Cutting equipment for textile and clothing processing based on artificial intelligence
1. The utility model provides a cutting equipment for textile tailoring based on artificial intelligence which characterized in that includes: the cutting machine comprises a fixed box (1), a cutting table plate (2), a cutting assembly (3), a sliding seat (4), a leveling assembly (5), a supporting column (6) and a driving assembly (7).
2. The cutting equipment for textile garment processing based on artificial intelligence is characterized in that the cutting platen (2) is fixedly installed at the top of the fixed box (1), the number of the sliding seats (4) is two, the two sliding seats (4) are respectively and fixedly installed at two sides of the cutting platen (2), the cutting assembly (3) is slidably connected to the top of the cutting platen (2), the leveling assembly (5) is located at one side of the cutting assembly (3), the number of the driving assemblies (7) is two, the two driving assemblies (7) are respectively and fixedly installed at two sides of the leveling assembly (5), and supporting columns (6) are welded at four corners of the bottom of the fixed box (1); the cutting bedplate (2) comprises a plate body (21), the plate body (21) is fixedly arranged at the top of the fixed box (1), a cutting groove (22) is formed in the top of the plate body (21), and partition plates (23) are welded on two sides of the cutting groove (22); the sliding seat (4) comprises two fixed long columns (41), the two fixed long columns (41) are welded to two sides of the plate body (21) respectively, the two fixed long columns (41) are symmetrically arranged, a rack (42) is welded on one side, away from the plate body (21), of each fixed long column (41), and a movable groove (43) is formed in the top of each fixed long column (41); leveling component (5) is including fixed roof (51), fixed roof (51) are located the top of plate body (21), the both sides of fixed roof (51) bottom all weld and have removed post (54), two remove post (54) and be the symmetry setting, the bottom welding of removing post (54) has link plate (55), the bottom welding of link plate (55) has two sets of gyro wheel fixed blocks (519), every group the quantity of gyro wheel fixed block (519) is two, and the center department of every group gyro wheel fixed block (519) has all run through gyro wheel axle (518), the surperficial rotation of gyro wheel axle (518) is connected with gyro wheel (517), gyro wheel (517) are located the center department of two gyro wheel fixed blocks (519), the center department fixed mounting of fixed roof (51) bottom has cylinder (56), the extension end welding of cylinder (56) has moving plate (52), the movable box (53) is welded on two sides of the bottom of the movable plate (52), the movable boxes (53) are symmetrically arranged, a movable cavity (516) is formed in the movable box (53), a second movable plate (515) is connected to the bottom of the inner cavity of the movable cavity (516) in a sliding mode, a spring (514) is welded on the top of the second movable plate (515), a first movable plate (513) is welded at one end, away from the second movable plate (515), of the spring (514), a supporting plate (510) is welded at the bottom of the second movable plate (515), the movable box (53) is penetrated through the bottom of the supporting plate (510), a first through hole for the supporting plate (510) to penetrate through is formed in the bottom of the movable box (53), the two supporting plates (510) are symmetrically arranged, and a fixed shaft (511) is welded on the inner side, opposite to the two supporting plates (510), the surface of the fixed shaft (511) is rotationally connected with a leveling roller (57); the driving assembly (7) comprises motor boxes (71), the motor boxes (71) are welded at two ends of a fixed top plate (51), the two motor boxes (71) are symmetrically arranged, a motor (74) is fixedly installed in an inner cavity of each motor box (71), a rotating shaft (72) is welded at the output end of each motor (74), a second through hole for the rotating shaft (72) to penetrate through is formed in the bottom of each motor box (71), the second through hole is penetrated through the bottom end of each rotating shaft (72), a gear (73) is welded at the bottom end of each rotating shaft (72), the gear (73) is located on one side of a rack (42), and the gear (73) is meshed with the fixed long column (41); limiting columns (59) are welded to the two sides of the top of the moving plate (52), and sleeves (58) are welded to the two sides of the bottom of the fixed top plate (51).
3. The cutting equipment for textile garment processing based on artificial intelligence is characterized in that a through groove is formed in the bottom of the sleeve (58), the diameter of the through groove is larger than that of the limiting column (59), and the top of the limiting column (59) is connected with the through groove in an inserted mode.
4. The cutting equipment for textile garment processing based on artificial intelligence is characterized in that rubber pads are bonded to the bottoms of the supporting columns (6), and the diameters of the rubber pads are larger than those of the supporting columns (6).
5. The cutting equipment for textile garment processing based on artificial intelligence is characterized in that limiting sliding grooves (44) are formed in inner walls of two sides of the moving groove (43), the width of each limiting sliding groove (44) is larger than the diameter of the roller shaft (518), two ends of each roller shaft (518) extend to inner cavities of the two limiting sliding grooves (44), and the roller shafts (518) are in sliding connection with the limiting sliding grooves (44).
6. The cutting equipment for textile garment processing based on artificial intelligence is characterized by further comprising an artificial intelligence module (8) and a camera (9), wherein the artificial intelligence module (8) is fixedly installed on the rear side of the fixed box (1), and the camera (9) is fixedly installed in the center of the rear side of the fixed top plate (51).
7. The cutting equipment for textile garment processing based on artificial intelligence of claim 6, wherein the electrical output end of the camera (9) is electrically connected with the electrical input end of the artificial intelligence module (8).
8. The cutting equipment for textile garment processing based on artificial intelligence as claimed in claim 2, characterized in that a pressure sensor (512) is fixedly installed on the top inside the movable cavity (516), and the bottom of the pressure sensor (512) is in contact with the top of the first movable plate (513).
9. The cutting apparatus for textile garment processing based on artificial intelligence according to claim 8, wherein the electrical output of the pressure sensor (512) is electrically connected to the electrical input of the artificial intelligence module (8).
10. The cutting apparatus for textile garment processing based on artificial intelligence of claim 6, wherein an electrical input of the motor (74) is electrically connected with an electrical output of the artificial intelligence module (8), and an electrical input of the air cylinder (56) is electrically connected with an electrical output of the artificial intelligence module (8).
Background
The textile origin is a general name taken from spinning and weaving, but with the continuous development and perfection of a textile knowledge system and a subject system, particularly after non-woven textile materials and three-dimensional compound weaving and other technologies are produced, the textile is not only produced by traditional hand spinning and weaving, but also produced by non-woven fabric technology, modern three-dimensional weaving technology, modern electrostatic nano-web forming technology and the like, and is used for clothing, industry and decoration. Modern spinning therefore refers to a technique for the multi-scale structural processing of fibers or fiber assemblies. Textile, i.e. a product made by textile processing. Including yarns, wovens, knits, braids, and the like. It is divided into woven fabric and knitted fabric.
In weaving clothing course of working, need use cutting equipment, cut the cloth, however traditional cutting equipment is in the use, and the cloth of laying at the cutting mesa usually uses the manual work to carry out the flattening, and artifical flattening is wasted time and energy, greatly reduced the convenience when flattening.
Therefore, the cutting equipment for processing the textile clothing based on the artificial intelligence is provided.
Disclosure of Invention
The technical task of the invention is to solve the above defects, and provide a cutting device for processing textile and clothing based on artificial intelligence, wherein a leveling component is additionally arranged, a cylinder at the bottom of the leveling component extends to enable a leveling roller to compress a laid cloth, and then the leveling component can be driven to move back and forth by starting a motor, so that the leveling roller rolls back and forth on the cloth, the purpose of leveling can be achieved, the problems of time and labor waste caused by artificial leveling are avoided, the convenience in leveling is improved, and the problems are solved.
The technical scheme of the invention is realized as follows:
the invention provides a cutting device for textile garment processing based on artificial intelligence, which comprises: the cutting table plate is fixedly arranged at the top of the fixed box, the number of the sliding seats is two, the two sliding seats are fixedly arranged on two sides of the cutting table plate respectively, the cutting assembly is connected to the top of the cutting table plate in a sliding mode, the leveling assembly is located on one side of the cutting assembly, the number of the driving assemblies is two, the two driving assemblies are fixedly arranged on two sides of the leveling assembly respectively, and the supporting columns are welded at four corners of the bottom of the fixed box;
the cutting table plate comprises a plate body, the plate body is fixedly arranged at the top of the fixed box, a cutting groove is formed in the top of the plate body, and partition plates are welded on two sides of the cutting groove;
the sliding seat comprises two fixed long columns which are welded on two sides of the plate body respectively, the two fixed long columns are symmetrically arranged, racks are welded on one sides of the fixed long columns, which are far away from the plate body, and the top of each fixed long column is provided with a movable slot;
the leveling component comprises a fixed top plate, the fixed top plate is positioned above a plate body, two moving columns are welded on two sides of the bottom of the fixed top plate, the two moving columns are symmetrically arranged, a connecting plate is welded on the bottom of the moving columns, two groups of roller fixing blocks are welded on the bottom of the connecting plate, the number of the roller fixing blocks in each group is two, a roller shaft penetrates through the center of each group of roller fixing blocks, the surface of the roller shaft is rotatably connected with a roller, the roller is positioned at the center of the two roller fixing blocks, a cylinder is fixedly arranged at the center of the bottom of the fixed top plate, a moving plate is welded at the extending end of the cylinder, movable boxes are welded on two sides of the bottom of the moving plate, the two movable boxes are symmetrically arranged, a movable cavity is formed in each movable box, and a second movable plate is slidably connected to the bottom of the inner cavity of the movable cavity, a spring is welded at the top of the second movable plate, a first movable plate is welded at one end, away from the second movable plate, of the spring, the first movable plate is connected with the inner wall of the movable cavity in a sliding mode, supporting plates are welded at the bottom of the second movable plate, the bottom end of each supporting plate penetrates through the movable box, a first through hole for the supporting plates to penetrate through is formed in the bottom of the movable box, the two supporting plates are symmetrically arranged, fixed shafts are welded on the opposite inner sides of the two supporting plates, and leveling rollers are rotatably connected to the surfaces of the fixed shafts;
the drive assembly includes the motor case, the motor case welds in the both ends of fixed roof, two the motor case is the symmetry setting, the inner chamber fixed mounting of motor case has the motor, the output welding of motor has the axis of rotation, the second through-hole that supplies the axis of rotation to pass is seted up to the bottom of motor case, the second through-hole is run through to the bottom of axis of rotation, the bottom welding of axis of rotation has the gear, the gear is located one side of rack, the gear meshes with fixed long post mutually.
Preferably, limiting columns are welded to two sides of the top of the moving plate, and sleeves are welded to two sides of the bottom of the fixed top plate.
Preferably, the bottom of the sleeve is provided with a through groove, the diameter of the through groove is larger than that of the limiting column, and the top of the limiting column is spliced with the through groove.
Preferably, rubber pads are bonded to the bottoms of the supporting columns, and the diameters of the rubber pads are larger than those of the supporting columns.
Preferably, the inner walls of the two sides of the moving slot are provided with limiting sliding grooves, the width of each limiting sliding groove is larger than the diameter of the roller shaft, the two ends of the roller shaft respectively extend to the inner cavities of the two limiting sliding grooves, and the roller shaft is connected with the limiting sliding grooves in a sliding mode.
Preferably, the intelligent cabinet further comprises an artificial intelligence module and a camera, wherein the artificial intelligence module is fixedly installed at the rear side of the fixed box, and the camera is fixedly installed at the center of the rear side of the fixed top plate.
Preferably, the electrical output end of the camera is electrically connected with the electrical input end of the artificial intelligence module.
Preferably, a pressure sensor is fixedly mounted at the top inside the movable cavity, and the bottom of the pressure sensor is in contact with the top of the first movable plate.
Preferably, the electrical output end of the pressure sensor is electrically connected with the electrical input end of the artificial intelligence module.
Preferably, the electrical input end of the motor is electrically connected with the electrical output end of the artificial intelligence module, and the electrical input end of the air cylinder is electrically connected with the electrical output end of the artificial intelligence module.
Compared with the prior art, the invention has the advantages and positive effects that:
1. according to the invention, the leveling component is additionally arranged, the cylinder at the bottom of the leveling component extends to enable the leveling roller to compress the laid cloth, and the leveling component can be driven to move back and forth by starting the motor, so that the leveling roller rolls back and forth on the cloth, and the purpose of leveling can be achieved, the problems of time and labor waste caused by manual leveling are avoided, and the convenience in leveling is further improved;
2. the movable column can be supported by arranging the connecting plate, the roller shaft and the roller fixing block, and the roller rolls in the inner cavity of the movable groove, so that the smoothness of the leveling assembly during movement can be greatly improved, and the phenomenon that the leveling assembly is blocked during movement is avoided;
3. according to the invention, the camera is used for collecting the video signal at the top of the cutting groove, and the artificial intelligence module is used for analyzing and processing the video signal, so that the shape, size and position of the clothing cloth paved at the top of the cutting groove are identified, the working range of the leveling roller is controlled in a targeted manner, the leveling efficiency is improved, and the leveling component is prevented from working in the empty place for paving the clothing cloth.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.
FIG. 1 is a schematic structural diagram of an artificial intelligence based cutting apparatus for textile garment processing according to an embodiment of the present invention;
FIG. 2 is a schematic bottom view of an artificial intelligence based cutting apparatus for textile garment processing according to an embodiment of the present invention;
FIG. 3 is a schematic left-side view of a cutting apparatus for textile garment processing based on artificial intelligence according to an embodiment of the present invention;
FIG. 4 is a schematic diagram of a rear view structure of a cutting device for textile garment processing based on artificial intelligence according to an embodiment of the invention;
FIG. 5 is a schematic view of a mating structure of a sliding seat and a leveling assembly according to an embodiment of the present invention;
FIG. 6 is an enlarged view of a portion of A of FIG. 5 in accordance with the present invention;
FIG. 7 is a schematic diagram of a structure of a flattening assembly according to an embodiment of the present invention;
FIG. 8 is a schematic view of a structure of a roller engaged with a supporting plate according to an embodiment of the present invention;
FIG. 9 is a schematic cross-sectional view of a portable housing according to an embodiment of the present invention;
FIG. 10 is a schematic cross-sectional view of a drive assembly according to an embodiment of the invention;
FIG. 11 is a schematic cross-sectional view of a sliding seat according to an embodiment of the present invention;
FIG. 12 is an enlarged view of a portion of FIG. 11B in accordance with the present invention;
fig. 13 is a schematic diagram of a system according to embodiment 4 of the present invention.
In the figure: 1. a fixed box; 2. cutting the bedplate; 3. a cutting assembly; 4. a sliding seat; 5. a leveling assembly; 6. a support pillar; 7. a drive assembly; 8. an artificial intelligence module; 9. a camera; 21. a plate body; 22. cutting the groove; 23. a partition plate; 41. fixing the long column; 42. a rack; 43. moving and slotting; 44. a limiting chute; 51. fixing a top plate; 52. moving the plate; 53. a movable box; 54. moving the column; 55. connecting plates; 56. a cylinder; 57. a leveling roller; 58. a sleeve; 59. a limiting column; 510. a support plate; 511. a fixed shaft; 512. a pressure sensor; 513. a first movable plate; 514. a spring; 515. a second movable plate; 516. a movable cavity; 517. a roller; 518. a roller shaft; 519. a roller fixing block; 71. a motor case; 72. a rotating shaft; 73. a gear; 74. an electric motor.
Detailed Description
In order that the above objects, features and advantages of the present invention can be more clearly understood, the present invention will be further described with reference to the accompanying drawings and examples. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.
The invention is further described with reference to the following figures and specific examples.
Example 1
As shown in fig. 1 to 12, according to the cutting device for processing textile garments based on artificial intelligence, according to an embodiment of the present invention, a fixed box 1, a cutting platen 2, a cutting assembly 3, sliding seats 4, a leveling assembly 5, supporting columns 6 and driving assemblies 7 are provided, the cutting platen 2 is fixedly installed on the top of the fixed box 1, the number of the sliding seats 4 is two, the two sliding seats 4 are respectively and fixedly installed on two sides of the cutting platen 2, the cutting assembly 3 is slidably connected to the top of the cutting platen 2, the leveling assembly 5 is located on one side of the cutting assembly 3, the number of the driving assemblies 7 is two, the two driving assemblies 7 are respectively and fixedly installed on two sides of the leveling assembly 5, and the supporting columns 6 are welded on four corners of the bottom of the fixed box 1.
The cutting bedplate 2 comprises a plate body 21, wherein the plate body 21 is fixedly installed at the top of the fixed box 1, a cutting groove 22 is formed in the top of the plate body 21, and partition plates 23 are welded on two sides of the cutting groove 22.
Slide holder 4 includes two fixed long posts 41, and two fixed long posts 41 weld respectively in the both sides of plate body 21, and two fixed long posts 41 are the symmetry and set up, and the welding of one side that plate body 21 was kept away from to fixed long post 41 has rack 42, and removal fluting 43 has been seted up at the top of fixed long post 41.
The leveling component 5 comprises a fixed top plate 51, the fixed top plate 51 is positioned above the plate body 21, two sides of the bottom of the fixed top plate 51 are welded with two moving columns 54, the two moving columns 54 are symmetrically arranged, the bottom of the moving column 54 is welded with a connecting plate 55, the bottom of the connecting plate 55 is welded with two groups of roller fixing blocks 519, the number of each group of roller fixing blocks 519 is two, a roller shaft 518 penetrates through the center of each group of roller fixing blocks 519, the surface of the roller shaft 518 is rotatably connected with a roller 517, the roller 517 is positioned at the center of the two roller fixing blocks 519, the center of the bottom of the fixed top plate 51 is fixedly provided with an air cylinder 56, the extending end of the air cylinder 56 is welded with a moving plate 52, two sides of the bottom of the moving plate 52 are welded with movable boxes 53, the two movable boxes 53 are symmetrically arranged, a movable cavity 516 is arranged in the movable box 53, and the bottom of the inner cavity of the movable cavity 516 is slidably connected with a second movable plate 515, the top welding of second movable plate 515 has spring 514, the one end welding that second movable plate 515 is kept away from to spring 514 has first movable plate 513, first movable plate 513 and the inner wall sliding connection of activity chamber 516, the bottom welding of second movable plate 515 has backup pad 510, movable box 53 is run through to the bottom of backup pad 510, the first through-hole that supplies backup pad 510 to pass is seted up to movable box 53's bottom, two backup pads 510 are the symmetry and set up, the relative inboard welding of two backup pads 510 has fixed axle 511, the surface rotation of fixed axle 511 is connected with leveling roller 57.
Drive assembly 7 includes motor case 71, motor case 71 welds in the both ends of fixed roof 51, two motor cases 71 are the symmetry and set up, the inner chamber fixed mounting of motor case 71 has motor 74, the output welding of motor 74 has axis of rotation 72, the second through-hole that supplies axis of rotation 72 to pass is seted up to motor case 71's bottom, the second through-hole is run through to axis of rotation 72's bottom, the bottom welding of axis of rotation 72 has gear 73, gear 73 is located one side of rack 42, gear 73 meshes with fixed long post 41 mutually.
By adopting the technical scheme, the leveling component 5 is additionally arranged, the cylinder 56 at the bottom of the leveling component 5 extends to enable the leveling roller 57 to compress the laid cloth, the motor 74 is started to drive the leveling component 5 to move back and forth, and the leveling roller 57 rolls back and forth on the cloth, so that the purpose of leveling can be achieved, the problems of time and labor waste of manual leveling are avoided, the convenience in leveling is further improved, the movable column 54 can be supported by arranging the connecting plate 55, the roller 517, the roller shaft 518 and the roller fixing block 519, and the roller 517 rolls in the inner cavity of the movable slot 43, so that the smoothness of the leveling component 5 in the movement process can be greatly improved, and the blocking condition of the leveling component 5 in the movement process is avoided.
Spacing post 59 has all been welded to the both sides at movable plate 52 top, sleeve pipe 58 has all been welded to the both sides of fixed roof 51 bottom, logical groove has been seted up to sleeve pipe 58's bottom, the diameter that leads to the groove is greater than spacing post 59's diameter, spacing post 59's top is pegged graft with leading to the groove, through adopting above-mentioned technical scheme, can drive the in-process that spacing post 59 moved down at movable plate 52, make spacing post 59 remain at same axis all the time, and then reached spacing purpose to spacing post 59, and then improved the stability when movable plate 52 moved down, the situation that the deflection appears in leveling roller 57 has been avoided.
The inner walls of the two sides of the movable slot 43 are provided with the limiting sliding grooves 44, the width of each limiting sliding groove 44 is larger than the diameter of each roller shaft 518, the two ends of each roller shaft 518 extend to the inner cavities of the two limiting sliding grooves 44 respectively, and the roller shafts 518 are connected with the limiting sliding grooves 44 in a sliding mode.
Example 2
More specifically, as shown in fig. 2, the difference between this embodiment and the above-mentioned embodiment is that the rubber pads are bonded to the bottoms of the supporting pillars 6, and the diameters of the rubber pads are larger than the diameter of the supporting pillars 6. The situation that the supporting column 6 slides is avoided.
Example 3
More specifically, as shown in fig. 1 and 13, the present embodiment is different from the above embodiments in that the present embodiment further includes an artificial intelligence module 8 and a camera 9, the artificial intelligence module 8 is fixedly installed at the rear side of the fixed box 1, the camera 9 is fixedly installed at the center of the rear side of the fixed top plate 51, an electrical output end of the camera 9 is electrically connected to an electrical input end of the artificial intelligence module 8, an electrical input end of the motor 74 is electrically connected to an electrical output end of the artificial intelligence module 8, the camera 9 can collect a video signal at the top of the cutting groove 22, the artificial intelligence module 8 analyzes and processes the video signal, thereby identifying the shape, size and position of the clothing cloth laid at the top of the cutting groove 22, the artificial intelligence module 8 respectively controls the two motors 74 to rotate at the same rotation speed, wherein the rotation directions of the two motors 74 are opposite, and then make two motors 74 drive two gears 73 through axis of rotation 72 respectively and rotate, gear 73 through cooperating with rack 42, and then drive flattening subassembly 5 and carry out the translation at the top of cutting platen 2, make flattening roller 57 of flattening subassembly 5 bottom carry out the flattening at the top of clothing cloth, improved flattening efficiency, avoided flattening subassembly 5 to carry out work in the vacancy for laying the clothing cloth.
Example 4
More specifically, as shown in fig. 9 and 13, the present embodiment is different from the above embodiments in that a pressure sensor 512 is fixedly installed at the top inside a movable cavity 516, the bottom of the pressure sensor 512 contacts with the top of a first movable plate 513, an electrical output end of the pressure sensor 512 is electrically connected with an electrical input end of an artificial intelligence module 8, an electrical input end of an air cylinder 56 is electrically connected with an electrical output end of the artificial intelligence module 8, by adopting the above technical solution, the air cylinder 56 is opened, an extension end of the air cylinder 56 presses down a leveling roller 57 through a movable plate 52, the leveling roller 57 is contacted with clothing cloth, the leveling roller 57 supports a supporting plate 510 through a fixed shaft 511, so that the supporting plate 510 is kept stationary, the supporting plate 510 further keeps a second movable plate 515 stationary, at this time, the movable plate 52 continuously pushes the movable box 53 to move downward, the movable box 53 drives the pressure sensor 512 of the inner cavity to move downward, the pressure sensor 512 compresses the spring 514 through the first movable plate 513, so that the pressure sensor 512 generates pressure data, and after the pressure data are transmitted to the artificial intelligence module 8, the pressure data are analyzed and processed by the artificial intelligence module 8, so that the cylinder 56 can be controlled to stop, and the leveling roller 57 is prevented from excessively pressing the clothing material.
For the convenience of understanding the technical solutions of the present invention, the following detailed description will be made on the working principle or the operation mode of the present invention in the practical process.
In practical application, the invention collects the video signal at the top of the cutting groove 22 through the camera 9, analyzes and processes the video signal through the artificial intelligence module 8, thereby recognizing the shape, size and position of the clothing cloth laid at the top of the cutting groove 22, starts the cylinder 56, when the extension end of the cylinder 56 presses down the leveling roller 57 through the movable plate 52, after the leveling roller 57 is in contact with the clothing cloth, the leveling roller 57 supports the supporting plate 510 through the fixed shaft 511, the supporting plate 510 is kept still, the supporting plate 510 further keeps the second movable plate 515 still, at this time, the movable plate 52 continues to push the movable box 53 to move down, the movable box 53 drives the pressure sensor 512 of the inner cavity to move down, the pressure sensor 512 compresses the spring 514 through the first movable plate 513, thereby the pressure sensor 512 generates pressure data, after the pressure data is transmitted to the artificial intelligence module 8, the pressure data is analyzed and processed through the artificial intelligence module 8, the cylinder 56 is controlled to be kept in the extended state, and then the two motors 74 are controlled to rotate at the same rotation speed, the two motors 74 rotate in opposite directions, so that the two motors 74 drive the two gears 73 to rotate through the rotating shafts 72, the gears 73 are matched with the racks 42, thereby driving the leveling component 5 to translate at the top of the cutting bedplate 2, the fixed top plate 51 drives the connecting plate 55 to slide in the inner cavity of the movable slot 43 through the movable column 54, the connecting plate 55 drives the roller 517 to rotate to move the inner cavity of the slot 43 to roll through the roller fixing block 519, and then drive leveling component 5 and carry out the translation at the top of cutting platen 2, make leveling roller 57 of leveling component 5 bottom roll at the top of clothing cloth, reached the purpose of flattening, improved the flattening efficiency, avoided leveling component 5 to carry out work in the vacancy for laying the clothing cloth.
The present invention can be easily implemented by those skilled in the art from the above detailed description. It should be understood, however, that the intention is not to limit the invention to the particular embodiments described. On the basis of the disclosed embodiments, a person skilled in the art can combine different technical features at will, thereby implementing different technical solutions.
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