Wire drawing device for welding wire production

By using a synergistic design of dual welding wire cleaning modules and processing components, the problem of residual impurities on the surface of welding wires is solved, achieving efficient cleaning and removal of contaminants, and improving the quality and efficiency of welding wire production.

CN224475463UActive Publication Date: 2026-07-10INNER MONGOLIA YIJI GRP SHENLU WELDING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
INNER MONGOLIA YIJI GRP SHENLU WELDING CO LTD
Filing Date
2025-06-30
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

In the current welding wire production process, residual coolant and metal shavings on the surface of the welding wire are not effectively removed, leading to defects in subsequent processing quality and affecting the yield of finished welding wires.

Method used

The dual-wire cleaning module structure design, combined with intermittent operation of the conveyor belt and segmented cleaning of the cleaning components, achieves efficient cleaning and removal of contaminants from the surface of the welding wire through the coordinated action of the bevel gear set, lead screw, and pressure plate of the processing components.

Benefits of technology

Ensuring the surface of the welding wire is smooth and dry reduces production costs, improves the stability and yield of subsequent processing, and enhances overall production efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a wire drawing device for welding wire production, which comprises a base, a wire drawing die and a welding wire processing mechanism composed of two welding wire cleaning modules arranged in sequence according to the wire drawing direction on the base, and a driving mechanism arranged on the processing mechanism. The welding wire cleaning module comprises a shell, a transmission roller (connected with the driving mechanism), a conveying belt (with a fixing groove for fixing a cleaning piece), an adjusting piece and a processing assembly (including a bevel gear set, a lead screw and a pressing plate for extruding the cleaning piece to discharge dirt) arranged in the shell. The driving mechanism is connected through a motor, a cam, a slide rod, a rack and a pulley assembly to realize intermittent driving of the transmission roller, so that the cleaning piece can clean the welding wire surface in sections and discharge dirt by the processing assembly during the pause. The device is designed through a double-module structure, intermittent operation and extrusion and discharge, so that the cleaning efficiency is improved, the service life of the cleaning piece is prolonged, the maintenance cost is reduced, the welding wire surface is ensured to be smooth and dry, and a stable quality basis is provided for subsequent processing.
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Description

Technical Field

[0001] This application belongs to the field of welding wire drawing technology, and specifically relates to a wire drawing device for welding wire production. Background Technology

[0002] The production process of welding wire typically includes key steps such as pre-drawing treatment, rough drawing, fine drawing, copper plating, fine winding, and packaging. Among them, the rough drawing process is an important step that draws the metal wire diameter from 5.5mm to 2.35mm, which directly affects the surface quality of the welding wire and the stability of subsequent processing.

[0003] In existing technologies, welding wire coarse drawing devices typically use drawing dies to draw and shape the welding wire. To reduce the damage to the die and welding wire caused by heat generated during the drawing process due to friction, a common technique is to install water injection rings or spray devices on the side walls of the drawing die. Circulating coolant removes heat, extending die life and improving drawing efficiency (refer to Chinese Utility Model Patent No. CN221109424U). However, such devices still have the following shortcomings in practical applications:

[0004] During the drawing process, impurities such as coolant and metal shavings will remain on the surface of the welding wire. However, since no cleaning structure is set up for the surface of the welding wire, the welding wire is directly wound after drawing. The residual coolant and metal shavings can easily cause quality defects in subsequent processes such as copper plating and fine winding (such as uneven plating, winding jamming, etc.), reducing the yield of the welding wire.

[0005] Therefore, developing a new wire drawing device for welding wire production that can efficiently clean residual impurities from the surface of welding wire has become a technical problem that urgently needs to be solved in this field. Utility Model Content

[0006] This application provides a wire drawing device for welding wire production that can efficiently clean residual impurities on the surface of welding wire, thereby solving the above-mentioned technical problems existing in the existing welding wire production process.

[0007] To achieve the above objectives, this application provides a wire drawing device for welding wire production, including a base. A wire drawing die and a welding wire processing mechanism are fixedly arranged on the base in sequence according to the welding wire drawing direction. The welding wire processing mechanism includes two welding wire cleaning modules and two driving mechanisms, which drive the two welding wire cleaning modules respectively.

[0008] The welding wire cleaning module includes a housing, which is fixedly mounted on a base. Two transmission rollers are rotatably mounted inside the housing. One of the transmission rollers is connected to a drive mechanism. A conveyor belt is mounted on the two transmission rollers. Multiple mounting slots are opened on the conveyor belt, and a cleaning component is fixedly mounted in each mounting slot.

[0009] The welding wire cleaning module also includes a processing component, which is installed inside the housing near the welding wire inlet. The processing component includes a pressure plate near the cleaning component, which can press against the cleaning component. A drain port is provided at the bottom of the housing near the processing component.

[0010] In one embodiment, the processing component further includes a bevel gear set, which is installed on the top of the housing. The input end is connected to the drive mechanism, and the output end is fixedly provided with a lead screw. A bolt is sleeved on the lead screw, and a pressure plate is fixedly provided below the bolt. A sliding groove is provided on the top wall of the housing, and the top end of the pressure plate is slidably connected in the sliding groove.

[0011] In one embodiment, the cleaning component includes a fixing seat, which is fixedly installed in the mounting groove. The fixing seat is fixedly provided with the mounting seat by a nut, and a cleaning cotton is fixedly provided on the mounting seat.

[0012] In one embodiment, the welding wire cleaning module further includes an adjusting component installed in the housing, which abuts against the conveyor belt near the welding wire side. The adjusting component includes a slide rail, a screw, and an adjusting slide.

[0013] The slide rail is located on the inner top wall of the housing. An adjusting slide is slidably installed inside the slide rail. The adjusting slide is equipped with a screw that is rotatably mounted on the inner wall of the housing via a thread.

[0014] In one embodiment, a knob is rotatably provided outside the housing, and the knob is also connected to a screw.

[0015] In one embodiment, the drive mechanism includes a transmission element and a pulley assembly, which are mounted on a housing. The transmission element is connected to a transmission roller, and the input end of the pulley assembly is connected to the transmission element, while the output end is connected to a bevel gear set.

[0016] In one embodiment, the transmission component includes a rotating wheel rotatably mounted on a housing. The rotating wheel is connected to the input end of a pulley assembly. A ratchet is disposed inside the rotating wheel and is also connected to a transmission roller. Multiple spikes are also rotatably disposed around the circumference inside the rotating wheel, and torsion springs are disposed at the connection points between the spikes and the rotating wheel.

[0017] In one embodiment, the drive mechanism further includes a motor, which is fixedly mounted on the housing. A cam is fixedly mounted on the output end of the motor. The cam is rotatably mounted on the housing. A bearing is fixedly mounted on the housing. A slide rod is slidably mounted through the bearing. A roller is rotatably mounted on one end of the slide rod near the motor. The roller abuts against the surface of the cam. A rack is fixedly mounted on the other end of the slide rod.

[0018] A compression spring is provided between the bearing seat and the slide rod, and a gear is provided on the outer sleeve of the rotating wheel, which meshes with the rack.

[0019] Compared with the prior art, the beneficial effects of this application are:

[0020] 1. The structure design of the dual welding wire cleaning module, combined with the intermittent operation of the conveyor belt and the segmented cleaning mode of the cleaning parts, achieves efficient and thorough cleaning of residual coolant and metal chips on the surface of the welding wire, ensuring that the surface of the welding wire is clean, dry and free of impurities, providing a stable and reliable foundation for subsequent processing.

[0021] 2. Through the synergistic effect of the processing components (bevel gear set, lead screw, pressure plate), the cleaning parts are squeezed and discharged after adsorption saturation, which effectively reduces the moisture and dirt content in the cleaning parts, so that they maintain high adsorption performance during recycling, extend the service life of the cleaning parts, reduce the replacement frequency, and reduce production costs.

[0022] 3. The drive mechanism uses the linkage design of cam, slide bar, rack and pulley assembly, combined with the cooperation of ratchet and thorn in the transmission component, to realize the intermittent drive of the transmission roller. This allows the cleaning parts to stop periodically during the conveying process and complete the squeezing and discharge of dirt, ensuring that the cleaning and discharge operations are synchronized and efficient, and improving the overall production efficiency. Attached Figure Description

[0023] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0024] Figure 1 A schematic diagram of the wire drawing device for welding wire production provided in this application;

[0025] Figure 2 A schematic diagram showing the connection of the wire cleaning module of the wire drawing device for wire production provided in this application;

[0026] Figure 3 A schematic diagram of the wire cleaning module structure of the wire drawing device for wire production provided in this application;

[0027] Figure 4 An enlarged schematic diagram of the bevel gear set for the wire drawing device used in welding wire production provided in this application;

[0028] Figure 5 A schematic diagram of the cleaning component of the wire drawing device for welding wire production provided in this application;

[0029] Figure 6 An enlarged schematic diagram of point C of the wire drawing device for welding wire production provided in this application;

[0030] Figure 7 An enlarged schematic diagram of the drive mechanism of the wire drawing device for welding wire production provided in this application;

[0031] Figure 8 This is a schematic diagram of the transmission component of the wire drawing device for welding wire production provided in this application.

[0032] Explanation of reference numerals in the attached drawings: 1. Base; 2. Wire drawing die; 3. Welding wire processing mechanism; 4. Welding wire cleaning module; 41. Housing; 42. Transmission roller; 43. Conveyor belt; 44. Adjusting component; 441. Slide rail; 442. Screw; 443. Adjusting slide; 45. Cleaning component; 451. Fixed seat; 452. Mounting seat; 453. Cleaning cotton; 46. Processing assembly; 461. Bevel gear set; 462. Pressure plate; 463. Slide groove; 464. Lead screw; 465. Bolt; 47. Mounting groove; 5. Drive mechanism; 51. Motor; 52. Cam; 53. Shaft seat; 54. Compression spring; 55. Slide rod; 56. Rack; 57. Transmission component; 571. Rotary wheel; 572. Ratchet; 573. Spike; 58. Pulley assembly; 59. Gear; 510. Roller. Detailed Implementation

[0033] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the technical solutions in the embodiments of this application are described clearly and completely below. Obviously, the described embodiments are only some embodiments of this application, not all embodiments. Based on the embodiments in this application, all other embodiments obtained by those skilled in the art without creative effort are also within the scope of protection of this application.

[0034] See Figures 1 to 8 As shown, the wire drawing device for welding wire production provided in this application includes a base 1. A wire drawing die 2 and a welding wire processing mechanism 3 are fixedly arranged on the base 1 in sequence according to the welding wire drawing direction. The welding wire processing mechanism 3 includes two welding wire cleaning modules 4. The welding wire processing mechanism 3 is also provided with two driving mechanisms 5, which drive the two welding wire cleaning modules 4 respectively.

[0035] When the wire drawing die 2 draws the welding wire to change its diameter and surface quality, a large amount of heat and metal chips will be generated between the welding wire and the wire drawing die 2 due to friction. In order to reduce the accumulation of frictional heat and metal chips, it is usually necessary to continuously spray coolant during the wire drawing process to cool and lubricate, thereby ensuring the surface smoothness of the welding wire and the drawing efficiency.

[0036] After the drawing die 2 completes the drawing of the welding wire, the welding wire enters the welding wire processing mechanism 3 for cleaning. Specifically, the welding wire enters between two welding wire cleaning modules 4. The two welding wire cleaning modules 4 thoroughly clean the residual coolant and metal shavings on the surface of the welding wire from both sides to ensure that the surface of the welding wire is clean, dry and free of impurities, so as to facilitate subsequent processing.

[0037] Among them, such as Figure 2 and Figure 3 As shown, Figure 2 and Figure 3 The welding wire cleaning module 4 is shown from a bottom-up perspective. The welding wire cleaning module 4 includes a housing 41, which is fixedly mounted on the base 1. Two transmission rollers 42 are rotatably mounted inside the housing 41. One of the transmission rollers 42 is connected to the drive mechanism 5. A conveyor belt 43 is mounted on the two transmission rollers 42. Multiple mounting grooves 47 are opened on the conveyor belt 43. A cleaning component 45 is fixedly mounted in each mounting groove 47. The welding wire cleaning module 4 also includes a processing component 46, which is installed in the housing 41 at one end near the welding wire inlet. The processing component 46 includes a pressure plate 462 on the side near the cleaning component 45. The pressure plate 462 can press against the cleaning component 45. A drain port is opened through the bottom of the housing 41 at one end near the processing component 46.

[0038] After the drive mechanism 5 is started, the rotation of the transmission roller 42 drives the conveyor belt 43 to start running. During the operation of the conveyor belt 43, when the cleaning component 45 moves to the side close to the welding wire, the cleaning component 45 can clean the surface of the welding wire to ensure that the surface of the welding wire is smooth, dry and free of residue after processing. At the same time, during the cleaning process, the cleaning component 45 will absorb the residue and moisture on the surface of the welding wire. Due to the operation of the conveyor belt 43, the conveyor belt 43 will transport the cleaning component 45 to the pressure plate 462 close to the processing component 46. When the cleaning component 45 comes into contact with the pressure plate 462, the pressure plate 462 of the processing component 46 will squeeze the cleaning component 45. During the squeezing process, the wastewater on the cleaning component 45 will be squeezed out, thereby ensuring that the cleaning component 45 is dry and that the cleaning component 45 can efficiently remove the residue and moisture on the surface of the welding wire each time it is cleaned. The wastewater squeezed out by the pressure plate 462 is discharged from the shell 41 through the drain port to prevent secondary pollution of the cleaning component 45 and the welding wire by the wastewater. Optionally, the drive mechanism 5 can also drive the transmission roller 42 to drive the conveyor belt 43 to run intermittently. When the cleaning component 45 runs to the pressure plate 462, the conveyor belt 43 stops running, so that the cleaning component 45 stays at the pressure plate 462, so that the pressure plate 462 can squeeze out the sewage in the cleaning component 45 more effectively.

[0039] When multiple cleaning components 45 clean the surface of the welding wire, the cleaning component 45 near the welding wire outlet gradually moves towards the welding wire inlet. During the movement, as the amount of residual coolant and metal shavings on the welding wire gradually increases, the amount of wastewater adsorbed by the cleaning component 45 also increases. After increasing to a certain extent, the cleaning component 45 is sent to the processing component 46 by the conveyor belt 43 and squeezed out by the pressure plate 462. After the squeezing and desiccation are completed, the cleaning component 45 follows the conveyor belt 43 to the welding wire inlet again to continue cleaning, ensuring that the surface of the welding wire remains clean.

[0040] That is, the cleaning part 45 near the welding wire outlet is in a dry state with a low liquid content, which can ensure that the surface of the welding wire is thoroughly dried in the final stage, avoid defects in subsequent processing due to residual liquid, ensure stable welding wire quality, and improve overall production efficiency.

[0041] Optionally, the processing component 46 includes a bevel gear set 461, which is mounted on the top of the housing 41. The input end is connected to the drive mechanism 5, and the output end is fixedly provided with a lead screw 464. A bolt 465 is sleeved on the lead screw 464, and a pressure plate 462 is fixedly provided below the bolt 465. A sliding groove 463 is provided on the top wall of the housing 41, and the top end of the pressure plate 462 is slidably connected in the sliding groove 463.

[0042] In this embodiment, the bevel gear set 461 includes two vertically meshing bevel gears. The input end of one bevel gear is connected to the drive mechanism 5, and the output end of the other bevel gear is fixedly connected to the lead screw 464. The bevel gear set 461 can reciprocate under the action of the drive mechanism 5. During rotation, the lead screw 464 rotates, causing the bolt 465 to move horizontally along the lead screw 464. The bolt 465 drives the pressure plate 462 to move back and forth within the slide groove 463, thereby squeezing and releasing the cleaning part 45, completing the squeezing and decontamination operation of the cleaning part 45, reducing the moisture content within the cleaning part 45, improving its drying effect, and ensuring that the cleaning part 45 maintains efficient cleaning capability in each cycle. This guarantees the dryness and cleanliness of the welding wire surface after drawing, providing a stable and reliable foundation for subsequent welding wire processing and manufacturing, effectively reducing processing interruptions caused by welding wire surface quality problems, and lowering maintenance costs.

[0043] It should be noted that the end of the lead screw 464 located away from the bolt on the cleaning part 45 extends beyond the side of the cleaning part 45 near the lead screw 464, in order to prevent the bolt from moving out of the lead screw 464 and to ensure the squeezing effect of the pressure plate 462 on the cleaning part 45.

[0044] Among them, the slide 463 is a T-slot, which can ensure that the pressure plate 462 moves horizontally along the slide 463 and avoids deflection.

[0045] Optionally, the cleaning component 45 includes a fixing seat 451, which is fixedly installed in the mounting groove. The fixing seat 451 is fixedly provided with a mounting seat 452 by a nut, and a cleaning cotton 453 is fixedly provided on the mounting seat 452.

[0046] In this embodiment, the cleaning cotton 453 is made of a highly absorbent material (such as a sponge), which can efficiently absorb residual liquid and metal shavings on the surface of the welding wire, ensuring the cleaning effect. After the cleaning cotton 453 is saturated, it is sent to the processing component 46 by the conveyor belt 43 for squeezing and desiccation. After desiccation, it is recycled, extending its service life, reducing the replacement frequency, and further optimizing production costs.

[0047] When the cleaning cotton 453 reaches the point where it needs to be replaced, the mounting base 452 and the cleaning cotton 453 can be easily removed by unscrewing the nut on the fixing base 451, and a new cleaning cotton can be quickly replaced to ensure production continuity and avoid affecting efficiency due to replacement delays.

[0048] Optionally, the welding wire cleaning module 4 also includes an adjusting component 44 installed inside the housing 41. The adjusting component 44 abuts against the conveyor belt 43 near the welding wire side. The adjusting component 44 includes a slide rail 441, a screw 442, and an adjusting slide 443. The slide rail 441 is formed on the inner top wall of the housing 41. The adjusting slide 443 is slidably disposed inside the slide rail 441. The screw 442 is rotatably disposed on the adjusting slide 443 via a thread. The screw 442 is rotatably disposed on the inner wall of the housing 41. A knob is also rotatably disposed outside the housing 41, and the knob is also connected to the screw 442.

[0049] In this embodiment, rotating the knob drives the screw 442 to rotate, which in turn pushes the adjusting slide 443 to move on the slide rail 441. During the movement, the adjusting slide 443 can advance or push the conveyor belt 43 away from the welding wire, thereby changing the tension of the conveyor belt 43. This further adjusts the contact pressure between the cleaning cotton 453 and the welding wire, ensuring the stability of the contact pressure between the cleaning cotton 453 and the welding wire. This avoids the cleaning effect being affected by excessive or insufficient pressure, thus ensuring the surface quality of the welding wire, improving the stability and reliability of the welding process, and ensuring the quality of the final product. Optionally, two slide rails 441 can be provided, with the adjusting slide 443 slidably connected within the two slide rails 441. One slide rail 441 can contain the screw 442, and the other slide rail 441 can contain a smooth rod that passes through the adjusting slide 443 to improve the smoothness of the movement of the adjusting slide 443.

[0050] Optionally, the drive mechanism 5 includes a transmission component 57 and a pulley assembly 58, which are mounted on the housing 41. The transmission component 57 is connected to the transmission roller 42, and the input end of the pulley assembly 58 is connected to the transmission component 57, while the output end is connected to the bevel gear set 461.

[0051] In this embodiment, by driving the transmission component 57 to rotate, thereby driving the transmission roller 42 to work, and by driving the bevel gear set 461 to work in coordination through the pulley assembly 58, the smoothness of the conveying of the cleaning cotton 453 and the pressure balance of the pressure plate 454 are ensured, avoiding uneven cleaning caused by unstable conveying, thereby ensuring the effect of squeezing and removing dirt from the cleaning cotton 453, ensuring that the cleaning cotton 453 remains in a good clean state after squeezing and removing dirt, and further improving the surface treatment quality of the welding wire.

[0052] Optionally, the transmission component 57 includes a rotating wheel 571, which is rotatably mounted on the housing 41. The rotating wheel 571 is connected to the input end of the pulley assembly 58. A ratchet 572 is provided inside the rotating wheel 571, and the ratchet 572 is also connected to the transmission roller 42. A plurality of thorns 573 are also rotatably provided around the circumference inside the rotating wheel 571, and a torsion spring is provided at the connection between the thorns 573 and the rotating wheel 571.

[0053] In this embodiment, during continuous driving, the drive mechanism 5 causes the rotary wheel 571 to reciprocate. When the rotary wheel 571 rotates counterclockwise, the thorn 573 engages with the ratchet 572 under the action of the torsion spring, so that the ratchet 572 synchronously follows the rotary wheel 571 to rotate counterclockwise. During the counterclockwise rotation, the ratchet 572 synchronously drives the transmission roller 42 to rotate, and the rotary wheel 571 drives the bevel gear set 56 to rotate through the pulley assembly 58, thereby driving the pressure plate 462 to move away from the conveyor belt 43 through the lead screw 464 and bolt 465. When the rotating wheel 571 rotates clockwise, the thorn 573 cannot engage with the ratchet 572, thus preventing the ratchet 572 from rotating with the rotating wheel 571. At this time, the drive roller 42 remains stationary, and the rotating wheel 571 drives the bevel gear set 56 to rotate via the pulley assembly 58. This, in turn, drives the pressure plate 462 to move closer to the conveyor belt 43 via the lead screw 464 and bolt 465. The pressure plate 462 then squeezes the stationary cleaning cotton 453. Through this process, the drive roller 42 drives the conveyor belt 43 to operate intermittently, and the bevel gear set 56 rotates reciprocally, causing the pressure plate 462 to move reciprocally.

[0054] The torsion spring provides a certain deflection torque to the thorn 573, so that the thorn 573 can fit against the surface of the ratchet 572, ensuring that the thorn 573 and the ratchet 572 remain stable during movement, and avoiding the problem of power transmission interruption when the wheel 571 rotates counterclockwise.

[0055] By setting up a ratchet 572 and a rotating wheel 571, the transmission roller 42 is intermittently driven by the ratchet 573. This ensures that the cleaning cotton 453 can pause intermittently during the conveying process. During these intermittent pauses, the pulley assembly 58 and the bevel gear set 461 work together to allow the pressure plate 454 to fully squeeze the cleaning cotton 453, effectively squeezing out the dirt inside. After squeezing is complete, the cleaning cotton 453 resumes conveying, repeating the cycle. This achieves thorough removal of residual moisture and dirt from the surface of the welding wire, ensuring the surface smoothness of the welding wire and improving the efficiency of subsequent welding wire production.

[0056] Optionally, the drive mechanism 5 also includes a motor 51, which is fixedly mounted on the housing 41. A cam 52 is fixedly mounted on the output end of the motor 51, and the cam 52 is rotatably mounted on the housing 41. A bearing 53 is fixedly mounted on the housing 41, and a slide rod 55 is slidably mounted through the bearing 53. A roller 510 is rotatably mounted on one end of the slide rod 55 near the motor 51, and the roller 510 abuts against the surface of the cam 52. A rack 56 is fixedly mounted on the other end of the slide rod 55. A compression spring 54 is provided between the bearing 53 and the end of the slide rod 55 near the motor 51. A gear 59 is sleeved on the rotating wheel 571, and the gear 59 meshes with the rack 56.

[0057] In this embodiment, the motor 51 drives the cam 52 to rotate. During rotation, the cam 52 pushes the slide bar 55 to slide within the bearing 53 via the rotating wheel. During movement, the slide bar 55 compresses the elastic force generated by the spring 54, causing the rack 56 to move smoothly in a reciprocating motion. During the reciprocating motion, the rack 56 drives the rotating wheel 571 to rotate reciprocally through the meshing of the gear 59, thereby driving the transmission roller 42 and the bevel gear set 461 to work together. This ensures the smooth conveying of the cleaning cotton 453 and the balanced pressure of the pressure plate 454, avoiding uneven cleaning caused by unstable conveying. This ensures the effective squeezing and decontamination of the cleaning cotton 453, ensuring that the cleaning cotton 453 remains in a good clean state after squeezing and decontamination, further improving the surface treatment quality of the welding wire.

[0058] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this application, and are not intended to limit them. Although this application has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some or all of the technical features therein. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the scope of the technical solutions of the embodiments of this application.

Claims

1. A wire drawing device for welding wire production, characterized in that: Includes a base (1), on which a wire drawing mold (2) and a wire processing mechanism (3) are fixedly arranged in sequence according to the wire drawing direction. The wire processing mechanism (3) includes two wire cleaning modules (4). The wire processing mechanism (3) is also provided with two driving mechanisms (5), which drive the two wire cleaning modules (4) respectively. The welding wire cleaning module (4) includes a housing (41), which is fixedly mounted on the base (1). Two transmission rollers (42) are rotatably mounted inside the housing (41). One of the transmission rollers (42) is connected to the drive mechanism (5). A conveyor belt (43) is mounted on the two transmission rollers (42). Multiple mounting grooves (47) are opened on the conveyor belt (43). A cleaning component (45) is fixedly mounted in each mounting groove (47). The welding wire cleaning module (4) further includes a processing component (46), which is installed inside the housing (41) at one end near the welding wire inlet. The processing component (46) includes a pressure plate (462) near the cleaning component (45), which can be squeezed against the cleaning component (45). A drain port is provided at the bottom of the housing (41) near the processing component (46).

2. The wire drawing device for welding wire production according to claim 1, characterized in that: The processing component (46) also includes a bevel gear set (461), which is installed on the top of the housing (41). The input end is connected to the drive mechanism (5), and the output end is fixedly provided with a lead screw (464). A bolt (465) is sleeved on the lead screw (464), and a pressure plate (462) is fixedly provided below the bolt (465). A sliding groove (463) is provided on the inner top wall of the housing (41), and the top end of the pressure plate (462) is slidably connected in the sliding groove (463).

3. The wire drawing device for welding wire production according to claim 1, characterized in that: The cleaning component (45) includes a fixing seat (451), which is fixedly installed in the mounting groove. The fixing seat (451) is fixedly provided with a mounting seat (452) by a nut, and a cleaning cotton (453) is fixedly provided on the mounting seat (452).

4. The wire drawing device for welding wire production according to claim 1, characterized in that: The welding wire cleaning module (4) also includes an adjusting component (44) installed in the housing (41). The adjusting component (44) abuts against the conveyor belt (43) near the welding wire side. The adjusting component (44) includes a slide rail (441), a screw (442), and an adjusting slide (443). The slide rail (441) is opened on the inner top wall of the housing (41). An adjusting slide (443) is slidably arranged in the slide rail (441). The adjusting slide (443) is provided with a screw (442) by means of a thread. The screw (442) is rotatably arranged on the inner wall of the housing (41).

5. The wire drawing device for welding wire production according to claim 4, characterized in that: A knob is rotatably provided outside the housing (41), and the knob is also connected to the screw (442).

6. The wire drawing device for welding wire production according to claim 2, characterized in that: The drive mechanism (5) includes a transmission component (57) and a pulley assembly (58). The transmission component (57) and the pulley assembly (58) are mounted on the housing (41). The transmission component (57) is connected to the transmission roller (42). The input end of the pulley assembly (58) is connected to the transmission component (57), and the output end is connected to the bevel gear set (461).

7. The wire drawing device for welding wire production according to claim 6, characterized in that: The transmission component (57) includes a rotating wheel (571) which is rotatably mounted on the housing (41). The rotating wheel (571) is connected to the input end of the pulley assembly (58). A ratchet (572) is provided inside the rotating wheel (571), and the ratchet (572) is also connected to the transmission roller (42). Multiple spikes (573) are also rotatably mounted around the circumference inside the rotating wheel (571), and a torsion spring is provided at the connection between the spikes (573) and the rotating wheel (571).

8. The wire drawing device for welding wire production according to claim 7, characterized in that: The drive mechanism (5) also includes a motor (51), which is fixedly mounted on the housing (41). A cam (52) is fixedly mounted on the output end of the motor (51). The cam (52) is rotatably mounted on the housing (41). A bearing seat (53) is fixedly mounted on the housing (41). A slide rod (55) is slidably mounted through the bearing seat (53). A roller (510) is rotatably mounted on one end of the slide rod (55) near the motor (51). The roller (510) abuts against the surface of the cam (52). A rack (56) is fixedly mounted on the other end of the slide rod (55). A compression spring (54) is provided between the bearing seat (53) and the slide rod (55), and a gear (59) is provided on the outer sleeve of the rotating wheel (571), the gear (59) meshing with the rack (56).