Wire marking device
By integrating electrolytic cleaning, secondary water cleaning, and drying cleaning into a wire processing device, combined with an optimized water circulation system, the problem of low efficiency in wire surface indentation treatment has been solved, achieving efficient and economical improvement in wire surface quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- MISUZU SEISENDONGGUAN LTD
- Filing Date
- 2025-07-31
- Publication Date
- 2026-07-07
AI Technical Summary
In the current wire processing technology, especially in the drawing or rolling stages, the methods for removing indentations on the wire surface are inefficient, costly, and ineffective. In particular, it is difficult to effectively remove indentations when processing complex shapes or microstructures, which affects the appearance quality and mechanical properties of the product.
The device integrates electrolytic cleaning, secondary water cleaning, and dry cleaning, combined with an optimized water circulation system, to achieve comprehensive treatment of the wire surface through an electrolytic water tank, a clean water tank, and a dry cleaning component.
It significantly improves wire surface quality and processing efficiency, electrolytic cleaning thoroughly removes indentations, the clean water tank ensures cleanliness and purity, the drying components quickly remove moisture, the water circulation system extends the lifespan of water resources, reduces operating costs, and improves the controllability and stability of the process.
Smart Images

Figure CN224463355U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of wire processing technology, and in particular to a wire indentation treatment device. Background Technology
[0002] In modern industrial manufacturing, wire processing technology, as a fundamental and crucial process, is widely used in various industries such as electronics, machinery, and construction. However, during wire processing, especially in the drawing or rolling stages, indentations often inevitably appear on the material surface. These indentations not only affect the appearance quality of the product but may also potentially damage its mechanical properties and corrosion resistance. Therefore, effectively treating the wire surface to eliminate or reduce indentations has become an important step in improving product quality and market competitiveness.
[0003] Existing technologies for treating surface marks on wires mainly include mechanical polishing, chemical etching, and electrochemical polishing. However, these methods all have certain limitations in practical applications. For example, while mechanical polishing can effectively remove surface marks, it is complex to operate and can easily introduce new defects; chemical etching can quickly treat the surface, but selecting a suitable etching solution is difficult, and the uniformity of the treated surface is hard to guarantee; electrochemical polishing requires sophisticated equipment and is relatively expensive. Furthermore, these methods often fail to achieve satisfactory results when treating wires with complex shapes or fine structures, significantly increasing the processing difficulty. Therefore, developing a new, efficient, economical technology applicable to the treatment of surface marks on various wires is particularly urgent. Utility Model Content
[0004] To address the aforementioned issues, this invention provides a wire indentation treatment device that integrates efficient electrolytic cleaning, secondary water cleaning, drying cleaning, and an optimized water circulation system to achieve comprehensive treatment of wire surface indentations, significantly improving the surface quality and processing efficiency of the wire.
[0005] The technical solution adopted by this utility model is: a wire indentation treatment device, including a support, an electrolytic water tank, a clean water tank, a drying and cleaning component, a first water circulation component, and a second water circulation component. The electrolytic water tank and the clean water tank are disposed on the surface of the support and arranged sequentially along the wire transmission direction. The first water circulation component is used for water circulation in the electrolytic water tank, and the second water circulation component is used for water circulation in the clean water tank. The electrolytic water tank is provided with an electrolytic mesh frame, an electrolytic support, and an electrolytic connecting element. The electrolytic support is disposed on the electrolytic mesh frame, and the electrolytic connecting element is disposed on the electrode support to supply power to the water in the electrolytic water tank to form electrolytic cleaning of the wire indentation. The clean water tank is used for clean water cleaning of the wire, and the drying and cleaning component is used for drying and cleaning the wire.
[0006] A further improvement to the above solution is that the support is provided with a base frame, and both the first water circulation component and the second water circulation component are mounted on the base frame.
[0007] A further improvement to the above scheme is that the first water circulation component is provided with a first water tank and a first water pump, the first water circulation component is provided with a first pipe connected to the electrolytic water tank, and the first water pump is located in the first water tank and used to connect to the electrolytic water tank.
[0008] A further improvement to the above scheme is that the second water circulation component is provided with a second water tank and a second water pump. The second water pump is located inside the second water tank, and the second water tank is provided with a second pipe connected to the clean water tank. The second water pump is used to connect to the clean water tank.
[0009] A further improvement to the above scheme is that an electrolytic inlet groove and an electrolytic outlet groove are respectively provided at both ends of the electrolytic water tank. An inlet guide wheel is provided on one side of the electrolytic inlet groove, and a first outlet guide wheel is provided on one side of the electrolytic outlet groove. The inlet guide wheel and the first outlet guide wheel are used to transmit and stretch the wire in the electrolytic water tank.
[0010] A further improvement to the above scheme is that the electrolytic water tank is provided with a first partition and a second partition, an electrolytic mesh frame is provided between the first partition and the second partition, and a through groove is provided at the bottom of both the first partition and the second partition for water flow.
[0011] A further improvement to the above scheme is that both the first partition and the second partition are provided with a first wire passage groove, the first wire passage groove is opposite to the electrolytic inlet groove and the electrolytic outlet groove, the first wire passage groove is located on both sides of the electrolytic mesh frame, and the inlet guide wheel and the first outlet guide wheel are used to stretch and flatten them within the electrolytic mesh frame.
[0012] A further improvement to the above solution is that a clean water inlet channel and a clean water outlet channel are respectively provided at both ends of the clean water tank. The clean water inlet channel is opposite to the electrolytic water tank and guides the wire toward the clean water tank through a first outlet guide wheel. A second outlet guide wheel is provided on one side of the clean water outlet channel for exporting the cleaned wire.
[0013] A further improvement to the above scheme is that the clean water tank is provided with a third partition and a fourth partition, and the bottom of the third partition and the fourth partition are provided with a channel for water flow.
[0014] A further improvement to the above scheme is that both the third and fourth partitions are provided with a second wire passage groove, which is opposite to the clean water inlet groove and the clean water outlet groove.
[0015] A further improvement to the above solution is that the drying and cleaning component is disposed between the clean water outlet trough and the second wire passage trough. The drying and cleaning component includes a cleaning sleeve, a cleaning wire passage spool, and an air pipe connector. The cleaning sleeve is disposed on one side of the clean water tank, the cleaning wire passage spool is disposed inside the cleaning sleeve, and the air pipe connector is used to supply air to the cleaning wire passage spool to blow air to clean and dry the passing wire.
[0016] The beneficial effects of this utility model are:
[0017] Compared to existing wire indentation treatments, this invention achieves effective electrolytic cleaning of wire indentations by incorporating an electrolytic mesh frame, electrolytic support, and electrolytic connecting elements within the electrolytic water tank. The electrolysis process penetrates deep into the tiny indentations on the wire surface, removing residual impurities and oxides to ensure thorough cleaning. Compared to traditional mechanical grinding or chemical cleaning methods, electrolytic cleaning is not only more efficient but also causes less damage to the wire surface, effectively protecting the wire's physical properties. After electrolytic cleaning, the wire enters a clean water tank for secondary cleaning. The second water circulation component within the clean water tank ensures continuous water renewal and flow, preventing the accumulation of cleaning solution contamination and ensuring optimal results with each cleaning. This improves the purity of the cleaning process and reduces water waste, reflecting an environmentally friendly approach. The drying and cleaning component completes the wire surface treatment process. It quickly removes moisture from the wire surface after cleaning, preventing secondary contamination or oxidation caused by residual moisture. The drying and cleaning component typically employs high-efficiency blowing or hot air drying technology to ensure uniform drying of the wire surface, providing a good foundation for subsequent processing or use. The first and second water circulation components are responsible for the water circulation within the electrolytic water tank and the clean water tank, respectively. This independent water circulation design not only ensures the cleaning effect at each stage but also significantly extends the service life of the water and reduces operating costs. Simultaneously, the water circulation system helps maintain a stable cleaning environment, avoiding interference from external impurities and improving the overall process controllability and stability. This invention, by integrating efficient electrolytic cleaning, secondary clean water cleaning, drying cleaning, and an optimized water circulation system, achieves comprehensive treatment of surface indentations on wires, significantly improving the surface quality and processing efficiency of the wires. Attached Figure Description
[0018] Figure 1 This is a three-dimensional schematic diagram of the wire indentation treatment device of this utility model;
[0019] Figure 2 for Figure 1 A three-dimensional schematic diagram of the wire indentation treatment device from another perspective;
[0020] Figure 3 for Figure 1 Front view schematic diagram of the wire indentation treatment device;
[0021] Figure 4 for Figure 1 A schematic diagram of part of the wire indentation treatment device.
[0022] Explanation of reference numerals in the attached drawings: 1. Support frame; 11. Base frame; 2. Electrolytic water tank; 21. Electrolytic mesh frame; 22. Electrolytic support; 23. Electrolytic connecting element; 24. Electrolytic inlet groove; 25. Electrolytic outlet groove; 26. Inlet guide wheel; 27. First outlet guide wheel; 28. First partition plate; 281. First wire passage groove; 29. Second partition plate; 3. Clean water tank; 31. Clean water inlet groove; 32. Clean water outlet groove; 33. Second outlet guide wheel; 34. Third partition plate; 35. Fourth partition plate; 36. Second wire passage groove; 4. Drying and cleaning assembly; 41. Cleaning sleeve; 42. Cleaning wire passage spool; 43. Air pipe connector; 5. First water circulation assembly; 51. First water tank; 52. First water pump; 53. First pipe; 6. Second water circulation assembly; 61. Second water tank; 62. Second water pump; 63. Second pipe. Detailed Implementation
[0023] To facilitate understanding of this utility model, a more complete description will be given below with reference to the accompanying drawings. Preferred embodiments of this utility model are shown in the drawings. However, this utility model can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a more thorough and complete understanding of the disclosure of this utility model.
[0024] It should be noted that when a component is said to be "fixed to" another component, it can be directly attached to the other component or there may be an intervening component. When a component is said to be "connected to" another component, it can be directly connected to the other component or there may be an intervening component.
[0025] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Figures 1-4As shown, in one embodiment of this utility model, a wire indentation treatment device is provided, including a support 1, an electrolytic water tank 2, a clean water tank 3, a drying and cleaning component 4, a first water circulation component 5, and a second water circulation component 6. The electrolytic water tank 2 and the clean water tank 3 are disposed on the surface of the support 1 and arranged sequentially along the wire transmission direction. The first water circulation component 5 is used for water circulation in the electrolytic water tank 2, and the second water circulation component 6 is used for water circulation in the clean water tank 3. The electrolytic water tank 2 is provided with an electrolytic mesh frame 21, an electrolytic support 22, and an electrolytic connecting element 23. The electrolytic support 22 is disposed on the electrolytic mesh frame 21, and the electrolytic connecting element 23 is disposed on the electrode support 1 to provide power to the water in the electrolytic water tank 2 to form an electrolytic cleaning effect on the wire indentation. The clean water tank 3 is used for clean water cleaning of the wire, and the drying and cleaning component 4 is used for drying and cleaning the wire. This embodiment achieves effective electrolytic cleaning of wire indentations by setting up an electrolytic mesh frame 21, an electrolytic support 22, and an electrolytic connecting element 23 within the electrolytic water tank 2. The electrolytic process can penetrate deep into the tiny indentations on the wire surface, removing residual impurities and oxides to ensure thorough cleaning. Compared to traditional mechanical grinding or chemical cleaning methods, electrolytic cleaning is not only more efficient but also causes less damage to the wire surface, effectively protecting the wire's physical properties. After electrolytic cleaning, the wire enters the clean water tank 3 for secondary cleaning. The second water circulation component 6 within the clean water tank 3 ensures continuous water renewal and flow, preventing the accumulation of cleaning solution contamination and ensuring optimal results with each cleaning. This improves the purity of the cleaning and reduces water waste, reflecting an environmentally friendly approach. The drying and cleaning component 4 completes the wire surface treatment process. It can quickly remove moisture from the wire surface after cleaning, preventing secondary contamination or oxidation caused by residual moisture. The drying and cleaning component 4 typically employs high-efficiency blowing or hot air drying technology to ensure uniform drying of the wire surface, providing a good foundation for subsequent processing or use. The first water circulation component 5 and the second water circulation component 6 are responsible for the water circulation within the electrolytic water tank 2 and the clean water tank 3, respectively. This independent water circulation design not only ensures the cleaning effect at each stage but also significantly extends the service life of the water and reduces operating costs. Simultaneously, the water circulation system helps maintain a stable cleaning environment, avoiding interference from external impurities and improving the overall process controllability and stability. This embodiment, by integrating efficient electrolytic cleaning, secondary clean water cleaning, drying cleaning, and an optimized water circulation system, achieves comprehensive treatment of surface indentations on wires, significantly improving the surface quality and processing efficiency of the wires.
[0026] In the above embodiments, the electrolytic water tank 2, which utilizes a chemical-physical synergistic mechanism for electrolytic cleaning, constitutes a complete electrolysis system via an electrolytic mesh frame 21, an electrolytic support 22, and connecting elements. When direct current is applied to the electrolyte (typically Na2CO3 or NaCl solution), oxygen microbubbles are generated at the anode and hydrogen microbubbles at the cathode. These microbubbles create a cavitation effect at the indentation site, while the reactive oxygen species (ROS) generated during electrolysis react with the metal oxides at the indentation site in a redox reaction. Experimental data show that under conditions of 12V voltage and 5A / dm² current density, the removal efficiency for copper wire indentations can reach over 92%, and the surface roughness Ra value is reduced to below 0.8μm.
[0027] The support frame 1 is equipped with a base frame 11, on which the first water circulation component 5 and the second water circulation component 6 are both mounted. Specifically, the first water circulation component 5 is equipped with a first water tank 51 and a first water pump 52. The first water circulation component 5 is connected to the electrolytic water tank 2 via a first pipe 53, and the first water pump 52 is located inside the first water tank 51 and is used to connect to the electrolytic water tank 2. The second water circulation component 6 is equipped with a second water tank 61 and a second water pump 62. The second water pump 62 is located inside the second water tank 61, and the second water tank 61 is connected to the clean water tank 3 via a second pipe 63. In this embodiment, the base frame 11 provides a stable foundation for the first water circulation component 5 and the second water circulation component 6, ensuring the stability and reliability of the entire system. It improves the structural strength of the device, facilitates maintenance and repair, and reduces the equipment failure rate and maintenance costs. The stability of the base frame 11 is crucial for ensuring the normal operation of the water circulation system, especially in high-pressure or high-flow working environments, effectively preventing loosening of pipe connections or leakage caused by vibration or impact. The first water circulation component 5, through the design of the first water tank 51 and the first water pump 52, achieves effective recycling of electrolyzed water. The first water pump 52 is located inside the first water tank 51 and directly connected to the electrolyzed water tank 2, ensuring efficient delivery and circulation of electrolyzed water. This improves the utilization rate of electrolyzed water, reduces water waste, and meets environmental protection and energy-saving requirements. A stable supply of electrolyzed water ensures the efficiency of the electrochemical reaction during the wire creasing process, improving processing quality and production efficiency. The second water circulation component 6, with its second water tank 61 and second water pump 62, further optimizes the clean water circulation system. The second water pump 62 is also located inside the second water tank 61 and connected to the clean water tank 3 via the second pipe 63, ensuring a continuous supply and circulation of clean water. This guarantees the water needs for cooling and cleaning during the wire creasing process and avoids equipment corrosion or product contamination caused by water quality issues. The efficient recycling of clean water not only extends the service life of the equipment but also improves the cleanliness and surface quality of the products.
[0028] The electrolytic water tank 2 has an electrolytic wire inlet groove 24 and an electrolytic wire outlet groove 25 at its two ends. An inlet guide wheel 26 is provided on one side of the electrolytic wire inlet groove 24, and a first outlet guide wheel 27 is provided on one side of the electrolytic wire outlet groove 25. The inlet guide wheel 26 and the first outlet guide wheel 27 are used to transport and stretch the wire within the electrolytic water tank 2. Specifically, the electrolytic water tank 2 has a first partition 28 and a second partition 29. An electrolytic mesh frame 21 is provided between the first partition 28 and the second partition 29. Both the first partition 28 and the second partition 29 have channels at their bottoms for water flow. Both the first partition 28 and the second partition 29 are provided with a first wire-passing groove 281. The first wire-passing groove 281 is opposite to the electrolytic inlet groove 24 and the electrolytic outlet groove 25. The first wire-passing groove 281 is located on both sides of the electrolytic mesh frame 21. The inlet guide wheel 26 and the first outlet guide wheel 27 are used to stretch and flatten the wire within the electrolytic mesh frame 21. In this embodiment, the electrolytic inlet groove 24 and the electrolytic outlet groove 25 are respectively provided at both ends of the electrolytic water tank 2. Together with the inlet guide wheel 26 and the first outlet guide wheel 27, precise control of the wire transmission path is achieved. This ensures the smoothness and stability of the wire when entering and leaving the electrolytic water tank 2, and avoids uneven electrolysis caused by wire shaking or deviation. The inlet guide wheel 26 and the first outlet guide wheel 27 are not only responsible for the introduction and export of the wire, but also undertake the task of stretching the wire, so that the wire always maintains appropriate tension during the electrolysis process, thereby ensuring the uniformity and consistency of the electrolysis treatment. The first partition 28 and the second partition 29 inside the electrolysis tank 2 rationally divide the space, forming a closed and controllable electrolysis environment. The electrolysis mesh frame 21 between the partitions provides the necessary support structure for the electrolysis reaction, ensuring that the electrolyte can be evenly distributed and fully contact the wire surface. The through grooves at the bottom of the first partition 28 and the second partition 29 promote the circulation of the electrolyte, avoiding the problem of excessively high or low local concentration of the electrolyte, and further improving the uniformity and stability of the electrolysis effect. The first wire passage groove 281 on the first partition 28 and the second partition 29 is opposite to the electrolysis inlet groove 24 and the electrolysis outlet groove 25, and is located on both sides of the electrolysis mesh frame 21, ensuring that the wire passes through the electrolysis mesh frame 21 in a straight line, reducing the bending and twisting of the wire during the electrolysis process, and effectively avoiding the problem of uneven electrolysis caused by wire deformation. Meanwhile, the synergistic effect of the inlet guide roller 26 and the first outlet guide roller 27 ensures that the wire is fully stretched and flattened within the electrolytic mesh frame 21, guaranteeing the quality of the electrolytic treatment on the wire surface and improving the electrolytic efficiency.
[0029] The clean water tank 3 has a clean water inlet channel 31 and a clean water outlet channel 32 at both ends. The clean water inlet channel 31 is opposite to the electrolytic water tank 2 and guides the wire towards the clean water tank 3 via a first outlet guide wheel 27. A second outlet guide wheel 33 is provided on one side of the clean water outlet channel 32 for exiting the cleaned wire. Specifically, the clean water tank 3 has a third partition 34 and a fourth partition 35. The bottom of both the third partition 34 and the fourth partition 35 has a channel for water flow. Both the third partition 34 and the fourth partition 35 have a second wire passage channel 36, which is opposite to the clean water inlet channel 31 and the clean water outlet channel 32. In this embodiment, the clean water inlet channel 31 and the clean water outlet channel 32 at both ends of the clean water tank 3 provide a clear path for the introduction and exit of the wire. The clean water inlet trough 31 is opposite to the electrolytic water tank 2, and the first outlet guide roller 27 guides the wire towards the clean water tank 3, ensuring that the wire has had its surface impurities initially removed before entering the clean water tank 3, laying the foundation for further cleaning. The second outlet guide roller 33, located on one side of the clean water outlet trough 32, is responsible for smoothly exporting the cleaned wire, avoiding secondary contamination or damage caused by improper export. The design of the third partition 34 and the fourth partition 35 inside the clean water tank 3 further enhances the cleaning effect. The two partitions not only divide the clean water tank 3 into multiple independent cleaning areas, but also ensure smooth water flow through the bottom channels, allowing the water flow in each area to maintain a certain speed and pressure, effectively rinsing away residues on the wire surface. The second wire passage groove 36 on the third partition 34 and the fourth partition 35 is opposite to the clean water inlet trough 31 and the clean water outlet trough 32, ensuring that the wire passes through in a straight line during the cleaning process, avoiding friction damage caused by a tortuous path, and ensuring the uniformity and thoroughness of the cleaning. The baffle design not only optimizes the cleaning effect but also facilitates regular cleaning and maintenance. Operators can easily disassemble the baffle for cleaning or replacement, ensuring the cleanliness of the inside of the clean water tank 3 and extending the service life of the equipment.
[0030] A drying and cleaning assembly 4 is disposed between the clean water outlet trough 32 and the second wire passage trough 36. The assembly includes a cleaning sleeve 41, a cleaning wire passage spool 42, and an air hose connector 43. The cleaning sleeve 41 is disposed on one side of the clean water tank 3, the cleaning wire passage spool 42 is disposed inside the sleeve 41, and the air hose connector 43 supplies air to the cleaning wire passage spool 42 to clean and dry the passing wire. In this embodiment, the cleaning sleeve 41 is installed on one side of the clean water tank 3, which is not only compact but also easy to maintain and replace. The cleaning wire passage spool 42, disposed inside the sleeve 41, can closely fit the surface of the wire, removing tiny particles and impurities through mechanical friction, further improving the cleanliness of the wire. The design of the cleaning wire passage spool 42 also considers different wire diameters and materials, possessing a certain degree of adaptability and flexibility, ensuring the stability and consistency of the cleaning effect. The introduction of the air hose connector 43 supplies air to the cleaning wire passage spool 42, realizing the function of air-blowing cleaning and drying of the wire. Combining the advantages of mechanical cleaning and airflow drying, it can quickly remove moisture and fine dust from the surface of the wire in a short time, effectively preventing problems such as oxidation and corrosion caused by moisture residue, and extending the service life of the wire. The blowing effect of the airflow also enhances the cleaning effect of cleaning the spool 42, ensuring that the wire surface meets high standards of cleanliness.
[0031] The above embodiments only illustrate several implementation methods of this utility model, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the scope of this utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.
Claims
1. A wire indentation treatment device, characterized in that: The device includes a support frame, an electrolytic water tank, a clean water tank, a drying and cleaning assembly, a first water circulation assembly, and a second water circulation assembly. The electrolytic water tank and the clean water tank are disposed on the surface of the support frame and arranged sequentially along the wire transmission direction. The first water circulation assembly is used for water circulation within the electrolytic water tank, and the second water circulation assembly is used for water circulation within the clean water tank. The electrolytic water tank contains an electrolytic mesh frame, an electrolytic support frame, and electrolytic connecting elements. The electrolytic support frame is disposed on the electrolytic mesh frame, and the electrolytic connecting elements are disposed on the electrode support frame to supply power to the water in the electrolytic water tank, thereby forming an electrolytic indentation on the wire for electrolytic cleaning. The clean water tank is used for clean water cleaning of the wire, and the drying and cleaning assembly is used for drying and cleaning the wire.
2. The wire indentation treatment device according to claim 1, characterized in that: The support frame is provided with a base frame, and both the first water circulation component and the second water circulation component are mounted on the base frame.
3. The wire indentation treatment device according to claim 2, characterized in that: The first water circulation component is provided with a first water tank and a first water pump. The first water circulation component is provided with a first pipe connected to the electrolytic water tank. The first water pump is located in the first water tank and is used to connect to the electrolytic water tank. The second water circulation component is provided with a second water tank and a second water pump. The second water pump is located inside the second water tank. The second water tank is provided with a second pipe that connects to the clean water tank. The second water pump is used to connect to the clean water tank.
4. The wire indentation treatment device according to claim 1, characterized in that: The electrolytic water tank is provided with an electrolytic inlet groove and an electrolytic outlet groove at both ends. An inlet guide wheel is provided on one side of the electrolytic inlet groove, and a first outlet guide wheel is provided on one side of the electrolytic outlet groove. The inlet guide wheel and the first outlet guide wheel are used to transmit and stretch the wire inside the electrolytic water tank.
5. The wire indentation treatment device according to claim 4, characterized in that: The electrolytic water tank is provided with a first partition and a second partition, and an electrolytic mesh frame is provided between the first partition and the second partition. The bottom of both the first partition and the second partition is provided with a through groove for water flow.
6. The wire indentation treatment device according to claim 5, characterized in that: Both the first partition and the second partition are provided with a first wire passage groove. The first wire passage groove is opposite to the electrolytic inlet groove and the electrolytic outlet groove. The first wire passage groove is located on both sides of the electrolytic mesh frame. The inlet guide wheel and the first outlet guide wheel are used to stretch and flatten the wires within the electrolytic mesh frame.
7. The wire indentation treatment device according to claim 6, characterized in that: The clean water tank is provided with a clean water inlet channel and a clean water outlet channel at both ends. The clean water inlet channel is opposite to the electrolytic water tank and guides the wire toward the clean water tank through the first outlet guide wheel. A second outlet guide wheel is provided on one side of the clean water outlet channel for the wire to be discharged after cleaning.
8. The wire indentation treatment device according to claim 7, characterized in that: The clean water tank is equipped with a third partition and a fourth partition, and the bottom of both the third partition and the fourth partition is provided with a channel for water flow.
9. The wire indentation treatment device according to claim 8, characterized in that: Both the third and fourth partitions are provided with a second wire passage groove, which is opposite to the clean water inlet groove and the clean water outlet groove.
10. The wire indentation treatment device according to claim 9, characterized in that: The drying and cleaning assembly is disposed between the clean water outlet trough and the second wire passage trough. The drying and cleaning assembly includes a cleaning sleeve, a cleaning wire passage spool, and an air pipe connector. The cleaning sleeve is disposed on one side of the clean water tank, the cleaning wire passage spool is disposed inside the cleaning sleeve, and the air pipe connector is used to supply air to the cleaning wire passage spool to blow air to clean and dry the passing wire.