Metal cable calendering apparatus
By introducing anti-wrinkle components, cooling components, and cutting adjustment components into the metal wire rolling equipment, the problem of longitudinal wrinkles in the ductile material was solved, achieving material flatness and rapid forming, and improving the quality and dimensional consistency of the finished product.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- CNNC FUJIAN FUQING NUCLEAR POWER
- Filing Date
- 2023-11-20
- Publication Date
- 2026-06-09
Smart Images

Figure CN117505524B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of rolling equipment technology, and in particular to a metal wire rolling processing equipment. Background Technology
[0002] Cables are a general term for items such as optical cables and electrical cables. Among them, metal cables refer to cables with metal material inside and silicone outer shell. They are mainly used for multiple functions such as control installation, connection of equipment and power transmission. They are a common and indispensable item in daily life. Since most metal cables are electrified, the quality of the outer shell material is very important. The outer shell material usually needs to be processed using rolling equipment.
[0003] Chinese Patent Application No. CN202310924900.4 discloses a calender, relating to the field of calender technology. The calender includes a base, a support frame on top of the base, and a first and second extrusion rollers symmetrically arranged on the inner wall of the support frame. It also includes an adjustment mechanism: the adjustment mechanism is symmetrically arranged inside the support frame, a support block is provided on the inner wall of the adjustment mechanism, a bearing is fixedly installed on the inner wall of the support block, a servo motor is symmetrically arranged on the top of the adjustment mechanism, a threaded screw corresponding to the servo motor is provided on the inner wall of the adjustment mechanism, and a slip ring corresponding to the threaded screw is provided on the inner wall of the slider. The calender provided by this invention achieves the technical effect of automatically removing impurities from the outer wall of the extrusion rollers using the calender through the provided strip scraper, concave scraper, adjustment mechanism, and cleaning mechanism.
[0004] However, in actual processing, the stretched material may develop longitudinal wrinkles, which are difficult to handle with commonly used calendering equipment, affecting the quality of the finished product. Summary of the Invention
[0005] The technical problem to be solved by the present invention is to provide a metal wire rolling processing equipment to avoid longitudinal wrinkles in the rolled material.
[0006] This invention provides a metal wire rolling processing equipment, comprising: a base, a conveyor belt, a housing plate, an anti-wrinkle assembly, a cutting and adjusting assembly, and a cooling assembly;
[0007] The top of the base is fixedly connected to an outer shell plate;
[0008] The outer shell is equipped with a conveyor belt, an anti-wrinkle assembly, a cooling assembly, and a cutting and adjusting assembly.
[0009] The anti-wrinkle assembly includes: a motor, an assembly plate, a reciprocating lead screw, a first lead screw seat, a connecting plate, a first telescopic rod, a stroke groove, a sliding block, and a leveling wheel;
[0010] Two reciprocating lead screws are connected by a rotating shaft; the two reciprocating lead screws are symmetrically distributed along the center of the rotating shaft, and the threads of the two reciprocating lead screws are in opposite directions; a motor is mounted on the outside of the outer casing, one end of each reciprocating lead screw is rotatably connected to the inner wall of the outer casing, and the other end extends to the outside of the outer casing and is fixedly connected to one end of the motor output shaft.
[0011] The reciprocating screw is threadedly connected to a first screw seat on its outer surface. A first telescopic rod is fixedly connected to the bottom of the first screw seat. A connecting plate is fixedly connected to the end of the first telescopic rod away from the first screw seat. A leveling wheel is rotatably connected to the bottom of the connecting plate, and the leveling wheel is in contact with the conveyor belt.
[0012] An assembly plate is fixedly connected inside the outer shell panel. A travel groove is provided on one side of the assembly plate. A sliding block is fixedly connected to the side of the first telescopic rod. The sliding block is slidably connected in the travel groove.
[0013] The cooling assembly includes: a second telescopic rod, a transmission gear, a rack, a mounting rod, a rotating slot, and a cooling fan.
[0014] Rotating grooves are provided on both sides of the connecting plate, and the mounting rod is fixed in the rotating groove. The top of the mounting rod is rotatably connected to the second telescopic rod; the top of the second telescopic rod is connected to the transmission gear, and the bottom is connected to the cooling fan.
[0015] Two racks are fixedly connected to one side of the assembly plate, and the racks mesh with one side of the transmission gear;
[0016] The cutting adjustment assembly includes: a drive wheel, a transmission belt, a driven wheel, a sliding box, a sleeve, a rotating rod, a transmission wheel, a transmission belt, a cutting blade, an adjusting screw, and a second screw seat;
[0017] One end of the rotating rod extends to the outside of the outer shell and is fixedly connected to a driven wheel, while the other end is rotatably connected to the inner wall of the outer shell.
[0018] A drive pulley is fixedly connected to one end of the motor output shaft, and a transmission belt connects the drive pulley and the driven pulley.
[0019] A sleeve is fitted onto the outer surface of the rotating rod. Two sliding boxes are rotatably connected to the outer surface of the sleeve. A rotating shaft is rotatably connected inside the sliding box, and a drive wheel is fixedly connected to both the rotating shaft and the outer surface of the sleeve. A drive belt connects the two drive wheels. A cutting blade is fitted onto the rotating shaft, with one end of the cutting blade extending outside the sliding box.
[0020] An adjusting screw is rotatably connected inside the outer shell plate. Two second screw seats are threadedly connected to the outer surface of the adjusting screw. One side of the second screw seat is fixedly connected to one side of the sliding box.
[0021] Furthermore, the travel groove consists of two layers, with the two ends of the upper and lower layers connected by an arc-shaped groove to form a unified whole.
[0022] Furthermore, the motor is fixedly mounted on the outer shell panel via a mounting plate.
[0023] Furthermore, connecting pieces are fixedly connected to both sides of the first telescopic rod, and the connecting pieces are rotatably connected to the second telescopic rod.
[0024] Furthermore, the top of the first lead screw seat is in contact with the top of the inner wall of the outer casing plate.
[0025] Furthermore, it includes two first lead screw seats, each of which is fixedly connected to a first telescopic rod at its bottom. A connecting plate is fixedly connected to the end of the first telescopic rod away from the first lead screw seat, and a leveling wheel is rotatably connected to the bottom of the connecting plate. The leveling wheel is in contact with the conveyor belt. A sliding block is fixedly connected to the side of each first telescopic rod, and the sliding block is slidably connected in the stroke groove.
[0026] Furthermore, a sliding box is fitted onto the outside of the sleeve, and the top of the sliding box is in contact with the top of the inner wall of the outer shell plate.
[0027] Furthermore, the rotating shaft is located at the bottom of the sliding box, with its orientation parallel to the sleeve, and the two transmission wheels are arranged perpendicularly.
[0028] Furthermore, the outer shell plate 3 has two adjusting screws rotatably connected inside, and the two adjusting screws are fixedly connected by a rotating shaft. The two adjusting screws are symmetrically distributed along the center position of the rotating shaft, and the threads of the two adjusting screws are opposite. The outer surface of the adjusting screw is threaded with a second screw seat, and one side of the second screw seat is fixedly connected to one side of the sliding box.
[0029] Furthermore, it also includes calendering rollers and a control panel. Two calendering rollers are arranged inside the outer shell plate, with the calendering surfaces of the two calendering rollers on the same horizontal plane as the conveyor belt. A control panel is provided on one side of the base, and the control panel controls the movement of the anti-wrinkle assembly, the cutting and adjusting assembly, the conveyor belt, and the cooling assembly.
[0030] Compared with the prior art, the metal wire rolling processing equipment of the present invention has the following advantages:
[0031] (1) In this invention, by setting an anti-wrinkle component, the motor drives the reciprocating screw to rotate through the rotating shaft. The reciprocating screw drives the first screw seat to reciprocate. The first screw seat drives the first telescopic rod to reciprocate. The first telescopic rod drives the connecting plate to move. The connecting plate drives the flattening wheel to move. During the movement, the first telescopic rod can change in the vertical direction through the cooperation of the sliding block and the stroke groove. When the two first telescopic rods move inward, the sliding block moves in the upper stroke groove, so that the flattening wheel separates from the extended material. When the two first telescopic rods move outward, the sliding block moves in the lower stroke groove, so that the flattening wheel fits into the extended material. This can prevent wrinkles from appearing in the extended material during the conveying process, so that the extended material can be fully unfolded and the flatness and integrity of the extended material can be guaranteed.
[0032] (2) In this invention, by setting a cooling component, during the movement of the first lead screw seat, the first telescopic rod drives the second telescopic rod to move through the connecting piece, the second telescopic rod drives the transmission gear to move on the rack, so that the transmission gear rotates, the transmission gear drives the second telescopic rod to rotate, the second telescopic rod drives the cooling fan to rotate, the cooling fan rotates to generate wind force and cools the extended material, thereby accelerating the forming speed of the extended material.
[0033] (3) In this invention, by setting up an adjustment cutting assembly, the screw drives the second screw seat to move through the adjustment screw. The second screw seat changes the distance between the two cutting blades through the sliding box. During processing, the motor drives the rotating wheel to rotate. The driving wheel drives the driven wheel to rotate through the transmission belt. The driven wheel drives the rotating rod to rotate. The rotating rod drives the sleeve to rotate. The sleeve drives the transmission wheel to rotate. The transmission wheel drives another transmission wheel to rotate through the transmission belt. The transmission wheel drives the cutting blade to rotate through the rotating shaft and performs edge trimming on the extended material. It can trim the corners of the formed material to ensure that the width of the formed material is uniform. At the same time, by adjusting the distance between the two cutting blades, the specifications of the formed material can be controlled. Attached Figure Description
[0034] Figure 1 This is a three-dimensional structural diagram of a metal cable rolling processing equipment proposed in this invention;
[0035] Figure 2 This is a front cross-sectional view of a metal wire rolling processing equipment proposed in this invention;
[0036] Figure 3 This invention proposes a metal wire rolling processing equipment. Figure 2 A magnified structural diagram of part A in the diagram;
[0037] Figure 4This is a side view cross-sectional structural diagram of a metal wire rolling processing equipment proposed in this invention;
[0038] Figure 5 This invention proposes a metal wire rolling processing equipment. Figure 4 A magnified structural diagram of part B in the diagram;
[0039] Figure 6 This is a side cross-sectional view of the cutting and adjusting assembly of a metal wire rolling processing equipment proposed in this invention.
[0040] Legend:
[0041] 1. Base; 2. Conveyor belt; 3. Outer shell plate; 4. Anti-wrinkle assembly; 401. Motor; 402. Assembly plate; 403. Reciprocating lead screw; 404. First lead screw seat; 405. Connecting plate; 406. First telescopic rod; 407. Stroke groove; 408. Sliding block; 409. Leveling wheel; 5. Cutting adjustment assembly; 501. Drive wheel; 502. Transmission belt; 503. Driven wheel; 504. Sliding box; 505. Sleeve; 506. Rotating rod; 507. Transmission wheel; 508. Transmission belt; 509. Cutting blade; 510. Adjusting lead screw; 511. Second lead screw seat; 6. Cooling assembly; 601. Second telescopic rod; 602. Transmission gear; 603. Rack; 604. Mounting rod; 605. Rotating groove; 606. Cooling fan; 7. Calendering roll. Detailed Implementation
[0042] To further understand the present invention, embodiments of the present invention are described below in conjunction with examples. However, it should be understood that these descriptions are only for further illustrating the features and advantages of the present invention, and not for limiting the present invention.
[0043] An embodiment of the present invention discloses a metal wire rolling processing equipment, such as... Figure 1 and Figure 2 As shown, it includes: base 1, conveyor belt 2, outer shell 3, anti-wrinkle assembly 4, cutting and adjusting assembly 5, and cooling assembly 6;
[0044] The top of the base 1 is fixedly connected to the outer shell plate 3;
[0045] The outer shell 3 is provided with a conveyor belt 2, an anti-wrinkle component 4, a cooling component 5, and a cutting and adjusting component 6.
[0046] The anti-wrinkle component 4 includes: a motor 401, an assembly plate 402, a reciprocating lead screw 403, a first lead screw seat 404, a connecting plate 405, a first telescopic rod 406, a stroke groove 407, a sliding block 408, and a leveling wheel 409.
[0047] A motor 401 is mounted on the outer side of the outer shell 3. Preferably, the motor 401 is fixedly mounted on the outer shell 3 by a mounting plate, that is, the mounting plate is fixed to the outer side wall of the outer shell 3 and the motor 401 is placed on the mounting plate.
[0048] One end of the reciprocating lead screw 403 is rotatably connected to one side of the inner wall of the outer casing 3, and the other end extends to the outside of the outer casing 3 through a rotating shaft and is fixedly connected to one end of the output shaft of the motor 401.
[0049] Two reciprocating lead screws 403 are connected by a rotating shaft; the two reciprocating lead screws 403 are symmetrically distributed along the center position of the rotating shaft, and the thread directions of the two reciprocating lead screws 403 are opposite; the outer surface of the reciprocating lead screw 403 is threadedly connected to a first lead screw seat 404, preferably, two first lead screw seats 404 are included, that is, each reciprocating lead screw 403 is provided with a first lead screw seat 404;
[0050] A first telescopic rod 406 is fixedly connected to the bottom of the first lead screw seat 404. A connecting plate 405 is fixedly connected to the end of the first telescopic rod 406 away from the first lead screw seat 404. A leveling wheel 409 is rotatably connected to the bottom of the connecting plate 405. The leveling wheel 409 is in contact with the conveyor belt 2.
[0051] The top of the first lead screw seat 404 is in contact with the top of the inner wall of the outer shell plate 3;
[0052] An assembly plate 402 is fixedly connected inside the outer shell 3. A stroke groove 407 is provided on one side of the assembly plate 402. Sliding blocks 408 are fixedly connected to the sides of the first telescopic rod 406. The sliding blocks 408 are slidably connected in the stroke groove 407.
[0053] The travel groove 407 has two layers, and the two ends of the upper and lower layers are connected by arc grooves to form a unified whole; the sliding block 408 moves within the travel groove 407;
[0054] The cooling assembly 6 includes: a second telescopic rod 601, a transmission gear 602, a rack 603, a mounting rod 604, a rotating groove 605, and a cooling fan 606.
[0055] Rotation slots 605 are provided on both sides of the connecting plate 405. The mounting rod 604 is fixed in the rotation slot 605. The top of the mounting rod 604 is rotatably connected to the second telescopic rod 601. The top of the second telescopic rod 601 is connected to the transmission gear 602, and the bottom is connected to the cooling fan 606.
[0056] Two racks 603 are fixedly connected to one side of the assembly plate 402, and the racks 603 mesh with one side of the transmission gear 602;
[0057] Both sides of the first telescopic rod 406 are fixedly connected to connectors, and the connectors are rotatably connected to the second telescopic rod 601.
[0058] The cutting adjustment assembly 5 includes: a drive wheel 501, a transmission belt 502, a driven wheel 503, a sliding box 504, a sleeve 505, a rotating rod 506, a transmission wheel 507, a transmission belt 508, a cutting blade 509, an adjusting screw 510, and a second screw seat 511.
[0059] The rotating rod 506 is arranged parallel to the reciprocating lead screw 403;
[0060] One end of the rotating rod 506 extends to the outside of the outer shell plate 3 and is fixedly connected to the driven wheel 503, while the other end is rotatably connected to the inner wall of the outer shell plate 3;
[0061] One end of the output shaft of motor 401 is fixedly connected to a drive pulley 501, and a drive belt 502 is used to drive the drive pulley 501 and the driven pulley 503.
[0062] A sleeve 505 is fitted onto the outer surface of the rotating rod 506. Two sliding boxes 504 are rotatably connected to the outer surface of the sleeve 505. A rotating shaft is rotatably connected inside the sliding box 504. The rotating shaft is located at the bottom of the sliding box and its direction is parallel to the sleeve.
[0063] Both the rotating shaft and the outer surface of the sleeve 505 are fixedly connected to transmission wheels 507, and the two transmission wheels 507 are arranged vertically.
[0064] A drive belt 508 is connected between the two drive wheels 507, and a cutting blade 509 is sleeved on the shaft. One end of the cutting blade 509 extends to the outside of the sliding box 504.
[0065] The sleeve 505 is fitted with a sliding box 504, and the top of the sliding box 504 is in contact with the top of the inner wall of the outer shell plate 3.
[0066] The outer shell 3 has two adjusting screws 510 rotatably connected inside, and the two adjusting screws 510 are fixedly connected by a rotating shaft. The two adjusting screws 510 are symmetrically distributed along the center position of the rotating shaft, and the threads of the two adjusting screws are opposite. The outer surface of the adjusting screw 510 is threadedly connected to a second screw seat 511, and one side of the second screw seat 511 is fixedly connected to one side of the sliding box 504.
[0067] The metal wire rolling processing equipment also includes rolling rollers 7 and a control panel. Two rolling rollers 7 are arranged inside the outer shell plate 3, with the rolling surfaces of the two rolling rollers 7 on the same horizontal plane as the conveyor belt 2. A control panel is provided on one side of the base 1. The control panel controls the movement of the anti-wrinkle component 3, the cutting and adjusting component 5, the conveyor belt 2, and the cooling component 6.
[0068] In practical use, by setting the anti-wrinkle component 4, the motor 401 drives the reciprocating screw 403 to rotate via the rotating shaft. The reciprocating screw 403 drives the first screw seat 404 to reciprocate. The first screw seat 404 drives the first telescopic rod 406 to reciprocate. The first telescopic rod 406 drives the connecting plate 405 to move. The connecting plate 405 drives the leveling wheel 409 to move. During the movement, the first telescopic rod 406 can change in the vertical direction through the cooperation of the sliding block 408 and the stroke groove 407. When the two first telescopic rods 406 move inward, the sliding block 408 moves in the upper travel groove 407, causing the flattening wheel 409 to separate from the extended material. When the two first telescopic rods 406 move outward, the sliding block 408 moves in the lower travel groove 407, causing the flattening wheel 409 to come into contact with the extended material. This prevents the extended material from wrinkling during the conveying process, allowing the extended material to fully unfold and ensuring the flatness and integrity of the extended material.
[0069] By setting up the cooling component 6, during the movement of the first lead screw seat 404, the first telescopic rod 406 drives the second telescopic rod 601 to move through the connecting piece. The second telescopic rod 601 drives the transmission gear 602 to move on the rack 603, causing the transmission gear 602 to rotate. The transmission gear 602 drives the second telescopic rod 601 to rotate, and the second telescopic rod 601 drives the cooling fan 606 to rotate. The cooling fan 606 rotates to generate airflow and dissipate heat to cool the extruded and extended material, thereby accelerating the forming speed of the extended material.
[0070] By setting and adjusting the cutting assembly, the second lead screw seat 511 is moved by two adjusting lead screws 510. The second lead screw seat 511 changes the distance between the two cutting blades 509 through the sliding box 504. During processing, the motor 401 drives the rotating wheel to rotate. The driving wheel 501 drives the driven wheel 503 to rotate through the transmission belt 502. The driven wheel 503 drives the rotating rod 506 to rotate. The rotating rod 506 drives the sleeve 505 to rotate. The sleeve 505 drives the transmission wheel 507 to rotate. The transmission wheel 507 drives another transmission wheel 507 to rotate through the transmission belt 508. The transmission wheel 507 drives the cutting blades 509 to rotate through the rotating shaft and performs edge trimming on the extended material. This can trim the corners of the formed material to ensure uniform width. At the same time, by adjusting the distance between the two cutting blades 509, the specifications of the formed material can be controlled.
[0071] Working principle: Before processing, the operator adjusts the distance between the two cutting blades 509. The operator uses a knob to drive the two adjusting screws 510 to rotate. The adjusting screws 510 drive the second screw seat 511 to move. The second screw seat 511 drives the sliding box 504 to move. The two sliding boxes 504 move towards each other, causing the distance between the two cutting blades 509 to change. When processing, the operator feeds the raw material between the calendering rollers 7. The calendering rollers 7 stretch and shape the raw material and transport it through the conveyor belt. During this process, the motor 401 drives the rotating wheel to rotate. The driving wheel 501 drives the driven wheel 503 to rotate through the transmission belt 502. The driven wheel 503 drives the rotating rod 506 to rotate. The rotating rod 506 drives the sleeve 505 to rotate. The sleeve 505 drives the transmission wheel 507 to rotate. The transmission wheel 507 drives another transmission wheel 507 to rotate through the transmission belt 508. The transmission wheel 507 drives the cutting blades 509 to rotate through the rotating shaft and performs edge trimming on the stretched material.
[0072] When the raw material enters the conveyor belt after being stretched, the motor 401 drives the reciprocating screw 403 to rotate via the shaft. The reciprocating screw 403 drives the first screw seat 404 to reciprocate, which in turn drives the first telescopic rod 406 to reciprocate. The first telescopic rod 406 drives the connecting plate 405 to move, which in turn drives the leveling wheel 409 to move. During its movement, the first telescopic rod 406 can change vertically through the cooperation of the sliding block 408 and the stroke groove 407. When the two first telescopic rods 406 move inward, the sliding block 408 moves in the upper stroke groove 407, allowing the leveling wheel 409 to contact the stretched material. Material separation occurs when the two first telescopic rods 406 move outwards, causing the sliding block 408 to move within the lower stroke groove 407, making the leveling wheel 409 contact the extended material. Simultaneously, during the movement of the first lead screw seat 404, the first telescopic rod 406 drives the second telescopic rod 601 to move via the connecting piece. The second telescopic rod 601 drives the transmission gear 602 to move on the rack 603, causing the transmission gear 602 to rotate. The transmission gear 602 then drives the second telescopic rod 601 to rotate, which in turn drives the cooling fan 606 to rotate. The cooling fan 606 generates airflow and cools the extruded extended material. The above description of the embodiments is merely for the purpose of helping to understand the method and core idea of the present invention. It should be noted that those skilled in the art can make various improvements and modifications to the present invention without departing from its principles, and these improvements and modifications also fall within the scope of protection of the claims of the present invention.
[0073] The above description of the disclosed embodiments enables those skilled in the art to make or use the invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the invention. Therefore, the invention is not to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
Claims
1. A metal wire rolling processing equipment, characterized in that, include: Base, conveyor belt, outer shell, anti-wrinkle assembly, cutting and adjustment assembly, cooling assembly; The top of the base is fixedly connected to an outer shell plate; The outer shell is equipped with a conveyor belt, an anti-wrinkle assembly, a cooling assembly, and a cutting and adjusting assembly. The anti-wrinkle assembly includes: a motor, an assembly plate, a reciprocating lead screw, a first lead screw seat, a connecting plate, a first telescopic rod, a stroke groove, a sliding block, and a leveling wheel; Two reciprocating lead screws are connected by a shaft; the two reciprocating lead screws are symmetrically distributed along the center of the shaft, and the threads of the two reciprocating lead screws are opposite in direction; A motor is mounted on the outside of the outer casing. One end of the reciprocating lead screw is rotatably connected to the inner wall of the outer casing, and the other end extends to the outside of the outer casing and is fixedly connected to one end of the motor output shaft. The reciprocating screw is threadedly connected to a first screw seat on its outer surface. A first telescopic rod is fixedly connected to the bottom of the first screw seat. A connecting plate is fixedly connected to the end of the first telescopic rod away from the first screw seat. A leveling wheel is rotatably connected to the bottom of the connecting plate, and the leveling wheel is in contact with the conveyor belt. An assembly plate is fixedly connected inside the outer shell panel. A travel groove is provided on one side of the assembly plate. A sliding block is fixedly connected to the side of the first telescopic rod. The sliding block is slidably connected in the travel groove. The cooling assembly includes: a second telescopic rod, a transmission gear, a rack, a mounting rod, a rotating slot, and a cooling fan. Rotating grooves are provided on both sides of the connecting plate, and the mounting rod is fixed in the rotating groove. The top of the mounting rod is rotatably connected to the second telescopic rod; the top of the second telescopic rod is connected to the transmission gear, and the bottom is connected to the cooling fan. Two racks are fixedly connected to one side of the assembly plate, and the racks mesh with one side of the transmission gear; The cutting adjustment assembly includes: a drive wheel, a transmission belt, a driven wheel, a sliding box, a sleeve, a rotating rod, a transmission wheel, a transmission belt, a cutting blade, an adjusting screw, and a second screw seat; One end of the rotating rod extends to the outside of the outer shell and is fixedly connected to a driven wheel, while the other end is rotatably connected to the inner wall of the outer shell. A drive pulley is fixedly connected to one end of the motor output shaft, and a transmission belt connects the drive pulley and the driven pulley. A sleeve is fitted onto the outer surface of the rotating rod. Two sliding boxes are rotatably connected to the outer surface of the sleeve. A rotating shaft is rotatably connected inside the sliding box, and a drive wheel is fixedly connected to both the rotating shaft and the outer surface of the sleeve. A drive belt connects the two drive wheels. A cutting blade is fitted onto the rotating shaft, with one end of the cutting blade extending outside the sliding box. An adjusting screw is rotatably connected inside the outer shell plate. Two second screw seats are threadedly connected to the outer surface of the adjusting screw. One side of the second screw seat is fixedly connected to one side of the sliding box.
2. The metal cable rolling processing equipment according to claim 1, characterized in that, The travel groove consists of two layers, with the two ends of the upper and lower layers connected by an arc-shaped groove to form a unified whole.
3. The metal cable rolling processing equipment according to claim 1, characterized in that, The motor is fixedly mounted on the outer casing via a mounting plate.
4. The metal cable rolling processing equipment according to claim 1, characterized in that, Both sides of the first telescopic rod are fixedly connected to connectors, and the connectors are rotatably connected to the second telescopic rod.
5. The metal cable rolling processing equipment according to claim 1, characterized in that, The top of the first lead screw seat is in contact with the top of the inner wall of the outer casing.
6. The metal cable rolling processing equipment according to claim 1, characterized in that, It includes two first lead screw seats, each of which is fixedly connected to a first telescopic rod at its bottom. A connecting plate is fixedly connected to the end of the first telescopic rod away from the first lead screw seat. A leveling wheel is rotatably connected to the bottom of the connecting plate and fits against the conveyor belt. A sliding block is fixedly connected to the side of each first telescopic rod and is slidably connected in the stroke groove.
7. The metal cable rolling processing equipment according to claim 1, characterized in that, A sliding box is fitted onto the outside of the sleeve, and the top of the sliding box is in contact with the top of the inner wall of the outer shell plate.
8. The metal cable rolling processing equipment according to claim 1, characterized in that, The rotating shaft is located at the bottom of the sliding box, with its orientation parallel to the sleeve, and the two transmission wheels are arranged perpendicularly.
9. The metal cable rolling processing equipment according to claim 1, characterized in that, The outer shell plate has two rotatably connected internally, and the two adjusting screws are fixedly connected by a rotating shaft. The two adjusting screws are symmetrically distributed along the center position of the rotating shaft, and the threads of the two adjusting screws are opposite. The outer surface of the adjusting screws is threaded with a second screw seat, and one side of the second screw seat is fixedly connected to one side of the sliding box.
10. The metal cable rolling processing equipment according to claim 1, characterized in that, It also includes calendering rollers and a control panel. Two calendering rollers are arranged inside the outer shell, with the calendering surfaces of the two calendering rollers on the same horizontal plane as the conveyor belt. A control panel is provided on one side of the base, and the control panel controls the movement of the anti-wrinkle assembly, the cutting and adjusting assembly, the conveyor belt, and the cooling assembly.