An electrical wire cooling and storage system

By designing guide wheels and duct pulleys to guide the wires, and combining them with the top placement of splash-proof boxes and wire storage devices, the problem of water splashing during wire cooling and storage is solved, achieving a dry working environment and efficient space utilization.

CN224377311UActive Publication Date: 2026-06-19ZHONGSHAN JINZHONG ELECTRONICS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHONGSHAN JINZHONG ELECTRONICS CO LTD
Filing Date
2025-07-02
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Water splashing during wire cooling and storage can lead to slippery workplaces, equipment damage, and reduced product quality.

Method used

A wire cooling and storage system was designed, comprising a water channel, a splash guard, and a wire storage device. The system prevents cooling water from splashing by the guidance of the channel wheel and guide wheel, and the wire storage device is placed on top of the splash guard to save space.

Benefits of technology

It effectively prevents cooling water splashing, keeps the working environment dry, avoids equipment damage, and improves the efficiency of production space utilization.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of wire technology, specifically disclosing a wire cooling and storage system, comprising: a water channel for cooling the extruded wire; a splash guard with an inlet and an outlet, the inlet being connected to the water channel and the outlet located at the top of the splash guard; two guide wheels and a first driving device for driving the two guide wheels to rotate inside the splash guard; a first guide wheel connected to the outlet; and a wire storage device with a wire storage state and a wire release state, located at the top of the splash guard, comprising two wire storage wheels that can move away from or close to each other. The wire passes sequentially through the water channel, the guide wheel, the first guide wheel, and the wire storage wheel. When the two wire storage wheels move away from each other, the wire storage device is in the wire storage state; when the two wire storage wheels move close to each other, the wire storage device is in the wire release state. This utility model solves the problem of water splashing in the existing wire cooling and storage process.
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Description

Technical Field

[0001] This utility model relates to the field of wire technology, and in particular to a wire cooling and storage system. Background Technology

[0002] In the wire manufacturing process, the extruded wires need to undergo a cooling process to ensure their quality. Traditional cooling methods typically involve passing the wires through water channels to lower their temperature. Simultaneously, to improve space utilization, the wire storage devices are placed at elevated locations.

[0003] However, when the power lines are led out of the ditch and moved to the elevated cable storage device, water splashes off the power lines due to factors such as surface tension and the speed at which the power lines move. This splashing not only makes the workplace slippery, increasing the risk of workers slipping, but it can also cause water to splash onto surrounding equipment and products, resulting in equipment damage and reduced product quality. Utility Model Content

[0004] To address the problem of water splashing during existing wire cooling and storage processes, this invention provides a wire cooling and storage system.

[0005] To solve the above problems, the present invention adopts the following technical solution:

[0006] An embodiment of this utility model provides a wire cooling and storage system, comprising:

[0007] A water channel, used to cool the extruded wires;

[0008] A splashproof box has an inlet and an outlet. The inlet is connected to the water channel, and the outlet is located on the top of the splashproof box. The splashproof box contains two channel wheels and a first drive device for driving the two channel wheels to rotate.

[0009] The first guide wheel is connected to the outlet;

[0010] A wire storage device is provided, which has a wire storage state and a wire release state. The wire storage device is located on the top of the splash-proof box. The wire storage device includes two wire storage wheels that can move away from each other and move closer together. The wire passes sequentially through the water channel, the guide wheel, the first guide wheel, and the wire storage wheel. When the two wire storage wheels move away from each other, the wire storage device is in the wire storage state; when the two wire storage wheels move closer together, the wire storage device is in the wire release state.

[0011] According to some embodiments of the present invention, the water channel includes a first water-blocking structure disposed at both ends thereof, and the wire can pass through the first water-blocking structure and enter the splash-proof box.

[0012] According to some embodiments of the present invention, the water channel further includes a second water-blocking structure disposed on top of the first water-blocking structure near the inlet.

[0013] According to some embodiments of the present invention, the wire storage device includes a fixed plate, a slide rail, a sliding block, and a second driving device. The sliding block is slidably connected to the slide rail, and the second driving device is connected to the sliding block and used to drive the sliding block to slide along the slide rail. The slide rail and one of the wire storage wheels are disposed on the fixed plate, and the other wire storage wheel is disposed on the sliding block.

[0014] According to some embodiments of the present invention, the second driving device includes a second belt, a gear, two second guide wheels and a second driver. The two second guide wheels are rotatably connected to the sliding block and are respectively disposed on both sides of the gear. The two ends of the second belt are respectively fixed to the fixed plate. The gear is meshed with the second belt. The second driver is connected to the gear and is used to drive the gear to rotate.

[0015] According to some embodiments of the present invention, the first driving device includes two driving wheels respectively connected to the two guide wheels, a first belt, and a first driver. The first belt is connected to the two driving wheels respectively, and the first driver is connected to one of the driving wheels and is used to drive the driving wheel to rotate.

[0016] According to some embodiments of the present invention, the wire storage reel has a plurality of first receiving grooves for placing wires.

[0017] According to some embodiments of the present invention, the guide wheel has a plurality of second receiving slots for placing wires.

[0018] According to some embodiments of the present invention, a wire cooling and storage system further includes a mounting frame, and the wire storage device is disposed at the top of the mounting frame.

[0019] According to some embodiments of this utility model, the first water-blocking structure is a sponge.

[0020] This utility model has at least the following beneficial effects: By setting up a splash-proof box with two guide wheels inside, the wire can pass smoothly through the splash-proof box under the guidance of the guide wheels, so that the cooling water on the wire falls into the splash-proof box, effectively preventing water from splashing when the wire is led out of the water channel and moved to a high place.

[0021] Meanwhile, by placing the wire storage device on top of the splashproof box, the wire storage is placed at a high position, thereby saving production space and improving the utilization efficiency of the production site. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the structure of one embodiment of the present utility model;

[0023] Figure 2 This is a schematic diagram of the structure of a splash-proof box door according to an embodiment of the present invention;

[0024] Figure 3 This is a partial structural schematic diagram of the second driving device according to an embodiment of the present invention;

[0025] Figure 4 This is a schematic diagram of the water channel portion according to an embodiment of the present invention;

[0026] Figure 5 This is a schematic diagram of the water channel section of one embodiment of the present invention, with the second water-blocking structure removed.

[0027] Figure 6 This is a schematic diagram of the rear structure of one embodiment of the present invention;

[0028] Figure 7 This is a schematic diagram illustrating the working principle of one embodiment of the present invention. Detailed Implementation

[0029] This invention provides the following description with reference to the accompanying drawings to aid in a comprehensive understanding of the various embodiments of the invention as defined by the claims and their equivalents. The description includes various specific details to aid understanding, but these details should be considered exemplary only. Therefore, those skilled in the art will recognize that various changes and modifications can be made to the various embodiments described herein without departing from the scope and spirit of the invention.

[0030] In the description of this utility model, the orientation descriptions, such as up, down, front, back, left, right, etc., are based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.

[0031] It should be understood that when one element (e.g., the first element) is “connected” to another element (e.g., the second element), the element may be directly connected to the other element, or there may be an intervening element (e.g., the third element) between the element and the other element.

[0032] Embodiments of this utility model provide a wire cooling and storage system, such as... Figure 1-7 As shown, it includes:

[0033] Water channel 100 is used to cool the extruded wires.

[0034] The splash box 200 has an inlet 210 and an outlet 220. The inlet 210 is connected to the water channel 100, and the outlet 220 is located on the top of the splash box 200. The splash box 200 is equipped with two channel wheels 230 and a first drive device 240 for driving the two channel wheels 230 to rotate.

[0035] The first guide wheel 300 is connected to the cable outlet 220;

[0036] The wire storage device 400 has a wire storage state and a wire release state. The wire storage device 400 is installed on the top of the splash-proof box 200. The wire storage device 400 includes two wire storage wheels 450 that can move away from each other and close to each other. The wire passes through the water channel 100, the guide wheel 230, the first guide wheel 300 and the wire storage wheel 450 in sequence. When the two wire storage wheels 450 are far apart, the wire storage device 400 is in the wire storage state; when the two wire storage wheels 450 are close to each other, the wire storage device 400 is in the wire release state.

[0037] The water channel 100 is used to cool the extruded wire. The extruded wire is at a high temperature; the cooling water in the water channel 100 quickly lowers its temperature, preventing damage or deformation due to high temperatures. After exiting the extrusion equipment, the wire directly enters the water channel 100. The cooling water contacts the wire, carrying away its heat through heat transfer, thus achieving cooling. The splash guard 200 has an inlet 210 and an outlet 220. The inlet 210 is connected to the water channel 100, and the wire enters the splash guard 200 after exiting the water channel 100. The outlet 220 is located at the top of the splash guard 200 and is used to lead the wire out. Two guide wheels 230 are installed inside the splash guard 200. Guided by the guide wheels 230, the wire can smoothly move from the inlet 210 to the outlet 220. The first drive device 240 drives the two guide wheels 230 to rotate, ensuring the wire can pass smoothly through the splash guard 200. The first guide wheel 300 is aligned with the outlet 220 of the splash-proof box 200. The first guide wheel 300 guides the wires exiting the splash-proof box 200, ensuring the wires accurately enter the wire storage device 400. The wire storage device 400 includes two wire storage wheels 450 that can move apart or closer together. Wires are stored or released through the wire storage wheels 450. The wire storage device 400 has a storage state and a release state. In the storage state, when the two wire storage wheels 450 are far apart, the wire can be wound around the storage wheels 450 for storage. In the release state, when the two wire storage wheels 450 are close together, the wire can be released. The wire storage device 400 is located on top of the splash-proof box 200, facilitating wire transmission and handling. Cooling the wires through the water channel 100 quickly reduces their temperature. The splash-proof box 200 is designed to effectively prevent cooling water from splashing out, maintaining a clean working environment. The wire storage device 400 can store or release wires as needed, offering flexible and convenient operation. The entire system is compact in design and occupies little space, making it suitable for use in limited spaces.

[0038] The working principle of this utility model is as follows:

[0039] After extrusion, the wire enters the water channel 100 and is cooled by cooling water. The cooled wire then enters the splash guard 200 from the water channel 100 and, guided by the guide wheel 230, exits from the outlet 220 of the splash guard 200. Guided by the first guide wheel 300, the wire enters the wire storage device 400. When the wire storage device 400 is in the wire storage state (the two wire storage wheels 450 are far apart), the wire is wound around the wire storage wheels 450 for storage. When the wire storage device 400 is in the wire release state (the two wire storage wheels 450 are close together), the wire is released from the wire storage wheels 450.

[0040] In some embodiments, the water channel 100 includes a first water-blocking structure 110 disposed at both ends thereof, through which an electric wire can pass and enter the splash guard 200.

[0041] The first water-blocking structure 110 is disposed at both ends of the water channel 100. It prevents water from overflowing from both ends of the water channel 100 while allowing electrical wires to pass through. The electrical wires can pass through the first water-blocking structure 110 and enter the splash guard 200. This means that the first water-blocking structure 110 needs to match the diameter and shape of the electrical wire to ensure that the wire can pass smoothly without damage. The first water-blocking structure 110 may have a certain degree of sealing to prevent water leakage from the point where the wire passes through. For example, rubber sealing rings or other waterproof materials can be used. In some embodiments, the first water-blocking structure 110 is a sponge. The first water-blocking structure 110 acts as a barrier to cooling water at both ends of the water channel 100, preventing cooling water from overflowing from both ends of the water channel 100, thereby maintaining a stable cooling water level and ensuring a cooling effect. When the electrical wire emerges from one end of the water channel 100, it passes through the first water-blocking structure 110. The design of the first water-blocking structure 110 must ensure that the electrical wire can pass smoothly while preventing water leakage from the point where the wire passes through. The first water-blocking structure 110 can be a baffle with a central hole through which the wire passes. The diameter of the central hole is slightly larger than the diameter of the wire to ensure that the wire can pass through smoothly. To enhance the sealing effect, an annular sealing groove may be designed around the central hole, and the sealing groove is filled with sealing material.

[0042] Furthermore, the water channel 100 also includes a second water-blocking structure 120 disposed on top of the first water-blocking structure 110 on the side near the inlet 210.

[0043] The second water-blocking structure 120 is disposed on top of the first water-blocking structure 110 on the side near the inlet 210. This means it is located on the side of the water channel 100 near the inlet 210 and above the first water-blocking structure 110. The second water-blocking structure 120 further enhances the waterproof performance of the end of the water channel 100, preventing cooling water from overflowing or splashing from the top of the first water-blocking structure 110. By adding the second water-blocking structure 120 on top of the first water-blocking structure 110, a double waterproof barrier is formed. This design can effectively prevent cooling water from leaking from the end of the water channel 100, especially when the water level in the water channel 100 is high or the water flow is rapid. The second water-blocking structure 120 can be designed as a baffle or fence of a certain height, capable of blocking the splashing of cooling water and ensuring the dryness and cleanliness of the end of the water channel 100. In some embodiments, the second water-blocking structure 120 is a sponge. The first water-blocking structure 110 and the second water-blocking structure 120 work together to prevent cooling water from overflowing or splashing from the right end of the water channel 100, ensuring a stable cooling water level and maintaining a clean working environment. The second water-blocking structure 120 can be a semi-circular or rectangular baffle, installed on top of the first water-blocking structure 110. Its shape is designed to fit the first water-blocking structure 110. The second water-blocking structure 120 can be installed on top of the first water-blocking structure 110 by bolts, welding, or other fixing methods. This installation method ensures its stability and reliability.

[0044] In some embodiments, the wire storage device 400 includes a fixed plate 410, a slide rail 420, a sliding block 430, and a second driving device 440. The sliding block 430 is slidably connected to the slide rail 420, and the second driving device 440 is connected to the sliding block 430 and is used to drive the sliding block 430 to slide along the slide rail 420. The slide rail 420 and one of the wire storage wheels 450 are disposed on the fixed plate 410, and the other wire storage wheel 450 is disposed on the sliding block 430.

[0045] The fixing plate 410 is used to install and fix other components. The fixing plate 410 is installed on top of the splash guard 200 to ensure a tight fit between the wire storage device 400 and the wire outlet 220 of the splash guard 200. The slide rail 420 is the track for the movement of the wire storage wheel 450, used to guide the movement of the sliding block 430, thereby realizing the adjustable function of the wire storage wheel 450. The slide rail 420 is installed on the fixing plate 410 together with one of the wire storage wheels 450 to ensure the stability of the slide rail 420. The sliding block 430 is a movable component that is slidably connected to the slide rail 420 to support the other wire storage wheel 450. By moving the sliding block 430, the distance between the two wire storage wheels 450 can be adjusted, thereby switching between the wire storage state and the wire dispensing state of the wire storage device 400. The sliding block 430 is connected to the second drive device 440, which drives it to slide along the slide rail 420. The second drive device 440 is the power source for the wire storage device 400, used to drive the sliding block 430 to slide along the slide rail 420. The second drive device 440 is connected to the sliding block 430 and is powered by a motor or other drive mechanism. By controlling the operation of the second drive device 440, the position of the sliding block 430 can be precisely adjusted, thereby enabling the wire storage wheels 450 to move closer or further apart.

[0046] The wire storage device 400 includes two wire storage rollers 450, one of which is fixed to a fixed plate 410, and the other is mounted on a sliding block 430. Through the design of the slide rail 420 and the sliding block 430, the position of the wire storage rollers 450 can be flexibly adjusted to accommodate the storage needs of wires of different lengths. Precise control of the second drive device 440 enables rapid switching of the wire storage rollers 450, improving work efficiency. The structural design of the fixed plate 410 and the slide rail 420 provides stable support for the wire storage device 400, ensuring that the wire storage rollers 450 remain stable during movement. The sliding connection between the sliding block 430 and the slide rail 420 reduces friction and extends the service life of the device.

[0047] The working principle of this embodiment is as follows:

[0048] Wire storage process: When wires need to be stored, the second drive device 440 is activated, driving the sliding block 430 to slide outward along the slide rail 420, causing the two wire storage wheels 450 to move away from each other. After the wires come out of the outlet 220 of the splash-proof box 200, they enter the wire storage device 400 through the first guide wheel 300 and are wound around the two wire storage wheels 450 for storage.

[0049] Cable release process: When it is necessary to release the cable, the second drive device 440 reverses its direction, driving the sliding block 430 to slide inward along the slide rail 420, bringing the two cable storage wheels 450 closer together. The cable is released from the cable storage wheels 450 and enters the subsequent processing or transportation stage.

[0050] Furthermore, the second drive device 440 includes a second belt 441, a gear 442, two second guide wheels 443 and a second driver 444. The two second guide wheels 443 are rotatably connected to the sliding block 430 and are respectively disposed on both sides of the gear 442. The two ends of the second belt 441 are respectively fixed on the fixing plate 410. The gear 442 is meshed with the second belt 441. The second driver 444 is connected to the gear 442 and is used to drive the gear 442 to rotate.

[0051] Both ends of the second belt 441 are fixed to the fixed plate 410 to ensure stability during operation. Through meshing with the gear 442, the second belt 441 converts the rotational motion of the gear 442 into the linear motion of the sliding block 430. The meshing connection between the gear 442 and the second belt 441 ensures efficient and accurate power transmission. The rotation of the gear 442 on the second belt 441 drives the sliding block 430 to move along the slide rail 420, thereby adjusting the position of the wire storage pulley 450. The second guide wheel 443 guides the movement of the gear 442, ensuring that the gear 442 maintains the correct path during operation. The second driver 444 is connected to the gear 442 and provides power through a motor or other drive mechanism. By controlling the operation of the second driver 444, the speed and direction of the gear 442 can be precisely adjusted, thereby achieving precise movement of the sliding block 430. Through the transmission method of the gear 442 and the belt, the second drive device 440 can achieve precise control of the sliding block 430, thereby ensuring accurate position adjustment of the wire storage pulley 450. The gear and belt drive system offers high reliability and durability, capable of withstanding heavy loads and frequent start / stop operations. The second drive unit 440 has a compact structure, occupies little space, and is suitable for use in confined spaces. The tight connections between all components ensure stable system operation.

[0052] The working principle of this embodiment is as follows:

[0053] After the second drive 444 is activated, it drives the gear 442 to rotate. The gear 442 is engaged with the second belt 441. Since the second belt 441 is fixed, when the gear 442 rotates, it drives the sliding block 430 to move relative to the second belt 441. The two second guide wheels 443 can press the second belt 441 tightly to ensure that the gear 442 maintains the correct path during operation.

[0054] The direction of movement of the sliding block 430 depends on the rotation direction of the gear 442. When the gear 442 rotates in the forward direction, the sliding block 430 moves outward along the slide rail 420, causing the two wire storage wheels 450 to move away from each other and enter the wire storage state; when the gear 442 rotates in the reverse direction, the sliding block 430 moves inward along the slide rail 420, causing the two wire storage wheels 450 to move closer to each other and enter the wire unloading state.

[0055] In some embodiments, the first drive device 240 includes two drive wheels 241 respectively connected to two guide pulleys 230, a first belt 242 and a first driver 243. The first belt 242 is connected to the two drive wheels 241 respectively, and the first driver 243 is connected to one of the drive wheels 241 and is used to drive the drive wheel 241 to rotate.

[0056] The first drive unit 240 includes two drive wheels 241, each connected to a guide wheel 230. The drive wheels 241 drive the guide wheels 230 to rotate via a first belt 242, thus achieving smooth wire transmission. The first belt 242 is connected to both drive wheels 241, forming a closed-loop transmission system. The first belt 242 is a transmission element used to transmit the power from the first driver 243 to the two drive wheels 241, thereby driving the guide wheels 230 to rotate. Belt transmission enables smooth power transmission, reduces vibration and noise, and ensures synchronous rotation of the guide wheels 230. The first driver 243 is connected to one of the drive wheels 241 and is powered by a motor or other drive mechanism. By controlling the operation of the first driver 243, the speed and direction of the drive wheels 241 can be adjusted, thereby achieving precise control of the guide wheels 230.

[0057] The working principle of this embodiment is as follows:

[0058] After the first driver 243 is activated, it drives one of the drive wheels 241 to rotate. This drive wheel 241, through the transmission of the first belt 242, drives the other drive wheel 241 to rotate synchronously. The two drive wheels 241 respectively drive the two guide pulleys 230 to rotate, thereby achieving smooth transmission of the wire within the splash guard 200. Because the first belt 242 connects the two drive wheels 241, the two guide pulleys 230 can rotate synchronously, ensuring that the wire will not twist or jam during transmission.

[0059] In some embodiments, the wire storage reel 450 has a plurality of first receiving slots for placing wires.

[0060] The first receiving slot is used to hold the wires, ensuring they are neatly arranged on the wire storage reel 450 and preventing them from crossing, tangling, or knotting during winding and releasing. The receiving slot also provides some protection for the wires, preventing damage during storage or release. By providing multiple receiving slots, the wire storage capacity of the wire storage reel 450 can be increased, improving storage efficiency. The wire storage reel 450 has several...

[0061] The number of the first receiving slots can be designed based on the diameter of the wire and the size of the 450mm reel. For example, more slots can be designed for thinner wires, while fewer slots can be designed for thicker wires. The shape of the first receiving slot matches the cross-sectional shape of the wire. If the wire is round, the receiving slot may be semi-circular or V-shaped; if the wire is flat, the receiving slot may be rectangular or trapezoidal. The depth and width of the receiving slot are designed according to the diameter of the wire to ensure that the wire can be stably placed in the slot while preventing the wire from becoming loose or slipping within the slot.

[0062] In some embodiments, the guide wheel 230 has a plurality of second receiving slots for placing wires.

[0063] The second receiving slot is used to place the wire, ensuring that the wire is accurately guided when passing through the guide wheel 230, and preventing the wire from shifting, swaying, or getting tangled during transmission. The design of the second receiving slot is similar to that of the first receiving slot, and will not be described in detail here.

[0064] In some embodiments, a wire cooling and storage system further includes a mounting bracket 500, with a wire storage device 400 disposed at the top of the mounting bracket 500.

[0065] The mounting bracket 500 provides stable support and fixation for the wire storage device 400, ensuring its stability during operation and preventing displacement or damage caused by external forces or equipment vibration. By rationally designing the structure of the mounting bracket 500, the spatial layout of the equipment can be optimized, making it more compact and saving floor space, while also facilitating operation and monitoring by personnel. The wire storage device 400 is positioned at the top of the mounting bracket 500. This design makes full use of space and allows wires to directly enter the wire storage device 400 from the outlet 220 of the splash-proof box 200, reducing resistance and wear during wire transmission.

[0066] Furthermore, the first water-blocking structure 110 is a sponge.

[0067] The sponge possesses excellent water absorption and elasticity, enabling it to absorb and block cooling water in the water channel 100, preventing leakage from both ends. The sponge's softness allows it to adapt to the shape of the wire, allowing the wire to pass through easily without damage. The sponge absorbs splashed cooling water, reducing the likelihood of water spilling out of the water channel 100 and keeping the working environment dry and clean. The sponge's elasticity provides cushioning for the wire, reducing friction and impact during passage and protecting the wire's surface.

[0068] The terms and words used in the foregoing description and claims are not limited to their literal meaning, but are merely used by the applicant to enable a clear and consistent understanding of the present invention. Therefore, those skilled in the art should understand that the foregoing description of various embodiments of the present invention is for illustrative purposes only, and not intended to limit the present invention as defined by the appended claims and their equivalents.

Claims

1. A wire cooling and storage system, characterized in that, include: Water channel (100), the water channel (100) is used to cool the extruded wire; A splash shield (200) has an inlet (210) and an outlet (220). The inlet (210) is connected to the water channel (100), and the outlet (220) is located on the top of the splash shield (200). The splash shield (200) is equipped with two channel rollers (230) and a first drive device (240) for driving the two channel rollers (230) to rotate. The first guide wheel (300) is connected to the outlet (220); A wire storage device (400) has a wire storage state and a wire release state. The wire storage device (400) is disposed on the top of the splash guard (200). The wire storage device (400) includes two wire storage wheels (450) that can move away from each other and move closer together. The wire passes sequentially through the water channel (100), the channel guide wheel (230), the first guide wheel (300), and the wire storage wheel (450). When the two wire storage wheels (450) move away from each other, the wire storage device (400) is in the wire storage state; when the two wire storage wheels (450) move closer together, the wire storage device (400) is in the wire release state.

2. The wire cooling and storage system according to claim 1, characterized in that, The water channel (100) includes a first water-blocking structure (110) disposed at both ends thereof, and the wire can pass through the first water-blocking structure (110) and enter the splash guard (200).

3. The wire cooling and storage system according to claim 2, characterized in that, The water channel (100) also includes a second water-blocking structure (120) disposed on top of the first water-blocking structure (110) near the inlet (210).

4. A wire cooling and storage system according to any one of claims 1 to 3, characterized in that, The wire storage device (400) includes a fixed plate (410), a slide rail (420), a sliding block (430), and a second driving device (440). The sliding block (430) is slidably connected to the slide rail (420). The second driving device (440) is connected to the sliding block (430) and is used to drive the sliding block (430) to slide along the slide rail (420). The slide rail (420) and one of the wire storage wheels (450) are disposed on the fixed plate (410), and the other wire storage wheel (450) is disposed on the sliding block (430).

5. The wire cooling and storage system according to claim 4, characterized in that, The second drive device (440) includes a second belt (441), a gear (442), two second guide wheels (443) and a second driver (444). The two second guide wheels (443) are rotatably connected to the sliding block (430) and are respectively disposed on both sides of the gear (442). The two ends of the second belt (441) are respectively fixed on the fixing plate (410). The gear (442) is meshed with the second belt (441). The second driver (444) is connected to the gear (442) and is used to drive the gear (442) to rotate.

6. A wire cooling and storage system according to any one of claims 1 to 3, characterized in that, The first drive device (240) includes two drive wheels (241) respectively connected to the two guide wheels (230), a first belt (242) and a first driver (243). The first belt (242) is connected to the two drive wheels (241) respectively, and the first driver (243) is connected to one of the drive wheels (241) and is used to drive the drive wheel (241) to rotate.

7. A wire cooling and storage system according to any one of claims 1 to 3, characterized in that, The wire storage reel (450) has several first receiving slots for placing wires.

8. A wire cooling and storage system according to any one of claims 1 to 3, characterized in that, The guide wheel (230) has several second receiving slots for placing wires.

9. A wire cooling and storage system according to any one of claims 1 to 3, characterized in that, It also includes a mounting bracket (500), on the top of which the wire storage device (400) is disposed.

10. A wire cooling and storage system according to claim 2, characterized in that, The first water-blocking structure (110) is a sponge.