CN113106646A - Production process of mixed embroidery fabric - Google Patents

Production process of mixed embroidery fabric Download PDF

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Publication number
CN113106646A
CN113106646A CN202110409281.6A CN202110409281A CN113106646A CN 113106646 A CN113106646 A CN 113106646A CN 202110409281 A CN202110409281 A CN 202110409281A CN 113106646 A CN113106646 A CN 113106646A
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CN
China
Prior art keywords
feeding
pipe
fabric
embroidery
sliding sleeve
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CN202110409281.6A
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Chinese (zh)
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CN113106646B (en
Inventor
周国军
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Shaoxing Keqiao Zero Textile Co ltd
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Shaoxing Keqiao Zero Textile Co ltd
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Priority to CN202110409281.6A priority Critical patent/CN113106646B/en
Publication of CN113106646A publication Critical patent/CN113106646A/en
Application granted granted Critical
Publication of CN113106646B publication Critical patent/CN113106646B/en
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    • DTEXTILES; PAPER
    • D05SEWING; EMBROIDERING; TUFTING
    • D05CEMBROIDERING; TUFTING
    • D05C7/00Special-purpose or automatic embroidering machines
    • D05C7/10Special-purpose or automatic embroidering machines for separating and burning-off parts of the base fabric
    • DTEXTILES; PAPER
    • D05SEWING; EMBROIDERING; TUFTING
    • D05CEMBROIDERING; TUFTING
    • D05C13/00Auxiliary devices incorporated in embroidering machines, not otherwise provided for; Ancillary apparatus for use with embroidering machines
    • DTEXTILES; PAPER
    • D05SEWING; EMBROIDERING; TUFTING
    • D05CEMBROIDERING; TUFTING
    • D05C7/00Special-purpose or automatic embroidering machines
    • D05C7/08Special-purpose or automatic embroidering machines for attaching cords, tapes, bands, or the like

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  • Engineering & Computer Science (AREA)
  • Textile Engineering (AREA)
  • Sewing Machines And Sewing (AREA)
  • Treatment Of Fiber Materials (AREA)

Abstract

The invention discloses a production process of a mixed type embroidery fabric, which relates to the technical field of embroidery fabric production, and the technical scheme is characterized in that: the method comprises the following steps: step S1, performing laser embroidery on the surface of the fabric to form a pattern; step S2, the cloth is stretched and clamped on the embroidery table-board; step S3, moving the tightened fabric, embroidering the fabric through an embroidering mechanism, and embroidering mixed embroidery beads on the surface of the fabric to form a flower-type pattern; at step S3, the mixed embroidery beads, including the main material and a plurality of auxiliary materials, are fed by a mixing and feeding mechanism. In the embroidering process, the fabric can be mixed and processed in different pattern styles, and the diversity and the layering of patterns on the surface of the fabric can be improved by combining a laser embroidering treatment technology and various embroidering processes.

Description

Production process of mixed embroidery fabric
Technical Field
The invention relates to the technical field of embroidery fabric production, in particular to a production process of a mixed type embroidery fabric.
Background
Bead tube embroidery, which means that beads are embroidered on cloth to form a relatively three-dimensional flower type pattern, and the cloth presents more unique luster and decorative effect according to different kinds of bead tubes; in the production process, special bead tube embroidery equipment and machine bead tube embroidery machinery are generally adopted to carry out embroidery processing according to computer plate-making embroidery patterns, and compared with the traditional manual embroidery processing, the method has higher working efficiency.
The bead tube particles have various types, different parameters such as size, color, shape and the like, so that a single embroidering procedure cannot be adopted for production and processing in the production process, wherein due to the fact that the sizes of some bead tubes with specific special-shaped structures are different greatly, certain limitations exist in the production and adaptation process, the bead tubes cannot pass through a single conveying pipe, and a separate machine head is required for production and processing; however, for part of the bead tubes, the shape and the size of the bead tubes are relatively regular, the bead tubes can be conveyed through the same conveying pipeline in the use process, particularly, the bead tubes are consistent in shape and size, only have different colors and gloss, and can be smoothly conveyed in the same material conveying pipeline.
Therefore, a new solution is needed to solve this problem.
Disclosure of Invention
The invention aims to solve the problems, provides a production process of a mixed type embroidery fabric, can perform mixed processing in different modes, adopts a laser embroidery processing technology and various embroidery processes to be combined, and can improve the diversity of patterns on the surface of the fabric.
The technical purpose of the invention is realized by the following technical scheme: a production process of a mixed type embroidery fabric comprises the following steps:
step S1, performing laser embroidery on the surface of the fabric to form a pattern;
step S2, the cloth is stretched and clamped on the embroidery table-board;
step S3, moving the tightened fabric, embroidering the fabric through an embroidering mechanism, and embroidering mixed embroidery beads on the surface of the fabric to form a flower-type pattern; at step S3, the mixed embroidery beads, including the main material and a plurality of auxiliary materials, are fed by a mixing and feeding mechanism.
The mixing and feeding mechanism comprises a material changing box, the lower part of the material changing box is connected with a material discharging pipe, the upper part of the material changing box is connected with a material feeding pipe and a plurality of auxiliary material pipes, the material feeding pipe is opposite to the material discharging pipe, a material changing disc is rotatably connected in the material changing box and comprises a plurality of material changing barrels, and when the material changing disc rotates, each material changing barrel is switched between the material discharging pipe and the material feeding pipe.
The auxiliary material pipe is provided with a feeding mechanism outside, through grooves are formed in two sides of the auxiliary material pipe, and the feeding mechanism extends into the through grooves and is used for driving the auxiliary materials in the auxiliary material pipe to move towards the material receiving cylinder at the bottom of the auxiliary material pipe.
The feeding mechanism further comprises an upper sliding sleeve and a lower sliding sleeve which are connected outside the auxiliary material pipe in a sliding mode, the inner side of the upper sliding sleeve is connected with an upper feeding deflector rod in a rotating mode, one end of the upper feeding deflector rod is connected to the inner side of the upper sliding sleeve in a rotating mode and is maintained through elasticity of a torsion spring, and the other end of the upper feeding deflector rod penetrates through the through groove to extend into the auxiliary material pipe and form a second feeding portion which is bent downwards.
The inner side of the lower sliding sleeve is rotatably connected with a lower feeding deflector rod, one end of the lower feeding deflector rod is rotatably connected with the inner side of the lower sliding sleeve and is maintained through the elasticity of a torsion spring, and the other end of the lower feeding deflector rod penetrates through the through groove to extend into the auxiliary material pipe and form a first feeding part which is bent upwards; and a space for containing an auxiliary material is formed between the first feeding part and the second feeding part.
Furthermore, a lower stop block is arranged on the inner side of the lower end of the through groove and used for pushing the lower feeding deflector rod to turn upwards to allow auxiliary materials to pass downwards when the lower sliding sleeve slides downwards; an upper stop block is arranged on the inner side of the upper end of the through groove and used for pushing the upper feeding deflector rod to turn downwards to allow auxiliary materials to pass downwards when the upper sliding sleeve slides upwards; the distance between the upper sliding sleeve and the lower sliding sleeve is adjustable.
The lower end of a discharge pipe of the mixing and feeding mechanism is connected with a discharge mechanism, the discharge mechanism comprises a feeding disc provided with a feeding slide rail, a limiting pressure plate positioned at the upper part of the feeding slide rail and a pushing piece used for pushing materials in the feeding slide rail in a reciprocating manner, a discharge hole is formed in the end part of the feeding slide rail, and the lower part of the limiting pressure plate is sunk into the feeding slide rail and is adjustable in height; the material changing mechanism comprises a discharging pipe, the lower end of the discharging pipe is connected with the limiting pressure plate, and the discharging end of the discharging pipe extends into the feeding slide rail and is flush with the bottom surface of the limiting pressure plate.
The feeding slide rail is provided with a feeding slide rail, a feeding tray is arranged in the feeding slide rail, a discharging hole is formed in the feeding slide rail, the feeding tray is arranged in the feeding slide rail, the discharging hole is downwards communicated with the feeding tray, a groove is formed in the side wall in the discharging hole, a stop block is hinged in the groove, the stop block partially extends into the discharging hole, and elastic support is achieved through a spring III; the lower part of the groove penetrates through the bottom of the feeding plate, the lower part of the stop block is fixedly connected with a push block, and the push block is used for elastically abutting against the table board and driving the stop block to retract into the groove.
In conclusion, the invention has the following beneficial effects: in the production process of the embroidery process, a mode of combining laser and bead tube embroidery is adopted, so that the pattern style of the surface of the fabric can be improved, and the diversity of surface patterns after the fabric is processed and presented is improved; in the process of bead tube embroidery, beads with approximate size parameters are mixed and processed, and switching can be performed among different embroidery beads, so that embroidering of various beads can be completed simultaneously in one-time embroidering process, embroidering efficiency is improved, and diversity of pattern structures on the surface of an embroidered fabric is improved.
Drawings
FIG. 1 is a schematic structural view of a mixing and feeding mechanism of the present invention;
FIG. 2 is a schematic structural view of a feeding mechanism of the present invention;
FIG. 3 is a schematic structural diagram of a take-up reel of the present invention;
FIG. 4 is a schematic view of a connection structure between a motor shaft and a material changing tray according to the present invention;
FIG. 5 is a schematic partial structural view of a tapping pipe according to the invention;
FIG. 6 is a schematic view of the eccentric wheel and the guide wheel of the present invention;
FIG. 7 is a schematic view of the feed tray of the present invention;
fig. 8 is an enlarged view of fig. 7 at a.
Reference numerals: 1. changing the material box; 2. a feed pipe; 3. a discharge pipe; 4. a motor; 5. a rotating shaft; 6. changing the material plate; 61. a material receiving barrel; 7. a material poking rod; 8. a pushing block; 9. a push rod; 10. an elastic deflector rod; 11. a limiting box; 12. a limiting cylinder; 13. an elastic rod; 14. an eccentric wheel; 15. a guide wheel; 16. an elastic limiting part; 17. an auxiliary material pipe; 18. a through groove; 19. a feeding mechanism; 20. main materials; 21. an auxiliary material; 22. an end cap; 23. a first spring; 24. a center pole; 25. a lower sliding sleeve; 26. an upper sliding sleeve; 27. a lower feed bar; 28. a first feeding part; 29. an upper feed rod; 30. a feeding part II; 31. a lower thread insert; 32. an upper threaded sleeve; 33. a lower stop block; 34. an upper stop block; 35. a support sleeve; 36. a slide bar; 37. a notch; 38. a connecting bond; 39. connecting grooves; 40. filtering with a screen; 41. an air exhaust pipe; 42. a feed tray; 43. a feeding slide rail; 44. a discharge hole; 45. a material pushing plate; 46. an elastic bulge; 47. a limiting pressure plate; 48. a support plate; 49. a screw; 50. a nut; 51. a second spring; 52. a groove; 53. a stopper; 54. a third spring; 55. a push block; 56. a drive assembly.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
The embodiment discloses a production process of a mixed type embroidery fabric, which comprises the following steps:
step S1, selecting a fabric made of proper materials as a base material according to production requirements, performing laser embroidery on the surface of the fabric, and processing to form a required pattern;
step S2, the cloth is stretched and clamped on the embroidery table-board, and the part with embroidery processing is positioned near the middle position of the embroidery table-board, and the edge embroidery mechanism can process normally;
and step S3, moving the tightened fabric, directly moving the frame for clamping the fabric during moving, embroidering the fabric by an embroidering mechanism during moving, and embroidering mixed embroidery beads on the surface of the fabric to form flower-type patterns.
At step S3, the mixed embroidery beads, including the main material and a plurality of auxiliary materials, are fed by a mixing and feeding mechanism. The mixed feeding mechanism is arranged on the machine head of the embroidery equipment for use and can convey bead tube materials to be embroidered; including trading magazine 1, it connects inlet pipe 2 and discharging pipe 3 to trade magazine 1, can carry out the transmission to the material and carry to the switching of the different materials of tray 6 realization through trading in the material changing pipe, thereby realizes the switching transport between major ingredient 20 and the auxiliary material 21, reaches the mixed effect of carrying the supply of type material.
The lower part of the material changing box 1 is connected with a material discharging pipe 3, and the material discharging pipe 3 is used for outputting materials and is connected with a material discharging structure arranged below; as shown in fig. 5, in order to increase the discharge speed, an air suction pipe 41 may be connected to the middle of the discharge pipe 3, and the air suction pipe 41 may form a downward negative pressure to form a certain negative pressure suction force on the material just entering the discharge pipe 3. Thus accelerating the material flow speed, and in order to ensure the normal flow of the material in the discharge pipe 3, a filter screen 40 is arranged at the joint position where the air suction pipe 41 is connected, so as to keep the conveying channel in the discharge pipe 3 relatively flat.
The upper part of the material changing box 1 is connected with a feeding pipe 2 and a plurality of auxiliary material pipes 17, the feeding pipe 2 is right opposite to the discharging pipe 3, the feeding pipe 2 is mainly used for conveying the main material 20, and the input quantity is large; three groups of auxiliary material pipes 17 can be arranged, and the auxiliary material pipes 17 are used for conveying auxiliary materials 21 in small batches, and the quantity of the auxiliary materials to be embroidered is small; a material changing disc 6 is rotationally connected in the material changing box 1, a plurality of material changing barrels are formed at the periphery of the material changing disc 6, and the number of the material changing barrels corresponds to the direction of the feeding pipe 2 and the auxiliary material pipe 17; when changing material dish 6 and rotating, each trades the feed cylinder and switches between discharging pipe 3 and inlet pipe 2, can transport the material of output among the different auxiliary material pipes 17 to the import position of discharging pipe 3 to export the material downwards.
As shown in fig. 1 and 3, in order to improve the accuracy of the rotation adjustment process of the material changing tray 6, a positioning notch 37 is formed in the periphery of the material changing tray 6, a material stirring rod 7 is arranged between the material receiving box corresponding to the material inlet pipe 2 and the material outlet pipe 3, one end of the material stirring rod 7 is hinged in the material receiving box and is elastically maintained by a torsion spring, and the other end of the material stirring rod 7 penetrates through the notch 37 and extends out of the material receiving box 61, so that the tip end of the material stirring rod can be partially sunk into the notch 37 in the periphery of the material changing tray 6, and the material changing tray 6 can be ensured to be well located at a determined position when rotating; and because the material stirring rod 7 has certain elasticity, and a certain curved surface chamfer is formed at the edge position of the tip of the material stirring rod 7, when the material stirring rod 7 slides away from the notch 37 and enters the notch 37, a certain guiding function can be formed, so that the material stirring rod 7 is ensured not to interfere with the normal action of the mechanism while positioning the rotating angle.
The material poking rod 7 can also realize upward overturning and push materials upwards to be separated from the material receiving barrel 61, so that the main materials 20 are completely moved out of the material receiving barrel 61 upwards; a push rod 9 is connected in the material receiving box in a sliding mode, the push rod 9 can stretch and retract in a reciprocating mode, a bent push block 8 is formed at the rear end of the material stirring rod 7, the push block 8 can be pushed in the process that the push rod 9 stretches and retracts in a reciprocating mode, the material stirring rod 7 is driven to swing upwards, and materials in the corresponding material receiving barrel 61 are separated from the material receiving barrel 61 upwards; when the kick-off lever 7 is turned upwards, the part of the kick-off lever 7 is still trapped in the notch 37, and can be continuously matched with the notch 37 to realize positioning in the rotating process of the material changing disc 6.
The material changing disc 6 is driven to rotate by the motor 4, and the servo motor 4 can be selected by the motor 4, so that the rotating angle of the material changing disc 6 can be stably controlled; a certain offset angle is formed between the rotating shaft 5 of the motor 4 and the material changing disc 6, namely, under the condition that the rotating shaft 5 of the motor 4 is static, the angle of the material changing disc 6 can be slightly adjusted, so that when the material changing disc 6 rotates nearby the material shifting rod 7, the position correction of movement can be realized under the limiting action of the material shifting rod 7; the key groove axial transmission can be specifically adopted between the rotating shaft 5 of the motor 4 and the material changing disc 6, the connecting key 38 is arranged on the periphery of the rotating shaft 5, the connecting groove 39 is formed in the inner periphery of the shaft hole of the material changing disc 6, and the width of the connecting groove 39 is larger than that of the connecting key 38, so that a certain buffering angle can be formed between the rotating shaft 5 and the material changing disc 6, and the rotating angle is generally double of the angle corresponding to the notch 37.
The upper part of the material changing box 1 is provided with a limiting box 11 communicated with each other, a limiting cylinder 12 is arranged in the limiting box 11, and the position of the limiting cylinder 12 is adjusted to block the feeding pipe 2, so that the output of materials is controlled; the limiting cylinder 12 is connected to the lower end of the feeding pipe 2 in a sliding manner, can slide along the radial direction of the feeding pipe 2, and is elastically supported by an elastic rod 13; in the sliding process, the limiting cylinder 12 can be just opposite to or staggered with the feeding pipe 2; an eccentric wheel 14 is arranged on a rotating shaft 5 of the motor 4, one side of the limiting cylinder 12 facing the eccentric wheel 14 is connected with a guide wheel 15 through a rod piece, and the guide wheel 15 is abutted against the peripheral surface of the eccentric wheel 14; when the eccentric wheel 14 rotates, the limiting cylinder 12 is driven to slide, and the minimum diameter position of the eccentric wheel 14 is abutted against the guide wheel 15, the limiting cylinder 12 is just opposite to the feeding cylinder, so that the limiting cylinder 12 is just opposite to the feeding pipe 2 only when the eccentric wheel 14 rotates to the position, that is, the material receiving cylinder 61 corresponding to the position on the material changing disc 6 corresponds to the feeding pipe 2 and the discharging rod, so that the main material 20 can normally pass through.
In order to ensure that the limiting cylinder 12 can stably contain materials, a plurality of elastic shifting pieces are arranged at the lower end of the limiting cylinder 12, are rotatably connected in the material changing box 1 and realize elastic limiting through a torsion spring, and when only one material exists in the limiting cylinder 12, the material is limited by the elasticity of the torsion spring, so that the lower end of the limiting cylinder 12 is sealed; and when spacing section of thick bamboo 12 was relative with inlet pipe 2, the material of inlet pipe 2 upper end will increase the pressure to the elasticity plectrum of spacing pipe lower extreme to can supply the material to pass through downwards, and realize certain stopping at the material through-process, will form certain elasticity when a material passes through at every turn and reply, thereby can control the speed that the material passed through in the middle of from spacing pipe, keep the stability that the material was carried.
A feeding mechanism 19 is arranged outside the auxiliary material pipe 17, and the feeding mechanism 19 can convey the auxiliary materials 21 in the auxiliary material pipe 17 individually; through grooves 18 are formed in two sides of the auxiliary material pipe 17, and the feeding mechanism 19 can extend into the through grooves 18 of the auxiliary material pipe 17, so that the auxiliary material 21 in the auxiliary material pipe 17 is driven to move towards the material receiving barrel 61 at the bottom of the auxiliary material pipe 17.
As shown in fig. 2, the feeding mechanism 19 includes an upper sliding sleeve 26 and a lower sliding sleeve 25, which can be fixed relatively and can slide up and down along the auxiliary pipe 17; a second feeding part 30 which is bent downwards is formed by connecting a second feeding deflector rod to the inner side of the upper sliding sleeve 26, wherein one end of the second feeding deflector rod is rotatably connected to the inner side of the upper sliding sleeve 26 and is maintained by the elasticity of a torsion spring, and the other end of the second feeding deflector rod penetrates through the through groove 18 and extends into the auxiliary material pipe 17; the inner side of the lower sliding sleeve 25 is rotatably connected with a lower feeding deflector rod, one end of the lower feeding deflector rod is rotatably connected with the inner side of the lower sliding sleeve 25 and is maintained by the elasticity of a torsion spring, and the other end of the lower feeding deflector rod penetrates through the through groove 18 to extend into the auxiliary material pipe 17 and form a feeding part I28 which is bent upwards; a space for accommodating one auxiliary material 21 is formed between the first feeding portion 28 and the second feeding portion 30.
A lower stop block 33 is arranged on the inner side of the lower end of the through groove 18, and the lower stop block 33 is used for pushing the lower feeding deflector rod to turn upwards for the auxiliary materials 21 to pass downwards when the lower sliding sleeve 25 slides downwards; an upper stop block 34 is arranged on the inner side of the upper end of the through groove 18, and the upper stop block 34 is used for pushing the upper feeding deflector rod to turn downwards to allow the auxiliary materials 21 to pass downwards when the upper sliding sleeve 26 slides upwards.
When the upper sliding sleeve 26 moves upwards, the second feeding part 30 of the upper feeding deflector rod can elastically abut against the upper stop block 34 in the auxiliary material pipe 17, so that the upper feeding deflector rod swings downwards, the two upper feeding deflector rods are opened downwards, and the auxiliary material 21 particles on the upper part enter a space between the first feeding part 28 and the second feeding part 30; in the downward moving process of the lower sliding sleeve 25, the first feeding portion 28 of the lower feeding deflector rod can elastically abut against the lower stop block 33 in the middle of the auxiliary material pipe 17, so that the lower feeding deflector rod swings upward, the two lower feeding deflector rods are opened downward, a space between the first feeding portion 28 and the second feeding portion 30 is formed, and materials in the middle of the auxiliary material pipe 17 can fall into the material receiving cylinder 61 corresponding to the lower portion.
The height of the upper stop block 34 of the auxiliary material pipe 17 is adjustable, the auxiliary material pipe 17 is connected with the supporting sleeve 35 in a sliding mode, the supporting sleeve 35 is a rubber sleeve, the rubber sleeve can be stably coated and fixed on the outer portion of the auxiliary material pipe 17, the inner portion of the supporting sleeve 35 extends into the through groove 18 and forms the upper stop block 34, and therefore the opening position of the upper feeding deflector rod can be adjusted, and materials with different lengths, models and sizes can be adjusted conveniently.
The distance between the upper sliding sleeve 26 and the lower sliding sleeve 25 can be adjusted, and the distance between the upper feeding rod 29 and the lower feeding rod 27 can be adjusted by adjusting the distance between the upper sliding sleeve and the lower sliding sleeve, so that the distance can be adjusted to the height for accommodating one material, and single grabbing can be formed in the material picking process; the upper sliding sleeve 26 and the lower sliding sleeve 25 are connected through two threaded sleeves, the opposite end of the upper sliding sleeve 26 and the opposite end of the lower sliding sleeve 25 are respectively connected with an upper threaded sleeve 32 and a lower threaded sleeve 31 in a rotating mode, the upper threaded sleeve 32 and the lower threaded sleeve 31 are connected through threads, and threaded rotation is formed between the two threaded sleeves, so that axial rotation can be adjusted to be axial movement, and therefore the distance between the upper sliding sleeve 25 and the lower sliding sleeve 25 can be adjusted.
The up-and-down movement of the lower sliding sleeve 25 and the upper sliding sleeve 26 can be driven in a reciprocating way through an external driving mechanism, and the sliding guide is realized by adopting the sliding rod 36, so that the smoothness of the adjusting process is improved; the driving assembly 56 can be a telescopic rod and has a telescopic movable end, the telescopic rod is fixedly mounted on the support of the equipment, and the movable end is fixedly connected with the lower sliding sleeve 25, so that reciprocating adjustment can be realized in the telescopic process of the movable end, and the upper sliding sleeve 26 and the lower sliding sleeve 25 can be lifted and floated.
The upper end of the auxiliary material pipe 17 is sealed through the end cover 22, the end cover 22 is detachably mounted at the upper end of the auxiliary material pipe 17, the end cover 22 is fixedly connected with a central rod 24, when the end cover 22 covers the auxiliary material pipe 17, the central rod 24 is just positioned in the middle of the auxiliary material pipe 17 and can penetrate through materials in the auxiliary material pipe to form a material string, so that the materials can be positioned, and the stability of the materials in the grabbing process can be improved; the first spring 23 is elastically pressed between the end cover 22 and the dressing, the first spring 23 has a certain downward elastic deformation tendency on the materials, the upper feeding rod 29 extrudes the materials on the upper side in the upward moving process of the lower sliding sleeve 25 and the upper sliding sleeve 26, the materials on the upper side are pushed out to move upwards in a certain floating mode, the compression amplitude of the first spring 23 is increased in the moving process, the elastic force generated by the first spring 23 is increased until the elastic force generated by a torsion spring at the hinged part of the upper material stirring rod 7 is overcome, so that the upper material stirring rod 7 can fluctuate downwards, a downward opening state is formed between the two upper material stirring rods 7 for the materials to pass through, and when the materials pass through the position between the upper material stirring rod 7 and the lower material stirring rod 7, the lower part of the upper material stirring rod 7 can be supported, so that the second materials are not allowed to enter the lower part of the upper material stirring rod 7, and single grabbing and conveying is realized.
An elastic limiting piece 16 is arranged at a position, corresponding to the auxiliary material pipe 17, of the material changing box 1, the elastic limiting piece 16 is elastically supported through a spring, an elastic floating structure is formed at the upper end of the elastic limiting piece 16, a spherical structure is formed at the upper end of the elastic limiting piece, an elastic floating curved end is formed, and the part of the curved end is sunk into the material receiving barrel 61 and abuts against the edge of the inner side of the material receiving barrel 61; when the curved surface end and the circular material changing barrel are mutually abutted to form an automatic centering structure, the material changing discs 6 can be rotated and positioned to a certain extent in the rotating process of the material changing discs 6.
As shown in fig. 8, in the present embodiment, the discharging structure and manner during the embroidering process are optimized, and the discharging mechanism is adopted to output the mixed embroidery beads; the discharging mechanism comprises a feeding disc 42, a limiting pressure plate 47 and a pushing piece, wherein a feeding slide rail 43 is arranged at the upper part of the feeding disc 42, a material enters the upper part of the discharging feeding end of the slide rail, and a discharging hole 44 is arranged at the discharging end of the slide rail and used for outputting the material; the lower part of the limiting pressure plate 47 extends into the feeding slide rail 43, and the upper part of the feeding slide rail 43 forms a shield to prevent the material from falling off from the feeding slide rail 43; the height of the materials can be adjusted according to the height of the materials, the materials are generally adjusted to the maximum height of each mixed material, and the materials can be normally conveyed while being shielded; the pushing member is located at the input end of the feeding slide rail 43 and has a pushing plate 45 that extends and retracts back and forth, and the pushing member can push the material in the feeding slide rail 43 to slide in the extending and retracting process, so that the material in the feeding slide rail 43 can be output from the discharge hole 44.
Two screws 49 are fixedly connected to the upper portion of the limiting pressing plate 47, the upper ends of the screws 49 penetrate through the supporting plate 48 and are in threaded connection with nuts 50, the position of the limiting pressing plate 47 is adjusted in a floating mode through the adjusting nuts 50, the second springs 51 are elastically abutted between the supporting plate 48 and the limiting pressing plate 47, and the lower end face of each nut 50 can be tightly attached to the supporting plate 48 during passing, so that stable supporting of the limiting pressing plate 47 is kept.
In order to keep the smoothness of material input, the material discharging pipe 3 is connected to the limiting pressure plate 47, and the material discharging pipe 3 can input the material into the feeding slide rail 43, so that the material supply is formed; the lower end of the discharge pipe 3 is flush with the bottom surface of the limit pressure plate 47.
Specific telescopic structure to the slurcam does not do specific restriction, can form reciprocal flexible can, and form the elastic bulge 46 of upwards uplifting on the upper portion of slurcam, the edge of elastic bulge 46 forms the arc transition, promotes the in-process forward when the slurcam, and elastic bulge 46 on its upper portion can fall into the inside of discharging pipe 3 just to form spacing of certain degree, at flexible in-process, and do not influence the normal flexible action of slurcam.
The discharge hole 44 is positioned at the discharge end of the feeding slide rail 43, and the discharge hole 44 penetrates through the feeding tray 42 downwards, so that the materials in the discharge hole 44 can normally flow downwards under the influence of self weight, and the materials can be normally output; in order to avoid uncontrollable discharging of materials from the discharging hole 44, a movable stop block 53 is arranged in the discharging hole 44 to limit and stop the materials, specifically, a groove 52 is formed on the side wall of the discharging hole 44, the stop block 53 is hinged in the groove 52, the lower end of the stop block 53 forms an arc-shaped part, and elastic support is realized through a spring III 54; the baffle plate extends into the discharge hole 44, so that the materials are prevented from being output downwards from the discharge hole 44, and the baffle plate can be retracted inwards to open the discharge hole 44 when the materials need to be discharged, so that the materials can be automatically output; the shrink of this baffle can adopt the aircraft nose to push down the pressure of in-process and drive, link up the bottom of feed tray 42 in the lower part of recess 52, and at the lower part fixed connection ejector pad 55 of dog 53, form the structure of type U between dog 53 and the ejector pad 55, press down when the aircraft nose, feed tray 42 follows downstream, feed tray 42 bottom and mesa elasticity support the pressure, and drive dog 53 rotatory retraction recess 52 in, open discharge opening 44, thereby can make the material export in the middle of discharge opening 44, realize the controllable of material output.
The above description is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention, and are considered to be within the scope of the invention.

Claims (8)

1. The production process of the mixed type embroidery fabric is characterized by comprising the following steps of:
step S1, performing laser embroidery on the surface of the fabric to form a pattern;
step S2, the cloth is stretched and clamped on the embroidery table-board;
step S3, moving the tightened fabric, embroidering the fabric through an embroidering mechanism, and embroidering mixed embroidery beads on the surface of the fabric to form a flower-type pattern; at step S3, the mixed embroidery beads, including the main material and a plurality of auxiliary materials, are fed by a mixing and feeding mechanism.
2. The production process of the mixed embroidery fabric as claimed in claim 1, wherein the mixing and feeding mechanism comprises a material changing box, the lower part of the material changing box is connected with a material discharging pipe, the upper part of the material changing box is connected with a material feeding pipe and a plurality of auxiliary material pipes, the material feeding pipe faces the material discharging pipe, a material changing plate is rotatably connected in the material changing box and comprises a plurality of material changing barrels, and when the material changing plate rotates, each material changing barrel is switched between the material discharging pipe and the material feeding pipe.
3. The production process of the mixed type embroidery fabric as claimed in claim 2, wherein a feeding mechanism is arranged outside the auxiliary material pipe, through grooves are formed in two sides of the auxiliary material pipe, and the feeding mechanism extends into the through grooves and is used for driving the auxiliary material in the auxiliary material pipe to move towards a material receiving cylinder at the bottom of the auxiliary material pipe.
4. The production process of the mixed type embroidery fabric as claimed in claim 3, wherein the feeding mechanism comprises an upper sliding sleeve and a lower sliding sleeve which are slidably connected to the outside of the auxiliary material tube, the inner side of the upper sliding sleeve is rotatably connected with an upper feeding deflector rod, one end of the upper feeding deflector rod is rotatably connected to the inner side of the upper sliding sleeve and is elastically maintained by a torsion spring, and the other end of the upper feeding deflector rod penetrates through the through groove to extend into the auxiliary material tube and form a second feeding part which is bent downwards.
5. The production process of the mixed type embroidery fabric as claimed in claim 4, wherein the inner side of the lower sliding sleeve is rotatably connected with a lower feeding deflector rod, one end of the lower feeding deflector rod is rotatably connected with the inner side of the lower sliding sleeve and is elastically maintained by a torsion spring, and the other end of the lower feeding deflector rod penetrates through the through groove to extend into the auxiliary material pipe and form a first feeding part which is bent upwards; and a space for containing an auxiliary material is formed between the first feeding part and the second feeding part.
6. The production process of the hybrid embroidery fabric as claimed in claim 5, wherein a lower stop is provided inside the lower end of the through groove, and the lower stop is used for pushing the lower feeding deflector rod to turn upwards for the auxiliary material to pass downwards when the lower sliding sleeve slides downwards; an upper stop block is arranged on the inner side of the upper end of the through groove and used for pushing the upper feeding deflector rod to turn downwards to allow auxiliary materials to pass downwards when the upper sliding sleeve slides upwards; the distance between the upper sliding sleeve and the lower sliding sleeve is adjustable.
7. The production process of the mixed type embroidery fabric as claimed in claim 2, wherein a discharging mechanism is connected to the lower end of a discharging pipe of the mixing and feeding mechanism, the discharging mechanism comprises a feeding disc provided with a feeding slide rail, a limiting pressure plate positioned on the upper part of the feeding slide rail and a pushing member used for pushing materials in the feeding slide rail in a reciprocating manner, a discharging hole is formed in the end part of the feeding slide rail, and the lower part of the limiting pressure plate is sunk into the feeding slide rail and is adjustable in height; the material changing mechanism comprises a discharging pipe, the lower end of the discharging pipe is connected with the limiting pressure plate, and the discharging end of the discharging pipe extends into the feeding slide rail and is flush with the bottom surface of the limiting pressure plate.
8. The production process of the mixed type embroidery fabric as claimed in claim 7, wherein the discharge hole is located at the discharge end of the feeding slide rail and penetrates through the feeding tray downwards, a groove is formed in the side wall in the discharge hole, a stopper is hinged in the groove, the stopper partially extends into the discharge hole, and elastic support is achieved through a third spring; the lower part of the groove penetrates through the bottom of the feeding plate, the lower part of the stop block is fixedly connected with a push block, and the push block is used for elastically abutting against the table board and driving the stop block to retract into the groove.
CN202110409281.6A 2021-04-16 2021-04-16 Production process of mixed embroidery fabric Active CN113106646B (en)

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