Wrapping wire winding device

Abstract

The utility model provides a kind of wrapping wire winding device, including machine shell, adjusting assembly, winding assembly and detection component;Adjusting assembly is arranged on machine shell, and adjusting assembly includes adjustably arranged adjusting component;Winding assembly is arranged on machine shell, and winding assembly includes rotatably arranged winding shaft, to make the free end of the wire to be wound after winding around adjusting component and be wound on winding shaft, to form wrapping coil, adjusting component is used to adjust the tension of the wire to be wound;Detection component is arranged on machine shell, to be used for detecting the outer diameter of wrapping coil on winding shaft, and winding shaft stops rotating when the outer diameter of wrapping coil is greater than set value.The technical scheme of the utility model solves the problem that conventional large coil is difficult to meet the production needs of wrapping knotter in the prior art, which affects the production efficiency.

Description

Technical Field

[0001] This utility model relates to the technical field of wire processing equipment, and more specifically, to a winding device for wrapping wire. Background Technology

[0002] Currently, glass fiber, as a widely used reinforcing material, demonstrates unique value in multiple fields due to its excellent insulation properties, corrosion resistance, and high strength-to-weight ratio. In the industrial production of glass fiber yarn, the yarn typically needs to maintain continuity to avoid overall performance degradation caused by breakage or wear at joints. Therefore, the method of connecting yarn bundles becomes a key factor affecting production efficiency and product quality. In existing technologies, commonly used yarn bundle connection and knotting methods include air knots, hand knots, and wrapping knots. Among these, the wrapping knot, due to its high connection strength and stability, is particularly suitable for the continuous production of glass fiber yarn. It forms a strong connection point by tightly winding the yarns together with an auxiliary wrapping material.

[0003] However, existing wrapping knotters are designed to accommodate only specific coils of fixed height and outer diameter, limiting their application in handling large-gauge yarn spools. Large yarn spools often have longer continuous lengths, significantly reducing changeover frequency, increasing production efficiency, and lowering costs. However, conventional knotters cannot precisely control the outer diameter and tension of the coils, restricting their direct application to large yarn spools. Furthermore, the wrapping coils used in wrapping knotters are currently primarily imported, resulting in high procurement costs and long delivery times, severely impacting production efficiency. Utility Model Content

[0004] The main purpose of this utility model is to provide a winding device for wrapping wire, so as to solve the problem that conventional large coils in the prior art cannot meet the production needs of wrapping knotters, thus affecting production efficiency.

[0005] To achieve the above objectives, according to one aspect of the present invention, a winding device for wrapping wire is provided, comprising: a housing; an adjustment assembly disposed on the housing, the adjustment assembly including a movably disposed adjustment member; a winding assembly disposed on the housing, the winding assembly including a rotatably disposed winding shaft, such that the free end of the wire to be wound passes through the adjustment member and is wound onto the winding shaft to form a wrapped coil, the adjustment member being used to adjust the tension of the wire to be wound; and a detection assembly disposed on the housing for detecting the outer diameter of the wrapped coil on the winding shaft, and stopping the rotation of the winding shaft when the outer diameter of the wrapped coil is greater than a set value.

[0006] Furthermore, the adjusting component includes: a mounting rod disposed on the housing; a first shim and a second shim disposed at intervals on the mounting rod; the free end of the wire to be wound is wound on the mounting rod and located between the first shim and the second shim; the wire to be wound contacts the first shim and the second shim respectively; the first shim is movably disposed in a direction toward or away from the second shim to adjust the tension of the wire to be wound.

[0007] Furthermore, the adjustment component also includes: an adjustment knob rotatably connected to the end of the mounting rod; and an elastic element disposed inside the adjustment knob, one end of which is connected to the inner wall of the adjustment knob, and the other end of which is connected to the first washer, so as to adjust the tension of the wire to be wound by rotating the adjustment knob.

[0008] Furthermore, the adjustment assembly also includes: a wire threading frame, which is mounted on the mounting rod. The wire threading frame has through holes at both ends. The free end of the wire to be wound passes through one through hole and is wound between the first and second pads, and then passes out through the other through hole and is wound on the winding shaft.

[0009] Furthermore, the detection assembly includes two detection components disposed relatively close to or far apart on the housing, with at least a portion of the winding shaft located between the two detection components, and the two detection components being spaced apart by a set value, to detect the outer diameter of the wound coil.

[0010] Furthermore, the detection assembly also includes: a slide rail, which is mounted on the housing and has scale lines along its extension direction; two sliding members, which are slidably mounted on the slide rail; two detection components, which are respectively mounted in the two sliding members; and the detection ends of the two detection components are arranged facing each other, so that the two detection components can be moved relative to each other along the scale lines to a distance of a set value by the two sliding members.

[0011] Furthermore, the winding device also includes a wire breaking assembly, which is disposed on the housing and located on the side close to the winding assembly. At least a portion of the wire breaking assembly is movably disposed in the vertical and horizontal directions, respectively, so as to cut the wire to be wound by at least a portion of the wire breaking assembly when the outer diameter of the winding coil is greater than a set value.

[0012] Furthermore, the housing is provided with a mounting groove extending in the horizontal direction. The wire breaking assembly includes: a movable part, which is disposed in the mounting groove and movably disposed in the extension direction of the mounting groove, and a first driving component is disposed on the movable part; and a wire breaking knife, which is connected to the driving end of the first driving component so as to drive the wire breaking knife to move in the vertical direction through the first driving component.

[0013] Furthermore, the set value 'a' satisfies: 10mm ≤ a ≤ 36mm; and / or,

[0014] The winding shaft is equipped with a winding wheel, and the winding wheel has a winding groove along its circumferential direction. The free end of the wire to be wound is placed in the winding groove so that the wire to be wound is wound in the winding groove.

[0015] Furthermore, the winding assembly also includes a second driving component, which is disposed within the housing. One end of the winding shaft is connected to the driving end of the second driving component. The winding device also includes a control component, which is disposed within the housing. The control component includes a relay module. The second driving component and the detection component are electrically connected to the relay module, so that when the detection component detects that the outer diameter of the winding coil is greater than a set value, the relay module controls the second driving component to stop.

[0016] The present invention provides a winding device for a wrapped wire, comprising a housing, an adjusting component, a winding component, and a detection component. The adjusting component is disposed on the housing and includes a movably disposed adjusting part. The winding component is disposed on the housing and includes a rotatably disposed winding shaft. The free end of the wire to be wound is wound around the winding shaft after passing through the adjusting part to form a wrapped coil. The adjusting part is used to adjust the tension of the wire to be wound. The detection component is disposed on the housing and is used to detect the outer diameter of the wrapped coil on the winding shaft. When the outer diameter of the wrapped coil is greater than a set value, the winding shaft stops rotating.

[0017] In this way, the tension of the wire to be wound can be adjusted according to actual needs by means of the adjustment component. The detection component allows the device to monitor the outer diameter of the winding coil in real time, and immediately stops the rotation of the winding shaft when the preset outer diameter value is reached, avoiding over-winding or under-winding, ensuring the dimensional consistency of each winding coil, and improving production accuracy. Furthermore, the outer diameter value detected by the detection component and the tension value adjusted by the adjustment component can be set simultaneously according to different production needs, enabling the device to adapt to the production of winding coils of various specifications and applications, improving the flexibility and adaptability of the production line, and thus solving the problem in the prior art where conventional large coils cannot meet the production needs of winding knotters, thus affecting production efficiency.

[0018] Furthermore, through automated control and precise adjustment, the device can effectively reduce material waste. At the same time, by reducing reliance on imported finished winding coils, it lowers procurement costs and shortens the supply chain cycle, which will significantly reduce overall production costs for the large-scale glass fiber industry. Attached Figure Description

[0019] The accompanying drawings, which form part of this application, are used to provide a further understanding of the present invention. The illustrative embodiments of the present invention and their descriptions are used to explain the present invention and do not constitute an undue limitation of the present invention. In the drawings:

[0020] Figure 1 A schematic diagram of the overall structure of an embodiment of the winding device for wrapping wire according to the present invention is shown;

[0021] Figure 2 A perspective view is shown provided according to an embodiment of the winding device for wrapping wire according to the present invention;

[0022] Figure 3 A schematic diagram of the structure of the adjustment assembly provided in an embodiment of the winding device for the present invention is shown.

[0023] The above figures include the following reference numerals:

[0024] 10. Housing; 20. Adjustment assembly; 21. Adjustment component; 210. Mounting rod; 211. First shim; 212. Second shim; 213. Adjustment knob; 214. Elastic element; 22. Wire threader; 220. Through hole; 30. Winding assembly; 31. Winding shaft; 32. Winding wheel; 33. Second drive component; 40. Detection assembly; 41. Detection component; 42. Slide rail; 43. Sliding element; 50. Wire breakage assembly; 60. Control assembly; 61. Relay module; 62. Switching power supply; 63. Touch switch; 64. Transformer; 65. Main control chip. Detailed Implementation

[0025] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. The present invention will now be described in detail with reference to the accompanying drawings and embodiments.

[0026] To address the problem that conventional large coils in the existing technology cannot meet the production needs of wrapping and knotting machines, thus affecting production efficiency, this utility model provides a wrapping wire winding device.

[0027] Please refer to Figures 1 to 3 As shown, the present invention provides a winding device for a wrapped wire, including a housing 10, an adjusting component 20, a winding component 30, and a detection component 40. The adjusting component 20 is disposed on the housing 10 and includes an adjusting member 21 that is movably disposed. The winding component 30 is disposed on the housing 10 and includes a rotatably disposed winding shaft 31, so that the free end of the wire to be wound passes through the adjusting member 21 and is wound onto the winding shaft 31 to form a wrapped coil. The adjusting member 21 is used to adjust the tension of the wire to be wound. The detection component 40 is disposed on the housing 10 and is used to detect the outer diameter of the wrapped coil on the winding shaft 31. When the outer diameter of the wrapped coil is greater than a set value, the winding shaft 31 stops rotating.

[0028] By employing the technical solution of this utility model, the tension of the wire to be wound can be adjusted according to actual needs through the adjustment component 20. The detection component 40 enables the device to monitor the outer diameter of the winding coil in real time. When the preset outer diameter value is reached, the rotation of the winding shaft 31 is immediately stopped, avoiding over-winding or under-winding, ensuring the dimensional consistency of each winding coil, and improving production accuracy. Furthermore, the outer diameter value detected by the detection component 40 and the tension value adjusted by the adjustment component 20 can be set simultaneously according to different production requirements, enabling the device to adapt to the production of winding coils of various specifications and applications. This improves the flexibility and adaptability of the production line, thereby solving the problem in the prior art where conventional large coils cannot meet the production needs of winding knotters, thus affecting production efficiency.

[0029] Furthermore, through automated control and precise adjustment, the device can effectively reduce material waste. At the same time, by reducing reliance on imported finished winding coils, it lowers procurement costs and shortens the supply chain cycle, which will significantly reduce overall production costs for the large-scale glass fiber industry.

[0030] In this embodiment, the wire to be wound is a low-elasticity wire; the outer diameter of the winding coil is the distance between the outer periphery of the wire to be wound on the winding shaft 31 and the axis of the winding shaft 31.

[0031] like Figure 3 As shown, the adjusting component 21 includes a mounting rod 210, a first gasket 211, and a second gasket 212. The mounting rod 210 is disposed on the housing 10. The first gasket 211 and the second gasket 212 are disposed on the mounting rod 210 at intervals. The free end of the wire to be wound is wound on the mounting rod 210 and located between the first gasket 211 and the second gasket 212. The wire to be wound contacts the first gasket 211 and the second gasket 212 respectively. The first gasket 211 is movably disposed in a direction toward or away from the second gasket 212 to adjust the tension of the wire to be wound.

[0032] The aforementioned configuration allows the operator to precisely control the tension of the wire to be wound by adjusting its position relative to the second pad 212, thus enabling the device to adapt to the characteristics of different wires and production needs, flexibly adjust the tension of the wire to be wound, ensure stable coil tension during the winding process, avoid coil deformation or loosening caused by excessive or insufficient tension, and improve the flexibility of the production line.

[0033] Specifically, the adjusting component 21 also includes an adjusting knob 213 and an elastic element 214. The adjusting knob 213 is rotatably connected to the end of the mounting rod 210. The elastic element 214 is disposed inside the adjusting knob 213, with one end connected to the inner wall of the adjusting knob 213 and the other end connected to the first pad 211. Rotating the adjusting knob 213 adjusts the tension of the wire to be wound. In this way, the operator only needs to rotate the adjusting knob 213 to intuitively adjust the tension of the wire to be wound, eliminating the need for complex mechanical structures or electronic equipment. This simplifies the operation process and reduces the difficulty of operation, allowing for rapid response even when tension requirements change quickly on the production line. Furthermore, the compression or extension stroke of the elastic element 214 forms a linear correspondence with the rotation angle of the adjusting knob 213, making the adjustment of the wire tension more precise and controllable. For example, each rotation of the adjustment knob 213 increases the tension by 0.8N, and clockwise rotation decreases it. The amount of tension increase or decrease is fixed, which helps maintain the consistency and stability of the coil.

[0034] In this embodiment, the elastic element 214 is a spring.

[0035] Specifically, the adjusting assembly 20 also includes a threader 22, which is mounted on the mounting rod 210. The threader 22 has through holes 220 at both ends. The free end of the wire to be wound passes through one through hole 220 and is wound between the first pad 211 and the second pad 212. It then exits through the other through hole 220 and is wound onto the winding shaft 31. This arrangement provides a clear guiding path for the wire to be wound, ensuring that it enters smoothly and orderly through one through hole 220, passes through the tension adjustment area between the first pad 211 and the second pad 212, and exits through the other through hole 220 to the winding shaft 31. This avoids the wire from becoming disorganized during the winding process, reduces the risk of the wire deviating, knotting, or breaking, and improves the stability and efficiency of the winding process.

[0036] like Figure 1 and Figure 2 As shown, the detection assembly 40 includes two detection components 41, which are disposed on the housing 10 relatively close to or far from each other. At least a portion of the winding shaft 31 is located between the two detection components 41, and the two detection components 41 are spaced apart by a set value to detect the outer diameter of the wound coil.

[0037] In the above configuration, the distance between the two detection components 41 serves as the detection benchmark for the outer diameter of the wound coil. As the outer diameter of the wound coil on the winding shaft 31 increases, when its outer diameter reaches or exceeds the distance between the two detection components 41, the detection components 41 can immediately sense this change and control the winding shaft 31 to stop rotating, thereby achieving automated detection and control, avoiding errors and delays caused by human judgment, and improving production efficiency and accuracy. Furthermore, the distance between the two detection components 41 can be set to different values, allowing the device to adapt to the production of wound coils with different outer diameter specifications, enhancing the equipment's versatility and adaptability. Operators can also flexibly adjust the target outer diameter of the coil according to production needs without frequently changing equipment or adjusting complex mechanical structures.

[0038] In this embodiment, the detection component 41 is an infrared beam sensor.

[0039] Specifically, the detection assembly 40 also includes a slide rail 42 and two sliding members 43; the slide rail 42 is disposed on the housing 10, and the slide rail 42 is provided with scale lines along its extension direction; the two sliding members 43 are slidably disposed on the slide rail 42, and the two detection components 41 are respectively disposed in the two sliding members 43, with the detection ends of the two detection components 41 facing each other, so that the two detection components 41 can be driven by the two sliding members 43 to move relative to each other along the scale lines to a distance of a set value.

[0040] In this way, the scale lines on the slide rail 42 make the position adjustment of the two detection components 41 more precise. The operator can refer to the scale lines to adjust the two detection components 41 to the preset distance value, thereby precisely controlling the detection range of the coil outer diameter and ensuring the consistency and accuracy of the coil size. Among them, the sliding component 43 uses a tightening screw to adjust the precision, with an adjustable accuracy of ±6.5mm.

[0041] To cut the wire to be wound, the winding device also includes a wire-cutting assembly 50. The wire-cutting assembly 50 is mounted on the housing 10 and located near the winding assembly 30. At least a portion of the wire-cutting assembly 50 is movably positioned in both the vertical and horizontal directions to cut the wire to be wound when the outer diameter of the winding coil exceeds a preset value. Thus, the wire-cutting assembly 50 can automatically move to the correct position in both the vertical and horizontal directions to cut the wire when the outer diameter of the winding coil reaches the set value, based on signals from the detection assembly 40. This method of cutting the wire after winding a single finished winding coil reduces reliance on manual labor, avoids human error that may be introduced by manual cutting, ensures that the length and outer diameter of each coil are strictly consistent, and improves the accuracy of the finished product.

[0042] Optionally, the wire cutting assembly 50 is directly an arc-shaped elastic blade, one end of which is fixed to the housing 10, and the other end of which is set toward the winding shaft 31 for cutting the wire to be wound.

[0043] Specifically, the housing 10 has a horizontally extending mounting groove, and the wire breaking assembly 50 includes a movable member and a wire breaking blade. The movable member is disposed within the mounting groove and is movably disposed along the extension direction of the mounting groove. A first driving component is disposed on the movable member. The wire breaking blade is connected to the driving end of the first driving component so that the wire breaking blade is driven to move vertically by the first driving component. The driving component is a drive motor.

[0044] The above setup, through the precise control of the vertical and horizontal movement of the wire-cutting knife by the movable parts and the first driving component, ensures that the wire-cutting knife can accurately cut the wire after the coil reaches the target outer diameter, reducing errors and wire waste during the wire-cutting process, ensuring the integrity and high quality of each finished coil, and enabling the wire-cutting operation to be automated, reducing the need for manual intervention, improving production efficiency and operator safety, and also reducing production costs.

[0045] In this embodiment, the set value a satisfies: 10mm≤a≤36mm.

[0046] Specifically, the winding shaft 31 is provided with a winding wheel 32, and the winding wheel 32 has a winding groove along its circumferential direction. The free end of the wire to be wound is placed in the winding groove so that the wire is wound within the winding groove. In this configuration, the winding groove provides a precise guiding path and positioning for the wire to be wound, avoiding random swinging or jumping of the wire during the winding process, ensuring that the wire can be wound orderly along the preset track, improving the stability of the winding process and the quality of the finished coil.

[0047] like Figure 2 As shown, the winding assembly 30 also includes a second drive component 33, which is disposed within the housing 10. One end of the winding shaft 31 is connected to the drive end of the second drive component 33. The winding device also includes a control component 60, which is disposed within the housing 10. The control component 60 includes a relay module 61. The second drive component 33 and the detection component 40 are electrically connected to the relay module 61, so that when the detection component 40 detects that the outer diameter of the winding coil is greater than a set value, the relay module 61 controls the second drive component 33 to stop. The second drive component 33 is a drive motor and is equipped with a 2-second delay stop to prevent inertial over-winding. The logic of the control component 60 is that the infrared photoelectric sensor is input to the controller after optical coupling isolation, and the relay module 61 performs a 0.5-second pre-deceleration control before actuation.

[0048] Thus, the introduction of the relay module 61 enables intelligent linkage between the detection component 40 and the second drive component 33. Once the outer diameter of the wound coil is detected to exceed the set value, the relay module 61 can quickly respond and control the second drive component 33 to stop, thereby automatically preventing over-winding and improving the intelligence level of the equipment. Furthermore, through the precise control of the second drive component 33 by the relay module 61, the device can ensure that the outer diameter of each finished coil meets the set requirements, greatly improving the dimensional accuracy in the production process and reducing errors caused by human factors or mechanical inertia.

[0049] In this embodiment, the control component 60 also includes a switching power supply 62, a touch switch 63, a transformer 64, and a main control chip. The relay module 61 is mounted on the main control chip. The switching power supply 62 is located on the front end face of the housing 10, and the touch switch 63 is located on the upper end face of the housing 10. After the device is plugged in, the switching power supply 62 is turned on to supply power, and the touch switch 63 is pressed to control the operation of the device.

[0050] For example, the current price of a single roll of special wrapping thread is 170 yuan. Based on a monthly output of 400 tons, the expenditure would be 510,000 yuan per year. However, by using the wrapping thread winding device of this utility model to achieve independent winding, and purchasing low-elasticity wire at 200 yuan / kg, the expenditure would only be 2,000 yuan per year, greatly saving production costs.

[0051] In this application, the specific usage process is as follows:

[0052] The wire to be wound is manually passed through the through hole 220 at one end of the wire threading frame 22 and then wound between the first pad 211 and the second pad 212. It then passes through the through hole 220 at the other end of the wire threading frame 22. The wire to be wound is then wound onto the winding shaft 31 and fixed. The distance between the two detection components 41 is adjusted according to actual needs. The first pad 211 and the second pad 212 are adjusted using the adjustment knob 213 to control the tension of the wire to be wound to the predetermined tension value. Then, the switching power supply 62 is turned on to power on the device. The second drive component 33 is automatically wound by pressing the touch switch 63. After the outer diameter of the winding coil on the winding shaft 31 reaches the set value, the infrared beam sensor signal is triggered to the control component 60. The relay module 61 cuts off the power to the second drive component 33, and the drive motor stops running. Finally, the wire to be wound is cut by the wire cutting component 50, and a single finished winding coil is completed.

[0053] As can be seen from the above description, the embodiments of this utility model achieve the following technical effects:

[0054] The winding device includes a housing 10, an adjusting component 20, a winding component 30, and a detection component 40. The adjusting component 20 is mounted on the housing 10 and includes a movably mounted adjusting member 21. The winding component 30 is mounted on the housing 10 and includes a rotatably mounted winding shaft 31. The free end of the wire to be wound is wound around the winding shaft 31 after passing through the adjusting member 21 to form a winding coil. The adjusting member 21 is used to adjust the tension of the wire to be wound. The detection component 40 is mounted on the housing 10 and is used to detect the outer diameter of the winding coil on the winding shaft 31. When the outer diameter of the winding coil is greater than a set value, the winding shaft 31 stops rotating. Thus, the tension of the wire to be wound can be adjusted according to actual needs via the adjusting component 20. The detection component 40 enables the device to monitor the outer diameter of the winding coil in real time. When the preset outer diameter value is reached, the rotation of the winding shaft 31 is immediately stopped, avoiding overwinding or underwinding, ensuring the dimensional consistency of each winding coil, and improving production accuracy. Furthermore, the outer diameter value detected by the detection component 40 and the tension value adjusted by the adjustment component 20 can be set simultaneously according to different production needs, allowing the device to adapt to the production of winding coils of various specifications and applications, improving the flexibility and adaptability of the production line. This solves the problem in the prior art where conventional large coils cannot meet the production needs of winding knotters, thus affecting production efficiency. Moreover, through automated control and precise adjustment, the device can effectively reduce material waste. Simultaneously, by reducing reliance on imported finished winding coils, procurement costs are lowered, and the supply chain cycle is shortened. For the large-scale glass fiber industry, this will significantly reduce overall production costs.

[0055] It should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the exemplary embodiments according to this application. As used herein, the singular form is intended to include the plural form as well, unless the context clearly indicates otherwise. Furthermore, it should be understood that when the terms "comprising" and / or "including" are used in this specification, they indicate the presence of features, steps, operations, devices, components, and / or combinations thereof.

[0056] Unless otherwise specifically stated, the relative arrangement, numerical expressions, and values ​​of the components and steps described in these embodiments do not limit the scope of this invention. It should also be understood that, for ease of description, the dimensions of the various parts shown in the drawings are not drawn to actual scale. Techniques, methods, and devices known to those skilled in the art may not be discussed in detail, but where appropriate, such techniques, methods, and devices should be considered part of the specification. In all examples shown and discussed herein, any specific values ​​should be interpreted as merely exemplary and not as limitations. Therefore, other examples of exemplary embodiments may have different values. It should be noted that similar reference numerals and letters in the following drawings denote similar items; therefore, once an item is defined in one drawing, it need not be further discussed in subsequent drawings.

[0057] In the description of this utility model, it should be understood that the directional terms such as "front, back, up, down, left, right", "horizontal, vertical, horizontal" and "top, bottom" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description. Unless otherwise stated, these directional terms do not indicate or imply that the device or element referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation on the scope of protection of this utility model. The directional terms "inner" and "outer" refer to the inner and outer contours of each component itself.

[0058] For ease of description, spatial relative terms such as "above," "over," "on the upper surface," "above," etc., are used herein to describe the spatial positional relationship of a device or feature as shown in the figures to other devices or features. It should be understood that spatial relative terms are intended to encompass different orientations in use or operation beyond the orientation of the device as described in the figures. For example, if the device in the figures were inverted, a device described as "above" or "above" other devices or structures would subsequently be positioned as "below" or "under" other devices or structures. Thus, the exemplary term "above" can include both "above" and "below." The device may also be positioned in other different ways (rotated 90 degrees or in other orientations), and the spatial relative descriptions used herein will be interpreted accordingly.

[0059] The above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A winding device for wrapping wire, characterized in that, include: Housing (10); An adjustment assembly (20) is disposed on the housing (10), the adjustment assembly (20) including an adjustment component that is movably disposed; A winding assembly (30) is disposed on the housing (10). The winding assembly (30) includes a rotatably disposed winding shaft (31) so that the free end of the wire to be wound is wound around the winding shaft (31) after passing through the adjusting component to form a wrapped coil. The adjusting component is used to adjust the tension of the wire to be wound. A detection component (40) is provided on the housing (10) for detecting the outer diameter of the winding coil on the winding shaft (31), and the winding shaft (31) stops rotating when the outer diameter of the winding coil is greater than a set value.

2. The winding device for wrapping wire according to claim 1, characterized in that, The adjusting component includes: Mounting rod (210) is provided on the housing (10); A first gasket (211) and a second gasket (212) are spaced apart on the mounting rod (210). The free end of the wire to be wound is wound around the mounting rod (210) and located between the first gasket (211) and the second gasket (212). The wire to be wound is in contact with the first gasket (211) and the second gasket (212) respectively. The first gasket (211) is movably disposed in a direction toward or away from the second gasket (212) to adjust the tension of the wire to be wound.

3. The winding device for wrapping wire according to claim 2, characterized in that, The adjustment component further includes: The adjustment knob (213) is rotatably connected to the end of the mounting rod (210); An elastic element (214) is disposed inside the adjustment knob (213). One end of the elastic element (214) is connected to the inner wall of the adjustment knob (213), and the other end of the elastic element (214) is connected to the first pad (211) so that the tension of the wire to be wound can be adjusted by rotating the adjustment knob (213).

4. The winding device for wrapping wire according to claim 2, characterized in that, The adjustment component (20) further includes: A wire threader (22) is provided on the mounting rod (210). The wire threader (22) has through holes (220) at both ends. The free end of the wire to be wound passes through one of the through holes (220) and is wound between the first pad (211) and the second pad (212). It then passes out from the other through hole (220) and is wound on the winding shaft (31).

5. The winding device for wrapping wire according to claim 1, characterized in that, The detection component (40) includes: Two detection components (41) are disposed on the housing (10) relatively close to or far from each other, at least a portion of the winding shaft (31) is located between the two detection components (41), and the two detection components (41) are spaced apart by the set value, in order to detect the outer diameter of the wound coil.

6. The winding device for wrapping wire according to claim 5, characterized in that, The detection component (40) further includes: A slide rail (42) is provided on the housing (10), and the slide rail (42) is provided with scale lines along its extension direction; Two sliding members (43) are slidably disposed on the slide rail (42), and two detection components (41) are respectively disposed in the two sliding members (43). The detection ends of the two detection components (41) are arranged facing each other, so that the two detection components (41) can be driven by the two sliding members (43) to move relative to each other along the scale line to a distance from the set value.

7. The winding device for wrapping wire according to claim 1, characterized in that, The wrapping wire winding device further includes: A wire breaking assembly (50) is disposed on the housing (10) and located on the side close to the winding assembly (30). At least a portion of the wire breaking assembly (50) is movably disposed in the vertical and horizontal directions respectively, so as to cut the wire to be wound by at least a portion of the wire breaking assembly (50) when the outer diameter of the winding coil is greater than the set value.

8. The winding device for wrapping wire according to claim 7, characterized in that, The housing (10) is provided with a horizontally extending mounting groove, and the wire break assembly (50) includes: A movable component is disposed within the mounting groove and movably disposed along the extending direction of the mounting groove, and a first driving component is disposed on the movable component; The wire cutter is connected to the drive end of the first drive component so that the wire cutter can be driven by the first drive component to move in the vertical direction.

9. The winding device for wrapping wire according to claim 1, characterized in that, The set value a satisfies: 10mm ≤ a ≤ 36mm; and / or, The winding shaft (31) is provided with a winding wheel (32), and the winding wheel (32) is provided with a winding groove along its circumferential direction. The free end of the wire to be wound is disposed in the winding groove so that the wire to be wound is wound in the winding groove.

10. The winding device for wrapping wire according to claim 1, characterized in that, The winding assembly (30) further includes a second driving component (33), which is disposed within the housing (10). One end of the winding shaft (31) is connected to the driving end of the second driving component (33). The winding device further includes: A control component (60) is disposed within the housing (10). The control component (60) includes a relay module (61). The second drive component (33) and the detection component (40) are electrically connected to the relay module (61) respectively, so that when the detection component (40) detects that the outer diameter of the wrapped coil is greater than the set value, the relay module (61) controls the second drive component (33) to stop.

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