Intelligent hanging and transporting device for garment production

By using the suction and transmission devices of intelligent suspended transport equipment to automatically clean and cut the threads on the garments, the problem of low thread removal efficiency and garment deformation caused by hanging production lines is solved, thus achieving high-efficiency automation in garment production.

CN122144375APending Publication Date: 2026-06-05JIANGXI XINGBAIXIANG SPORTS GOODS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
JIANGXI XINGBAIXIANG SPORTS GOODS CO LTD
Filing Date
2026-03-02
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

In hanging production lines, the thread removal tooling has low efficiency in removing thread ends, and the removal of thread ends can cause garment deformation.

Method used

The intelligent suspended transport equipment, which includes a suction device and a transmission device, cleans, straightens and cuts the threads wrapped around the garment through a suction nozzle, a cutting component and a tufting component. It uses a small suction force to separate the threads from the garment, and then the cutting component cuts off any threads that are not properly cut to prevent the garment from deforming.

Benefits of technology

It improves the efficiency of thread removal, avoids garment rework and deformation, reduces labor and economic costs, and achieves high-efficiency automation in garment production.

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Abstract

The application provides a kind of intelligent suspension transport equipment for clothing production, and the intelligent suspension transport equipment for clothing production includes a line suction device and a transmission device.The line suction device includes a suction main body, a suction nozzle, a shearing assembly and a hair smoothing assembly arranged on the suction nozzle.The suction nozzle includes a housing, one side of which is in communication with a pipeline, and the other side has an opening at the bottom.The shearing assembly includes first and second shearing blades arranged in sequence and a first drive component connected to the second shearing blade.The first shearing blade is fixedly connected to the inner side of the housing on one side and placed at the opening on the other side.The first drive component is connected to the second shearing blade through a drive rod.The hair smoothing assembly includes a roller and a second drive component connected to the roller, and the roller is provided with uniformly distributed bristles.The transmission device includes a conveying track and a clothing suspension component.The application solves the problem of low efficiency of removing thread ends in the existing technology and the deformation of clothing caused by removing thread ends.
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Description

Technical Field

[0001] This invention relates to the field of garment production technology, and in particular to an intelligent suspended transport device for garment production. Background Technology

[0002] In garment production workshops, garments are typically hung on hangers, which are then transported via tracked conveyor systems. This ensures the garments move neatly and orderly to the next processing stage, thereby improving production efficiency. Compared to traditional bundled production lines, garment hanging production lines have significantly lower excess capacity. Employing a flexible hanging production management system eliminates the need for manual transfer of cut pieces or semi-finished products, thus reducing excess time on the production line. It also effectively avoids the need for traditional bundling and equipment movement, significantly minimizing downtime and production line chaos caused by incorrect garment layout and numbering, ultimately improving overall garment production efficiency.

[0003] Although hanging production lines reduce the contact between clothing and the ground, resulting in cleaner garments, the cutting and sewing processes typically involve sewing the fabric together with thread. After sewing, loose threads are often present, leading to both loose threads and surface debris. Current technologies usually only remove surface debris by blowing air through the garment, but they cannot handle loose threads, requiring them to be transported to a specific workstation or fitted with thread-removing fixtures on the production line.

[0004] However, in existing technologies, the cutting and adsorption of thread ends in thread removal fixtures are usually carried out in two steps. This can lead to situations where thread ends are not properly cut during the adsorption step, requiring rework and affecting production efficiency and thread adsorption efficiency. Furthermore, when adsorbing thread ends, they may become entangled with the garment, requiring a large adsorption force to remove them. However, a large adsorption force can cause garment deformation, thus affecting garment quality. Summary of the Invention

[0005] Based on this, the purpose of the present invention is to provide an intelligent suspended transport device for garment production, which aims to solve the problems of low efficiency in removing thread ends from the thread removal fixtures in the existing hanging production line and the deformation of garments caused by thread removal.

[0006] An intelligent hanging transport device for garment production according to an embodiment of the present invention includes a wire suction device and a transmission device; The suction device includes a suction body, a suction nozzle connected to the suction body via a pipe, a shearing component and a smoothing component disposed on the suction nozzle; The suction nozzle includes a housing, one side of which is connected to the pipe, and the bottom of the other side is provided with an opening, at which the shearing component and the smoothing component are disposed; The shearing assembly includes a first shearing blade, a second shearing blade stacked on top of the first shearing blade, and a first driving component connected to the second shearing blade. One side of the first shearing blade is placed inside the housing and fixedly connected to the housing, and the other side is placed at the opening. The first driving component is disposed above the housing and connected to the second shearing blade via a driving rod. The brushing assembly includes a roller and a second drive component connected to the roller, wherein the roller is provided with evenly distributed bristles; The conveying device includes a conveying track and a garment hanging component disposed on the conveying track, the garment hanging component being used to suspend garments on the conveying track for transport.

[0007] In addition, the intelligent suspended transport device for garment production according to the above embodiments of the present invention may also have the following additional technical features: Preferably, the transmission rod of the second driving component is provided with a first pulley, the roller is provided with a second pulley, the first pulley and the second pulley are connected by a belt, the roller is provided with a flat surface formed by inward recesses on both sides of one end of the second pulley, and the second pulley is provided with a groove adapted to the shape of the roller.

[0008] Preferably, the intelligent suspended transport equipment for garment production further includes a toggle assembly, which includes a first reciprocating screw connected to the transmission rod, a connecting rod connecting the first reciprocating screw and the roller, and a guide rod disposed on the housing. One end of the connecting rod is provided with a collar, and the inner side of the collar is adapted to the thread on the first reciprocating screw. The other end is provided with a horizontal plate, and both sides of the horizontal plate are provided with guide holes adapted to the guide rod.

[0009] Preferably, the nap-guiding assembly further includes an anti-tangle component, which includes a second reciprocating lead screw, a blade holder mounted on the second reciprocating lead screw, and a blade mounted on the blade holder. The inner side of the blade holder is adapted to the thread on the second reciprocating lead screw. Extension rods are provided at both ends of the second reciprocating lead screw, and the diameter of the extension rods is smaller than that of the second reciprocating lead screw. The roller is sleeved on the second reciprocating lead screw and the extension rods and is clearance-fitted with the second reciprocating lead screw and the extension rods. The blade holder is located between the roller and the second reciprocating lead screw. The roller is provided with a clearance groove so that the blade extends out of the clearance groove to the outside of the roller. One end of the extension rod is fixedly connected to the middle of the cross plate.

[0010] Preferably, the plurality of clearance grooves are equidistantly distributed around the axis of the roller, the bristles are distributed between two clearance grooves, the blade holder extends outward with a fixing part, the blade is disposed on the fixing part, and the fixing part is embedded in the clearance groove.

[0011] Preferably, the two horizontal plates are symmetrically arranged on both sides of the housing, and the plurality of guide rods are symmetrically distributed on both sides of the housing and are respectively adapted to the guide holes.

[0012] Preferably, the housing has a sliding rod on one side of the connecting rod, and the connecting rod has a sliding hole adapted to the sliding rod.

[0013] Preferably, the bottom of the housing on the side away from the opening is provided with ball bearings, and a plurality of ball bearings are equidistantly distributed on the housing.

[0014] Preferably, the suction body includes a filter component disposed within the housing and a suction component disposed within the housing, the top cavity of the housing being connected to the pipe, and the filter component being connected to the top cavity.

[0015] Preferably, a lever is provided on one side of the box, and the lever is slidably connected to the box to allow the inside of the box to communicate with the outside. A movable component is provided at the bottom of the box to allow the box to move freely.

[0016] This invention utilizes a garment hanging component and conveyor track within a transmission device to automatically hang and transport garments. A suction device on one side of the transmission device removes loose threads, dust, and loose threads from the garments. Specifically, a smoothing component cleans and straightens loose threads tangled in the garment, preventing them from becoming entangled. This allows for separation of the threads from the garment with relatively low suction force, avoiding deformation caused by excessive suction. A cutting component then cuts any loose threads, preventing rework. In practice, a second drive component rotates a roller, which in turn drives brush bristles to clean and straighten loose threads from the garment. This prevents threads from becoming tangled or adhering to the roller. Straightened threads on the garment can be removed with relatively low suction force, while threads adhering to the roller can be removed with increased suction force as they move away from the garment, thus preventing deformation caused by excessive suction. Furthermore, the suction force causes the straightened thread ends to stand upright towards the inside of the casing, facilitating staggered cutting by the first and second shearing blades. This ensures the thread ends are cut precisely from the root, preventing them from becoming tangled in the clothing and unable to be properly cut. Furthermore, tangled threads can lead to multiple threads being cut at the same point, affecting the cutting effect and potentially requiring repeated cutting, thus impacting thread removal efficiency. Therefore, this invention solves the problems of low thread removal efficiency and garment deformation caused by thread removal in existing hanging production lines. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the wire-absorbing device in one embodiment of the present invention; Figure 2 This is a cross-sectional schematic diagram of the wire-absorbing device in one embodiment of the present invention; Figure 3 This is a schematic diagram of the suction nozzle in one embodiment of the present invention; Figure 4 This is a partial assembly diagram of the suction nozzle, the smoothing component, and the agitator component in one embodiment of the present invention. Figure 5 This is a partial cross-sectional view of the suction nozzle and shearing assembly in one embodiment of the present invention. Figure 6 This is a partial cross-sectional view of the suction nozzle and the smoothing component after assembly in one embodiment of the present invention; Figure 7 This is a schematic diagram of the anti-winding component in one embodiment of the present invention; Figure 8 This is an exploded view of the anti-winding component in one embodiment of the present invention; Figure 9 This is a top view of the transmission device according to an embodiment of the present invention; Explanation of key component symbols: Detailed Implementation

[0018] To facilitate understanding of the present invention, a more complete description will be given below with reference to the accompanying drawings. Several embodiments of the invention are illustrated in the drawings. However, the invention can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

[0019] It should be noted that when a component is said to be "fixed to" another component, it can be directly on the other component or there may be an intervening component. When a component is said to be "connected to" another component, it can be directly connected to the other component or there may be an intervening component. The terms "vertical," "horizontal," "left," "right," and similar expressions used in this document are for illustrative purposes only.

[0020] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.

[0021] Please see Figures 1 to 9 The image shows an intelligent hanging transport device for garment production according to an embodiment of the present invention, which includes a wire suction device and a transmission device. The suction device includes a suction body 10, a suction nozzle 30 connected to the suction body 10 via a pipe 20, a shearing component 40 and a tufting component 50 disposed on the suction nozzle 30; The nozzle 30 includes a housing 31, one side of which is connected to the pipe 20, and the bottom of the other side is provided with an opening 32. The shearing component 40 and the smoothing component 50 are disposed at the opening 32. The shearing assembly 40 includes a first shearing blade 41, a second shearing blade 42 stacked on top of the first shearing blade 41, and a first driving component 43 connected to the second shearing blade 42. One side of the first shearing blade 41 is placed inside the housing 31 and fixedly connected to the housing 31, and the other side is placed at the opening 32. The first driving component 43 is disposed above the housing 31 and connected to the second shearing blade 42 through a driving rod 44. The brushing assembly 50 includes a roller 51 and a second drive component 52 connected to the roller 51. The roller 51 is provided with evenly distributed bristles 53. The conveying device includes a conveying track 70 and a garment hanging component 80 disposed on the conveying track 70. The garment hanging component 80 is used to suspend garments on the conveying track 70 for transport.

[0022] Understandably, the garment hanging component 80 and conveyor track 70 of the transmission device enable automatic hanging and transport of garments. A suction device on one side of the transmission device removes loose threads, dust, and loose threads from the garments. Specifically, the smoothing component 50 cleans and straightens loose threads tangled in the garment, preventing them from becoming entangled. A relatively small suction force is sufficient to separate the threads from the garment, avoiding deformation caused by excessive suction. The cutting component 40 then cuts any uncut threads, preventing rework. In practice, the second drive component 52 rotates the roller 51, causing the roller 51 to drive the bristles 53 to clean and straighten loose threads on the garment. This prevents threads from becoming tangled or adhering to the roller 51. Straightened threads on the garment can be removed with a small suction force, while threads adhering to the roller 51 can be removed with increased suction force after being moved away from the garment, thus avoiding deformation caused by excessive suction. Furthermore, the adsorption force causes the straightened thread ends to stand upright towards the inside of the housing 31, facilitating staggered cutting by the first and second shearing blades 41 and 42. This ensures the thread ends are cut precisely from the root, preventing them from becoming tangled in the clothing and unable to be properly cut. Furthermore, tangled threads can lead to multiple threads being cut at the same point, affecting the cutting effect and potentially requiring repeated cutting, thus impacting thread removal efficiency. Therefore, this invention solves the problems of low thread removal efficiency and garment deformation caused by thread removal in existing hanging production lines.

[0023] It should be noted that in practical implementation, intelligent and automatic cleaning of garments on the hanging production line can be achieved by using a robotic arm in conjunction with a thread-absorbing device. Alternatively, to reduce costs, avoid the expenses of program development and supporting design, and avoid the problem of dispatching workers for thread absorption and removal, the thread-absorbing device and the conveying device can be operated manually, thus avoiding the economic and labor costs incurred by requiring major modifications.

[0024] Specifically, the second drive component 52 has a first pulley 55 on its transmission rod 54 and a second pulley 56 on its roller 51. The first pulley 55 and the second pulley 56 are connected by a belt 57. One end of the roller 51 has the second pulley 56, and its two sides are recessed inward to form a flat surface. The second pulley 56 has a groove 561 that matches the shape of the roller 51. In a specific implementation, the second drive component 52, located above the housing 31, extends out of the transmission rod 54. The first pulley 55 on the transmission rod 54 and the second pulley 56 on the roller 51 cooperate to drive the roller 51 to rotate. In addition, the second pulley 56 and the roller 51 are connected by the groove 561. Due to the shape of the outer side of the roller 51, the second pulley 56 can drive the roller 51 to rotate, but it does not restrict the roller 51 from moving back and forth relative to the second pulley 56.

[0025] As an example, and not a limitation, in some optional embodiments, the intelligent suspended transport equipment for garment production further includes an actuating component 60. The actuating component 60 includes a first reciprocating screw 61 connected to a transmission rod 54, a connecting rod 62 connecting the first reciprocating screw 61 and the roller 51, and a guide rod 63 disposed on the housing 31. One end of the connecting rod 62 is provided with a collar 64, the inner side of which is adapted to the thread on the first reciprocating screw 61. The other end is provided with a horizontal plate 65, and both sides of the horizontal plate 65 are provided with guide holes 651 adapted to the guide rod 63. In specific implementations, by setting the actuating component 60, the roller 51 can rotate back and forth and move left and right while rotating, thereby increasing the effective range and area of ​​the brush bristles 53 on the roller 51, preventing thread ends from being missed in the seams. In addition, the left and right movement of the roller 51 while rotating ensures that the movement trajectory of the brush bristles 53 is not a single rotation, thus reducing the probability of thread ends getting tangled on the roller 51. Furthermore, the left and right swaying action makes it easier to straighten the thread ends from the tangled state, thereby improving the efficiency of thread removal. Specifically, the rotation of the second drive component 52 drives the first reciprocating screw 61 to rotate, which in turn causes the connecting rod 62 to move along the first reciprocating screw 61. The connecting rod 62 is guided by the guide rod 63, thereby driving the roller 51 to move back and forth along its own length. Since the second belt 57 is sleeved on the roller 51 and connected to the roller 51 through the groove 561, the specific shape of the roller 51 ensures that the movement of the roller 51 does not drive the second pulley 56 to move back and forth, thus ensuring that the second pulley 56 drives the roller 51 to rotate stably. In addition, the rotation and wobbling of the roller 51 are achieved by a single power source, which greatly reduces the cost, and the movement in both directions is consistent, ensuring the synergy of the movement effects.

[0026] Additionally, the straightening component 50 also includes an anti-winding component 58, which includes a second reciprocating screw 581, a blade holder 582 mounted on the second reciprocating screw 581, and a blade 583 mounted on the blade holder 582. The inner side of the blade holder 582 is adapted to the thread on the second reciprocating screw 581. Extension rods 584 are provided at both ends of the second reciprocating screw 581. The diameter of the extension rods 584 is smaller than that of the second reciprocating screw 581. A roller 51 is sleeved on the second reciprocating screw 581 and the extension rods 584 and is clearance-fitted with the second reciprocating screw 581 and the extension rods 584. The blade holder 582 is located between the roller 51 and the second reciprocating screw 581. The roller 51 is provided with a clearance groove 511 so that the blade 583 extends out of the clearance groove 511 to the outside of the roller 51. One end of the extension rod 584 is fixedly connected to the middle of the cross plate 65. In practical implementation, the roller 51 drives the blade holder 582 to rotate, thereby causing the blade holder 582 to move along the second reciprocating lead screw 581, which in turn drives the blade 583 to move along the clearance groove 511, thus cutting the thread ends wound on the roller 51. Furthermore, it should be noted that because the second reciprocating lead screw 581 and the extension rod 584 have a structure that is narrower at both ends and thicker in the middle, and the roller 51 is fitted onto the second reciprocating lead screw 581 and the extension rod 584, and the internal shape of the roller 51 conforms to the external shape of the second reciprocating lead screw 581 and the extension rod 584, the roller 51 can rotate relative to the second reciprocating lead screw 581. Moreover, under the action of the actuating component 60, when the roller 51 moves, it also drives the second reciprocating lead screw 581 to move synchronously through both ends. Therefore, by incorporating the anti-tangling component 58, the thread ends are prevented from tangling and accumulating on the roller 51. Instead, the blade 583 cuts the tangled thread ends into smaller segments, reducing the interaction force between the thread ends and the bristles 53, allowing the cut thread ends to be sucked away. This further improves the thread removal efficiency of the device, eliminating the need for periodic cleaning of the roller 51. It should be noted that, in practical implementation, a protrusion extends outward from the opening 32, ensuring a certain distance between the bristles 53 and the garment. This prevents the base area of ​​the bristles 53 from contacting the garment, and the blade 583 only moves within the base area of ​​the bristles 53, thus ensuring that the blade 583 does not damage the garment when cleaning the thread ends tangled on the bristles 53. Furthermore, to ensure the straightening effect of the bristles 53, the bristles 53 are typically stiff and densely distributed on the roller 51. This prevents decorative parts on the garment from being sucked into the opening 32 due to the resistance of the bristles 53, thus avoiding damage from the blade 583. Only when excessive thread ends accumulate will they reach the bottom of the bristles 53 and be cut by the blade 583.

[0027] Specifically, multiple clearance grooves 511 are equidistantly distributed circumferentially around the axis of the roller 51. Brush bristles 53 are distributed between two clearance grooves 511. The blade holder 582 extends outward with a fixing part 585, and the blade 583 is set on the fixing part 585. The fixing part 585 is embedded in the clearance groove 511. By setting multiple fixing parts 585 and setting blades 583 on each fixing part 585, the roller 51 can cut the thread ends wrapped and accumulated on the brush bristles 53 at multiple points, so as to avoid excessive accumulation of thread ends, which would require cleaning the roller 51 and thus affect the efficiency of removing thread ends from the garment.

[0028] Additionally, two horizontal plates 65 are symmetrically arranged on both sides of the housing 31, and multiple guide rods 63 are symmetrically distributed on both sides of the housing 31 and are respectively adapted to the guide holes 651. In specific implementation, the connecting rod 62 is guided by the two symmetrically arranged guide rods 63 to prevent the connecting rod 62 from rotating or deflecting when it moves, thereby affecting the stability of the left and right movement of the roller 51.

[0029] Specifically, the housing 31 has a connecting rod 62 and a sliding rod 66 on one side. The connecting rod 62 has a sliding hole 621 that matches the sliding rod 66. In a specific implementation, the connecting rod 62 also has a sliding hole 621 in the middle that matches the sliding rod 66 on the housing 31. The collars 64 and the cross plates 65 at both ends of the connecting rod 62 are used to connect with the first reciprocating lead screw 61 and the second reciprocating lead screw 581, respectively. Therefore, the stability of the movement of the connecting rod 62 is greatly affected by the external environment at both ends. Thus, it is necessary to set another sliding rod 66 in the connecting rod 62 to limit the overall movement of the connecting rod 62 through the middle of the connecting rod 62, so as to ensure the stable movement of the connecting rod 62.

[0030] Additionally, a ball bearing 33 is provided on the bottom side of the housing 31 away from the opening 32, with multiple ball bearings 33 evenly distributed on the housing 31. In practical implementation, by additionally providing ball bearings 33, the friction between the suction nozzle 30 and the garment during relative movement is reduced, making it more convenient and faster for the suction nozzle 30 to move on the garment to cut and remove thread ends.

[0031] Specifically, the suction unit 10 includes a housing 11, a filter component 12 disposed within the housing 11, and a suction component 13 disposed within the housing 11. The top cavity of the housing 11 is connected to the pipe 20, and the filter component 12 is connected to the top cavity. In practical implementation, the suction component 13 provides suction force so that the nozzle 30 can suck up and remove the loose threads from the clothing, and the sucked-up threads are collected in the filter component 12, usually accumulating in the filter screen of the filter component 12. Once a certain number of threads have accumulated in the filter screen, they are then cleaned uniformly.

[0032] Additionally, a lever 14 is provided on one side of the housing 11, which is slidably connected to the housing 11 to allow the inside of the housing 11 to communicate with the outside. A movable component 15 is provided at the bottom of the housing 11 to allow the housing 11 to move freely. In practical implementation, by providing the movable component 15, the automatic wire suction device can be moved or transported with the user, thereby increasing the applicable scenarios and application range of the automatic wire suction device. Furthermore, by providing the lever 14, the interior of the housing 11 can be easily connected to the outside, thereby facilitating the cleaning or replacement of the filter screen in the filter component 12.

[0033] In summary, this invention enables automatic hanging and transport of garments via the garment hanging component 80 and the conveying track 70 of the transmission device. A suction device located on one side of the transmission device removes loose threads, dust, and loose threads from the garments. Specifically, the smoothing component 50 cleans and straightens loose threads tangled in the garment, preventing them from becoming entangled. This allows for separation of the threads from the garment with relatively low suction force, avoiding deformation caused by excessive suction. The cutting component 40 then cuts any loose threads, preventing rework. In practical implementation, the second drive component 52 rotates the roller 51, causing the roller 51 to drive the bristles 53 to clean and straighten the loose threads on the garment. This prevents the threads from becoming tangled or adhering directly to the roller 51. This allows for the removal of straightened threads with relatively low suction force, while threads adhering to the roller 51 can be removed with increased suction force after being moved away from the garment, thus avoiding deformation caused by excessive suction. Furthermore, the adsorption force causes the straightened thread ends to stand upright towards the inside of the housing 31, facilitating staggered cutting by the first and second shearing blades 41 and 42. This ensures the thread ends are cut precisely from the root, preventing them from becoming tangled in the clothing and unable to be properly cut. Furthermore, tangled threads can lead to multiple threads being cut at the same point, affecting the cutting effect and potentially requiring repeated cutting, thus impacting thread removal efficiency. Therefore, this invention solves the problems of low thread removal efficiency and garment deformation caused by thread removal in existing hanging production lines.

[0034] In the description of this specification, references to terms such as "one embodiment," "some embodiments," "example," "specific example," or "some examples," 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 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.

[0035] The embodiments described above are merely illustrative of several implementations of the present invention, and while the descriptions are specific and detailed, they should not be construed as limiting the scope of the present invention. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of the present invention, and these modifications and improvements all fall within the scope of protection of the present invention. Therefore, the scope of protection of this patent should be determined by the appended claims.

Claims

1. An intelligent suspended transport device for garment production, characterized in that, Includes a wire-feeding device and a transmission device; The suction device includes a suction body, a suction nozzle connected to the suction body via a pipe, a shearing component and a smoothing component disposed on the suction nozzle; The suction nozzle includes a housing, one side of which is connected to the pipe, and the bottom of the other side is provided with an opening, at which the shearing component and the smoothing component are disposed; The shearing assembly includes a first shearing blade, a second shearing blade stacked on top of the first shearing blade, and a first driving component connected to the second shearing blade. One side of the first shearing blade is placed inside the housing and fixedly connected to the housing, and the other side is placed at the opening. The first driving component is disposed above the housing and connected to the second shearing blade via a driving rod. The brushing assembly includes a roller and a second drive component connected to the roller, wherein the roller is provided with evenly distributed bristles; The conveying device includes a conveying track and a garment hanging component disposed on the conveying track, the garment hanging component being used to suspend garments on the conveying track for transport.

2. The intelligent suspended transport equipment for garment production according to claim 1, characterized in that, The transmission rod of the second drive component is provided with a first pulley, and the roller is provided with a second pulley. The first pulley and the second pulley are connected by a belt. The roller has a flat surface formed by inward indentation on both sides of one end of the second pulley. The second pulley is provided with a groove that matches the shape of the roller.

3. The intelligent suspended transport equipment for garment production according to claim 2, characterized in that, The intelligent suspended transport equipment for garment production also includes a toggle assembly. The toggle assembly includes a first reciprocating screw connected to the transmission rod, a connecting rod connecting the first reciprocating screw and the roller, and a guide rod disposed on the housing. One end of the connecting rod is provided with a collar, and the inner side of the collar is adapted to the thread on the first reciprocating screw. The other end is provided with a horizontal plate, and both sides of the horizontal plate are provided with guide holes adapted to the guide rod.

4. The intelligent suspended transport equipment for garment production according to claim 3, characterized in that, The straightening assembly also includes an anti-winding component, which includes a second reciprocating lead screw, a blade holder mounted on the second reciprocating lead screw, and a blade mounted on the blade holder. The inner side of the blade holder is adapted to the thread on the second reciprocating lead screw. Extension rods are provided at both ends of the second reciprocating lead screw, and the diameter of the extension rods is smaller than that of the second reciprocating lead screw. A roller is sleeved on the second reciprocating lead screw and the extension rods and is clearance-fitted with the second reciprocating lead screw and the extension rods. The blade holder is located between the roller and the second reciprocating lead screw. The roller is provided with a clearance groove so that the blade extends out of the clearance groove to the outside of the roller. One end of the extension rod is fixedly connected to the middle of the cross plate.

5. The intelligent suspended transport equipment for garment production according to claim 4, characterized in that, Multiple clearance grooves are equidistantly distributed around the axis of the roller, the bristles are distributed between two clearance grooves, the blade holder extends outward with a fixing part, the blade is disposed on the fixing part, and the fixing part is embedded in the clearance groove.

6. The intelligent suspended transport equipment for garment production according to claim 4, characterized in that, The two horizontal plates are symmetrically arranged on both sides of the housing, and the multiple guide rods are symmetrically distributed on both sides of the housing and are respectively adapted to the guide holes.

7. The intelligent suspended transport equipment for garment production according to claim 4, characterized in that, The housing has a sliding rod on one side of the connecting rod, and the connecting rod has a sliding hole that matches the sliding rod.

8. The intelligent suspended transport equipment for garment production according to claim 1, characterized in that, The bottom of the housing on the side away from the opening is provided with ball bearings, and a plurality of ball bearings are equidistantly distributed on the housing.

9. The intelligent suspended transport equipment for garment production according to any one of claims 1 to 8, characterized in that, The suction body includes a filter component housed within the housing and a suction component housed within the housing. The top cavity of the housing is connected to the pipe, and the filter component is connected to the top cavity.

10. The intelligent suspended transport equipment for garment production according to claim 9, characterized in that, A lever is provided on one side of the box, and the lever is slidably connected to the box to allow the inside of the box to communicate with the outside. A movable part is provided at the bottom of the box to allow the box to move freely.