Elastic rotating rod constant weight winding mechanism of elephant trunk wire collecting machine

Abstract

The utility model discloses an elephant trunk wire take -up machine elastic rotary lever fixed weight offline mechanism relates to wire take -up device technical field, the utility model discloses an elephant trunk wire take -up machine still includes: ration part, ration part installs on elephant trunk wire take -up machine for ration discharging steel wire coil, make the recovered steel wire coil close, and it is convenient to pack, and fixed part, the fixed part sets up on ration part for the fixed ration part, wherein, after using fixed part to ration part fixed, the steel wire coil that elephant trunk wire take -up machine releases will pass through ration part, and the ration of passing through ration part discharging can make the recovered steel wire coil more close, and it is convenient to pack. The utility model discloses through setting ration part, in the discharging operation process of elephant trunk wire take -up machine, when steel wire coil is transported to ration part, will be contacted with the triangular wire baffle of being in the rotating state, and the triangular wire baffle will be blocked in the rotation process by the limiting sliding block.

Description

Technical Field

[0001] This utility model belongs to the technical field of wire take-up devices, and in particular relates to a fixed-weight wire unloading mechanism with a spring-loaded rotating rod of an elephant trunk wire take-up machine. Background Technology

[0002] The elephant trunk wire take-up machine's fixed-weight unloading mechanism is a component of equipment used in industries such as metal wire drawing. In the elephant trunk wire take-up machine, an elephant trunk wire take-up mechanism is provided on one side of the frame. The frame is equipped with an unloading drive mechanism to provide power for the metal wire to be wound onto the elephant trunk wire take-up mechanism. A single unloading mechanism is fixed above the elephant trunk wire take-up mechanism by a bracket. During operation, the processed metal wire is guided by a guide wheel and continuously wound onto the elephant trunk wire take-up mechanism under the drive of the unloading drive mechanism. Then, the single unloading mechanism lowers the wires one by one to the online weighing and take-up device.

[0003] Currently, the elephant trunk wire take-up machine relies solely on the weight of the steel wire as it spirals down during take-up. Due to the lack of an additional conditioning mechanism, the coil is prone to loosening. This not only takes up more storage space but also causes problems such as wire displacement and tangling during packaging, thereby reducing packaging efficiency and finished product quality. Utility Model Content

[0004] The purpose of this utility model is to provide a fixed-weight unloading mechanism for an elephant trunk take-up machine with a spring-loaded rotating rod. By setting a quantitative part, it solves the problem that the lack of an additional straightening mechanism can easily lead to loose coils, which not only takes up more storage space but also causes problems such as wire displacement and tangling during packaging, thereby reducing packaging efficiency and finished product quality.

[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:

[0006] This utility model relates to a spring-loaded wire unloading mechanism for an elephant trunk wire take-up machine. It includes an elephant trunk wire take-up machine and a metering section, which is installed on the machine and used to meter the wire coil, ensuring a tight and easily packaged coil. It also includes a fixing section, which is mounted on the metering section and used to fix it in place. After the metering section is fixed, the wire coil released by the elephant trunk wire take-up machine passes through it. This metering process ensures a tighter and easier-to-package wire coil.

[0007] Furthermore, the quantitative part includes a quantitative component installed on the elephant trunk take-up machine for combing the coil fed by the elephant trunk take-up machine; and a positioning component installed on the quantitative component for controlling the quantitative degree of the quantitative component; wherein, the positioning component can control the quantitative degree of the quantitative component, so that the quantitative component can flexibly adjust the feeding amount according to actual needs.

[0008] Furthermore, the fixing part includes a fixing component, which is mounted on the metering component to fix the metering component on the elephant trunk take-up machine; and two limiting components, which are mounted on the fixing component to limit the movement of the components on the fixing component, reducing manual operation; wherein, through the cooperation of the fixing component and the limiting component, the metering part can be fixed, thereby completing subsequent operations.

[0009] Furthermore, the metering component includes a mounting plate mounted on the elephant trunk take-up machine. A triangular wire guide is rotatably connected to the mounting plate, and a sliding frame is fixedly connected to the mounting plate. A sliding groove is formed on the sliding frame, and a sliding rod is slidably connected to the inner wall of the groove. A limiting slider is sleeved on the outer wall of the sliding rod. The limiting slider is adapted to the triangular wire guide and is equipped with a reset component. During the feeding operation of the elephant trunk take-up machine, when the wire coil passes through the metering section, it will contact the rotating triangular wire guide. During the rotation of the triangular wire guide frame, it is blocked by the limit slider, causing the falling wire coils to temporarily accumulate. As the coils continue to accumulate, the weight gradually increases, which will push the triangular wire guide frame to continue rotating. At this time, the rotational force of the triangular wire guide frame will be transmitted to the limit slider, which in turn acts on the spring connected to it. When the force exceeds the elastic force of the spring, the spring is compressed, and the limit slider can move in the direction of the spring, allowing the triangular wire guide frame to pass over the limit slider and continue rotating, releasing the accumulated wire coils onto the take-up roller.

[0010] Furthermore, the positioning component includes a stop block fixedly connected to the limiting slider. The top of the sliding frame has several screw holes, and the inner wall of the corresponding screw holes is threaded with bolts. The bolts are adapted to the stop block. Through the cooperation of the bolts, screw holes, and stop block, the contact surface distance between the limiting slider and the triangular wire guide frame can be adjusted, so that the limiting slider can pass over the triangular wire guide frame more smoothly, thereby realizing the rapid release of the steel wire coil.

[0011] Furthermore, the fixing component includes a screw fixedly connected to the right side of the mounting plate, a mounting frame slidably connected to the outer wall of the screw, two folding rods hinged to the mounting frame, and a manual knob threadedly connected to the outer wall of the screw; wherein, when fixing the metering part, the fixing component is first passed through the elephant trunk take-up machine as a whole, then the two folding rods folded on the mounting frame are unfolded, and finally, the manual knob on the outer wall of the screw is used to complete the fixing of the metering part.

[0012] Furthermore, the limiting component includes a stop bar fixedly connected to the folding rod, a telescopic rod fixedly connected to the top plate of the mounting frame, a trapezoidal slider fixedly connected to the top of the telescopic rod, the trapezoidal slider being adapted to the stop bar, and a second spring wound around the outer wall of the telescopic rod. One end of the second spring is fixedly connected to the mounting frame, and the other end of the second spring is fixedly connected to the trapezoidal slider. When the two folding rods on the mounting frame are unfolded, the stop bar on the folding rod will contact the inclined surface of the trapezoidal slider. During the contact process, the stop bar pushes the trapezoidal slider, causing it to move downward with the help of the telescopic rod. This action allows the folding rod to smoothly drive the stop bar past the trapezoidal slider. Subsequently, the trapezoidal slider automatically resets, thereby limiting the folding rod and reducing manual operation. In addition, when the stop bar squeezes the trapezoidal slider and the telescopic rod, the second spring on the outer wall of the telescopic rod is simultaneously compressed, thereby accumulating elastic potential energy and providing power support for the reset of the trapezoidal slider and the telescopic rod.

[0013] Furthermore, the reset component includes a spring fixedly connected to the slide frame, the front end of which is fixedly connected to the limiting slider. When the triangular wire stop is subjected to weight, it transmits rotational force to the limiting slider, which then applies a force to the spring connected to it. When this force exceeds the elastic force of the spring, the spring is compressed and accumulates elastic potential energy, thereby providing power support for the subsequent reset process.

[0014] This utility model has the following beneficial effects:

[0015] 1. By setting a quantitative section, during the feeding operation of the elephant trunk take-up machine, when the steel wire coil is fed to the quantitative section, it will come into contact with the rotating triangular wire guide frame. During the rotation of the triangular wire guide frame, it will be blocked by the limit slider, causing the falling steel wire coil to temporarily accumulate. As the coil continues to accumulate, its weight gradually increases. When it reaches a certain level, it can push the triangular wire guide frame to continue rotating. At this time, the rotational force of the triangular wire guide frame is transmitted to the spring connected to it through the limit slider. When the force exceeds the elastic force of the spring, the spring is compressed, and the limit slider moves in the direction of the spring, so that the triangular wire guide frame can pass the limit slider and continue to rotate, thereby releasing the accumulated steel wire coil onto the take-up roller. This design effectively avoids the problem of loose coils during take-up, thereby improving packaging efficiency and finished product quality.

[0016] 2. By setting up a fixing part, when installing the fixed metering part, the fixing assembly is first passed through the elephant trunk take-up machine. Then, the two folding rods folded on the mounting frame are unfolded. During the unfolding process, the stop bar on the folding rod will contact the inclined surface of the trapezoidal slider. The stop bar pushes the trapezoidal slider, causing it to move downward with the help of the telescopic rod. This allows the folding rod to smoothly drive the stop bar past the trapezoidal slider. After the folding rod passes the trapezoidal slider, the trapezoidal slider automatically resets, thus limiting the folding rod and reducing manual operation. It is worth noting that when the stop bar presses the trapezoidal slider and the telescopic rod, the spring on the outer wall of the telescopic rod is simultaneously compressed, accumulating elastic potential energy to provide power for the reset of the trapezoidal slider and the telescopic rod. Finally, the metering part can be fixed by turning the manual knob on the outer wall of the screw. This fixing method simplifies the cumbersome process of device installation and effectively improves work efficiency.

[0017] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description

[0018] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0019] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0020] Figure 2 This is a partial cross-sectional view of the quantitative part of this utility model;

[0021] Figure 3 This is a partial cross-sectional view of the fixing part of this utility model;

[0022] Figure 4 This utility model Figure 2 A magnified structural diagram of A in the middle;

[0023] Figure 5 This utility model Figure 3 A magnified structural diagram of B in the diagram.

[0024] The attached diagram lists the components represented by each number as follows:

[0025] 111. Elephant Trunk Take-up Machine; 2. Metering Section; 21. Metering Component; 211. Mounting Plate; 212. Triangular Wire Stop Frame; 213. Sliding Frame; 214. Sliding Groove; 215. Sliding Rod; 216. Limiting Slider; 217. Spring One; 22. Positioning Component; 221. Stop Block; 222. Screw Hole; 223. Bolt; 3. Fixing Section; 31. Fixing Component; 311. Screw; 312. Mounting Frame; 313. Folding Rod; 314. Manual Knob; 32. Limiting Component; 321. Stop Bar; 322. Telescopic Rod; 323. Trapezoidal Slider; 324. Spring Two. Detailed Implementation

[0026] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0027] Please see Figure 1-5 As shown, this utility model is a fixed-weight unloading mechanism for an elephant trunk take-up coil spring lever, including an elephant trunk take-up coil 111, and further including: a metering part 2, which is installed on the elephant trunk take-up coil 111 and is used to meter the steel wire coil, so that the recovered steel wire coil is tight and easy to pack; and a fixing part 3, which is set on the metering part 2 and is used to fix the metering part 2; wherein, after the metering part 2 is fixed by the fixing part 3, the steel wire coil released by the elephant trunk take-up coil 111 will pass through the metering part 2. The metering of the steel wire coil by the metering part 2 makes the recovered steel wire coil tighter and easier to pack.

[0028] The metering unit 2 includes a metering component 21, which is mounted on the elephant trunk take-up machine 111 and used to comb the coils fed by the elephant trunk take-up machine 111; and a positioning component 22, which is mounted on the metering component 21 and used to control the metering accuracy of the metering component 21. The positioning component 22 controls the metering accuracy of the metering component 21, allowing the metering component 21 to flexibly adjust the feeding amount according to actual needs. The metering component 21 includes a mounting plate 211 mounted on the elephant trunk take-up machine 111, and a triangular wire guide frame 21 is rotatably connected to the mounting plate 211. 2. A sliding frame 213 is fixedly connected to the mounting plate 211. A sliding groove 214 is provided on the sliding frame 213. A sliding rod 215 is slidably connected to the inner wall of the sliding groove 214. A limiting slider 216 is sleeved on the outer wall of the sliding rod 215. The limiting slider 216 is adapted to the triangular wire guide frame 212. A reset component is provided on the limiting slider 216. During the feeding operation of the elephant trunk wire take-up machine 111, when the wire coil passes through the metering section 2, it will contact the rotating triangular wire guide frame 212. During the rotation of the triangular wire guide frame 212, it will be blocked by the limiting slider 216, causing the falling wire coil to be temporarily stopped. As the coils accumulate, the weight gradually increases, pushing the triangular wire guide 212 to continue rotating. At this time, the rotational force of the triangular wire guide 212 is transmitted to the limiting slider 216, which in turn acts on the connected spring 217. When this force exceeds the elastic force of the spring 217, the spring is compressed, and the limiting slider 216 can move towards the spring 217, allowing the triangular wire guide 212 to pass over the limiting slider 216 and continue rotating, releasing the accumulated wire coils onto the take-up roller. The positioning assembly 22 includes a stop block 221 fixedly connected to the limiting slider 216. The top of the slide frame 213 has several screw holes 222, and the inner wall of the corresponding screw holes 222 is threaded with bolts 223. The bolts 223 are adapted to the stop block 221. The bolts 223, screw holes 222, and stop block 221 are used to adjust the contact distance between the limiting slider 216 and the triangular wire stop frame 212, so that the limiting slider 216 can pass over the triangular wire stop frame 212 more smoothly, thereby realizing the rapid release of the wire coil. The reset component includes a spring 217 fixedly connected to the slide frame 213, and the front end of the spring 217 is fixedly connected to the limiting slider 216.When the triangular wire guide 212 is subjected to weight, it transmits rotational force to the limiting slider 216. The limiting slider 216 then applies a force to the connected spring 217. When this force exceeds the elastic force of the spring 217, the spring 217 is compressed and accumulates elastic potential energy, thus providing power support for the subsequent reset process. By setting the metering section 2, during the feeding operation of the elephant trunk take-up machine 111, when the wire coil is conveyed to the metering section 2, it will contact the rotating triangular wire guide 212. During the rotation of the triangular wire guide 212, it will be blocked by the limiting slider 216, causing the falling wire coil to be blocked. The coils are temporarily piled up, and as they accumulate, their weight gradually increases. When a certain weight is reached, it pushes the triangular wire guide 212 to continue rotating. At this point, the rotational force of the triangular wire guide 212 is transmitted to the connected spring 217 via the limiting slider 216. When this force exceeds the elastic force of the spring 217, the spring 217 is compressed, and the limiting slider 216 moves towards the spring 217. This allows the triangular wire guide 212 to pass over the limiting slider 216 and continue rotating, thereby releasing the piled-up wire coils onto the take-up roller. This design effectively avoids the problem of loose coils during take-up, thus improving packaging efficiency and finished product quality.

[0029] The fixing part 3 includes a fixing component 31, which is mounted on the metering component 21 and can fix the metering component 21 on the elephant trunk take-up machine 111; and two limiting components 32, which are mounted on the fixing component 31 and are used to limit the components on the fixing component 31 to reduce manual operation; wherein, through the cooperation of the fixing component 31 and the limiting components 32, the metering part 2 can be fixed, thereby completing subsequent operations. The fixing component 31 includes a screw 311 fixedly connected to the right side of the mounting plate 211, a mounting frame 312 slidably connected to the outer wall of the screw 311, two folding rods 313 hinged on the mounting frame 312, and a manual knob 314 threadedly connected to the outer wall of the screw 311; wherein, When fixing the metering part 2, first pass the fixing component 31 through the elephant trunk take-up machine 111. Then, unfold the two folding rods 313 folded on the mounting frame 312. Finally, use the manual knob 314 on the outer wall of the screw 311 to fix the metering part 2. The limiting component 32 includes a stop bar 321 fixedly connected to the folding rod 313. The top plate of the mounting frame 312 is fixedly connected to a telescopic rod 322. The top end of the telescopic rod 322 is fixedly connected to a trapezoidal slider 323. The trapezoidal slider 323 is adapted to the stop bar 321. The outer wall of the telescopic rod 322 is wrapped with a second spring 324. One end of the second spring 324 is fixedly connected to the mounting frame 312, and the other end of the second spring 324 is fixedly connected to the trapezoidal slider 323.When the two folding rods 313 on the mounting frame 312 are unfolded, the stop bar 321 on the folding rod 313 will contact the inclined surface of the trapezoidal slider 323. During the contact process, the stop bar 321 pushes the trapezoidal slider 323, causing it to move downward with the help of the telescopic rod 322. This action allows the folding rod 313 to drive the stop bar 321 to smoothly pass over the trapezoidal slider 323. Subsequently, the trapezoidal slider 323 automatically resets, achieving the limit of the folding rod 313 and reducing manual operation. In addition, when the stop bar 321 squeezes the trapezoidal slider 323 and the telescopic rod 322, the spring 324 on the outer wall of the telescopic rod 322 is compressed simultaneously, thereby accumulating elastic potential energy and providing power support for the reset of the trapezoidal slider 323 and the telescopic rod 322. By setting the fixing part 3, when installing the fixing quantitative part 2, the fixing component 31 is first passed through the elephant trunk take-up machine 111 as a whole, and then the two folding rods 313 folded on the mounting frame 312 are unfolded. During the unfolding of the folding rod 313, the stop bar 321 on the folding rod 313 contacts the inclined surface of the trapezoidal slider 323. The stop bar 321 pushes the trapezoidal slider 323, causing it to move downwards with the help of the telescopic rod 322. This allows the folding rod 313 to smoothly pass the stop bar 321 over the trapezoidal slider 323. After the folding rod 313 passes the trapezoidal slider 323, the trapezoidal slider 323 automatically resets, thus limiting the folding rod 313 and reducing manual operation. It is worth noting that when the stop bar 321 presses against the trapezoidal slider 323 and the telescopic rod 322, the spring 324 on the outer wall of the telescopic rod 322 is simultaneously compressed, accumulating elastic potential energy to provide power for the reset of the trapezoidal slider 323 and the telescopic rod 322. Finally, by rotating the manual knob 314 on the outer wall of the screw 311, the metering part 2 can be fixed. This fixing method simplifies the cumbersome installation process of the device and effectively improves work efficiency.

[0030] A specific application of this embodiment is as follows: During the feeding operation of the elephant trunk wire take-up machine 111, when the wire coil is conveyed to the metering section 2, it will come into contact with the rotating triangular wire guide frame 212. During the rotation of the triangular wire guide frame 212, it will be blocked by the limiting slider 216, causing the falling wire coil to temporarily accumulate. As the coil continues to accumulate, its weight gradually increases. When it reaches a certain level, it can push the triangular wire guide frame 212 to continue rotating. At this time, the rotational force of the triangular wire guide frame 212 is transmitted through... The limiting slider 216 transmits the force to the connected spring 217. When the force exceeds the elastic force of the spring 217, the spring 217 is compressed, and the limiting slider 216 moves towards the spring 217, allowing the triangular wire guide frame 212 to pass over the limiting slider 216 and continue rotating, thereby releasing the accumulated wire coil onto the take-up roller. This design effectively avoids the problem of loosening during coil take-up, thus improving packaging efficiency and finished product quality. When installing the fixed metering section 2, first install the fixing component 3. The entire assembly passes through the elephant trunk take-up machine 111, and then unfolds the two folding rods 313 folded on the mounting frame 312. During the unfolding of the folding rods 313, the stop bar 321 on the folding rod 313 contacts the inclined surface of the trapezoidal slider 323. The stop bar 321 pushes the trapezoidal slider 323, causing it to move downward with the help of the telescopic rod 322, so that the folding rod 313 drives the stop bar 321 to smoothly pass over the trapezoidal slider 323. After the folding rod 313 passes over the trapezoidal slider 323, the trapezoidal slider 323 automatically returns to its original position. The limiting of the folding rod 313 reduces the amount of manual operation. It is worth noting that when the stop rod 321 presses the trapezoidal slider 323 and the telescopic rod 322, the spring 324 on the outer wall of the telescopic rod 322 is compressed simultaneously, accumulating elastic potential energy to provide power for the reset of the trapezoidal slider 323 and the telescopic rod 322. Finally, the metering part 2 can be fixed by rotating the manual knob 314 on the outer wall of the screw 311. This fixing method simplifies the cumbersome process of device installation and effectively improves work efficiency.

[0031] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.

[0032] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.

Claims

1. A spring-loaded winding mechanism for an elephant trunk winding machine, comprising an elephant trunk winding machine (111), characterized in that, Also includes: The metering unit (2), installed on the elephant trunk take-up machine (111), is used to meter the steel wire coils, so that the recovered steel wire coils are tightly packed for easy packaging; and A fixing part (3) is provided on the metering part (2) for fixing the metering part (2); When the fixing part (3) is used to fix the quantitative part (2), the steel wire coil released by the elephant trunk coiler (111) will pass through the quantitative part (2). The quantitative feeding by the quantitative part (2) can make the recovered steel wire coil more compact and easier to pack.

2. The elastic rotating rod constant weight unloading mechanism of the elephant trunk take-up machine according to claim 1, characterized in that, The quantitative part (2) includes a quantitative component (21), which is installed on the elephant trunk take-up machine (111) and is used to comb the coils fed by the elephant trunk take-up machine (111); as well as Positioning component (22), which is mounted on metering component (21), is used to control the metering degree of metering component (21); Among them, the positioning component (22) can control the quantitative degree of the quantitative component (21), so that the quantitative component (21) can flexibly adjust the feeding amount according to actual needs.

3. The elastic rotating rod constant weight unloading mechanism of the elephant trunk winding machine according to claim 2, characterized in that, The fixing part (3) includes a fixing component (31) which is mounted on the metering component (21) and enables the metering component (21) to be fixed on the elephant trunk take-up machine (111); and Two limiting components (32) are installed on the fixed component (31) to limit the parts on the fixed component (31) and reduce manual operation; The quantitative part (2) can be fixed by the cooperation of the fixing component (31) and the limiting component (32), thereby completing the subsequent operation.

4. The elastic rotating rod constant weight unloading mechanism of the elephant trunk take-up machine according to claim 3, characterized in that, The quantitative component (21) includes a mounting plate (211) disposed on the elephant trunk wire take-up machine (111), a triangular wire guide frame (212) rotatably connected to the mounting plate (211), a sliding frame (213) fixedly connected to the mounting plate (211), a sliding groove (214) provided on the sliding frame (213), a sliding rod (215) slidably connected to the inner wall of the sliding groove (214), a limiting slider (216) sleeved on the outer wall of the sliding rod (215), the limiting slider (216) being adapted to the triangular wire guide frame (212), and a reset component provided on the limiting slider (216); In the feeding operation of the elephant trunk take-up machine (111), when the wire coil passes through the metering section (2), it will come into contact with the rotating triangular wire guide frame (212). During the rotation of the triangular wire guide frame (212), it will be blocked by the limiting slider (216), causing the falling wire coil to temporarily accumulate. As the coil continues to accumulate, the weight gradually increases, which will push the triangular wire guide frame (212) to continue to rotate. At this time, the rotational force of the triangular wire guide frame (212) will be transmitted to the limiting slider (216), and then act on the spring 1 (217) connected to it. When the force exceeds the elastic force of the spring 1 (217), the spring is compressed, and the limiting slider (216) can move towards the spring 1 (217), so that the triangular wire guide frame (212) can pass over the limiting slider (216) to continue rotating, releasing the accumulated wire coil onto the take-up roller.

5. The elastic rotating rod constant weight unloading mechanism of the elephant trunk winding machine according to claim 4, characterized in that, The positioning component (22) includes a stop (221) fixedly connected to the limiting slider (216). The top of the slide frame (213) is provided with a plurality of screw holes (222). The inner wall of the corresponding screw holes (222) is threaded with bolts (223). The bolts (223) are adapted to the stop (221). The contact distance between the limit slider (216) and the triangular wire stop (212) can be adjusted by the cooperation of the bolt (223) with the screw hole (222) and the stop (221), so that the limit slider (216) can pass over the triangular wire stop (212) more smoothly, thereby realizing the rapid release of the wire coil.

6. The elastic rotating rod constant weight unloading mechanism of the elephant trunk take-up machine according to claim 5, characterized in that, The fixing component (31) includes a screw (311) fixedly connected to the right side of the mounting plate (211), a mounting frame (312) slidably connected to the outer wall of the screw (311), two folding rods (313) hinged on the mounting frame (312), and a manual knob (314) threadedly connected to the outer wall of the screw (311). When fixing the quantitative part (2), first pass the fixing component (31) through the elephant trunk take-up machine (111), then unfold the two folding rods (313) folded on the mounting frame (312), and finally, use the manual knob (314) on the outer wall of the screw (311) to fix the quantitative part (2).

7. The elastic rotating rod constant weight unloading mechanism of the elephant trunk take-up machine according to claim 6, characterized in that, The limiting component (32) includes a stop bar (321) fixedly connected to the folding rod (313), a telescopic rod (322) fixedly connected to the top plate of the mounting frame (312), a trapezoidal slider (323) fixedly connected to the top end of the telescopic rod (322), the trapezoidal slider (323) being adapted to the stop bar (321), and a second spring (324) wound around the outer wall of the telescopic rod (322). One end of the second spring (324) is fixedly connected to the mounting frame (312), and the other end of the second spring (324) is fixedly connected to the trapezoidal slider (323). When the two folding rods (313) on the mounting frame (312) are unfolded, the stop bar (321) on the folding rod (313) will contact the inclined surface of the trapezoidal slider (323). During the contact process, the stop bar (321) pushes the trapezoidal slider (323) so that it moves downward with the help of the telescopic rod (322). This action allows the folding rod (313) to drive the stop bar (321) to pass smoothly over the trapezoidal slider (323). Subsequently, the trapezoidal slider (323) automatically resets, thereby limiting the folding rod (313) and reducing manual operation. In addition, when the stop bar (321) squeezes the trapezoidal slider (323) and the telescopic rod (322), the second spring (324) on the outer wall of the telescopic rod (322) is compressed simultaneously, thereby accumulating elastic potential energy and providing power support for the reset of the trapezoidal slider (323) and the telescopic rod (322).

8. The elastic rotating rod constant weight unloading mechanism of the elephant trunk take-up machine according to claim 7, characterized in that, The reset component includes a spring (217) fixedly connected to the slide frame (213), and the front end of the spring (217) is fixedly connected to the limiting slider (216); When the triangular wire stop (212) is subjected to weight, it will transmit the rotational force to the limiting slider (216). The limiting slider (216) will then apply a force to the spring (217) connected to it. When the force exceeds the elastic force of the spring (217), the spring (217) will be compressed and accumulate elastic potential energy, thereby providing power support for the subsequent reset process.

Images