on one side, and an installation box (302) is fixedly installed on the installation port. A drive motor (303) is fixedly installed inside the installation box (302). A rotating rod (304) is fixedly installed on the output end of the drive motor (303). Multiple fan blades (305) arranged in a ring array are fixedly installed on the cylindrical surface of the rotating rod (304).
5. A cooling device for the production of mining cables as described in claim 4, characterized in that, The drying cylinder (301) has a collection groove (7) at the bottom of its inner cavity, and a third collection port (8) is provided at the bottom of the inner wall of the collection groove (7). The water storage tank (202) has a fourth collection port (9) on one side of its top, and the third collection port (8) and the fourth collection port (9) are connected.
6. The cooling device for mining cable production as described in claim 4, characterized in that, A support plate (10) is fixedly installed at the bottom of the water storage tank (202), and a plurality of support rods (11) are fixedly installed at the top of the support plate (10). The top of each support rod (11) is fixedly installed with a cooling box (201) or a drying cylinder (301), and the water pump (203) is fixedly installed at the top of the support plate (10).