Cooling equipment for electrolytic copper processing
By designing a cooling device that includes a bottom box and a top box, and using a conveyor belt to transport electrolytic copper in combination with water spraying and air blowing for drying, the problem of uneven cooling of electrolytic copper is solved, achieving efficient cooling and water resource recycling.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGXI YIXIN COPPER MATERIALS CO LTD
- Filing Date
- 2025-07-10
- Publication Date
- 2026-06-12
Smart Images

Figure CN224350786U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of electrolytic copper processing equipment, and in particular to a cooling device for electrolytic copper processing. Background Technology
[0002] Electrolytic copper is a non-ferrous metal closely related to human life, widely used in electrical, light industry, machinery manufacturing, construction, and defense industries. In my country, it ranks second only to aluminum in non-ferrous metal consumption. Copper is most widely used and consumed in the electrical and electronics industries, accounting for more than half of total consumption. It is used in various cables and wires, windings for motors and transformers, switches, and printed circuit boards, among other applications.
[0003] Electrolytic copper needs to be cooled during processing, but currently, most cooling methods involve stacking the electrolytic copper together before cooling. This method results in poor internal cooling and uneven cooling.
[0004] Therefore, a cooling device for electrolytic copper processing is proposed. Utility Model Content
[0005] (a) Technical problems to be solved
[0006] To overcome the shortcomings of existing technologies, a cooling device for electrolytic copper processing is proposed to solve the problems of uneven cooling efficiency and poor cooling effect in current electrolytic copper processing.
[0007] (II) Technical Solution
[0008] This utility model is achieved through the following technical solution: This utility model proposes a cooling device for electrolytic copper processing, including a bottom box with an opening at the top, a water exchange port at the bottom of the bottom box, and a top box spanning across the middle of the bottom box. The top box has inlets and outlets at the bottom ends of both sides.
[0009] The upper part of the bottom box is covered with transport components for moving electrolytic copper.
[0010] The bottom box is divided into a water storage chamber and a filter chamber by a partition plate that slopes towards the center. Both the water storage chamber and the filter chamber have openings at their bottom ends. The filter chamber has a mounting platform inside, and a removable filter layer is installed on the upper part of the platform. A water pump is installed on one side of the bottom box, and the water pump's suction end passes through the water storage chamber. The bottom box and the top box have symmetrical bottom and top spray nozzles inside, and the top spray nozzle is located inside the transport assembly. Both the bottom and top spray nozzles have several nozzles on their inner sides. The bottom and top spray nozzles are connected to each other by a three-way pipe, and the water pump's outlet end is connected to one side of the three-way pipe by a suction pipe.
[0011] Furthermore, the transport assembly includes rotating rollers located on both sides of the opening at the top of the bottom box, and a mesh conveyor belt is connected between the rotating rollers. A motor is installed on the outside of the bottom box and connected to one of the rotating rollers.
[0012] Furthermore, the bottom and top boxes are symmetrically equipped with bottom and top air pipes, and the bottom and top air pipes are connected by a T-junction on their outer sides. A fan is installed at the top of the top box, and the output end of the fan is connected to one side of the T-junction via an air supply pipe. The bottom and top air pipes are equipped with nozzles on their inner sides, and the nozzles are inclined at opposite ends.
[0013] Furthermore, a force-bearing plate is connected between the top spray nozzle and the top air pipe, and an electric push rod is installed at the top of the force-bearing plate. The output end of the electric push rod passes through the top box and is connected to the force-bearing plate.
[0014] Furthermore, telescopic rods are installed on both sides of the top of the top box and connected to the force-bearing plate.
[0015] Furthermore, a controller and a water level gauge are installed on the outside of the bottom tank, and a side door is installed on the outside of the bottom tank at the filter layer.
[0016] (III) Beneficial Effects
[0017] Compared with the prior art, this utility model has the following advantages:
[0018] 1. In this utility model, the electrolytic copper can be moved by the conveyor belt, so that the electrolytic copper is moved to the top box. Under the action of the water pump, water is sprayed onto the electrolytic copper through the nozzles on the bottom and top spray nozzles to cool it. This can avoid the situation where the electrolytic copper is piled up and cooled unevenly inside and outside, resulting in low cooling effect and efficiency. The goal of achieving good cooling effect and high efficiency is achieved.
[0019] Furthermore, bottom and top spray nozzles are installed to spray the upper and lower ends of the electrolytic copper, resulting in better and faster spray cooling and saving cooling time.
[0020] 2. In this utility model, by setting a partition plate inside the bottom box, the sprayed water is easily input into the filter layer for filtration. After filtration, the water is pumped out for use, thereby realizing the recycling of water resources and achieving the goal of saving water resources.
[0021] 3. In this utility model, by passing the bottom air pipe and the top air pipe through the fan, the inner nozzles blow air again on the cooled electrolytic copper, thereby improving the cooling effect and allowing the water stains on the surface of the electrolytic copper to dry quickly, resulting in better work efficiency and reducing subsequent cleaning time. Attached Figure Description
[0022] Other features, objects, and advantages of this invention will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:
[0023] Figure 1 This is a schematic diagram of the internal structure of the present invention;
[0024] Figure 2 This is a top view of the conveyor belt structure of this utility model;
[0025] Figure 3 This is a schematic diagram of the rear end face structure of this utility model;
[0026] Figure 4 This is a schematic diagram of the bottom box and top box of this utility model;
[0027] In the diagram: Bottom box-1, Top box-2, Rotating roller-3, Conveyor belt-4, Inlet / outlet-5, Separator plate-6, Mounting platform-7, Filter layer-8, Water pump-9, Bottom spray nozzle-10, Top spray nozzle-11, Nozzle-12, Bottom air pipe-13, Top air pipe-14, Nozzle-15, Force plate-16, Electric push rod-17, Fan-18, Telescopic rod-19, Water exchange port-110, Motor-111, T-pipe-112, Water suction pipe-113, Air supply pipe-114, Controller-115, Water level gauge-116, Side box door-117. Detailed Implementation
[0028] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain this utility model and are not intended to limit this utility model.
[0029] Please see Figure 1 and Figure 2This utility model provides a cooling device for electrolytic copper processing, including a bottom box 1 with an open top, allowing the conveyor belt 4 to be located inside, thus enabling more complete water recycling during spraying. A water exchange port 110 is provided at the bottom of the bottom box 1 to replace the internal water. A top box 2 is horizontally arranged across the upper middle part of the bottom box 1. Inlet and outlet ports 5 are provided at the bottom ends of both sides of the top box 2, facilitating the movement of the electrolytic copper via the conveyor belt 4. This increases the closed surface of the top box 2, reducing water spraying. A controller 115 and a water level gauge 116 are installed on the outside of the bottom box 1. The controller 115 facilitates the operation of the electrical components in the device, making the work simpler, and the water level gauge 116... The bottom box 1 has a side door 117 installed on the outside of the bottom box 1 at the filter layer 8, which facilitates the removal of the filter layer 8 for cleaning. The bottom box 1 has a transport assembly for moving electrolytic copper. The transport assembly includes rotating rollers 3 on both sides of the opening at the top of the bottom box 1, and a mesh conveyor belt 4 is connected between the rotating rollers 3. The mesh design facilitates the spraying of water and air at the bottom, increasing the contact surface and enhancing the cooling effect. A motor 111 is installed on the outside of the bottom box 1 and connected to a rotating roller 3. When the motor 111 drives the rotating roller 3 to rotate the conveyor belt 4, the electrolytic copper at the top can be rotated and transported, preventing the electrolytic copper from accumulating and cooling.
[0030] Please see Figures 1-4The bottom chamber 1 is divided into a water storage chamber and a filtration chamber by a partition plate 6 that slopes inward. The upper end of the partition plate 6 covers one side of the bottom of the conveyor belt 4, and its slope facilitates downward water flow. Openings are provided at the bottom of both the water storage chamber and the filtration chamber, allowing filtered water to be reused, thus enabling water resource recycling. A platform 7 is provided inside the filtration chamber, and a removable filter layer 8 is installed on top of the platform 7. The filter layer 8 filters the cooled water, allowing it to be reused. Multiple filter layers 8 can be installed for better filtration. A water pump 9 is installed on one side of the bottom chamber 1, with its suction end penetrating the water storage chamber. The cavity, under the action of the water pump 9, facilitates the extraction of water for spraying. The bottom box 1 and the top box 2 are symmetrically equipped with a bottom spray nozzle 10 and a top spray nozzle 11, with the top spray nozzle 11 located inside the conveyor belt 4. Both the bottom spray nozzle 10 and the top spray nozzle 11 have several nozzles 12 on their inner sides. The outer sides of the bottom spray nozzle 10 and the top spray nozzle 11 are connected by a three-way pipe 112, and the water outlet of the water pump 9 is connected to one side of the three-way pipe 112 via a suction pipe 113. This allows water to be drawn into the bottom spray nozzle 10 and the top spray nozzle 11 through the suction pipe 113 under the suction force of the water pump 9, and then sprayed onto the electrolytic copper surface by the nozzles 12. Cooling is achieved by spraying water onto both the top and bottom ends of the electrolytic copper, allowing simultaneous cooling of both surfaces for better and more efficient cooling. A telescopic tube can be installed at one end of the T-connector 112 connecting to the top spray nozzle 11 for easy vertical movement. Bottom air pipes 13 and top air pipes 14 are symmetrically arranged inside the bottom box 1 and top box 2, connected externally by the T-connector 112. A fan 18 is installed at the top of the top box 2, with its output connected to one side of the T-connector 112 via an air supply pipe 114. Nozzles 15 are installed on the inner sides of both the bottom air pipe 13 and top air pipe 14. Under the fan 18, air is fed through the air pipe 114 into the three-way pipe 112, and then into the bottom air pipe 13 and the top air pipe 14. The air is then sprayed out under the nozzle 15 to blow air onto the surface of the electrolytic copper, thereby enhancing the cooling effect and drying the water stains remaining on the surface, reducing subsequent cleaning time and making the work more efficient. The connection between the top air pipe 14 and the three-way pipe 112 can be set as a telescopic pipe for easy lifting and lowering. The nozzle 15 is set with opposite tilts at the top and bottom. The bottom tilt prevents water from dripping in, while the top tilt is tilted in the direction of water spraying to blow the water on the surface of the electrolytic copper to one side, resulting in a better drying effect.
[0031] A force-bearing plate 16 connects the top spray nozzle 11 and the top air pipe 14. An electric push rod 17 is installed at the top of the force-bearing plate 16. The output end of the electric push rod 17 passes through the top box 2 and connects to the force-bearing plate 16. When the electric push rod 17 moves the force-bearing plate 16 up and down, the distance between the top spray nozzle 11, the top air pipe 14, and the electrolytic copper can be adjusted, so that the spray cooling effect is better. It can be used according to different types of electrolytic copper, so that the working effect is better and the practicality is higher. Telescopic rods 19 are installed on both sides of the top of the top box 2 and connected to the force-bearing plate 16 to enhance the stability of the force-bearing plate 16.
[0032] Working principle: In use, first connect the water pump 9, electric push rod 17, fan 18, motor 111, and controller 115, and connect them to an external power supply. Then, place the electrolytic copper on the upper end of the conveyor belt 4. Under the rotation of the conveyor belt 4 caused by the motor 111 driving the rotating roller 3, the electrolytic copper can rotate into the top box 2. Under the action of the electric push rod 17, the height of the top spray nozzle 11 and the top air pipe 14 can be adjusted. Then, under the action of the water pump 9, the water in the water storage chamber is drawn out through the water suction pipe 113. The water is fed into the bottom spray nozzle 10 and the top spray nozzle 11 through the three-way pipe 112, and sprayed onto the surface of the electrolytic copper through the nozzle 12 for cooling. After being sprayed and cooled, the water moves between the bottom air pipe 13 and the top air pipe 14. Under the action of the fan 18 through the air supply pipe 114 and the three-way pipe 112, the inner nozzle 15 blows air to dry the surface of the electrolytic copper. The water dripping during spraying enters the filter chamber and is filtered by the filter layer 8. It is then easily sucked out for use through the opening at the lower end of the partition plate 6, thus completing the work.
[0033] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A cooling device for electrolytic copper processing, comprising a bottom box (1) with an open top, wherein a water exchange port (110) is provided at the bottom end of the bottom box (1), and a top box (2) is horizontally arranged across the upper middle part of the bottom box (1), wherein inlet and outlet (5) are provided at the bottom ends of both sides of the top box (2), characterized in that ; The bottom box (1) is equipped with a transport component for moving electrolytic copper at its upper end; The bottom box (1) is divided into a water storage chamber and a filter chamber by a partition plate (6) that slopes towards the center. The bottom of the water storage chamber and the filter chamber are provided with openings. The filter chamber is provided with a mounting platform (7) and a removable filter layer (8) is installed on the upper end of the mounting platform (7). A water pump (9) is installed on one side of the bottom box (1) and the water pump (9) has its suction end penetrating through the water storage chamber. The bottom box (1) and the top box (2) are symmetrically provided with a bottom spray nozzle (10) and a top spray nozzle (11). The top spray nozzle (11) is located inside the transport component. The bottom spray nozzle (10) and the top spray nozzle (11) are provided with several nozzles (12) on their inner sides. The bottom spray nozzle (10) and the top spray nozzle (11) are connected to each other by a three-way pipe (112). The water pump (9) has its outlet end connected to one side of the three-way pipe (112) by a suction pipe (113).
2. The cooling equipment for electrolytic copper processing according to claim 1, characterized in that: The transport assembly includes rotating rollers (3) located on both sides of the upper opening of the bottom box (1), and a mesh conveyor belt (4) is connected between the rotating rollers (3). A motor (111) is installed on the outside of the bottom box (1) and connected to a rotating roller (3).
3. The cooling device for electrolytic copper processing according to claim 2, characterized in that: The bottom box (1) and the top box (2) are symmetrically equipped with bottom air pipes (13) and top air pipes (14), and the bottom air pipes (13) and top air pipes (14) are connected on the outside by a three-way pipe (112). A fan (18) is installed at the top of the top box (2). The output end of the fan (18) is connected to one side of the three-way pipe (112) through the air supply pipe (114). The bottom air pipe (13) and the top air pipe (14) are both equipped with nozzles (15), and the nozzles (15) are inclined at opposite ends.
4. A cooling device for electrolytic copper processing according to claim 3, characterized in that: A force plate (16) is connected between the top spray nozzle (11) and the top air pipe (14). An electric push rod (17) is installed at the top of the force plate (16). The output end of the electric push rod (17) passes through the top box (2) and is connected to the force plate (16).
5. A cooling device for electrolytic copper processing according to claim 4, characterized in that: The top box (2) has telescopic rods (19) installed on both sides of its top end, which are connected to the force plate (16).
6. A cooling device for electrolytic copper processing according to claim 1, characterized in that: A controller (115) and a water level gauge (116) are installed on the outside of the bottom tank (1), and a side door (117) is installed on the outside of the bottom tank (1) at the filter layer (8).