A steel wire rotary dry rubbing device

By using a rotating cage filled with steel wool on the surface of the steel wire, the problem of low cleaning efficiency in existing devices is solved, and the thorough removal and efficient collection of dust on the surface of the steel wire are achieved.

CN224423633UActive Publication Date: 2026-06-30SHANDONG TENGHE MACHINERY EQUIP MFG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANDONG TENGHE MACHINERY EQUIP MFG CO LTD
Filing Date
2025-07-30
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

In existing steel wire surface residue removal devices, the steel wire brush has a limited contact area and the blanket is easily detached from the steel wire surface after wear, resulting in low removal efficiency.

Method used

The structure uses a rotating cage filled with steel wool. The steel wool in the rotating cage removes dust from the surface of the steel wool through friction. The steel wool is then guided by a guiding mechanism, and the dust is collected by a collection mechanism.

Benefits of technology

It improves the thoroughness and efficiency of dust removal from the steel wire surface, ensures full contact between the steel wool and the steel wire, and enhances the cleaning effect.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a steel wire rotary dry wiping device, relating to the technical field of steel wire surface residue removal devices; it includes a frame, a wiping mechanism, and a collection mechanism; the wiping mechanism is connected to the top of the frame; the wiping mechanism includes steel wool, a rotating cage, an input shaft, and an output shaft; one end of the rotating cage is rotatably connected to one side of the frame via the input shaft, and the other end of the rotating cage is rotatably connected to the other side of the frame via the output shaft; the rotating cage is filled with multiple steel wool, the input shaft has a first opening corresponding to the rotating cage, and the output shaft has a second opening corresponding to the rotating cage; the steel wire enters the rotating cage through the first opening, and the steel wool in the rotating cage rubs the steel wire to remove dust from the surface of the steel wire, and the steel wire is output through the second opening; the collection mechanism is connected to the frame below the wiping mechanism; it is capable of collecting the dust that falls from the wiping mechanism.
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Description

Technical Field

[0001] This utility model belongs to the technical field of steel wire surface residue removal device, specifically relating to a steel wire rotary dry wiping device. Background Technology

[0002] To improve drawing efficiency and quality during the wire drawing process, drawing powder is typically coated onto the surface of the wire. This powder forms a lubricating film on the wire surface, enhancing lubrication between the wire and the drawing device, preventing friction, and extending the life of the drawing die. However, drawing powder can easily remain on the wire surface during drawing, affecting subsequent wire processing. Therefore, a wire surface residue removal device is needed to remove the dust from the wire surface.

[0003] Existing wire wire surface residue removal devices use rotating wire brushes to remove dust from the wire surface. However, with the wire constantly moving, the area of ​​the wire brush in contact with the wire surface is limited, leaving some residue unremoved and resulting in poor dust removal efficiency. Other dust removal devices use felt to apply pressure to the wire, but over time, the felt wears down and fails, leaving significant residue on the wire surface. These devices require additional rotary motors to constantly adjust the felt's wiping angle and monitor its position, which is time-consuming and labor-intensive. Furthermore, they require additional compression cylinders to apply pressure to the felt to press it firmly against the wire. Since the felt is long and lightweight, the compression cylinder's connection range to the felt is limited. Therefore, in areas without compression cylinders, the felt easily detaches from the wire, significantly reducing the efficiency of removing residue from the wire surface. Utility Model Content

[0004] This invention provides a steel wire rotary dry wiping device to solve the problems of incomplete residue removal using traditional steel wire brushes and reduced residue removal efficiency when using felt, where the felt part without a compression cylinder is prone to detaching from the steel wire surface due to the lack of pressure from the compression cylinder.

[0005] The technical solution adopted in this utility model is as follows:

[0006] A steel wire rotary dry wiping device includes a frame, a wiping mechanism, and a collecting mechanism;

[0007] The erasing mechanism is connected to the top of the frame;

[0008] The wiping mechanism includes steel wool, a rotating cage, an input shaft, and an output shaft. One end of the rotating cage is rotatably connected to one side of the frame via the input shaft, and the other end of the rotating cage is rotatably connected to the other side of the frame via the output shaft. The rotating cage is filled with multiple steel wool balls. The input shaft has a first opening corresponding to the rotating cage, and the output shaft has a second opening corresponding to the rotating cage. Steel wool enters the rotating cage through the first opening and is rubbed by the steel wool balls in the rotating cage to remove dust from the surface of the steel wool. The steel wool is then output through the second opening. A collection mechanism is connected to the frame below the wiping mechanism to collect the dust that falls from the wiping mechanism.

[0009] The steel wire rotary dry wiping device also includes a guiding mechanism; the guiding mechanism includes a first guiding mechanism and a second guiding mechanism, the first guiding mechanism is connected to the side of the frame corresponding to the first opening, and the second guiding mechanism is connected to the side of the frame corresponding to the second opening; the steel wire, under the action of the wire drawing machine, enters the rotating cage through the first guiding mechanism and the first opening to wipe off surface dust, and then exits through the second guiding mechanism and the second opening.

[0010] The first guiding mechanism includes a first bracket, a first rotating roller assembly, and a second rotating roller assembly; the first bracket is connected to the frame, the first rotating roller assembly is vertically connected to the first bracket, the second rotating roller assembly is disposed on the side of the first rotating roller facing the frame, and the second rotating roller assembly is horizontally connected to the first bracket.

[0011] The second guiding mechanism includes a second bracket, a third rotating roller assembly, and a fourth rotating roller assembly; the second bracket is connected to the frame, the third rotating roller assembly is vertically connected to the second bracket, the fourth rotating roller assembly is disposed on the side of the third rotating roller assembly facing the frame, and the fourth rotating roller assembly is horizontally connected to the second bracket.

[0012] The rotating cage includes multiple rotating plates and multiple rotating rods; one end of the multiple rotating rods along the axial direction is connected to the input rotating shaft, and the other end of the multiple rotating rods along the axial direction is connected to the output rotating shaft. The multiple rotating plates are spaced apart along the axial direction of the rotating rods, and each rotating plate is connected through the multiple rotating rods. The multiple rotating rods can be spaced apart along the circumference of the rotating plates, so that the multiple rotating plates and the multiple rotating rods form a cage-like structure with internal cavities.

[0013] The rotating plate has a through hole at its center, and the through holes of multiple rotating plates arranged along the axis of the rotating rod are connected to form a guide channel for conveying steel wire; the rotating plate has multiple mounting holes in its circumference for connecting the rotating rod.

[0014] The rotating plate is also provided with an installation groove. One end of the installation groove is set inside the rotating plate, and the other end of the installation groove extends through the edge of the rotating plate. One of the rotating rods is connected to the installation groove through a first fastening component, so that when the first fastening component is loosened, the rotating rod can be removed from the installation groove, making it easier to fill the steel wool into the rotating cage.

[0015] The rotating plate has multiple fastening holes corresponding to the mounting holes on its periphery. The corresponding rotating rods are fastened by connecting the second fastening component to the mounting holes.

[0016] The steel wire rotary dry rubbing equipment also includes a drive unit, which includes a drive motor, a transmission assembly, and a positioning assembly. The positioning assembly includes a first positioning plate and a second positioning plate. The first positioning plate is connected to the frame, and the second positioning plate is connected to the first positioning plate by fastening bolts. The second positioning plate is connected to the drive motor, and the drive motor is connected to the input shaft through the transmission assembly.

[0017] The top of the frame is connected to a cover plate, and the top of the cover plate is connected to a handle. The cover plate is opened by using the handle to install the rotating cage.

[0018] Due to the adoption of the above technical solution, the beneficial effects achieved by this utility model are as follows:

[0019] 1. This application relates to a steel wire rotary dry wiping device, comprising a frame, a wiping mechanism, and a collection mechanism; the wiping mechanism is connected to the top of the frame; the wiping mechanism includes steel wool, a rotating cage, an input shaft, and an output shaft; one end of the rotating cage is rotatably connected to one side of the frame via the input shaft, and the other end of the rotating cage is rotatably connected to the other side of the frame via the output shaft; the rotating cage is filled with multiple steel wool, the input shaft has a first opening corresponding to the rotating cage, and the output shaft has a second opening corresponding to the rotating cage; the steel wire enters the rotating cage through the first opening, and the steel wool in the rotating cage rubs the steel wire to remove dust from the surface of the steel wire, and the steel wire is output through the second opening; the collection mechanism is connected to the frame below the wiping mechanism; it is capable of collecting the dust falling from the wiping mechanism.

[0020] In this application, the rotating cage, besides having space reserved for the movement of the steel wire, is filled with steel wool spheres circumferentially around the steel wire. The purpose of this design is that the steel wire enters the rotating cage through the first opening, and the wiping action of the steel wool spheres within the rotating cage removes residual dust from the surface of the steel wire. One end of the rotating cage is connected to the input shaft, and the other end is connected to the output shaft. Both the input and output shafts are rotatably connected to the frame, so the rotating cage can rotate under the combined action of the input and output shafts. In other words, the steel wool spheres inside the rotating cage not only come into contact with the steel wire but also benefit from the rotation of the cage. The steel wire is subjected to rotational friction. Since the steel wire is surrounded by steel wool balls, it is equivalent to the steel wool balls rotating around the steel wire. The steel wire can also move linearly between the steel wool balls, shuttling along the length direction of the rotating cage, i.e., the axis direction. This achieves bidirectional movement between the steel wool balls and the steel wire, enhancing the efficiency of the rotational rubbing of the steel wire by the steel wool balls. This makes the removal of residues on the outer surface of the steel wire more thorough and improves the cleaning efficiency. Moreover, the steel wool balls of this application can maintain the technical effect of rotational rubbing of the steel wire under the restriction of the rotating cage, thereby further ensuring sufficient contact between the steel wool balls and the steel wire and improving the rubbing efficiency. Attached Figure Description

[0021] The accompanying drawings, which are included to provide a further understanding of the present invention and constitute a part of this invention, illustrate exemplary embodiments of the present invention and, together with the description thereof, serve to explain the present invention and do not constitute an undue limitation thereof. In the drawings:

[0022] Figure 1 This is a schematic diagram of the overall structure of a steel wire rotary dry rubbing device according to one embodiment of this application;

[0023] Figure 2 This is a schematic diagram of the internal structure of the frame of a steel wire rotary dry rubbing device according to one embodiment of this application;

[0024] Figure 3 This is a schematic diagram of the wiping mechanism of a steel wire rotary dry wiping device according to one embodiment of this application;

[0025] Figure 4 This is a schematic diagram of the wiping mechanism of a steel wire rotary dry wiping device according to one embodiment of this application, taken from another angle.

[0026] Figure 5 This is a schematic diagram of the drive device of a steel wire rotary dry rubbing device according to one embodiment of this application;

[0027] Figure 6 This is a schematic diagram of the structure of the first guide mechanism of a steel wire rotary dry rubbing device according to one embodiment of this application;

[0028] In the picture,

[0029] 1. Frame; 2. Erasing mechanism; 21. Rotating cage; 211. Rotating plate; 212. Rotating rod; 22. Input shaft; 23. Output shaft; 3. Collection mechanism; 4. Guiding mechanism; 41. First guiding mechanism; 411. First support; 412. First rotating roller assembly; 413. Second rotating roller assembly; 42. Second guiding mechanism; 421. Second support; 422. Third rotating roller assembly; 423. Fourth rotating roller assembly; 5. First opening; 6. 7. Second opening; 8. Mounting slot; 9. First fastening assembly; 10. Second fastening assembly; 11. Drive motor; 12. First transmission wheel; 13. Second transmission wheel; 14. First positioning plate; 15. Second positioning plate; 16. Cover plate; 17. Handle; 18. First positioning rod; 19. Second positioning rod; 20. Long strip hole; 30. Positioning hole; 41. First mounting plate; 52. Second mounting plate; 63. Third mounting plate; 74. Fourth mounting plate; 85. Through hole. Detailed Implementation

[0030] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Therefore, the scope of protection of the present invention is not limited to the specific embodiments disclosed below.

[0031] Furthermore, it should be understood in the description of this utility model that the terms "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", etc., indicate the orientation or positional relationship 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.

[0032] In this utility model, unless otherwise explicitly specified and limited, the terms "installation," "connection," "linking," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection, an electrical connection, or a communication connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model according to the specific circumstances.

[0033] In this invention, unless otherwise expressly specified and limited, the first feature "on" or "below" the second feature may be in direct contact with the first and second features, or indirect contact through an intermediate medium. In the description of this specification, references to terms such as "implementation," "example," "aspect," or "specific example" indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of this invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.

[0034] To more clearly illustrate the overall concept of this utility model, a detailed description will be provided below with reference to the accompanying drawings.

[0035] This utility model relates to a steel wire rotary dry rubbing device, such as... Figure 1-6 As shown, it includes a frame 1, an erasing mechanism 2, and a collection mechanism 3;

[0036] The wiping mechanism 2 is connected to the top of the frame 1;

[0037] The wiping mechanism 2 includes steel wool, a rotating cage 21, an input shaft 22, and an output shaft 23. One end of the rotating cage 21 is rotatably connected to one side of the frame 1 via the input shaft 22, and the other end of the rotating cage 21 is rotatably connected to the other side of the frame 1 via the output shaft 23. The rotating cage 21 is filled with multiple steel wool balls. The input shaft 22 has a first opening 5 corresponding to the rotating cage 21, and the output shaft 23 has a second opening 6 corresponding to the rotating cage 21. The steel wire enters the rotating cage 21 through the first opening 5, and the steel wool balls in the rotating cage 21 rub against the steel wire to remove dust from its surface. The steel wire is then output through the second opening 6. A collection mechanism 3 is connected to the frame 1 below the wiping mechanism 2 and is capable of collecting the dust that falls from the wiping mechanism 2.

[0038] In use, the steel wire enters the rotating cage 21 through the first opening 5, then exits through the second opening 6. The rotating cage 21 is filled with multiple steel wool balls, arranged around the central through-hole 70 described below, and also along the length of the rotating cage 21. This arrangement fills the circumference of the steel wire with steel wool balls, except for the space reserved for its movement. The purpose of this arrangement is to remove residual dust from the surface of the steel wire as it enters the rotating cage 21 through the first opening 5, where the steel wool inside the rotating cage 21 acts as a cleaning agent. One end of the rotating cage 21 is connected to the input shaft 22, and the other end is connected to the output shaft 23. The input shaft 22 and the output shaft 23 are rotatably connected to the frame 1. Therefore, during input rotation... Under the combined action of shaft 22 and output shaft 23, the rotating cage 21 can rotate. That is to say, the steel wool in the rotating cage 21 can not only contact the steel wire, but also rotate and rub the steel wire under the action of the rotation of the rotating cage 21. Since the steel wire is surrounded by steel wool, it is equivalent to the steel wool rotating around the steel wire. The steel wire can also move linearly between the steel wool and shuttle along the length direction of the rotating cage 21, that is, the axial direction. This realizes bidirectional movement between the steel wool and the steel wire, enhances the efficiency of the steel wool's rotational wiping of the steel wire, makes the removal of residue on the outer surface of the steel wire more thorough, and improves the cleaning efficiency. Moreover, the steel wool of this application can always maintain the technical effect of rotational wiping of the steel wire under the restriction of the rotating cage 21, thereby further ensuring full contact between the steel wool and the steel wire and improving the wiping efficiency.

[0039] It should be noted that the input shaft 22 is rotatably connected to the frame 1 via bearings, and the output shaft 23 is rotatably connected to the frame 1 via bearings. Both bearings are sealed with two skeleton oil seals to prevent dust.

[0040] In a preferred embodiment, the steel wire rotary dry wiping device further includes a guiding mechanism 4; the guiding mechanism 4 includes a first guiding mechanism 41 and a second guiding mechanism 42, the first guiding mechanism 41 is connected to the side of the frame 1 corresponding to the first opening 5, and the second guiding mechanism 42 is connected to the side of the frame 1 corresponding to the second opening 6; the steel wire, under the action of the wire drawing machine, enters the rotating cage 21 through the first guiding mechanism 41 and the first opening 5 to wipe off surface dust, and then exits through the second guiding mechanism 42 and the second opening 6.

[0041] like Figure 1-2 As shown, the guide mechanism 4 is disposed on both sides of the frame 1. For ease of distinction, the guide mechanism 4 includes a first guide mechanism 41 and a second guide mechanism 42. The first guide mechanism 41 and the second guide mechanism 42 have the same structure and are symmetrically arranged along both sides of the frame 1. Specifically, as shown... Figure 1As shown, a first connecting hole is provided on the left side of the frame 1. The first connecting hole is used to rotatably connect the input shaft 22. A first opening 5 is provided on one side of the input shaft 22 along the axial direction corresponding to the first connecting hole. A second connecting hole is provided on the right side of the frame 1. The second connecting hole is used to install the output shaft 23. A second opening 6 is provided on the output shaft 23 along the axial direction corresponding to the second connecting hole. A first guide mechanism 41 is connected to the frame 1 corresponding to the first connecting hole, so that the steel wire can be input into the first opening 5 through the first guide mechanism 41, and then the steel wire is output through the second opening 6 and the second guide mechanism 42.

[0042] Furthermore, the first guide mechanism 41 includes a first bracket 411, a first rotating roller assembly 412, and a second rotating roller assembly 413; the first bracket 411 is connected to the frame 1, the first rotating roller assembly 412 is vertically connected to the first bracket 411, the second rotating roller assembly 413 is disposed on the side of the first rotating roller facing the frame 1, and the second rotating roller assembly 413 is horizontally connected to the first bracket 411.

[0043] The first support 411 is connected to the left side of the frame 1. The first support 411 includes a bottom support and side supports connected to the four sides of the bottom support. A first guide hole corresponding to the first opening 5 is provided on the bottom support. A second rotating roller assembly 413 is connected between the two side supports in the horizontal direction, and a first rotating roller assembly 412 is connected between the two side supports in the vertical direction. The first rotating roller assembly 412 is disposed outside the second rotating roller assembly 413. The first rotating roller assembly 412 includes a first rotating roller and a second rotating roller. The first rotating roller includes a first roller wheel and a first shaft. The shaft is connected to the side supports on both sides along the axial direction. The first roller is connected to the first shaft. The second rotating roller includes a second roller and a second shaft. The second shaft is connected to the side supports on both sides along the vertical direction. The second roller is connected to the second shaft. A preset distance is reserved between the first rotating roller and the second rotating roller so that the steel wire can pass between the first roller and the second roller. This can straighten the steel wire and guide it, so that the steel wire can smoothly enter the first opening 5 of the input rotating shaft 22 through the first roller and the second roller.

[0044] The second rotating roller assembly 413 includes a third rotating roller and a fourth rotating roller. The third rotating roller and the fourth rotating roller are connected between two symmetrical side supports along the horizontal direction. The third rotating roller is perpendicular to the first rotating roller, and the fourth rotating roller is perpendicular to the first rotating roller. A preset gap is reserved between the third rotating roller and the fourth rotating roller to allow the steel wire to pass through between them. The gap between the third rotating roller and the fourth rotating roller needs to correspond to the gap between the first rotating roller and the second rotating roller to facilitate the steel wire to pass smoothly between the third rotating roller and the fourth rotating roller after passing between the first rotating roller and the second rotating roller. The third rotating roller includes a third roller wheel and a third shaft. The two sides of the third shaft along the axial direction are respectively connected between the two side supports along the horizontal direction, and the third roller wheel is connected to the third shaft. The fourth rotating roller includes a fourth roller wheel and a fourth shaft. The two sides of the fourth shaft along the axial direction are respectively connected between the two side supports along the horizontal direction, and the fourth roller wheel is connected to the fourth shaft.

[0045] Furthermore, the second guide mechanism 42 includes a second bracket 421, a third rotating roller assembly 422, and a fourth rotating roller assembly 423; the second bracket 421 is connected to the frame 1, the third rotating roller assembly 422 is vertically connected to the second bracket 421, the fourth rotating roller assembly 423 is disposed on the side of the third rotating roller assembly 422 facing the frame 1, and the fourth rotating roller assembly 423 is horizontally connected to the second bracket 421.

[0046] The second guide mechanism 42 has the same structure as the first guide mechanism 41 and is symmetrically arranged on both sides of the frame 1. Therefore, the structure of the second guide mechanism 42 will not be described in detail. The third rotating roller assembly 422 of the second guide mechanism 42 has the same structure as the first rotating roller assembly 412 of the first guide mechanism 41 and is symmetrical. The fourth rotating roller assembly 423 of the second guide mechanism 42 has the same structure as the second rotating roller assembly 413 of the first guide mechanism 41 and is symmetrical. A preset gap is reserved between the fifth and sixth rotating rollers in the third rotating roller assembly 422 and between the seventh and eighth rotating rollers in the fourth rotating roller assembly 423, so that the steel wire can pass through the preset gap.

[0047] In a preferred embodiment, the rotating cage 21 includes a plurality of rotating plates 211 and a plurality of rotating rods 212; one end of the plurality of rotating rods 212 along the axial direction is connected to the input rotating shaft 22, and the other end of the plurality of rotating rods 212 along the axial direction is connected to the output rotating shaft 23; the plurality of rotating plates 211 are spaced apart along the axial direction of the rotating rods 212, and each rotating plate 211 is connected through the plurality of rotating rods 212; the plurality of rotating rods 212 can be spaced apart along the circumference of the rotating plates 211, so that the plurality of rotating plates 211 and the plurality of rotating rods 212 form a cage-like structure with an internal cavity.

[0048] One end of the rotating cage 21 is connected to the input rotating shaft 22, and the other end of the rotating cage 21 is connected to the output rotating shaft 23. The rotating cage 21 consists of multiple rotating plates 211 and multiple rotating rods 212, as shown below. Figure 2 and Figure 3 As shown, multiple rotating plates 211 are spaced apart along the length of the frame 1. The leftmost rotating plate 211 is connected to the input shaft 22, and the rightmost rotating plate 211 is connected to the output shaft 23. The multiple rotating plates 211 are connected by rotating rods 212. Multiple rotating rods 212 are provided and spaced apart circumferentially along the rotating cage 21. One end of the rotating rod 212 along the axial direction is connected to the input shaft 22 through the leftmost rotating plate 211, and the other end of the rotating rod 212 along the axial direction is connected to the output shaft 23 through the rightmost rotating plate 211. Therefore, the multiple rotating rods 212 can be distributed spaced apart circumferentially along the rotating plates 211, so that the multiple rotating plates 211 and the multiple rotating rods 212 form a cage-like structure with an internal cavity. The steel wool can be filled into the cavity.

[0049] Furthermore, a through hole 70 is provided in the center of the rotating plate 211, and the through holes 70 of multiple rotating plates 211 arranged along the axial direction of the rotating rod 212 are connected to form a guide channel for conveying steel wire; steel wire balls are arranged around the guide channel so that space is reserved between the steel wire balls to allow the steel wire to pass through. That is to say, a through hole 70 is provided in the center of the rotating plate 211, and steel wire balls are filled around the through hole 70 to reserve space for the steel wire to pass through.

[0050] Furthermore, the rotating plate 211 is provided with a plurality of mounting holes in the circumference for through-connecting the rotating rod 212.

[0051] The rotating plate 211 has multiple mounting holes for the rotating rod 212 to pass through and connect, such as Figure 2 As shown, this application preferably provides four rotating rods 212, and eight rotating plates 211 are provided on the four rotating rods 212 at intervals. Each rotating plate 211 is provided with four mounting holes, which are used to install the rotating rods 212 respectively. The rotating plate 211 is also provided with a slot, which is connected to one of the mounting holes to form a mounting groove 7. One end of the mounting groove 7 is located in the rotating plate 211, and the other end of the mounting groove 7 extends through the edge of the rotating plate 211. One of the rotating rods 212 is connected to the mounting groove 7 through a first fastening component 8, so that when the first fastening component 8 is loosened, the rotating rod 212 can be removed from the mounting groove 7, which facilitates the filling of the steel wool into the rotating cage 21.

[0052] The first fastening assembly 8 includes a first fastening bolt and a first fastening nut; the first fastening nut is connected to the first fastening bolt. To achieve positioning and fastening of the rotating rod 212 located within the mounting groove 7, a first fastening hole is also provided on the circumference of the rotating plate 211 corresponding to the mounting groove 7. The first fastening hole extends radially into the mounting groove 7. Thus, when the rotating rod 212 is connected to the mounting groove 7, the first fastening bolt passes through the first fastening hole, and the first fastening nut is screwed onto the first fastening bolt, thereby allowing the first fastening bolt to fasten the rotating rod 212 to the mounting groove 7. This arrangement facilitates the installation of the steel wool in the rotating cage 21 or its removal for replacement. When the steel wool needs to be replaced... By loosening the first fastening nut and removing the first fastening bolt from the first fastening hole, the rotating rod 212 is removed from the mounting slot 7 of each rotating plate 211. Then, steel wool is filled into the rotating cage 21 or removed from the rotating cage 21 for replacement. When it is necessary to encapsulate the rotating cage 21, the rotating rod 212 is passed through the mounting slots 7 of multiple rotating plates 211 until it abuts against the bottom wall of the mounting slot 7. Then, the first fastening bolt is inserted into the first fastening hole, and the first fastening nut is screwed onto the first fastening bolt. This allows the rotating rod 212 to be installed in multiple rotating plates 211, thereby encapsulating the rotating cage 21.

[0053] In addition, in order to enable the other three rotating rods 212 to be fastened to the rotating plate 211, a number of fastening holes corresponding to the mounting holes are provided on the periphery of the rotating plate 211. The corresponding rotating rods 212 are fastened to the mounting holes by connecting the second fastening assembly 9. Specifically, this application uses four rotating rods 212, so four mounting holes are provided on the rotating plate 211. One mounting hole is connected to the slot to form a mounting groove 7, and the other three mounting holes are used to connect the three rotating rods 212 respectively. Three fastening holes are opened on the periphery of the rotating plate 211, corresponding to the three mounting holes, and are respectively marked as the second fastening hole, the third fastening hole, and the fourth fastening hole. The second fastening hole corresponds to one of the mounting holes, the third fastening hole corresponds to one of the mounting holes, and the fourth fastening hole corresponds to one of the mounting holes. The second fastening assembly 9 is connected to the second fastening hole, the third fastening hole, and the fourth fastening hole respectively. The second fastening assembly 9 includes a second fastening bolt and a second fastening nut. The corresponding rotating rods 212 are inserted into the corresponding second fastening hole, the third fastening hole, and the fourth fastening hole, and then fastened by the second fastening bolt and the second fastening nut.

[0054] In a preferred embodiment, the steel wire rotary dry rubbing device further includes a drive unit, which includes a drive motor 10, a transmission assembly, and a positioning assembly. The positioning assembly includes a first positioning plate 13 and a second positioning plate 14. The first positioning plate 13 is connected to the frame 1, and the second positioning plate 14 is connected to the first positioning plate 13 by fastening bolts. The second positioning plate 14 is connected to the drive motor 10, and the drive motor 10 is connected to the input shaft 22 through the transmission assembly.

[0055] like Figure 5 As shown, the driving device includes a drive motor 10, which is connected to a transmission assembly. The transmission assembly includes a first transmission wheel 11 and a second transmission wheel 12. The first transmission wheel 11 is connected to the drive motor 10, and the second transmission wheel 12 is connected to the input shaft 22. A belt connects the first transmission wheel 11 and the second transmission wheel 12. The drive motor 10 drives the first transmission wheel 11 to rotate. When the first transmission wheel 11 rotates, it drives the second transmission wheel 12 to rotate via the belt. The rotation of the second transmission wheel 12 realizes the rotation of the input shaft 22, thereby realizing the rotation of the rotating cage 21.

[0056] In addition, the drive unit also includes a positioning assembly, which is used to connect the drive unit and can adjust the tension distance between the first transmission wheel 11 and the second transmission wheel 12 of the drive unit accordingly, so that the first transmission wheel 11 and the second transmission wheel 12 are kept in a tensioned state, preventing the first transmission wheel 11 and the second transmission wheel 12 from becoming loose and affecting the rotation of the rotating cage 21; specifically, the positioning assembly includes a first positioning plate 13 and a second positioning plate 14, the first positioning plate 13 is connected to the frame 1, and the second positioning plate 14 is connected to the first positioning plate 13 by fastening bolts, and the drive motor 10 is fixedly connected to it. The second positioning plate 14 is connected to the first positioning plate 13, which has multiple elongated holes 19. The first positioning plate 13 has multiple positioning holes 20 that correspond to the elongated holes 19. By adjusting the position of the second positioning plate 14 relative to the first positioning plate 13, the second positioning plate 14 can move along the first positioning plate 13. The position of the elongated holes 19 of the second positioning plate 14 relative to the positioning holes 20 of the first positioning plate 13 can be adjusted to adjust the distance between the drive motor 10 connected to the second positioning plate 14 and the first transmission wheel 11 relative to the second transmission wheel 12 above it.

[0057] A first mounting plate 30 protruding from the first positioning plate 13 is also connected to the first positioning plate 13. A second mounting plate 40 protruding from the second positioning plate 14 is also connected to the second positioning plate 14 corresponding to the first positioning plate 13. A first positioning rod 17 is connected between the first mounting plate 30 and the second mounting plate 40. One end of the first positioning rod 17 is inserted into the second mounting plate 40 and fixedly connected to it. The first positioning rod 17 has external threads. The other end of the first positioning rod 17 is inserted into the first mounting plate 30 and connected to it by bolt threads, so that the first positioning rod 17 is tightly connected to the first mounting plate 30. Washers are provided on both sides of the first positioning rod 17 inserted into the first mounting plate 30. The diameter of the washers is larger than the diameter of the inner hole opened in the first mounting plate 30, so that the first positioning rod 17 can be fastened in the first mounting plate 30.

[0058] Similarly, a third mounting plate 50, symmetrical to the first mounting plate 30, is connected to one side of the first positioning plate 13, and a fourth mounting plate 60, symmetrical to the second mounting plate 40, is connected to one side of the second positioning plate 14. A second positioning rod 18 is inserted and connected inside the third mounting plate 50 and the fourth mounting plate 60. The structure of the second positioning rod 18 is the same as that of the first positioning rod 17, so that the first positioning plate 13 and the second positioning plate 14 can be stably connected.

[0059] In a preferred embodiment, a cover plate 15 is connected to the top of the frame 1, and a handle 16 is connected to the top of the cover plate 15. The cover plate 15 is opened by the handle 16 to install the rotating cage 21.

[0060] The frame 1 includes a box structure at the top and supports around the box structure. The box has a hollow interior. A collection device is connected to the bottom of the box structure. A collection port is provided at the bottom of the box. The collection device has a hollow interior and is connected to the collection port. The cross-section of the collection device is triangular, with the length gradually decreasing from top to bottom. A recovery port is provided at the bottom of the collection device. A storage device is provided below the recovery port of the collection device for storing the dust collected from inside the collection device and output through the recovery port.

[0061] For any parts not mentioned in this utility model, existing technologies can be used or referenced.

[0062] The various embodiments in this specification are described in a progressive manner. The same or similar parts between the various embodiments can be referred to each other. Each embodiment focuses on describing the differences from other embodiments.

[0063] The above description is merely an embodiment of this utility model and is not intended to limit the scope of this utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principle of this utility model should be included within the scope of the claims of this utility model.

Claims

1. A steel wire rotary dry rubbing device, characterized in that, Includes the rack, erasing mechanism, and collection mechanism; The erasing mechanism is connected to the top of the frame; The wiping mechanism includes steel wool, a rotating cage, an input shaft, and an output shaft. One end of the rotating cage is rotatably connected to one side of the frame via the input shaft, and the other end of the rotating cage is rotatably connected to the other side of the frame via the output shaft. The rotating cage is filled with multiple steel wool balls. The input shaft has a first opening corresponding to the rotating cage, and the output shaft has a second opening corresponding to the rotating cage. The steel wire enters the rotating cage through the first opening, and the steel wool balls in the rotating cage rub against the steel wire to remove dust from its surface. The steel wire is then output through the second opening. A collection mechanism is attached to the frame below the wiping mechanism; it is capable of collecting the dust that falls from the wiping mechanism.

2. The steel wire rotary dry rubbing device according to claim 1, characterized in that, The steel wire rotary dry rubbing device also includes a guiding mechanism; The guiding mechanism includes a first guiding mechanism and a second guiding mechanism. The first guiding mechanism is connected to the side of the frame corresponding to the first opening, and the second guiding mechanism is connected to the side of the frame corresponding to the second opening. Under the action of the wire drawing machine, the steel wire enters the rotating cage through the first guiding mechanism and the first opening to remove surface dust, and then exits through the second guiding mechanism and the second opening.

3. The steel wire rotary dry rubbing device according to claim 2, characterized in that, The first guiding mechanism includes a first bracket, a first rotating roller assembly, and a second rotating roller assembly; the first bracket is connected to the frame, the first rotating roller assembly is vertically connected to the first bracket, the second rotating roller assembly is disposed on the side of the first rotating roller facing the frame, and the second rotating roller assembly is horizontally connected to the first bracket.

4. The steel wire rotary dry rubbing device according to claim 2, characterized in that, The second guiding mechanism includes a second bracket, a third rotating roller assembly, and a fourth rotating roller assembly; the second bracket is connected to the frame, the third rotating roller assembly is vertically connected to the second bracket, the fourth rotating roller assembly is disposed on the side of the third rotating roller assembly facing the frame, and the fourth rotating roller assembly is horizontally connected to the second bracket.

5. The steel wire rotary dry rubbing device according to claim 1, characterized in that, The rotating cage includes multiple rotating plates and multiple rotating rods; one end of the multiple rotating rods along the axial direction is connected to the input rotating shaft, and the other end of the multiple rotating rods along the axial direction is connected to the output rotating shaft. The multiple rotating plates are spaced apart along the axial direction of the rotating rods, and each rotating plate is connected through the multiple rotating rods. The multiple rotating rods can be spaced apart along the circumference of the rotating plates, so that the multiple rotating plates and the multiple rotating rods form a cage-like structure with internal cavities.

6. The steel wire rotary dry rubbing device according to claim 5, characterized in that, The rotating plate has a through hole at its center, and the through holes of multiple rotating plates arranged along the axis of the rotating rod are connected to form a guide channel for conveying steel wire; the rotating plate has multiple mounting holes in its circumference for connecting the rotating rod.

7. The steel wire rotary dry rubbing device according to claim 6, characterized in that, The rotating plate is also provided with an installation groove. One end of the installation groove is set inside the rotating plate, and the other end of the installation groove extends through the edge of the rotating plate. One of the rotating rods is connected to the installation groove through a first fastening component, so that when the first fastening component is loosened, the rotating rod can be removed from the installation groove, making it easier to fill the steel wool into the rotating cage.

8. The steel wire rotary dry rubbing device according to claim 6, characterized in that, The rotating plate has multiple fastening holes corresponding to the mounting holes on its periphery. The corresponding rotating rods are fastened by connecting the second fastening component to the mounting holes.

9. A steel wire rotary dry rubbing device according to claim 1, characterized in that, The steel wire rotary dry rubbing equipment also includes a drive unit, which includes a drive motor, a transmission assembly, and a positioning assembly. The positioning assembly includes a first positioning plate and a second positioning plate. The first positioning plate is connected to the frame, and the second positioning plate is connected to the first positioning plate by fastening bolts. The second positioning plate is connected to the drive motor, and the drive motor is connected to the input shaft through the transmission assembly.

10. A steel wire rotary dry rubbing device according to claim 1, characterized in that, The top of the frame is connected to a cover plate, and the top of the cover plate is connected to a handle. The cover plate is opened by using the handle to install the rotating cage.