A synchronous fork twisting high-speed wrapping machine for cable processing and a cable

The design of the synchronous fork twisting high-speed wrapping machine solves the problem of uneven wrapping of protective tape in traditional cable wrapping equipment, realizes uniform packaging and wrinkle removal of cables, and improves the protection and appearance quality of cables.

CN120809385BActive Publication Date: 2026-06-09RUITIAN CABLE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
RUITIAN CABLE CO LTD
Filing Date
2025-09-12
Publication Date
2026-06-09

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Abstract

The application relates to the field of cable wrapping, in particular to a synchronous fork-twisting high-speed wrapping machine for cable processing and a cable, which can automatically synchronously fork-twist and wind a protective belt, can avoid the occurrence of wrinkle phenomenon of the protective belt, can prevent the occurrence of the problem of the gap in the wrapping, and comprises a base and a driving motor, the front end and the rear end of the top of the base are respectively provided with a material collecting roller and a material discharging roller, the material collecting roller is driven by the driving motor, a winding drum is arranged at the inlet of the material collecting roller, a follow-up disc and a rotating disc are arranged on the top of the base, and the follow-up disc and the rotating disc are drivingly connected with the driving motor through a linkage shaft. The application can realize synchronous fork-twisting wrapping, can uniformly wrap the outer wall of the cable by the wrapping belt, can automatically tension and scrape the outer surface of the wrapping belt under the action of a transverse scraper and a guide frame, can avoid the occurrence of the wrinkle phenomenon, can eliminate the wrinkle, and can avoid the occurrence of the gap in the wrapping caused by the wrinkle.
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Description

Technical Field

[0001] This invention relates to the field of cable wrapping technology, specifically to a synchronous fork-stirring high-speed wrapping machine for cable processing and a cable. Background Technology

[0002] In the cable processing industry, with increasingly stringent requirements for cable quality and performance, cable wrapping has become a crucial step. Cables, in practical use, need to possess good insulation, abrasion resistance, and anti-interference capabilities, and protective wrapping tape is an important means of achieving these properties. Traditional cable wrapping methods often rely on manual operation, which is not only inefficient but also makes it difficult to guarantee the quality and consistency of the wrapping.

[0003] Currently, common cable wrapping equipment on the market struggles to achieve ideal synchronous twisting when wrapping protective tape. This not only affects the aesthetics of the wrapping but may also cause the protective tape to be wrapped too tightly or too loosely in certain areas, reducing the protective effect on the cable and potentially damaging the cable's insulation layer due to localized stress concentration.

[0004] In the traditional wrapping process, the protective tape may develop wrinkles or the tape itself may have wrinkles. These wrinkles not only affect the appearance quality of the cable and reduce the product's market competitiveness, but also weaken the protective function of the tape for the cable, making it easier for harmful substances such as moisture and dust to penetrate into the cable, thus accelerating the aging and damage of the cable.

[0005] Therefore, the present invention provides a synchronous fork-stirring high-speed wrapping machine for cable processing and a cable to solve the above problems. Summary of the Invention

[0006] In view of the above situation and to overcome the defects of the prior art, the present invention provides a synchronous fork-twisting high-speed wrapping machine for cable processing and a cable, so as to solve the problem of automatically and synchronously fork-twisting and wrapping protective tape, while avoiding wrinkles in the protective tape and preventing gaps in the packaging.

[0007] To achieve the above objectives, the technical solution adopted by the present invention is as follows:

[0008] A synchronous fork-and-twist high-speed wrapping machine for cable processing includes a base and a drive motor. A take-up roller and a release roller are respectively installed at the front and rear ends of the top of the base. The take-up roller is driven by the drive motor, and a winding drum is installed at the inlet of the take-up roller. A follower plate and a rotating plate are installed on the top of the base. The follower plate and the rotating plate are connected to the drive motor via a linkage shaft. A hollow tube is installed between the follower plate and the rotating plate. A packaging frame is installed on the outer wall of the rotating plate. A guide frame is installed on the outer wall of the hollow tube, and a transverse scraper is slidably connected to the outer wall of the guide frame. The transverse scraper is drivenly connected to the packaging frame. This device, through the setting of the follower plate and the rotating plate, enables the packaging tape to rotate synchronously, achieving synchronous fork-and-twist wrapping. This ensures that the packaging tape evenly wraps the outer wall of the cable. Simultaneously, under the action of the transverse scraper and the guide frame, the outer surface of the packaging tape is automatically tensioned and scraped, preventing wrinkles and eliminating wrinkles, and avoiding gaps in the packaging caused by wrinkles.

[0009] Preferably, a bracket one is fixedly installed on the side wall of the front end of the base, the take-up roller is installed on the inner side wall of the bracket one, and the drive motor is fixedly installed on the outer side wall of the bracket one; a bracket two is fixedly installed on the side wall of the rear end of the base, the feed roller is installed on the inner side wall of the bracket two, and a cable is wound on the outer wall of the feed roller; when the device is in use, the drive motor is started to stretch the cable, so that the take-up roller drives the cable to stretch and wind up, and simultaneously drives the feed roller to rotate. The unpackaged cable is wound on the outer wall of the feed roller, and the packaged cable is located on the outer wall of the take-up roller.

[0010] Preferably, there are two guide frames, which are connected by a fixed frame. The outer wall of each guide frame has a guide hole, and a scraper is installed on the outer wall of the guide hole. A horizontal plate is installed on the side wall of the fixed frame. When the rotating disk and the follower disk of this device rotate, they will drive the hollow tube and the packaging rack to rotate. At this time, the guide frame on the outer wall of the hollow tube can rotate with it, thereby realizing the function that the follower disk, the hollow tube, the guide frame and the packaging rack are stationary in relative positions. The packaging strip on the packaging rack passes through the guide hole. At this time, the scraper can initially remove vertical wrinkles, and the multiple guide holes can initially achieve the tensioning function.

[0011] Preferably, a rotating shaft is rotatably connected to the side wall of the horizontal plate, and a first rotating bevel gear is fixedly installed on the outer wall of the rotating shaft. The first rotating bevel gear meshes with a second rotating bevel gear. The second rotating bevel gear is fixedly installed on the outer wall of one end of a reciprocating screw. The reciprocating screw is rotatably connected to the outer wall of the fixed frame. A threaded box is threadedly connected to the outer wall of the reciprocating screw. The transverse scraper is slidably connected inside the threaded box. A resisting spring is fixedly installed on the inner wall of the threaded box. The other end of the resisting spring is fixedly connected to one end of the transverse scraper. A wrinkle-removing block is fixedly installed on the other end of the transverse scraper. There are multiple wrinkle-removing blocks. The wrinkle-removing blocks are arranged in pairs, with two pairs arranged vertically opposite each other. The two groups of wrinkle-removing blocks are connected by a drive belt. When the device is in use, the threaded box rotates with the guide frame. In its initial state, the wrinkle-removing block and the transverse scraper extend under the action of the supporting spring. The wrinkle-removing block abuts against the outer wall of the packaging tape. When the rotating shaft is driven by the two rotating bevel gears, it drives the reciprocating screw to rotate. The two threaded boxes of this device are installed on the outer wall of the reciprocating screw with opposite threads. When the reciprocating screw rotates, the two threaded boxes first move in opposite directions and then move relative to each other, so that the wrinkle-removing block scrapes left and right. When the packaging is started, the threaded boxes of this device can rotate with it. When the threaded boxes move, they can synchronously drive the wrinkle-removing block to move, so as to achieve transverse scraping of the packaging tape, avoid wrinkles on the outer wall of the packaging tape, and prevent incomplete packaging or gaps caused by wrinkles on the packaging tape itself or wrinkles caused by stretching. This device has multiple wrinkle-removing blocks to ensure wrinkle removal efficiency.

[0012] Preferably, a first connecting bevel gear is fixedly installed on the outer wall of the middle part of the rotating shaft; a fixed rotating shaft is rotatably connected to the bottom of the fixed frame, and a second connecting bevel gear is installed on the outer wall of the upper part of the fixed rotating shaft, the second connecting bevel gear meshing with the first connecting bevel gear.

[0013] Preferably, the inner bottom of the fixed rotating shaft is slidably connected to a telescopic shaft via a limiting block. A first drive bevel gear is fixedly installed on the outer wall of the bottom of the telescopic shaft. The first drive bevel gear meshes with a second drive bevel gear. The second drive bevel gear is installed on the outer wall of one end of the mounting shaft. A drive wheel is installed on the outer wall of the middle part of the mounting shaft. The drive wheel abuts against the outer wall of the packaging strap. The other end of the mounting shaft is rotatably connected to the outer wall of the telescopic box. The fixed end of the telescopic box is installed at the bottom of the fixing frame. A compression spring is fixedly installed on the inner wall of the fixed rotating shaft. The other end of the compression spring is fixedly connected to one end of the telescopic shaft. The interior of the fixed rotating shaft... The structure is the same as the internal structure of the telescopic box. In the initial state, the drive wheel of this device extends outward under the action of the compression spring, so that the drive wheel can always be tightly pressed against the outer wall of the packaging strap. At the same time, the drive wheel presses against the packaging strap, achieving tensioning again and satisfying the multiple tensioning function. This enables multiple steps to remove vertical wrinkles and avoid the formation of wrinkles. When the drive wheel rotates, the telescopic shaft is driven to rotate under the action of the two drive bevel teeth. Under the action of the fixed rotating shaft, the wrinkle removal block is driven to move, realizing the linkage function. This allows the removal of vertical wrinkles and the removal of horizontal wrinkles to be achieved simultaneously, forming a linkage function.

[0014] Preferably, a first fixing plate and a second fixing plate are fixedly installed at the top two ends of the base, respectively. The rotating disk is rotatably connected to the inner wall of the second fixing plate, and the follower disk is rotatably connected to the outer wall of the first fixing plate. External teeth are provided on the outer wall of the follower disk, and a drive gear is fixedly installed on the outer wall of the linkage shaft. The drive gear meshes with the follower disk. A cable hole is opened in the middle of the follower disk, and a fork-and-loop hole is opened at one end of the surface of the follower disk. The follower disk has the same structure as the rotating disk. When using this device, the cable is passed through the cable hole, and the packaging tape is passed through the fork-and-loop hole, so that the packaging tape wraps and packages the cable. Through the linkage shaft, this device enables the wrapping and cable winding to be linked, so that the fork-and-loop wrapping function is only activated when winding begins, thus avoiding energy waste.

[0015] Preferably, a compression spring is fixedly installed on the inner wall of the winding drum, and a compression arc plate is fixedly installed on the other end of the compression spring. There are multiple compression arc plates, and the compression arc plates are matched with the cable. After the wrapping is completed, the device can compress the outer wall of the cable again through the compression arc plates to prevent the packaging tape on the outer wall of the cable from falling off.

[0016] Preferably, the output end of the driving motor is drivingly connected to the gear control box, and one end of the linkage shaft is drivingly connected to the gear control box through a driving belt; the device can adjust the rotation speed of the linkage shaft through the gear control box to meet the requirements for different speeds and the winding control of the cable in sequence.

[0017] A cable, the cable includes a core, an insulating layer, a fireproof layer, a protective layer and a wrapping tape, and the outer wall of the core is sequentially wrapped with an insulating layer, a fireproof layer, a protective layer and a wrapping tape.

[0018] The beneficial effects of the present invention are as follows:

[0019] 1. Through the settings of the follower disc and the rotating disc, the device can make the packaging tape rotate synchronously, realize synchronous cross winding and wrapping, make the packaging tape evenly wrap the outer wall of the cable. At the same time, under the action of the transverse scraper and the guide frame, it can automatically tension and scrape the outer surface of the packaging tape, avoid the appearance of wrinkles, eliminate wrinkles, and avoid the phenomenon of gaps in the packaging caused by wrinkles.

[0020] 2. When the device starts packaging, the threaded box of the device can rotate accordingly. When the threaded box moves, it can synchronously drive the wrinkle removal block to displace, realize the transverse scraping of the packaging tape, avoid the appearance of wrinkles on the outer wall of the packaging tape, and prevent the phenomenon of incomplete packaging or gaps caused by the wrinkles inherent in the packaging tape or the wrinkles generated during stretching. There are multiple wrinkle removal blocks in the device, which can ensure the wrinkle removal efficiency.

[0021] 3. In the initial state, the driving wheel of the device extends outwards under the action of the compression spring, so that the driving wheel can always tightly abut against the outer wall of the packaging tape. At the same time, the driving wheel plays a role in pressing the packaging tape tightly, realizes re-tensioning, meets the function of multiple tensionings, realizes the removal of vertical wrinkles in multiple steps, avoids the generation of wrinkles. At the same time, when the driving wheel rotates, under the action of two driving bevel gears, it drives the telescopic shaft to rotate. Under the action of the fixed rotating shaft, it drives the wrinkle removal block to act, realizes the linkage function, and synchronously realizes the removal of vertical wrinkles and horizontal wrinkles, and the two form a linkage function.

[0022] 4. Through the setting of the linkage shaft, the device can make the winding of the device and the winding of the cable form a linkage function, so that the cross winding function will only be started when the winding is started, and the phenomenon of energy waste can be avoided.

[0023] 5. After the winding is completed, the device can re-press the outer wall of the cable through the pressing arc plate to avoid the phenomenon of the packaging tape falling off the outer wall of the cable; the device can adjust the rotation speed of the linkage shaft through the gear control box to meet the requirements for different speeds and the winding control of the cable in sequence. BRIEF DESCRIPTION OF THE DRAWINGS

[0024] Figure 1 This is a schematic diagram of the front view of the present invention.

[0025] Figure 2 This is a schematic diagram of the second front view of the present invention.

[0026] Figure 3 This is a three-dimensional schematic diagram of the guide frame of the present invention.

[0027] Figure 4 This is a three-dimensional schematic diagram of the threaded box of the present invention.

[0028] Figure 5 This is a schematic side view of the threaded box of the present invention.

[0029] Figure 6 For the present invention Figure 1 A magnified diagram of point A in the middle.

[0030] Figure 7 This is a three-dimensional schematic diagram of the fixed rotating shaft of the present invention.

[0031] Figure 8 This is a schematic cross-sectional view of the fixed rotating shaft of the present invention.

[0032] Figure 9 This is a schematic diagram showing the connection between the fixed plate and the follower disk of the present invention.

[0033] Figure 10 This is a schematic diagram of the interior of the winding drum of the present invention.

[0034] Figure 11 This is a schematic diagram of the cable of the present invention.

[0035] In the picture: 1. Base;

[0036] 2. Receiving roller; 201. Support bracket one;

[0037] 3. Feeding roller; 301. Support bracket two;

[0038] 4. Drive motor; 401. Gear control box; 402. Drive belt;

[0039] 5. Follower plate; 501. Fixing plate one; 502. Cable hole; 503. Fork hinge hole;

[0040] 6. Rotating disc; 601. Fixed plate two;

[0041] 7. Linkage shaft; 701. Drive gear;

[0042] 8. Hollow tube; 9. Packaging rack;

[0043] 10. Guide frame; 1001. Fixing frame; 1002. Guide hole; 1003. Scraper box; 1004. Horizontal plate;

[0044] 11. Horizontal scraper; 1101. Rotating shaft; 1102. First rotating bevel gear; 1103. Reciprocating lead screw; 1104. Second rotating bevel gear; 1105. Threaded box; 1106. Wrinkle-removing block; 1107. Pushing spring; 1108. Drive belt; 1109. Fixed rotating shaft; 1111. Second connecting bevel gear; 1112. Telescopic shaft; 1113. First driving bevel gear; 1114. Second driving bevel gear; 1115. Mounting shaft; 1116. Drive wheel; 1117. Telescopic box; 1118. Compression spring;

[0045] 12. Winding drum; 1201. Compression spring; 1202. Compression arc plate;

[0046] 13. Cable; 1301. Insulation layer; 1302. Fireproof layer; 1303. Protective layer; 1304. Wrapping tape; 1305. Battery cell. Detailed Implementation

[0047] The embodiments of the present invention will now be described in detail with reference to the accompanying drawings. Those skilled in the art should understand that these embodiments are merely illustrative of the technical principles of the present invention and are not intended to limit the scope of protection of the present invention.

[0048] A high-speed synchronous fork-and-spindle wrapping machine for cable processing, as shown in the attached figure. Figure 1-2 As shown, the device includes a base 1 and a drive motor 4. The base 1 has a take-up roller 2 and a release roller 3 mounted at its front and rear ends, respectively. The take-up roller 2 is driven by the drive motor 4. A winding drum 12 is installed at the inlet of the take-up roller 2. A follower disk 5 and a rotating disk 6 are mounted on the top of the base 1. The follower disk 5 and the rotating disk 6 are connected to the drive motor 4 via a linkage shaft 7. A hollow tube 8 is installed between the follower disk 5 and the rotating disk 6. A packaging rack 9 is mounted on the outer wall of the rotating disk 6. A guide frame 10 is mounted on the outer wall of the hollow tube 8. A transverse scraper 11 is slidably connected to the outer wall of the guide frame 10, and the transverse scraper 11 is driven to the packaging frame 9. This device, through the setting of the follower plate 5 and the rotating plate 6, enables the packaging tape to rotate synchronously, realize synchronous fork winding and wrapping, so that the packaging tape evenly wraps the outer wall of the cable. At the same time, under the action of the transverse scraper 11 and the guide frame 10, the outer surface of the packaging tape can be automatically tensioned and scraped to avoid wrinkles, eliminate wrinkles, and avoid gaps in the packaging caused by wrinkles.

[0049] As attached Figure 1-2As shown, a bracket 201 is fixedly installed on the side wall of the front end of the base 1, and a take-up roller 2 is installed on the inner side wall of the bracket 201. A drive motor 4 is fixedly installed on the outer side wall of the bracket 201. A bracket 301 is fixedly installed on the side wall of the rear end of the base 1, and a feed roller 3 is installed on the inner side wall of the bracket 301. A cable 13 is wound on the outer wall of the feed roller 3. When the device is in use, the drive motor 4 is started to stretch the cable 13, which causes the take-up roller 2 to drive the cable 13 to stretch and wind up, and simultaneously drives the feed roller 3 to rotate. The unpackaged cable 13 is wound on the outer wall of the feed roller 3, and the packaged cable 13 is located on the outer wall of the take-up roller 2.

[0050] As attached Figure 3 As shown, there are two guide frames 10, which are connected by a fixed frame 1001. The outer wall of the guide frame 10 has a guide hole 1002, and a scraper box 1003 is installed on the outer wall of the guide hole 1002. A horizontal plate 1004 is installed on the side wall of the fixed frame 1001. When the rotating disk 6 and the follower disk 5 of this device rotate, they will drive the hollow tube 8 and the packaging rack 9 to rotate. At this time, the guide frame 10 on the outer wall of the hollow tube 8 can rotate with it, so as to realize the function of the follower disk, the hollow tube 8, the guide frame 10 and the packaging rack 9 being stationary in relative positions. The packaging strip on the packaging rack 9 passes through the guide hole 1002. At this time, the vertical wrinkles can be initially removed by the scraper box 1003. At the same time, the multiple guide holes 1002 can realize the initial tensioning function.

[0051] As attached Figure 3-5As shown, a rotating shaft 1101 is rotatably connected to the side wall of the horizontal plate 1004. A first rotating bevel gear 1102 is fixedly installed on the outer wall of the rotating shaft 1101. The first rotating bevel gear 1102 meshes with a second rotating bevel gear 1104. The second rotating bevel gear 1104 is fixedly installed on the outer wall of one end of the reciprocating screw 1103. The reciprocating screw 1103 is rotatably connected to the outer wall of the fixed frame 1001. A threaded box 1105 is threadedly connected to the outer wall of the reciprocating screw 1103. The transverse scraper 11 is slidably connected to... Inside the thread box 1105, a stop spring 1107 is fixedly installed on the inner wall of the thread box 1105. The other end of the stop spring 1107 is fixedly connected to one end of the transverse scraper 11, and a wrinkle removal block 1106 is fixedly installed on the other end of the transverse scraper 11. There are multiple wrinkle removal blocks 1106, with two left and two right groups of wrinkle removal blocks 1106 arranged opposite each other. The two groups of wrinkle removal blocks 1106 are driven and connected by a transmission belt 1108. When this device is in use, the thread box 1105 follows the guide frame 10. In the initial state, the wrinkle-removing block 1106 and the transverse scraper 11 extend under the action of the abutment spring 1107, and the wrinkle-removing block 1106 abuts against the outer wall of the packaging tape. When the rotating shaft 1101 is driven by the two rotating bevel gears, it drives the reciprocating screw 1103 to rotate. The two threaded boxes 1105 of this device are installed on the outer wall of the reciprocating screw 1103 with opposite threads. When the reciprocating screw 1103 rotates, the two threaded boxes 1105 first move in opposite directions, and then move in opposite directions. The device moves, causing the wrinkle-removing blocks 1106 to scrape left and right. When the packaging is started, the threaded box 1105 of the device can rotate accordingly. When the threaded box 1105 moves, it can synchronously drive the wrinkle-removing blocks 1106 to move, thereby scraping the packaging tape laterally and avoiding wrinkles on the outer wall of the packaging tape. This prevents incomplete packaging or gaps caused by wrinkles on the packaging tape itself or wrinkles caused by stretching. The device has multiple wrinkle-removing blocks 1106 to ensure wrinkle removal efficiency.

[0052] As attached Figure 6 As shown, a first connecting bevel gear 1110 is fixedly installed on the outer wall of the middle part of the rotating shaft 1101; a fixed rotating shaft 1109 is rotatably connected to the bottom of the fixed frame 1001, and a second connecting bevel gear 1111 is installed on the outer wall of the upper part of the fixed rotating shaft 1109, and the second connecting bevel gear 1111 meshes with the first connecting bevel gear 1110.

[0053] As attached Figure 7-8As shown, a telescopic shaft 1112 is slidably connected to the inner bottom of the fixed rotating shaft 1109 via a limiting block. A first drive bevel gear 1113 is fixedly installed on the outer wall of the bottom of the telescopic shaft 1112. The first drive bevel gear 1113 meshes with a second drive bevel gear 1114. The second drive bevel gear 1114 is installed on the outer wall of one end of the mounting shaft 1115. A drive wheel 1116 is installed on the outer wall of the middle part of the mounting shaft 1115. The drive wheel 1116 abuts against the outer wall of the packaging strap. The other end of the mounting shaft 1115 is rotatably connected to the outer wall of the telescopic box 1117. The fixed end of the telescopic box 1117 is installed at the bottom of the fixing frame 1001. A compression spring 1118 is fixedly installed on the inner wall of the fixed rotating shaft 1109. The other end of the compression spring 1118 is fixedly connected to one end of the telescopic shaft 1112. The internal structure of the rotating shaft 1109 is the same as that of the telescopic box 1117. In the initial state, the drive wheel 1116 of this device extends outward under the action of the compression spring 1118, so that the drive wheel 1116 can always be tightly pressed against the outer wall of the packaging belt. At the same time, the drive wheel 1116 presses against the packaging belt to achieve tensioning again, satisfying the multiple tensioning function and realizing multiple steps to remove vertical wrinkles and avoid wrinkle formation. At the same time, when the drive wheel 1116 rotates, the telescopic shaft 1112 is driven to rotate under the action of the two drive bevel teeth. Under the action of the fixed rotating shaft 1109, the wrinkle removal block 1106 is driven to move, realizing the linkage function. The removal of vertical wrinkles and the removal of horizontal wrinkles are achieved simultaneously, forming a linkage function.

[0054] As attached Figure 1 and attached Figure 9 As shown, a first fixing plate 501 and a second fixing plate 601 are fixedly installed at the top two ends of the base 1, respectively. The rotating disk 6 is rotatably connected to the inner wall of the second fixing plate 601, and the follower disk 5 is rotatably connected to the outer wall of the first fixing plate 501. External teeth are provided on the outer wall of the follower disk 5, and a drive gear 701 is fixedly installed on the outer wall of the linkage shaft 7. The drive gear 701 meshes with the follower disk 5. A cable hole 502 is opened in the middle of the follower disk 5, and a fork-and-loop hole 503 is opened at one end of the surface of the follower disk 5. The follower disk 5 has the same structure as the rotating disk 6. When using this device, the cable is passed through the cable hole 502, and the packaging tape is passed through the fork-and-loop hole 503, so that the packaging tape wraps the cable 13. Through the setting of the linkage shaft 7, this device can make the wrapping and cable winding of this device linked, so that the fork-and-loop wrapping function is only activated when winding is started, which can avoid energy waste.

[0055] As attached Figure 1 and attached Figure 10As shown, a compression spring 1201 is fixedly installed on the inner wall of the winding drum 12, and a compression arc plate 1202 is fixedly installed on the other end of the compression spring 1201. There are multiple compression arc plates 1202, and the compression arc plates 1202 are matched with the cable 13. After the wrapping is completed, this device can compress the outer wall of the cable 13 again through the compression arc plate 1202 to prevent the packaging tape on the outer wall of the cable 13 from falling off.

[0056] As attached Figure 1 As shown, the output end of the drive motor 4 is driven and connected to the gear control box 401, and one end of the linkage shaft 7 is driven and connected to the gear control box 401 through the drive belt 402. This device can adjust the speed of the linkage shaft 7 through the gear control box 401 to meet the control of different speeds and the wrapping of the cable 13.

[0057] A type of cable, as shown in the attached document Figure 11 As shown, the cable 13 includes a battery core 1305, an insulation layer 1301, a fireproof layer 1302, a protective layer 1303, and a wrapping tape 1304. The outer wall of the battery core 1305 is sequentially wrapped with the insulation layer 1301, the fireproof layer 1302, the protective layer 1303, and the wrapping tape 1304.

[0058] It should be noted that in the description of this invention, terms such as "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," which indicate direction or positional relationships, are based on the direction or positional relationships shown in the accompanying drawings. These are used merely for ease of description and do not indicate or imply that the device or element must have a specific orientation, or be constructed and operated in a specific orientation; therefore, they should not be construed as limitations on this invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0059] Furthermore, it should be noted that, in the description of this invention, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.

[0060] The technical solution of the present invention has been described above with reference to the preferred embodiments shown in the accompanying drawings. However, it will be readily understood by those skilled in the art that the scope of protection of the present invention is obviously not limited to these specific embodiments. Without departing from the principles of the present invention, those skilled in the art can make equivalent changes or substitutions to the relevant technical features, and the technical solutions after such changes or substitutions will all fall within the scope of protection of the present invention.

Claims

1. A high-speed synchronous fork-and-twist wrapping machine for cable processing, comprising a base (1) and a drive motor (4), characterized in that, The front end and rear end of the top of the base (1) are respectively equipped with a receiving roller (2) and a discharging roller (3). The receiving roller (2) is driven by the drive motor (4). A winding drum (12) is installed at the inlet of the receiving roller (2). The top of the base (1) is equipped with a follower disk (5) and a rotating disk (6). The follower disk (5) and the rotating disk (6) are connected to the drive motor (4) through a linkage shaft (7). A hollow tube (8) is installed between the follower disk (5) and the rotating disk (6). A packaging rack (9) is installed on the outer wall of the rotating disk (6). A guide frame (10) is installed on the outer wall of the hollow tube (8), and a transverse scraper (11) is slidably connected to the outer wall of the guide frame (10). The transverse scraper (11) is driven to be connected to the packaging frame (9). There are two guide frames (10), and the two guide frames (10) are connected by a fixing frame (1001). A guide hole (1002) is provided on the outer wall of the guide frame (10), and a scraper box (1003) is installed on the outer wall of the guide hole (1002). A cross plate (1004) is installed on the side wall of the fixing frame (1001). A rotating shaft (1101) is rotatably connected to the side wall of the horizontal plate (1004). A first rotating bevel gear (1102) is fixedly installed on the outer wall of the rotating shaft (1101). The first rotating bevel gear (1102) meshes with a second rotating bevel gear (1104). The second rotating bevel gear (1104) is fixedly installed on the outer wall of one end of a reciprocating screw (1103). The reciprocating screw (1103) is rotatably connected to the fixed frame (1001). On the outer wall, a threaded box (1105) is threadedly connected to the outer wall of the reciprocating screw (1103). The transverse scraper (11) is slidably connected inside the threaded box (1105). A push spring (1107) is fixedly installed on the inner wall of the threaded box (1105). The other end of the push spring (1107) is fixedly connected to one end of the transverse scraper (11). A wrinkle removal block (1106) is fixedly installed on the other end of the transverse scraper (11).

2. The synchronous fork-and-twist high-speed wrapping machine for cable processing according to claim 1, characterized in that, A bracket (201) is fixedly installed on the side wall at the front end of the base (1), the receiving roller (2) is installed on the inner side wall of the bracket (201), and the drive motor (4) is fixedly installed on the outer side wall of the bracket (201). A bracket (301) is fixedly installed on the side wall at the rear end of the base (1). The feeding roller (3) is installed on the inner side wall of the bracket (301). A cable (13) is wound on the outer wall of the feeding roller (3).

3. The synchronous fork-and-twist high-speed wrapping machine for cable processing according to claim 1, characterized in that, The number of wrinkle removal blocks (1106) is multiple. The two wrinkle removal blocks (1106) are arranged in pairs, one on the left and one on the right, and the two pairs are arranged opposite each other. The two pairs of wrinkle removal blocks (1106) are connected by a drive belt (1108).

4. A high-speed synchronous fork-and-stirrer wrapping machine for cable processing according to claim 3, characterized in that, A first connecting bevel gear (1110) is fixedly installed on the outer wall of the middle part of the rotating shaft (1101). The bottom of the fixed frame (1001) is rotatably connected to a fixed shaft (1109), and a second connecting bevel tooth (1111) is installed on the outer wall of the upper part of the fixed shaft (1109). The second connecting bevel tooth (1111) meshes with the first connecting bevel tooth (1110).

5. A high-speed synchronous fork-and-twist wrapping machine for cable processing according to claim 4, characterized in that, The inner bottom of the fixed rotating shaft (1109) is slidably connected to the telescopic shaft (1112) via a limiting block. A first drive bevel gear (1113) is fixedly installed on the outer wall of the bottom of the telescopic shaft (1112). The first drive bevel gear (1113) is meshed with the second drive bevel gear (1114). The second drive bevel gear (1114) is installed on the outer wall of one end of the mounting shaft (1115). A drive wheel (1116) is installed on the outer wall of the middle part of the mounting shaft (1115). The drive wheel (1116) abuts against the outer wall of the packaging strap. The other end of the mounting shaft (1115) is rotatably connected to the outer wall of the telescopic box (1117). The fixed end of the telescopic box (1117) is installed at the bottom of the fixed frame (1001). A compression spring (1118) is fixedly installed on the inner wall of the fixed rotating shaft (1109). The other end of the compression spring (1118) is fixedly connected to one end of the telescopic shaft (1112). The internal structure of the fixed rotating shaft (1109) is the same as the internal structure of the telescopic box (1117).

6. A high-speed synchronous fork-and-stirrer wrapping machine for cable processing according to claim 5, characterized in that, The base (1) has a fixed plate 1 (501) and a fixed plate 2 (601) fixedly installed at its top two ends respectively. The rotating disk (6) is rotatably connected to the inner wall of the fixed plate 2 (601), and the follower disk (5) is rotatably connected to the outer wall of the fixed plate 1 (501). The outer wall of the follower disk (5) is provided with external teeth, and the outer wall of the linkage shaft (7) is fixedly installed with a drive gear (701), which meshes with the follower disk (5). The follower disk (5) has a cable hole (502) in the middle and a fork hole (503) at one end of the surface of the follower disk (5). The follower disk (5) has the same structure as the rotating disk (6).

7. A high-speed synchronous fork-stirring wrapping machine for cable processing according to claim 6, characterized in that, A compression spring (1201) is fixedly installed on the inner wall of the winding drum (12), and a compression arc plate (1202) is fixedly installed on the other end of the compression spring (1201). There are multiple compression arc plates (1202), and the compression arc plates (1202) are matched with the cable (13).

8. A high-speed synchronous fork-and-stirrer wrapping machine for cable processing according to claim 7, characterized in that, The output end of the drive motor (4) is driven and connected to the gear control box (401), and one end of the linkage shaft (7) is driven and connected to the gear control box (401) through the drive belt (402).