Textile device with flexible cooling function
By setting a filament folding and guiding mechanism in the spinning device, the running path of the filament is changed, which solves the problem of insufficient cooling efficiency under limited layer height, realizes flexible control and uniformity of the cooling process, and improves the quality stability of the spun products.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU PRIMERIKE IND EQUIP MFG CO LTD
- Filing Date
- 2025-09-08
- Publication Date
- 2026-07-14
AI Technical Summary
In factories with limited floor height, insufficient cooling distance in the spinning tunnels prevents the heat inside the filaments from dissipating fully, resulting in a large temperature difference between the filament surface and the core layer. This leads to asynchronous molecular chain segment orientation and crystallization process, causing quality defects such as fuzzy filaments and broken ends, which affects the production of high-end chemical fiber products.
By setting up a filament folding guide mechanism, the filament running path is changed from the traditional single vertical direction to a multi-segment folding path, which extends the cooling time. The cooling process can be flexibly controlled by adjusting the folding angle and path length, increasing the contact area between the filament and the air and promoting heat dissipation.
It significantly extends the cooling time of the filament bundle, improves cooling uniformity and efficiency, ensures that the filament bundle achieves optimal cooling effect before entering the oiling device, and enhances the quality stability of the final product.
Smart Images

Figure CN224494425U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of spinning equipment technology, specifically relating to a textile device with flexible cooling function. Background Technology
[0002] In the field of chemical fiber spinning, the production quality of the mother yarn (or precursor yarn) directly determines the performance of the subsequent finished yarn. The spinning tunnel, as the core area for yarn cooling and solidification, has a decisive influence on the cooling efficiency, crystallinity, and orientation of the yarn. Traditional spinning processes require the tunnel to have sufficient vertical height (usually 8-15 meters) to ensure that the yarn is fully cooled and shaped under a constant temperature gradient. However, the floor height of many existing factories is generally less than 6 meters, severely restricting tunnel design due to physical space constraints. New factories often compress floor heights to reduce construction costs. With limited floor height, insufficient yarn cooling distance leads to inadequate heat dissipation, excessive temperature difference between the yarn surface and core layer, and asynchronous molecular chain segment orientation and crystallization. Incompletely cooled yarn is prone to adhesion and structural loosening during the winding stage, causing quality defects such as fuzz and breakage. This results in significant deterioration of product evenness and fiber separation performance, severely restricting the production of high-end chemical fiber products.
[0003] Therefore, the above problems urgently need to be solved. Utility Model Content
[0004] Purpose of the utility model: To overcome the above shortcomings, this utility model provides a textile device with flexible cooling function. By setting a yarn bundle folding guide mechanism, the yarn bundle running path is changed from the traditional single vertical direction to a multi-segment folding path, significantly extending the cooling time. At the same time, the mechanism can adjust the folding angle and path length according to actual production needs, realizing flexible control of the cooling process.
[0005] Technical solution: To achieve the above objectives, this utility model provides a textile device with flexible cooling function, comprising, from top to bottom, the following components arranged sequentially:
[0006] Spinning assembly, connecting the spinning assembly to the extruder.
[0007] The air blowing device cools the filaments output from the spinning assembly.
[0008] The spinning tunnel receives the filament bundles that have been cooled by air blowing.
[0009] A filament folding guide mechanism is located below the outlet of the spinning tunnel.
[0010] Oiling device, used to apply oil to the filament bundle.
[0011] The drawing device is equipped with multiple sets of drawing rollers and draws the filament bundle.
[0012] A winding device winds a bundle of filaments into a cylinder.
[0013] The filament folding and guiding mechanism folds the filament bundle from a vertical downward path and guides it to the oiling device, extending the cooling time of the filament bundle from the spinning tunnel to the oiling device. This invention is used in the spinning industry. The spinning assembly connected to the extruder outputs a filament bundle. A blowing device cools the output filament bundle, which then enters the spinning tunnel for further cooling and solidification. Subsequently, the filament bundle folding and guiding mechanism changes its running path, changing the filament bundle from a vertical to an inclined or horizontal state, extending the cooling path and providing sufficient heat conduction time, making the temperature of the inner and outer layers of the filament bundle more uniform. During the folding and guiding process, the contact area between the filament bundle and the air increases, further promoting heat dissipation. After folding and guiding, the filament bundle enters the oiling device, which uniformly coats the surface of the filament bundle with oil to enhance its antistatic properties and cohesiveness. The oiled filament bundle then enters the drafting device, which continuously drafts the filament bundle using multiple sets of drafting rollers, adjusting the fiber orientation and improving the fiber mechanical properties. Finally, the winding device winds the drawn filament bundle into a cylinder for subsequent processing. The entire cooling path is flexibly adjustable, effectively solving the cooling efficiency problem under limited layer height, thus ensuring the production stability of high-quality chemical fibers. This invention, by setting a filament bundle folding guide mechanism, transforms the filament bundle running path from the traditional single vertical direction to a multi-segment folding path, significantly extending the cooling time. Simultaneously, this mechanism can adjust the folding angle and path length according to actual production needs, achieving flexible control of the cooling process.
[0014] Furthermore, in the aforementioned textile device with flexible cooling function, the filament folding and guiding mechanism includes an L-shaped base, which is formed by a horizontal crossbar and a vertical bar. A first guide roller is rotatably connected to the horizontal crossbar and is located below the outlet of the spinning channel. A lifting slide is connected to the vertical bar, and a second guide roller is driven to slide up and down along the vertical bar. The second guide roller is rotatably mounted on the lifting slide. The lifting slide allows for adjustment of the axial distance between the second and first guide rollers, and the two rollers cooperate to form a folding path. By adjusting the lifting slide, the distance between the second and first guide rollers can be flexibly changed, thereby adjusting the height of the folding path to adapt to different cooling requirements and filament characteristics. This structure extends the filament's travel path during the cooling process, improves cooling uniformity and efficiency, ensures optimal cooling before the filament enters the oiling device, and thus enhances the quality stability of the final product.
[0015] Furthermore, the aforementioned textile device with flexible cooling function includes a first motor base and a second motor base. The first motor base is fixed to the end of a horizontal crossbar and is equipped with a first drive motor, which is driven by the first guide roller. The second motor base is connected to a lifting slide, which drives the second motor base to slide up and down. The second motor base is connected to a second drive motor, which is driven by the second guide roller. The first and second drive motors independently control the rotational speeds of the first and second guide rollers. By independently adjusting the rotational speeds of the two drive motors, precise matching between the yarn tension and the running speed can be achieved, thereby avoiding fiber damage or uneven tension caused by speed differences. In addition, the surfaces of the first and second guide rollers are provided with uniformly distributed guide grooves to ensure that the yarn bundle does not shift or entangle during the guiding process.
[0016] Furthermore, in the aforementioned textile device with flexible cooling function, a first motor base is connected to a first filament splitter, which is located above the first guide roller. A second motor base is connected to a second filament splitter, which is located below the second guide roller. The first and second filament splitters are used to separate the filament bundles passing through the first and second guide rollers, respectively, to ensure that the filament bundles are evenly arranged and spaced, preventing the filament bundles from sticking together or tangling.
[0017] Furthermore, in the aforementioned textile device with flexible cooling function, the first yarn splitter includes a first connecting block connected to the top surface of the first motor base. The first connecting block is connected to a first support rod, which is parallel to the axis of the first guide roller. A second support rod is adjustablely connected to the first support rod via a first connecting column, and the first and second support rods are arranged in a cross configuration. The second support rod is connected to a first yarn splitter seat, which is connected to a first yarn splitting bar, which is arranged in an array along the axis of the first guide roller. A first yarn-blocking bar is connected to the top surface of the first yarn splitter seat, located on the side of the first yarn splitter seat away from the first support rod, and is parallel to the axis of the first guide roller.
[0018] Furthermore, in the aforementioned textile device with flexible cooling function, the second yarn splitter includes a second connecting block connected to the bottom surface of the second motor base. The second connecting block is connected to a third support rod, which is parallel to the axis of the second guide roller. A fourth support rod is adjustablely connected to the third support rod via a second connecting column. The third and fourth support rods are arranged in a cross configuration. The fourth support rod is connected to a second yarn splitting seat, which is connected to a second yarn splitting bar, which is arrayed along the axis of the second guide roller. A second yarn-blocking bar is connected to the bottom surface of the second yarn splitting seat, located on the side of the second yarn splitting seat away from the third support rod, and is parallel to the axis of the second guide roller. Both the first and second yarn splitting bars are made of high-temperature resistant ceramic material with smooth, burr-free surfaces to reduce frictional damage to the yarn bundles during the splitting process. Both the first and second yarn-blocking bars are coated with an anti-static coating to prevent the yarn bundles from agglomerating or shifting due to electrostatic adsorption. In addition, both the first and second fiber splitting seats are provided with multiple holes to adjust the fiber splitting spacing according to the diameter and quantity of the fiber bundle, thereby achieving efficient fiber splitting operation for fiber bundles of different specifications.
[0019] Furthermore, in the aforementioned textile apparatus with flexible cooling function, the drafting device includes a first drafting roller group, a second drafting roller group, a third drafting roller group, and a fourth drafting roller group arranged sequentially along the yarn bundle travel direction. The first and second drafting roller groups are located between the oiling device and the winding device. The second drafting roller group is located on the side of the first drafting roller group away from the oiling device, the third drafting roller group is located above the second drafting roller group, and the fourth drafting roller group is located above the third drafting roller group. After being oiled by the oiling device, the yarn bundle passes through the first, second, third, and fourth drafting roller groups and is then wound by the winding device. The first, second, third, and fourth drafting roller groups each include drafting rollers and tension rollers. The drafting rollers are independently driven by servo motors, with their speed increasing gradually along the yarn bundle's travel direction to establish a speed difference and stretch the yarn bundle step by step. The yarn bundle tension is detected by monitoring the displacement of the tension rollers. When the tension is abnormal, the corresponding drafting roller speed is automatically adjusted to prevent yarn breakage or insufficient drafting. Each drafting roller is equipped with an individually adjustable heating device, which uses resistance wire. The heating device heats the yarn bundle, reducing tensile stress and improving orientation uniformity.
[0020] Furthermore, in the aforementioned textile device with flexible cooling function, the lifting slide is configured as a rodless cylinder with a guide rod and magnetic coupling, arranged along a vertical rod.
[0021] A guide rod type magnetically coupled rodless cylinder is a pneumatic actuator that integrates a magnetically coupled rodless cylinder with a guide rod. Through the magnetic coupling between an internal magnetic ring and an external slider, it drives an external load to achieve long-distance linear reciprocating motion, effectively saving axial installation space and meeting the motion requirements of long-stroke automated equipment. High-precision magnetic induction or photoelectric position sensors are installed on the external slider or guide rod of the cylinder to monitor the actual position of the slider in real time and feed the data back to the control system. Combined with the controller, the cylinder's intake and exhaust pressures and flow rates are adjusted in real time to precisely control the piston's speed and position, achieving accurate positioning.
[0022] As can be seen from the above technical solution, this utility model has the following beneficial effects: The textile device with flexible cooling function, by setting a yarn bundle folding guide mechanism, transforms the yarn bundle running path from the traditional single vertical direction to a multi-segment folding path, significantly extending the cooling time. Simultaneously, this mechanism can adjust the folding angle and path length according to actual production needs, achieving flexible control of the cooling process. By adjusting the lifting slide, the distance between the second guide roller and the first guide roller can be flexibly changed, thereby adjusting the height of the folding path to adapt to different cooling requirements and yarn bundle characteristics. This structure extends the yarn bundle's travel path during the cooling process, improves cooling uniformity and efficiency, ensures the yarn bundle achieves optimal cooling before entering the oiling device, and thus enhances the quality stability of the final product. Attached Figure Description
[0023] Figure 1 This is a front view of the textile device with flexible cooling function according to this utility model;
[0024] Figure 2 This is a partial front view of the textile device with flexible cooling function according to this utility model;
[0025] Figure 3 This is a schematic diagram of the structure of the filament folding guide mechanism;
[0026] Figure 4 As shown Figure 3 A magnified view of a portion of the image;
[0027] Figure 5 As shown Figure 3 A magnified view of a portion of the image;
[0028] Figure 6 As shown Figure 2 A magnified view of a portion of the image;
[0029] Figure 7 This is a schematic diagram of the textile device with flexible cooling function of this utility model installed in a rectangle.
[0030] In the diagram: 1. Spinning assembly; 2. Blowing device; 3. Spinning duct; 4. Oiling device; 5. Drafting device; 51. First drafting roller group; 52. Second drafting roller group; 53. Third drafting roller group; 54. Fourth drafting roller group; 6. Winding device; 7. Tow folding guide mechanism; 71. Horizontal crossbar; 72. Vertical bar; 73. First guide roller; 74. Lifting slide; 75. Second guide roller; 76. First drive motor; 761. First motor base; 77. Second drive motor. 771. Second motor base; 78. First wire splitter; 781. First connecting block; 782. First support rod; 783. First connecting column; 784. Second support rod; 785. First wire splitter seat; 786. First wire splitter bar; 787. First wire stop bar; 79. Second wire splitter; 791. Second connecting block; 792. Third support rod; 793. Second connecting column; 794. Fourth support rod; 795. Second wire splitter seat; 796. Second wire splitter bar; 797. Second wire stop bar. Detailed Implementation Example
[0031] like Figure 1-2 The textile apparatus shown includes, from top to bottom, the following components arranged in sequence:
[0032] Spinning assembly 1 is connected to the extruder.
[0033] The air blowing device 2 cools the filament bundle output from the spinning assembly 1.
[0034] Spinning channel 3 receives the filament bundles cooled by air blowing.
[0035] The filament folding guide mechanism 7 is located below the outlet of the spinning channel 3.
[0036] Oiling device 4 applies oil to the filament bundle.
[0037] The drawing device 5 is equipped with multiple sets of drawing rollers and the drawing device 5 draws the filament bundle.
[0038] Winding device 6 winds the filament bundle into a cylinder.
[0039] The filament folding and guiding mechanism 7 folds the filament from a vertical downward path and guides it to the oiling device 4, extending the cooling time of the filament from the spinning channel 3 to the oiling device 4.
[0040] like Figure 3The textile apparatus shown has a flexible cooling function. The yarn bundle folding guide mechanism 7 includes an L-shaped base, which is formed by a horizontal crossbar 71 and a vertical bar 72. A first guide roller 73 is rotatably connected to the horizontal crossbar 71 and is located below the outlet of the spinning channel 3. A lifting slide 74 is connected to the vertical bar 72. A second guide roller 75 is driven to slide up and down along the vertical bar 72 via the lifting slide 74. The second guide roller 75 is rotatably mounted on the lifting slide 74. The lifting slide 74 allows the axial distance between the second guide roller 75 and the first guide roller 73 to be adjustable. The second guide roller 75 and the first guide roller 73 cooperate to form a folding path. By adjusting the lifting slide 74, the distance between the second guide roller 75 and the first guide roller 73 can be flexibly changed, thereby adjusting the height of the folding path to adapt to different cooling requirements and yarn bundle characteristics. This structure extends the travel path of the filament bundle during the cooling process, improves cooling uniformity and efficiency, ensures that the filament bundle achieves optimal cooling before entering the oiling device, and thus enhances the quality stability of the final product.
[0041] In this embodiment, a first motor base 761 and a second motor base 771 are included. The first motor base 761 is fixed to the end of a horizontal crossbar 71, and a first drive motor 76 is mounted on the first motor base 761. The first drive motor 76 and the first guide roller 73 are driven together. The second motor base 771 is connected to a lifting slide 74, which drives the second motor base 771 to slide up and down. The second motor base 771 is connected to a second drive motor 77, which is driven together with the second guide roller 75. The first drive motor 76 and the second drive motor 77 independently control the rotational speed of the first guide roller 73 and the second guide roller 75. By independently adjusting the rotational speed of the two drive motors, precise matching between the yarn tension and the running speed can be achieved, thereby avoiding fiber damage or uneven tension caused by speed differences. The yarn tension is calculated by detecting the current of the drive motors. The surfaces of the first guide roller 73 and the second guide roller 75 are provided with uniformly distributed guide grooves to ensure that the yarn does not shift or entangle during the guiding process.
[0042] like Figure 3 The textile apparatus shown has a flexible cooling function. A first motor mount 761 is connected to a first yarn splitter 78, which is located above the first guide roller 73. A second motor mount 771 is connected to a second yarn splitter 79, which is located below the second guide roller 75. The first yarn splitter 78 and the second yarn splitter 79 are used to separate the yarn bundles passing through the first guide roller 73 and the second guide roller 75, respectively, to ensure that the yarn bundles are evenly arranged and spaced, preventing the yarn bundles from sticking together or tangling.
[0043] like Figure 4The textile apparatus shown has a flexible cooling function. The first yarn splitter 78 includes a first connecting block 781 connected to the top surface of a first motor base 761. A first support rod 782 is connected to the first connecting block 781 and is arranged parallel to the axis of the first guide roller 73. A second support rod 784 is adjustablely connected to the first support rod 782 via a first connecting column 783. The first and second support rods 782 and 784 are arranged in a cross shape. A first yarn splitter seat 785 is connected to the second support rod 784, and a first yarn splitter bar 786 is connected to the first yarn splitter seat 785. The first yarn splitter bars 786 are arranged in an array along the axis of the first guide roller 73. A first yarn stop bar 787 is connected to the top surface of the first yarn splitter seat 785 and is located on the side of the first yarn splitter seat 785 away from the first support rod 782. The first yarn stop bar 787 is arranged parallel to the axis of the first guide roller 73.
[0044] like Figure 5 The textile apparatus shown has a flexible cooling function. The second yarn splitter 79 includes a second connecting block 791 connected to the bottom surface of the second motor base 771. A third support rod 792 is connected to the second connecting block 791, and the third support rod 792 is arranged parallel to the axis of the second guide roller 75. A fourth support rod 794 is adjustablely connected to the third support rod 792 via a second connecting column 793. The third support rod 792 and the fourth support rod 794 are arranged in a cross shape. The fourth support rod 794 is connected to a second yarn splitter seat 795, and the second yarn splitter seat 795 is connected to a second yarn splitter bar 796, which is arranged in an array along the axis of the second guide roller 75. A second yarn stop bar 797 is connected to the bottom surface of the second yarn splitter seat 795, and the second yarn stop bar 797 is located on the side of the second yarn splitter seat 795 away from the third support rod 792, and is arranged parallel to the axis of the second guide roller 75. Both the first dividing rod 786 and the second dividing rod 796 are made of high-temperature resistant ceramic material. Both the first stop rod 787 and the second stop rod 797 are equipped with an antistatic coating.
[0045] like Figure 6The textile apparatus shown has a flexible cooling function. The drafting device 5 includes a first drafting roller group 51, a second drafting roller group 52, a third drafting roller group 53, and a fourth drafting roller group 54 arranged sequentially along the yarn travel direction. The first drafting roller group 51 and the second drafting roller group 52 are located between the oiling device 4 and the winding device 6. The second drafting roller group 52 is located on the side of the first drafting roller group 51 away from the oiling device 4. The third drafting roller group 53 is located above the second drafting roller group 52, and the fourth drafting roller group 54 is located above the third drafting roller group 53. After being oiled by the oiling device 4, the yarn is wound by the winding device 6 after passing through the first drafting roller group 51, the second drafting roller group 52, the third drafting roller group 53, and the fourth drafting roller group 54. The first drafting roller group 51, the second drafting roller group 52, the third drafting roller group 53, and the fourth drafting roller group 54 each include drafting rollers and tension rollers. The drafting rollers are independently driven by servo motors, and their speed increases progressively along the yarn bundle's travel direction, gradually establishing a speed difference to stretch the yarn bundle step by step. The tension rollers are floating rollers equipped with displacement sensors that detect the displacement of the tension rollers, thus detecting the yarn bundle tension value. When the tension is abnormal, the corresponding drafting roller speed is automatically adjusted to prevent yarn breakage or insufficient drafting. The drafting rollers are equipped with individually adjustable heating devices to heat the yarn bundle, reducing tensile stress and improving orientation uniformity.
[0046] The lifting slide 74 is a rodless cylinder with a guide rod and magnetic coupling, installed along the vertical rod 72. The spinning assembly 1, blowing device 2, spinning channel 3, oiling device 4, winding device 6, and other components used for spinning yarn in the textile device described in this embodiment are conventionally configured, and those skilled in the art can configure them according to production needs.
[0047] The production steps of this utility model include: a spinning assembly 1 connected to an extruder outputs a filament bundle; a blowing device 2 cools the output filament bundle; the cooled filament bundle enters a spinning channel 3 for further cooling and solidification; subsequently, a filament bundle folding and guiding mechanism 7 changes the running path, causing the filament bundle to change from a vertical state to an inclined or horizontal state, thus extending the cooling path. The working steps of the filament bundle folding and guiding mechanism 7 include: a lifting slide 74 driving a second motor base 771 to rise, increasing the distance between the first guide roller 73 and the second guide roller 75, and extending the filament bundle running path; the lifting slide 74 driving the second motor base 771 to fall, decreasing the distance between the first guide roller 73 and the second guide roller 75, and extending the filament bundle running path. When the lifting slide 74 is at its lowest point, the distance between the first guide roller 73 and the second guide roller 75 is at its minimum. During the filament folding process, the first drive motor 76 operates at a constant speed according to the process settings, while the second drive motor 77 starts at a slightly lower speed than the first drive motor 76. As the filament is continuously fed in by the first drive motor, while the speed of the second drive motor 77 remains temporarily unchanged, the filament gradually accumulates a length difference between the two rollers, resulting in elastic elongation. The tension of the filament between the two rollers increases, and the load torque of the second drive motor 77 increases. To maintain the speed of the second drive motor 77, the current of the second drive motor 77 increases. The current of the second drive motor 77 is detected. If the current is higher than a set threshold, the tension is too high, and the speed of the second drive motor 77 is reduced to decrease the length difference between the first guide roller 73 and the second guide roller 75, thus reducing the tension. Conversely, if the current is too low, the speed of the second drive motor 77 is increased to increase the tension, keeping the filament tension within the process range.
[0048] The above embodiments are exemplary and are intended to illustrate the technical concept and features of this utility model, so that those skilled in the art can understand the content of this utility model and implement it accordingly. They should not be construed as limiting the scope of protection of this utility model. All equivalent changes or modifications made in accordance with the spirit and essence of this utility model should be covered within the scope of protection of this utility model.
Claims
1. A textile device with flexible cooling function, characterized in that: Including the settings from top to bottom: Spinning assembly (1), which is connected to an extruder; A blower (2) is used to cool the filament bundle output from the spinning assembly (1); Spinning tunnel (3), which receives filament bundles cooled by blowing air; A filament folding guide mechanism (7) is provided on the lower side of the outlet of the spinning channel (3); Oiling device (4), which applies oil to the filament bundle; The drawing device (5) is provided with multiple sets of drawing rollers and the drawing device (5) draws the filament bundle; The winding device (6) winds the filament bundle into a cylinder; The filament folding and guiding mechanism (7) folds the filament from a vertical downward path and guides it to the oiling device (4), extending the cooling time of the filament from the spinning channel (3) to the oiling device (4).
2. The textile apparatus with flexible cooling function according to claim 1, characterized in that: The filament folding guide mechanism (7) includes an L-shaped base, which is formed by a horizontal crossbar (71) and a vertical bar (72); the horizontal crossbar (71) is rotatably connected to a first guide roller (73), which is located below the outlet of the spinning channel (3); the vertical bar (72) is connected to a lifting slide (74), which drives a second guide roller (75) to slide up and down along the vertical bar (72); the second guide roller (75) is rotatably mounted on the lifting slide (74); the lifting slide (74) makes the axial distance between the second guide roller (75) and the first guide roller (73) adjustable, and the second guide roller (75) and the first guide roller (73) cooperate to form a folding path.
3. The textile apparatus with flexible cooling function according to claim 2, characterized in that: It includes a first motor base (761) and a second motor base (771); the first motor base (761) is fixed to the end of a horizontal bar (71), and a first drive motor (76) is installed on the first motor base (761), and the first drive motor (76) and the first guide roller (73) are driven to connect; the second motor base (771) is connected to a lifting slide (74), and the lifting slide (74) drives the second motor base (771) to slide up and down, and a second drive motor (77) is connected to the second motor base (771), and the second drive motor (77) and the second guide roller (75) are driven to connect; the first drive motor (76) and the second drive motor (77) independently control the rotation speed of the first guide roller (73) and the second guide roller (75).
4. The textile apparatus with flexible cooling function according to claim 3, characterized in that: The first motor base (761) is connected to a first wire splitter (78), which is located on the upper side of the first wire guide roller (73); the second motor base (771) is connected to a second wire splitter (79), which is located on the lower side of the second wire guide roller (75).
5. The textile apparatus with flexible cooling function according to claim 4, characterized in that: The first wire splitter (78) includes a first connecting block (781), which is connected to the top surface of the first motor base (761). The first connecting block (781) is connected to a first support rod (782), which is parallel to the axis of the first guide roller (73). The first support rod (782) is adjustablely connected to a second support rod (784) via a first connecting post (783). The first support rod (782) and the second support rod (784) are arranged in a cross shape. The second support rod (784) is connected to the first wire splitting seat (785), the first wire splitting seat (785) is connected to the first wire splitting rod (786), the first wire splitting rod (786) is arranged in an array along the axis of the first guide roller (73); the top surface of the first wire splitting seat (785) is connected to the first wire blocking rod (787), the first wire blocking rod (787) is located on the side of the first wire splitting seat (785) away from the first support rod (782), and the first wire blocking rod (787) is arranged parallel to the axis of the first guide roller (73).
6. The textile apparatus with flexible cooling function according to claim 4, characterized in that: The second wire splitter (79) includes a second connecting block (791), which is connected to the bottom surface of the second motor base (771). The second connecting block (791) is connected to a third support rod (792), which is parallel to the axis of the second guide roller (75). The third support rod (792) is adjustablely connected to a fourth support rod (794) via a second connecting column (793). The third support rod (792) and the fourth support rod (794) are arranged in a cross shape. The fourth support rod (794) is connected to the second wire splitting seat (795), the second wire splitting seat (795) is connected to the second wire splitting rod (796), the second wire splitting rod (796) is arranged in an array along the axis of the second guide roller (75); the bottom surface of the second wire splitting seat (795) is connected to the second wire blocking rod (797), the second wire blocking rod (797) is located on the side of the second wire splitting seat (795) away from the third support rod (792), and the second wire blocking rod (797) is arranged parallel to the axis of the second guide roller (75).
7. The textile apparatus with flexible cooling function according to claim 1, characterized in that: The drawing device (5) includes a first drawing roller group (51), a second drawing roller group (52), a third drawing roller group (53), and a fourth drawing roller group (54) arranged sequentially along the direction of the yarn bundle travel. The first drawing roller group (51) and the second drawing roller group (52) are located between the oiling device (4) and the winding device (6). The second drawing roller group (52) is located on the side of the first drawing roller group (51) away from the oiling device (4). The third drawing roller group (53) is located on the upper side of the second drawing roller group (52). The fourth drawing roller group (54) is located on the upper side of the third drawing roller group (53). After being oiled by the oiling device (4), the yarn bundle is wound by the winding device (6) after passing through the first drawing roller group (51), the second drawing roller group (52), the third drawing roller group (53), and the fourth drawing roller group (54).
8. The textile apparatus with flexible cooling function according to claim 2, characterized in that: The lifting slide (74) is configured as a rodless magnetically coupled cylinder with a guide rod arranged along the vertical rod (72).