A wire-cable winding rack
By using a transmission mechanism and a motor-driven adjustment mechanism, the problem of cumbersome adjustment of the cable routing block position in the cable winding frame is solved, thereby improving the neatness of cable winding and storage capacity.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- NANJING YIHANG INFORMATION TECH CO LTD
- Filing Date
- 2024-04-01
- Publication Date
- 2026-06-30
AI Technical Summary
In the existing cable winding frame, the position adjustment of the cable guide block is cumbersome during the winding process and can easily affect the fit between the lead screw sleeve and the reciprocating lead screw, resulting in irregular winding.
By rotating synchronously with the transmission mechanism of the reciprocating lead screw and the winding frame, combined with the adjustment mechanism driven by the motor, the position of the wire guide block can be easily adjusted, avoiding the need to disassemble the lead screw sleeve and ensuring neat winding.
It enables convenient adjustment of the wiring block position, improves the neatness of the winding and the storage capacity of the wire spool, and avoids the impact of frequent disassembly of the lead screw sleeve on the fit.
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Figure CN118025891B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of cable laying technology, and in particular to a winding frame for wires and cables. Background Technology
[0002] Cable winding frames are tools frequently used in power construction. The cable winding frame is equipped with a reciprocating screw and a cable guide block. The reciprocating screw and the cable reel rotate synchronously, and the cable is evenly wound on the reel under the action of the reciprocating screw.
[0003] For example, the "Cable Winding Frame" with the authorization announcement number "CN214455780U" allows two rotating shafts to rotate synchronously under the action of belt one by turning the handle. Moving block one and moving block two separate, and the cable routing block can be moved to a suitable position to ensure that the cable routing hole corresponds to the position of the cable winding on the reel through the cable routing hole, so that the cable is neatly and orderly wound on the reel, increasing the reel's storage capacity.
[0004] For example, the "Cable Winding Frame" with authorization announcement number "CN113666188B" drives the upper and lower blocks to separate by rotating bolt one. At this time, the movable block can be moved freely to a suitable position. After being moved to the suitable position, the upper and lower blocks are closed by rotating bolt one in the opposite direction and re-engaged on the reciprocating screw, thus completing the adjustment of the position of the cable routing block. The structure is simple and the adjustment is convenient. The cable routing block can slide freely on the movable block and then be fixed. The position of the cable routing block can be finely adjusted, making the adjustment more precise and ensuring the winding effect.
[0005] While both of the above methods can evenly wind the cable onto the reel under the action of the reciprocating screw, resulting in neat winding and increased winding length, irregular winding still occurs during actual cable winding. This necessitates fine-tuning the position of the cable routing blocks. The first method lacks this fine-tuning capability, while the second method, although capable of fine-tuning, requires separating the upper and lower blocks by rotating bolt one, then adjusting, and finally reversing bolt one to reassemble them. This cumbersome and inconvenient fine-tuning process makes it impractical for precisely controlling the cable routing block's position. Summary of the Invention
[0006] The purpose of this invention is to provide a winding frame for wires and cables that allows the position of the lead screw sleeve and the wire guide block to be adjusted by rotating the reciprocating lead screw, without having to disassemble and move the lead screw sleeve to adjust the position of the wire guide block. This makes adjusting the position of the wire guide block more convenient and avoids the problem of frequent disassembly and adjustment of the lead screw sleeve affecting the fit between the lead screw sleeve and the reciprocating lead screw, thus solving the problems mentioned in the background art.
[0007] To achieve the above objectives, the present invention provides the following technical solution: a winding frame for wires and cables, comprising a base, connecting plates fixedly connected to the top left and right sides of the base, a winding frame rotatably connected between the two connecting plates, a first motor fixedly connected to the right side of the right connecting plate, the output shaft of the first motor passing through the right connecting plate and fixedly connected to the winding frame, a reciprocating lead screw rotatably connected between the tops of the two connecting plates, a lead screw sleeve threadedly connected to the outer wall of the reciprocating lead screw, a guide block fixedly connected to the bottom of the lead screw sleeve, a wire guide block fixedly connected to the bottom of the guide block, a guide rod fixedly connected between the two connecting plates, the outer wall of the guide rod slidably connected to the guide block, and a transmission mechanism provided between the left side of the reciprocating lead screw and the left side of the winding frame, the transmission mechanism being used to drive the reciprocating lead screw when the winding frame rotates, so that when winding wires and cables, the reciprocating lead screw and the winding frame rotate synchronously, and the wires and cables are evenly wound on the winding frame under the action of the reciprocating lead screw.
[0008] Preferably, the transmission mechanism includes a first sprocket fixedly connected to the left side of the winding frame, and the transmission mechanism also includes a second sprocket rotatably connected to the left side of the reciprocating lead screw, with a transmission chain disposed between the first sprocket and the second sprocket.
[0009] Preferably, a limiting block is fixedly connected to the right side of the second sprocket, a limiting frame is rotatably connected to the right side of the limiting block, a sliding rod is slidably connected inside the limiting frame, a limiting seat is slidably connected to the right side of the sliding rod, and the limiting seat is fixedly connected to the outer wall of the reciprocating lead screw.
[0010] Preferably, the limiting block has several slots near the limiting frame, the limiting seat has an empty slot inside, a slider is slidably connected inside the empty slot, a first spring is fixedly connected between the slider and the limiting seat, and the slider is fixedly connected to a sliding rod inside.
[0011] Preferably, the first motor is a brake-type servo motor.
[0012] Preferably, a slide is slidably connected to the side of the limiting seat away from the winding frame, a second spring is fixedly connected between the slide and the limiting seat, and a small groove is provided on the slider near the slide.
[0013] Preferably, the connecting plate on the right side is provided with an adjustment mechanism, which is used to adjust the position of the wiring block.
[0014] Preferably, the adjustment mechanism includes a second motor, which is fixedly connected to the right side of the connecting plate on the right side. The output shaft of the second motor is rotatably connected to a sleeve, and gears are fixedly connected to both the outer wall of the sleeve and the right side of the reciprocating lead screw. The two gears mesh with each other.
[0015] Preferably, a slot is provided on the right side of the sleeve, a retaining plate is slidably connected to the outer wall of the output shaft of the second motor, and a third spring is fixedly connected between the retaining plate and the output shaft of the second motor.
[0016] Preferably, a mounting plate is fixedly connected to the right side of the output shaft of the second motor, a small frame is fixedly connected to the right side of the mounting plate, a locking hole is provided on the side of the mounting plate near the small frame, a sliding rod is slidably connected to the right side of the small frame, and a magnetic block is fixedly connected to the bottom of the sliding rod and the inside of the locking hole.
[0017] Compared with the prior art, the beneficial effects of the present invention are:
[0018] 1. Under the action of the reciprocating screw rotation and the action of the guide block sliding along the guide rod, the screw sleeve adapted to the reciprocating screw can move back and forth, thereby causing the cable block to move back and forth with the wires and cables passing through it, ensuring that the position of the cable block and the cable passing through the cable block corresponds to the position of the cable reel, so that the wires and cables are neatly and orderly wound on the cable reel, increasing the cable reel's storage capacity;
[0019] 2. When the reciprocating screw rotates at this time, the second sprocket will not rotate. At this time, the position of the screw sleeve and the wire guide block can be adjusted by rotating the reciprocating screw, thereby ensuring the winding effect. This way, the position of the wire guide block does not need to be adjusted by disassembling and moving the screw sleeve. On the one hand, it makes the adjustment of the position of the wire guide block more convenient, and on the other hand, it avoids the frequent disassembly and adjustment of the screw sleeve, which would affect the fit between the screw sleeve and the reciprocating screw.
[0020] 3. When you slide the sliding rod to the right, the slider will slide to the right as well. When the slide reaches the position of the slot, the second spring will help the slide to insert into the slot. At this time, the slider and the sliding rod are limited, so that when adjusting the wiring block, you do not need to hold the sliding rod with your hand, which makes it easier to adjust the position of the wiring block.
[0021] 4. When the output shaft of the second motor rotates, the sleeve can rotate with the output shaft of the second motor. When adjusting, the rotation of the output shaft of the second motor causes the sleeve to rotate, which in turn causes the two meshing gears to rotate. This drives the reciprocating screw to rotate, thereby adjusting the position of the wiring block. In this way, the position of the wiring block is adjusted by driving the reciprocating screw to rotate through the rotation of the output shaft of the second motor, avoiding the need to manually rotate the reciprocating screw, making the adjustment of the position of the wiring block more convenient.
[0022] 5. After adjusting the position of the wiring block, manually slide the small frame to the right until it reaches the top of the locking hole. Then, slide the slide rod closer to the locking hole so that its bottom inserts into the locking hole. Under the action of the two magnetic blocks, the small frame and the locking plate can be limited. At this time, when wiring the wires and cables, the reciprocating screw will not affect the second motor. Attached Figure Description
[0023] To more clearly illustrate the specific embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of the present invention. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.
[0024] Figure 1 This is an overall structural view of the present invention;
[0025] Figure 2 This is a schematic diagram of the rear view structure of the present invention;
[0026] Figure 3 This is a half-sectional view of the limiting block of the present invention;
[0027] Figure 4 This is a partial structural diagram of the slot of the present invention;
[0028] Figure 5 This is a partial structural diagram of the gear of the present invention;
[0029] Figure 6 This is a schematic diagram of a half-section of the sleeve of the present invention;
[0030] Figure 7 For the present invention Figure 6 Enlarged view of point A;
[0031] Figure 8 This is a partial structural diagram of the card slot of the present invention.
[0032] Explanation of reference numerals in the attached figures:
[0033] 1. Base; 2. Connecting plate; 3. Winding frame; 4. First motor; 5. Cable guide block; 6. Reciprocating lead screw; 7. Lead screw sleeve; 8. Transmission mechanism; 81. First sprocket; 82. Second sprocket; 83. Transmission chain; 84. Limiting block; 85. Limiting frame; 86. Sliding rod; 87. Limiting seat; 88. Slot; 89. Empty slot; 810. Slider; 811. First spring; 812. Slide; 813. Small slot; 814. Second spring; 9. Adjustment mechanism; 91. Second motor; 92. Sleeve; 93. Slot; 94. Slot plate; 95. Third spring; 96. Mounting plate; 97. Small frame; 98. Sliding rod; 99. Magnetic block; 910. Slot; 911. Gear; 10. Guide block; 11. Guide rod. Detailed Implementation
[0034] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0035] Please see Figures 1 to 4 This invention provides a technical solution: a winding frame for wires and cables, comprising a base 1, with connecting plates 2 fixedly connected to the top left and right sides of the base 1, and a winding frame 3 rotatably connected between the two connecting plates 2. A first motor 4 is fixedly connected to the right side of the right connecting plate 2, and the output shaft of the first motor 4 passes through the right connecting plate 2 and is fixedly connected to the winding frame 3. A reciprocating lead screw 6 is rotatably connected between the tops of the two connecting plates 2, and a lead screw sleeve 7 is threadedly connected to the outer wall of the reciprocating lead screw 6. A guide block 10 is fixedly connected to the bottom of the guide block 10, and a cable guide block 5 is fixedly connected to the bottom of the guide block 10. A guide rod 11 is fixedly connected between the two connecting plates 2. The outer wall of the guide rod 11 is slidably connected to the guide block 10. A transmission mechanism 8 is provided between the left side of the reciprocating screw 6 and the left side of the winding frame 3. The transmission mechanism 8 is used to drive the reciprocating screw 6 when the winding frame 3 rotates. When winding the wire and cable, the reciprocating screw 6 and the winding frame 3 rotate synchronously. The wire and cable are evenly wound on the winding frame 3 under the action of the reciprocating screw 6.
[0036] By adopting the above technical solution, when it is necessary to wind wires and cables, the end of the wire or cable to be wound is passed through the inside of the cable guide block 5 and wound around the temporal part of the winding frame 3. Then, the output shaft of the first motor 4 is rotated, causing the winding frame 3 to rotate. This allows the winding frame 3 to wind the wire or cable. At the same time, under the action of the transmission mechanism 8, the reciprocating screw 6 can rotate synchronously with the winding frame 3. Under the action of the rotation of the reciprocating screw 6, and with the action of the guide block 10 sliding along the guide rod 11, the screw sleeve 7 adapted to the reciprocating screw 6 can move back and forth. This causes the cable guide block 5 to move back and forth with the wire or cable passing through it, ensuring that the position of the cable guide block 5 and the cable winding on the reel correspond, so that the wire or cable is neatly and orderly wound on the reel, increasing the storage capacity of the reel.
[0037] The transmission mechanism 8 includes a first sprocket 81 fixedly connected to the left side of the winding frame 3, and a second sprocket 82 rotatably connected to the left side of the reciprocating screw 6. A transmission chain 83 is provided between the first sprocket 81 and the second sprocket 82. A limiting block 84 is fixedly connected to the right side of the second sprocket 82. A limiting frame 85 is rotatably connected to the right side of the limiting block 84. A sliding rod 86 is slidably connected inside the limiting frame 85. A limiting seat 87 is slidably connected to the right side of the sliding rod 86. The limiting seat 87 is fixedly connected to the outer wall of the reciprocating screw 6. Several slots 88 are provided on the limiting block 84 near the limiting frame 85. A hollow groove 89 is provided inside the limiting seat 87. A slider 810 is slidably connected inside the hollow groove 89. A first spring 811 is fixedly connected between the slider 810 and the limiting seat 87. The inside of the slider 810 is fixedly connected to the sliding rod 86.
[0038] By adopting the above technical solution, the first sprocket 81 and the second sprocket 82 are driven by the transmission chain 83. When the output shaft of the first motor 4 rotates, it drives the winding frame 3 to rotate, thereby causing the first sprocket 81 to rotate. Under the action of the transmission chain 83, the second sprocket 82 rotates, thereby enabling the reciprocating screw 6 to rotate synchronously with the winding frame 3. This ensures that the position of the cable guide block 5 corresponds to the position of the cable passing through the cable guide block 5 wound on the reel, so that the wires and cables are neatly and orderly wound on the reel.
[0039] When the wires and cables are not neatly wound, the position of the cable routing block 5 needs to be adjusted. To adjust, first disconnect the power to the first motor 4, then manually slide the sliding rod 86 to the right, moving it away from the slot 88 where it was originally positioned. The left end of the sliding rod 86 is now inside the limiting frame 85. Since the second sprocket 82 is rotatably connected to the left side of the winding frame 3, the second sprocket 82 will not rotate when the reciprocating screw 6 rotates. At this point, rotating the reciprocating screw 6 adjusts the position of the screw sleeve 7 and the cable routing block 5, thus ensuring the winding effect. This eliminates the need to disassemble and move the screw sleeve 7 to adjust the position of the cable routing block 5. The position is adjusted to make the adjustment of the wire guide block 5 more convenient, and to avoid the frequent disassembly and adjustment of the lead screw sleeve 7, which would affect the fit between the lead screw sleeve 7 and the reciprocating lead screw 6. After the adjustment is completed, by releasing the sliding rod 86, under the elastic force of the first spring 811, the slider 810 moves to the left with the sliding rod 86. Then the output shaft of the first motor 4 rotates, causing the winding frame 3, the first sprocket 81 and the second sprocket 82 to rotate until the slider 810 reaches the nearest slot 88, and the sliding rod 86 is inserted into the slot 88. At this time, when the second sprocket 82 rotates, it can rotate the reciprocating lead screw 6 so that the device can operate normally.
[0040] The first motor 4 is a brake-type servo motor. The side of the limiting seat 87 away from the winding frame 3 is slidably connected to the slide 812. The slide 812 and the limiting seat 87 are fixedly connected to the second spring 814. The slider 810 is provided with a small groove 813 near the slide 812.
[0041] By adopting the above technical solution, the output shaft of the brake-type servo motor will lock up after power failure and will not rotate. This prevents the winding frame 3, the first sprocket 81, and the second sprocket 82 from rotating when adjusting the wiring block 5. When the sliding rod 86 is slid to the right by hand, the slider 810 can slide to the right as well. When the slide 812 reaches the position of the slot 813, the second spring 814 makes it easy for the slide 812 to be inserted into the slot 813. At this time, the slider 810 and the sliding rod 86 are limited, so that when adjusting the wiring block 5, it is not necessary to hold the sliding rod 86 by hand, which further facilitates the adjustment of the position of the wiring block 5. After the adjustment is completed, by pulling the slide 812 upward by hand, the first spring 811 makes it easy for the slider 810 to move to the left with the sliding rod 86.
[0042] Specifically, such as Figure 1 , Figure 2 and Figures 5 to 8As shown, the connecting plate 2 on the right side is provided with an adjustment mechanism 9. The adjustment mechanism 9 is used to adjust the position of the wiring block 5. The adjustment mechanism 9 includes a second motor 91, which is fixedly connected to the right side of the connecting plate 2 on the right side. The output shaft of the second motor 91 is rotatably connected to a sleeve 92. The outer wall of the sleeve 92 and the right side of the reciprocating lead screw 6 are both fixedly connected to gears 911. The two gears 911 mesh with each other. A slot 93 is provided on the right side of the sleeve 92. A retaining plate 94 is slidably connected to the outer wall of the output shaft of the second motor 91. A third spring 95 is fixedly connected between the retaining plate 94 and the output shaft of the second motor 91.
[0043] By adopting the above technical solution, when it is necessary to adjust the position of the wiring block 5, the clamping plate 94 moves to the left under the elastic force of the third spring 95, making it easier for the clamping plate 94 to be inserted into the slot 93. At this time, when the output shaft of the second motor 91 rotates, the sleeve 92 can rotate with the output shaft of the second motor 91. When adjusting, the output shaft of the second motor 91 rotates, causing the sleeve 92 to rotate, which in turn causes the two meshing gears 911 to rotate. This drives the reciprocating screw 6 to rotate, thereby adjusting the position of the wiring block 5. In this way, the position of the wiring block 5 is adjusted by driving the reciprocating screw 6 to rotate through the output shaft of the second motor 91, avoiding the need to manually rotate the reciprocating screw 6, making the adjustment of the position of the wiring block 5 more convenient.
[0044] A mounting plate 96 is fixedly connected to the right side of the output shaft of the second motor 91, and a small frame 97 is fixedly connected to the right side of the clamping plate 94. A clamping hole 910 is opened on the side of the mounting plate 96 near the small frame 97. A slide rod 98 is slidably connected to the right side of the small frame 97. A magnetic block 99 is fixedly connected to the bottom of the slide rod 98 and inside the clamping hole 910.
[0045] By adopting the above technical solution, after adjusting the position of the wiring block 5, the small frame 97 is manually slid to the right and slids to the top of the locking hole 910. The slide rod 98 is then slid closer to the locking hole 910, so that the bottom of the slide rod 98 is inserted into the locking hole 910. Under the action of the two magnetic blocks 99, the small frame 97 and the locking plate 94 can be limited. At this time, when the reciprocating screw 6 rotates, it will not affect the second motor 91 when the wire and cable are being handled. When the wiring block 5 needs to be adjusted, the slide rod 98 is pulled away from the locking hole 910. Under the elastic force of the third spring 95, the locking plate 94 moves to the left. When the second motor 91 rotates, when the locking plate 94 reaches the locking slot 93, the locking plate 94 is inserted into the locking slot 93.
[0046] Working principle: The end of the wire or cable to be wound passes through the inside of the cable guide block 5 and is wound around the temporal part of the winding frame 3. Then, the output shaft of the first motor 4 rotates, causing the winding frame 3 to rotate. This allows the winding frame 3 to wind the wire or cable. At the same time, under the action of the transmission mechanism 8, the reciprocating screw 6 rotates synchronously with the winding frame 3, thereby causing the cable guide block 5 to reciprocate with the wire or cable passing through it. This ensures that the position of the cable guide block 5 corresponds to the position of the cable winding on the reel, so that the wire or cable... The wires are neatly wound onto the spool, increasing the spool's storage capacity. When the wires and cables are not neatly wound, the position of the cable guide block 5 needs to be adjusted. First, the first motor 4 is de-energized. Then, the sliding rod 86 is manually slid to the right, moving it away from the slot 88 where it was originally located. The left end of the sliding rod 86 is inside the limiting frame 85. Because the second sprocket 82 is rotatably connected to the left side of the winding frame 3, the second sprocket 82 will not rotate when the reciprocating screw 6 rotates. Under the elastic force of the third spring 95, the cable is wound neatly. The card plate 94 moves to the left to facilitate its insertion into the slot 93. At this point, when the output shaft of the second motor 91 rotates, the sleeve 92 rotates along with it, causing the two meshing gears 911 to rotate. This drives the reciprocating screw 6 to rotate, allowing adjustment of the position of the wiring block 5. After adjustment, the small frame 97 is manually slid to the right until it reaches the top of the slot 910. The slide rod 98 is then slid closer to the slot 910, allowing its bottom to insert into the slot 910. Inside 10, under the action of two magnetic blocks 99, the small frame 97 and the card plate 94 can be limited, and the sliding rod 86 is released. Under the elastic force of the first spring 811, the slider 810 moves to the left with the sliding rod 86. Then the output shaft of the first motor 4 rotates, causing the winding frame 3, the first sprocket 81 and the second sprocket 82 to rotate until the slider 810 reaches the nearest slot 88. The sliding rod 86 is then inserted into the slot 88. At this time, when the second sprocket 82 rotates, it can drive the reciprocating screw 6 to rotate so that the device can operate normally.
[0047] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention, and are not intended to limit them. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some or all of the technical features therein. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the scope of the technical solutions of the embodiments of the present invention.
Claims
1. A winding frame for wires and cables, comprising a base (1), characterized in that: The base (1) has connecting plates (2) fixedly connected to the top left and right sides. A winding frame (3) is rotatably connected between the two connecting plates (2). A first motor (4) is fixedly connected to the right side of the connecting plate (2) on the right side. The output shaft of the first motor (4) passes through the connecting plate (2) on the right side and is fixedly connected to the winding frame (3). A reciprocating screw (6) is rotatably connected between the tops of the two connecting plates (2). A screw sleeve (7) is threadedly connected to the outer wall of the reciprocating screw (6). A guide block (10) is fixedly connected to the bottom of the screw sleeve (7). A wire guide block (5) is fixedly connected to the bottom of the guide block (10). A guide rod (11) is fixedly connected between the two connecting plates (2). The outer wall of the guide rod (11) is slidably connected to the guide block (10). A transmission mechanism (8) is provided between the left side of the reciprocating screw (6) and the left side of the winding frame (3). The transmission mechanism (8) is used to drive the reciprocating screw (6) when the winding frame (3) rotates. When winding the wire and cable, the reciprocating screw (6) and the winding frame (3) rotate synchronously, and the wire and cable are evenly wound on the winding frame (3) under the action of the reciprocating screw (6). The transmission mechanism (8) includes a first sprocket (81) fixedly connected to the left side of the winding frame (3), and the transmission mechanism (8) also includes a second sprocket (82) rotatably connected to the left side of the reciprocating screw (6). A transmission chain (83) is provided between the first sprocket (81) and the second sprocket (82). A limiting block (84) is fixedly connected to the right side of the second sprocket (82), a limiting frame (85) is rotatably connected to the right side of the limiting block (84), a sliding rod (86) is slidably connected inside the limiting frame (85), a limiting seat (87) is slidably connected to the right side of the sliding rod (86), and the limiting seat (87) is fixedly connected to the outer wall of the reciprocating screw (6). The limiting block (84) has several slots (88) near the limiting frame (85). The limiting seat (87) has an empty slot (89) inside. A slider (810) is slidably connected inside the empty slot (89). A first spring (811) is fixedly connected between the slider (810) and the limiting seat (87). The slider (810) is fixedly connected to the sliding rod (86) inside.
2. A winding frame for wires and cables according to claim 1, characterized in that: The first motor (4) is a brake-type servo motor.
3. A winding frame for wires and cables according to claim 2, characterized in that: The limiting seat (87) is slidably connected to a slide (812) on the side away from the winding frame (3). A second spring (814) is fixedly connected between the slide (812) and the limiting seat (87). A small groove (813) is provided on the slider (810) near the slide (812).
4. A winding frame for wires and cables according to claim 3, characterized in that: The connecting plate (2) on the right side is provided with an adjustment mechanism (9), which is used to adjust the position of the wiring block (5).
5. A winding frame for wires and cables according to claim 4, characterized in that: The adjustment mechanism (9) includes a second motor (91), which is fixedly connected to the right side of the connecting plate (2) on the right side. The output shaft of the second motor (91) is rotatably connected to a sleeve (92). The outer wall of the sleeve (92) and the right side of the reciprocating screw (6) are both fixedly connected to gears (911), and the two gears (911) mesh with each other.
6. A winding frame for wires and cables according to claim 5, characterized in that: A slot (93) is provided on the right side of the sleeve (92), and a retaining plate (94) is slidably connected to the outer wall of the output shaft of the second motor (91). A third spring (95) is fixedly connected between the retaining plate (94) and the output shaft of the second motor (91).
7. A winding frame for wires and cables according to claim 6, characterized in that: A mounting plate (96) is fixedly connected to the right side of the output shaft of the second motor (91), and a small frame (97) is fixedly connected to the right side of the clamping plate (94). A clamping hole (910) is provided on the side of the mounting plate (96) near the small frame (97). A slide rod (98) is slidably connected to the right side of the small frame (97). A magnetic block (99) is fixedly connected to the bottom of the slide rod (98) and inside the clamping hole (910).