CN111364137A

CN111364137A - Production process of polyester composite yarn

Info

Publication number: CN111364137A
Application number: CN202010354977.9A
Authority: CN
Inventors: 吴小马; 李继平; 顾日强; 楼宝良; 俞建芳; 吴祯山
Original assignee: Zhejiang Jiaren New Materials Co ltd
Current assignee: Zhejiang Jiaren New Materials Co ltd
Priority date: 2020-04-29
Filing date: 2020-04-29
Publication date: 2020-07-03

Abstract

The invention discloses a production process of polyester composite yarns, which is characterized in that two yarns with different styles are respectively conveyed in two paths, one yarn is output after the processes of deformation, cooling, shaping and the like, the other yarn is shaped yarn and is output after transfer through transfer structures, the two yarns are combined and screened at a network nozzle to form the composite yarns, and then the composite yarns are output to a winding roller to be wound into finished yarn cakes after oiling.

Description

Production process of polyester composite yarn

Technical Field

The invention relates to the technical field of chemical fiber composite yarn production, in particular to a production process of a polyester composite yarn.

Background

The regenerated high-shrinkage polyester composite yarn is a yarn with a high-shrinkage wrinkling effect, and is characterized in that the regenerated high-shrinkage polyester composite yarn is woven by adopting two strands of yarns with different shrinkages (one is regenerated high-shrinkage FDY, and the other is common regenerated polyester yarn or regenerated cation), the cloth cover is wrinkled due to different tightness shrinkage of yarn combination caused by different nozzles and overfeeding, the finished fabric is endowed with concave-convex feeling, the regenerated high-shrinkage polyester or regenerated cation composite yarn can be used for wool spinning, yarn weaving and knitting products, and an attractive and practical environment-friendly product can be obtained by skillful weaving and design after post-processing, and the regenerated high-shrinkage polyester composite yarn has a new style of soft suspension, soft luster, double-color flashing and concave-convex wrinkling,

the existing composite yarn production process is to combine and combine high-shrinkage FDY and regenerated polyester or regenerated cation DTY together on a net combining machine to form the high-shrinkage polyester composite yarn, which needs to invest manpower, material resources (net combining machine), field and machine material consumption again after elastication to produce the composite yarn, and has low production efficiency (generally, the net combining speed is lower than 400M/min), various yarns are in a free state, the tension control difficulty is high, the requirement on the net combining pressure is high, and the energy waste is large.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a production process of polyester composite yarns.

In order to achieve the purpose, the invention adopts the following technical scheme:

a production process of polyester composite yarns comprises the following steps:

1) the raw silk cakes are hung on a raw silk frame, a plurality of raw silk cake inserting rods are arranged in the raw silk frame and used for inserting the raw silk cakes, first raw silk and second raw silk are respectively wound on different raw silk cakes and are respectively output outwards through raw silk pipes, the raw silk pipes are fixedly arranged on the upper end face of the raw silk frame, the first raw silk and the second raw silk are respectively connected in the raw silk pipes in a penetrating manner and are output outwards, and the raw silk pipes play a role in output and guide;

2) the first raw silk and the second raw silk output from the raw silk pipe are output outwards through the filament cutter, the first raw silk is output to the first feeding roller, the second raw silk is output to the zero-feeding roller, the first raw silk is supported by the spinning-head rod frame and output upwards after passing through the first feeding roller, the second raw silk is output to the spinning-head rod filament guide after passing through the zero-crossing feeding roller, the filament cutter is installed on the equipment frame, the equipment frame is a door-shaped frame structure consisting of a left frame, a right frame and a top frame, the spinning-head frame is installed on the right side of the equipment frame, the filament cutter is installed on the end face of the right side of the right frame, the spinning-head rod frame, the first feeding roller and the zero-feeding roller are sequentially installed on the end face of the left side of the right frame from top to bottom, and the spinning-head rod;

3) the first raw silk is supported by the spinning-head rod frame to be ejected to the texturing hot box for heating, texturing and stretching, the first raw silk enters the cooling plate for cooling after being ejected from the texturing hot box, and then is ejected to the false twister to enable the first raw silk to be false-twisted and textured, the first raw silk after passing through the false twister is ejected to the texturing hot box through the transfer of the second feeding roller for heating and shaping, then the first raw silk is ejected from the texturing hot box, the second raw silk is ejected to the cooling plate beam silk guide through the spinning-head rod silk guide, the second raw silk does not pass through the texturing hot box, is guided to the external pipe from the cooling plate beam silk guide and is ejected, the texturing hot box is fixedly arranged above the top frame, the upper end of the texturing hot box is connected with the upper end of the spinning-head rod frame, a plurality of cooling plates are connected below the texturing hot box, the false twister is sequentially arranged on the right side surface of the left frame from, A setting hot box, a false twister is positioned below a cooling plate, the cooling plate is connected and fixed through a cooling plate fixing cross beam, a plurality of cooling plate cross beam yarn guides are arranged on the cooling plate fixing cross beam, a hot box upper cover plate is arranged at the upper end of the setting hot box, a first yarn guide opening is arranged on the hot box upper cover plate, the external thread guide pipe is fixedly arranged on the outer side wall of the shaping hot box, a thread outlet is formed in the lower end of the shaping hot box, the first thread guide port penetrates through the upper cover plate of the hot box and the upper end surface of the shaping hot box, the position of the first thread guide port corresponds to that of the thread outlet, first precursor is output from a second feeding roller, enters the shaping hot box through the first thread guide port and is output from the thread outlet, the second thread guide port penetrates through the upper cover plate of the hot box, the position of the second thread guide port corresponds to that of the external thread guide pipe, and second precursor is output from the cooling plate beam thread guide device, comes to the second thread guide port, then enters the external thread guide pipe and is output;

4) the first precursor output from the shaping hot box and the second precursor output from the external silk guide pipe enter a network nozzle together to be screened and doubled to form composite yarns, the composite yarns are output from the network nozzle and enter an oiling system through transfer of a third feeding roller, the composite yarns are output to a winding roller to be coiled into a finished product spinning cake after the oiling system finishes oiling, the network nozzle, the third feeding roller and the oiling system are sequentially installed on the right side face of the left frame from top to bottom, the network nozzle is located below the shaping hot box, and the plurality of winding rollers are installed on the side end face of the shaping hot box.

The processing speed of the composite wire is preferably 500-700 m/min.

The thread feeding speed of the zero feeding roller is less than that of the third feeding roller.

The temperature of the shaping hot box in the step 3) is preferably controlled within the range of 150-170 ℃.

The network pressure of the network nozzle in the step 4) is more than 4KG, and the network nozzle core preferably has a hole diameter of 1.4 mm.

The invention has the beneficial effects that: the invention has reasonable process design, can directly complete the composite operation of yarns with different style characteristics on the elasticizer, is different from the traditional process flow that the double yarns are combined by a special net combining machine after being elasticated, improves the production efficiency, greatly reduces the equipment and labor input and reduces the production cost of the composite yarn.

Drawings

FIG. 1 is a front view of a polyester composite yarn manufacturing apparatus used in the present invention;

FIG. 2 is a schematic view of the installation position of a cooling plate beam yarn guide of a polyester composite yarn production device used in the present invention;

fig. 3 is a schematic view of the mounting structure of each component on the left frame of the equipment rack of the polyester composite yarn production equipment used in the present invention.

In the figure: the device comprises an equipment rack 1, a left frame 101, a right frame 102, a top frame 103, a raw silk frame 2, a silk cake inserting rod 21, a raw silk tube 22, a filament cutter 3, a first feeding roller 4, a zero feeding roller 5, a raw silk rod frame 6, a raw silk rod guide 61, a texturing hot box 7, a cooling plate 8, a cooling plate fixing cross beam 81, a cooling plate cross beam guide 82, a false twister 9, a second feeding roller 10, a sizing hot box 11, a hot box upper cover plate 111, a first silk guide opening 112, a second silk guide opening 113, an external pipe 114, a silk outlet opening 115, a network nozzle 12, a third feeding roller 13, an oiling system 14, a winding roller 15, a first raw silk 16, a second raw silk 17, a composite silk 18 and a raw silk cake 19.

Detailed Description

The present invention will be further described with reference to the following drawings and detailed description, wherein the descriptions of "left", "right", etc. refer to fig. 1 for reference:

as shown in fig. 1 to 3, a production process of a polyester composite yarn comprises the following steps:

1) hanging a plurality of raw silk cakes 19 on a raw silk frame 2, arranging a plurality of silk cake inserting rods 21 in the raw silk frame 2, inserting the raw silk cakes 19 into the silk cake inserting rods 21, respectively winding first precursor wires 16 and second precursor wires 17 on different raw silk cakes 19, respectively outputting the first precursor wires 16 and the second precursor wires 7 outwards through raw silk pipes 22, fixedly installing the precursor silk pipes 22 on the upper end surface of the raw silk frame 2, respectively inserting the first precursor wires 16 and the second precursor wires 17 into the raw silk pipes (22) and outputting outwards, and enabling the raw silk pipes (22) to play a role in output and guide;

2) the first protofilament 16 and the second protofilament 17 output from the protofilament pipe 22 are both output outwards through the filament cutter 3, after the filament cutter 3, the first protofilament 16 and the second protofilament 17 are respectively output in two ways, the first protofilament 16 is output to the first feeding roller 4, the second protofilament 17 is output to the zero feeding roller 5, the first protofilament 16 is supported by the spinning rod frame 6 and output upwards through the first feeding roller 4, the second protofilament 17 is output to the spinning rod guide 61 through the zero feeding roller 5, the filament cutter 3 is installed on the equipment frame 1, the equipment frame 1 is a door-shaped frame structure composed of a left frame 101, a right frame 102 and a top frame 103, the spinning rod frame 2 is installed on the right side of the equipment frame 1, the filament cutter 3 is installed on the right side end face of the right frame 102, the spinning rod frame 6, the first feeding roller 4 and the zero roller 5 are sequentially installed on the left side end face of the right frame 102 from top to bottom, a thread guide 61 of the thread-taking-up rod is arranged on the thread-taking-up rod frame 6;

3) the first protofilament 16 is made of common regenerated polyester filaments or regenerated cations, the first protofilament 16 needs to be subjected to an elasticizing and shaping process, the first protofilament 16 is supported by a spinning bar frame 6 to be ejected into a texturing hot box 7 for heating, texturing and stretching, the first protofilament 16 is ejected from the texturing hot box 7 and then enters a cooling plate 8 for cooling, then the first protofilament 16 is ejected into a false twister 9 for false twisting and texturing of the first protofilament 16, the first protofilament 16 passing through the false twister 9 is transferred to the shaping hot box 11 through a second feeding roller 10 for heating and shaping of the first protofilament 16, then the first protofilament 16 is ejected from the shaping hot box 11, the second protofilament 17 is ejected into a cooling plate beam filament guide 82 through a spinning bar filament guide 61, the second protofilament 17 is made of shaped high-shrinkage filaments, the second protofilament 17 does not pass through the shaping hot box 11 and is guided to an external protofilament pipe 114 from the cooling plate beam filament guide 82 for outputting, the texturing hot box 7 is fixedly arranged above the top frame 103, the upper end of the texturing hot box 7 is connected with the upper end of the spinning head rod frame 6, a plurality of cooling plates 8 are connected below the texturing hot box 7, the right side surface of the left frame 101 is sequentially provided with a false twister 9, a second feeding roller 10 and a shaping hot box 11 from top to bottom, the false twister 9 is positioned below the cooling plates 8, the cooling plates 8 are connected and fixed through a cooling plate fixing cross beam 81, the cooling plate fixing cross beam 81 is provided with a plurality of cooling plate cross beam thread guides 82, the upper end of the shaping hot box 11 is provided with a hot box upper cover plate 111, the hot box upper cover plate 111 is provided with a first thread guide port 112 and a second thread guide port 113, the outer side wall of the shaping hot box 11 is fixedly provided with a thread guide pipe 114, the lower end of the shaping hot box 11 is provided with a thread outlet 115, the first thread guide port 112 penetrates through the hot box upper cover plate 111 and the upper end surface of the shaping hot, the first protofilament 16 is output from the second feeding roller 10, enters the shaping hot box 11 through the first filament guide port 112 and is output from the filament outlet 115, the second filament guide port 113 penetrates through the upper cover plate 111 of the hot box, the setting position of the second filament guide port 113 corresponds to the external filament guide pipe 114, and the second protofilament 17 is output from the cooling plate beam filament guide 82, then enters the second filament guide port 113, then enters the external filament guide pipe 114 and is output;

4) the first precursor 16 output from the shaping hot box 11 and the second precursor 17 output from the external filament guiding pipe 114 enter the network nozzle 12 together for screening and doubling to form a composite filament 18, the composite filament 18 is output from the network nozzle 12 and transferred to the oiling system 14 through the third feeding roller 13, the composite filament 18 is output to the winding roller 15 after the oiling system 14 finishes oiling and is wound into a finished product cake, the network nozzle 12, the third feeding roller 13 and the oiling system 14 are sequentially installed on the right side surface of the left frame 101 from top to bottom, the network nozzle 12 is located below the shaping hot box 11, and the winding rollers 15 are installed on the side end surface of the shaping hot box 11.

The functions of each part in the production equipment used in the process steps are as follows: the raw silk frame 2 is used for supplying yarn to spinning cakes, the filament cutter 3 is used for closing yarn feeding and cutting off yarn when operation faults occur, the yarn feeding rod frame 6 plays a role of supporting and lifting the yarn to output, the texturing hot box 7 enables the passing yarn to be heated and textured, the cooling plate 8 gradually cools the yarn coming out of the texturing hot box 7 in the conveying process, the false twister 9 enables the yarn to be false-twisted and textured, the texturing hot box 11 is used for heating and shaping the yarn, the network nozzle 12 meshes the yarn into composite yarn, the oiling system 14 oils the finished composite yarn to improve the processing performance of the finished composite yarn in subsequent textile processing, the winding roller 15 winds the finished composite yarn 18 into a cake shape to facilitate outputting, and each roller part in the production equipment plays a role of drawing, feeding, transferring and the like.

Example (b):

the first protofilament 16 is selected from regenerated semi-gloss 75D/72F or DTY (regenerated high shrinkage filament) corresponding to regenerated cations.

The second precursor 17 is regenerated semi-optical 30D/12F FDY (regenerated polyester or regenerated cationic filament).

DTY and FDY are divided into two paths of inlet wires, and after the process steps, the inlet wires are drawn off and doubled to form the regenerated high-shrinkage polyester composite yarn 18.

The processing speed of the composite yarn 18 is preferably 500-.

The yarn feeding speed of the zero feeding roller 5 is lower than that of the third feeding roller 13, the FDY is formed high-shrinkage yarn, the zero feeding roller 5 plays a role in assisting feeding, the yarn feeding speed of the zero feeding roller 5 is lower than that of the third feeding roller 13, micro-traction can be formed on the FDY, traction force is generated, and the FDY is tensioned.

The temperature of the shaping hot box 11 in the step 3) should be adjusted according to the fluffy effect of the DTY, and the temperature is preferably controlled within the range of 150 ℃ and 170 ℃.

The network pressure of the network nozzle 12 in the step 4) is more than 4KG, so as to achieve the effect of network fastness and facilitate subsequent weaving or double twisting, the network nozzle 12 is one model larger than that of the network yarn normally made, and the diameter of the spray core is preferably 1.4 mm.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A production process of polyester composite yarn is characterized in that: the method comprises the following steps:

1) the raw silk cakes (19) are hung on a raw silk frame (2), a plurality of silk cake inserting rods (21) are arranged in the raw silk frame (2), the silk cake inserting rods (21) are used for inserting the raw silk cakes (19), different raw silk cakes (19) are respectively wound with first protofilaments (16) and second protofilaments (17), the first protofilaments (16) and the second protofilaments (17) are respectively output outwards through raw silk pipes (22), the raw silk pipes (22) are fixedly installed on the upper end face of the raw silk frame (2), the first protofilaments (16) and the second protofilaments (17) are respectively connected in the raw silk pipes (22) in a penetrating mode and output outwards, and the raw silk pipes (22) play a role in output and guide;

2) first precursor (16) of follow precursor pipe (22) output, second precursor (17) are all outwards exported again through filament cutter (3), first precursor (16) are exported first feeding roller (4), zero feeding roller (5) are exported to second precursor (17), first precursor (16) support through first feeding roller (4) back through first bull stick frame (6) and push up the output, second precursor (17) export first bull stick guide (61) through zero feeding roller (5) back, filament cutter (3) are installed on equipment rack (1), equipment rack (1) is by left frame (101), right frame (102), the door-shaped frame structure that top frame (103) are constituteed, install on equipment rack (1) right side original filament frame (2), filament cutter (3) are installed to right frame (102) right side terminal surface, install on right frame (102) left side terminal surface down in proper order from last raw bull stick frame (6), A first feeding roller (4) and a zero feeding roller (5), wherein a spinning rod guide (61) is arranged on a spinning rod frame (6);

3) the first protofilament (16) is supported by a spinning bar frame (6) to be ejected upwards and output into a texturing hot box (7) for heating, texturing and stretching, the first protofilament (16) is ejected from the texturing hot box (7) and then enters a cooling plate (8) for cooling, then the first protofilament (16) is ejected into a false twister (9) to enable the first protofilament (16) to be false-twisted and textured, the first protofilament (16) after passing through the false twister (9) is transferred and output into a texturing hot box (11) through a second feeding roller (10) to heat and shape the first protofilament (16), then the first protofilament (16) is ejected from the texturing hot box (11), the second protofilament (17) is ejected to a cooling plate beam wire guide device (82) through a spinning bar wire guide device (61), the second protofilament (17) does not pass through the texturing hot box (11), the second protofilament is guided from the cooling plate beam wire guide device (82) to an external wire guide pipe (114) for outputting, the texturing hot box (7) is fixedly installed above a top frame (103, the upper end of a texturing hot box (7) is connected with the upper end of a spinning-head rod frame (6), a plurality of cooling plates (8) are connected below the texturing hot box (7), a false twister (9), a second feeding roller (10) and a sizing hot box (11) are sequentially arranged on the right side surface of a left frame (101) from top to bottom, the false twister (9) is positioned below the cooling plates (8), the cooling plates (8) are connected and fixed through a cooling plate fixing cross beam (81), a plurality of cooling plate cross beam thread guides (82) are arranged on the cooling plate fixing cross beam (81), a hot box upper cover plate (111) is arranged at the upper end of the sizing hot box (11), a first thread guide port (112) and a second thread guide port (113) are arranged on the hot box upper cover plate (111), an external thread guide pipe (114) is fixedly arranged on the outer side wall of the sizing hot box (11), a thread outlet (115) is arranged at the lower end of the sizing hot box (11), and the first thread guide port (112) penetrates through the hot box, the position of a first yarn guide opening (112) corresponds to that of a yarn outlet (115), a first raw yarn (16) is output from a second feeding roller (10), enters a shaping hot box (11) through the first yarn guide opening (112) and then is output from the yarn outlet (115), a second yarn guide opening (113) penetrates through an upper cover plate (111) of the hot box, the setting position of the second yarn guide opening (113) corresponds to that of an external yarn guide pipe (114), and a second raw yarn (17) is output from a cross beam yarn guide device (82) of a cooling plate, comes to the second yarn guide opening (113) and then enters the external yarn guide pipe (114) and is output;

4) the net oiling device comprises a net nozzle (12), a first raw silk (16) output from a shaping hot box (11) and a second raw silk (17) output from an external silk guide pipe (114) enter the net nozzle (12) together to be netted and doubled to form a composite silk (18), the composite silk (18) is output from the net nozzle (12) and transferred through a third feeding roller (13) to enter an oiling system (14), the composite silk (18) is output to a winding roller (15) to be rolled into a finished silk cake after the oiling of the oiling system (14) is finished, the net nozzle (12), the third feeding roller (13) and the oiling system (14) are sequentially installed on the right side face of a left frame (101) from top to bottom, the net nozzle (12) is located below the shaping hot box (11), and a plurality of winding rollers (15) are installed on the side end face of the shaping hot box (11).

2. The production process of the polyester composite yarn as claimed in claim 1, wherein the production process comprises the following steps: the processing speed of the composite wire (18) is preferably 500-700 m/min.

3. The production process of the polyester composite yarn as claimed in claim 1, wherein the production process comprises the following steps: the thread feeding speed of the zero feeding roller (5) is less than that of the third feeding roller (13).

4. The production process of the polyester composite yarn as claimed in claim 1, wherein the production process comprises the following steps: the temperature of the shaping hot box (11) in the step 3) is preferably controlled within the range of 150-170 ℃.

5. The production process of the polyester composite yarn as claimed in claim 1, wherein the production process comprises the following steps: the network pressure of the network nozzle (12) in the step 4) is more than 4KG, and the diameter of the network nozzle (12) spray core is preferably 1.4 mm.