CN116949625A - Spinning processing preparation technology of antibacterial composite knitting yarn - Google Patents

Abstract

The invention discloses a spinning processing preparation process of antibacterial composite knitting yarns, which comprises the steps of raw material selection, preparation of core yarns, wool mixing, carding, needle carding, drawing, preparation of twistless roving and preparation of core-spun composite yarns; the wool fiber is used as a raw material of the covering fiber and the antibacterial fiber is used as a core yarn; 2 needle carding processes and 2 drawing processes are carried out, and non-twist slubbing equipment is adopted to prepare non-twist slubbing; an antimicrobial composite knit yarn is prepared using a core spun yarn production apparatus wherein the core yarn and the coated fiber have opposite lay directions. The core yarn adopts antibacterial fibers, so that the composite knitting yarn has good antibacterial effect. The core yarn has certain twist and twisting direction after being made. And then the core yarn is wrapped with other short fibers by a core-spun process for production and processing, and the twist of the core yarn is configured in the opposite direction to the twist of the wrapped short fibers, so that the purpose that the single yarn can be used for producing the knitted sweater is achieved, and the antibacterial function is given to the product.

Description

Spinning processing preparation technology of antibacterial composite knitting yarn

Technical Field

The invention relates to a spinning process preparation technology of antibacterial composite knitting yarns, and belongs to the technical field of wool core-spun yarn production technology.

Background

The similar conventional core-spun yarn products for the knitted sweater in the market are all manufactured by combining and twisting 2 core-spun yarns, and mainly because the inclined piece phenomenon occurs when the single yarns are used for weaving the sweater, the yarn form is needed to be adopted to balance the twist so as to meet the use requirement of the knitted sweater. The twisted yarns are required to be balanced, so that the twisted core-spun yarns can meet the use requirement, the yarn count applicable to the sweater preparation process is considered, the twisted yarn count is low, the yarn diameter is large, the application of the fine-count knitted sweater product is limited, and the market popularization and application are not facilitated. And the protein component and good hygroscopicity of wool fiber are easy to grow bacteria, and the yarn used is required to have good antibacterial effect.

Disclosure of Invention

The invention aims to provide an antibacterial composite knitting yarn spinning processing preparation process which can be used for knitting yarns for sweaters.

In order to solve the technical problems, the aim of the invention is realized as follows:

the invention relates to a spinning processing preparation process of antibacterial composite knitting yarn, which comprises the following steps:

s1, selecting raw materials: selecting wool fibers as cladding fibers and antibacterial fibers as raw materials of core yarns;

s2, preparing core yarns: preparing the antibacterial fiber and the blend fiber into blend yarn serving as core yarn;

s3, mixing: opening and mixing wool fibers serving as coated fibers, spraying a wool mixing solution on wool, and performing wool mixing treatment;

s4, carding: preparing the wool fibers subjected to the blending into raw strips through a carding process;

s5, needle comb: the prepared raw strips are made into needle-combed wool tops through a 2-needle-combing process;

s6, drawing: 2 drawing processes are carried out on the prepared needle combed sliver, and self-leveling drawing equipment is selected for final drawing;

s7, preparing a twistless roving: the wool tops after drawing are made into non-twist slub by non-twist slub equipment;

s8, preparing a core-spun composite yarn: the core yarn and the roving are made into the antibacterial composite knitting yarn by adopting core yarn production equipment, the core yarn and the cladding fiber have opposite twisting directions, and the twisting degree of the core yarn and the twisting degree of the cladding fiber are controlled according to 0.45-0.6:1.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: in the step S3, the mixed solution of the wool and the polyester comprises 3 to 4 percent of the wool and the polyester oil, 0.5 to 0.7 percent of the antistatic agent, 0.5 to 1 percent of the yarn reinforcing agent and water; the addition agent is prepared by mixing wool fiber with water in an amount of 20-22% by weight.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: in the step S4, the carding equipment is a wool spinning roller type carding machine; the wool spinning roller type carding machine comprises a wool bucket, a licker-in, a pre-carding cylinder, a main cylinder, doffers and a wool stripping device which are sequentially arranged on a frame; the pre-carding system is characterized in that three groups of working rolls and stripping roll combinations are arranged on the pre-carding cylinder, a transfer roll is arranged between the pre-carding cylinder and the main cylinder, and a cover plate is arranged on the main cylinder; the pre-carding system comprises 3 pairs of working rolls, 84 carding cover plates, 30 working cover plates are adopted by the main carding system, and four-point gauge distances of the cover plates are respectively 9, 10 and 12 English filaments;

the group of working rolls and the hair stripping rolls close to the licker-in are a first group, the group of working rolls and the hair stripping rolls close to the main cylinder are a third group, and the middle working rolls and the hair stripping rolls are a second group; the working rolls in the first group have a gauge of 20-22 filament, the dehairing rolls have a gauge of 21-22 filament, the working rolls in the second group have a gauge of 18-20 filament, the dehairing rolls have a gauge of 22 filament, and the working rolls in the third group have a gauge of 16-18 filament and the dehairing rolls have a gauge of 22 filament.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: in step S5, a small roller distance needle plate gill box is used in the gill process.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: in the step S7, the roving equipment and the drafting gauge are smaller by 25mm in the front adjusting area, and the total gauge is 110mm; the draft multiple is designed to be smaller and controlled to be between 5.5 and 7.5 times; the tension of each yarn guiding area is widened to 1X; the speed of the rubbing board is increased to 110-120m/min, the evenness is controlled below 5%, and the weight unevenness is controlled below 1.0%.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the core-spun yarn production equipment comprises a core yarn twisting device 1 and a core-spun yarn device 2;

the core yarn twisting device 1 comprises a yarn storage disc 3, wherein a hollow spindle rod 21 is arranged on the yarn storage disc 3, and a core yarn roll 4 is arranged on the hollow spindle rod 21;

the core-spun yarn device 2 comprises a ring twisting and winding device 9, a drafting device and a roving feeding device 11; the drafting device comprises a rear roller 13, a middle roller 14 and a front roller 15, wherein the rear roller 13 is close to the roving feeding device 11, and the front roller 15 is close to the ring twisting and winding device; the middle roller 14 is provided with a rubber ring 16; the roving feeding device 11 is provided with a roving roll; a first yarn guiding device is arranged between the ring twisting and winding device 9 and the drafting device;

a second yarn guiding device is arranged above the yarn storage disc 3, and the core yarn 6 led out from the core yarn roll 4 passes through the hollow spindle rod 21 to the lower part of the yarn storage disc 1, is guided by the second yarn guiding device and is fed into the front roller 15.

The above-mentioned scheme is based on and is a preferable scheme of the above-mentioned scheme: the mercerized wool fibers are 70S mercerized Australian wool.

The beneficial effects of the invention are as follows: according to the spinning processing preparation process of the antibacterial composite knitting yarn, the antibacterial fibers are adopted in the core yarn, so that the composite knitting yarn has a good antibacterial effect. The core yarn has certain twist and twisting direction after being made. And then the core yarn is wrapped with other short fibers by a core-spun process for production and processing, and the twist of the core yarn is configured in the opposite direction to the twist of the wrapped short fibers, so that the purpose that the single yarn can be used for producing the knitted sweater is achieved, and the antibacterial function is given to the product.

Drawings

FIG. 1 is a schematic view in longitudinal cross section of an antimicrobial composite knit yarn in accordance with the present invention;

FIG. 2 is a schematic representation of a transverse cross-section of an antimicrobial composite knit yarn in accordance with the present invention;

fig. 3 is a schematic structural view of the core yarn production apparatus according to the present invention.

The labels in the figures are illustrated below: 1-a core yarn twisting device; 2-core spinning device; 3-a silk storage disc; 4-core yarn roll; 5-a first yarn guide hook; 6-core yarn; 7-a second yarn guiding hook; 8-a third yarn guide hook; 9-a ring twisting and winding device; 10-a fourth yarn guiding hook; 11-roving feeding device; 12-roving; 13-a rear roller; 14-middle roller; 15-rubber rings; 16-front roller; 17-composite core spun yarn; 21-hollow spindle pole; 200-coating layers; 201-wool fibers; 101-antimicrobial fibers; 102-blend fiber.

Detailed Description

The invention will be further described with reference to the drawings and specific examples.

The present invention will be described in detail with reference to fig. 1, 2 and 3. The invention relates to a spinning processing preparation process of antibacterial composite knitting yarn, which comprises the following steps:

s1, selecting raw materials: wool fibers are selected as the cover fibers and antimicrobial fibers are selected as the raw materials of the core yarns.

S2, preparing core yarns: the antibacterial fiber and the blend fiber are made into blend yarn which is used as core yarn.

S3, mixing: wool fibers as the covered fibers were subjected to opening mixing, and wool was sprayed with a wool-and-wool mixed solution, followed by wool-and-wool treatment.

S4, carding: and (3) preparing the wool fibers subjected to the sum wool into raw strips through a carding process.

S5, needle comb: and (3) preparing the prepared raw strips into the needle-combed wool tops through a 2-needle-combed process.

S6, drawing: the prepared needle-combed sliver is subjected to 2-channel drawing processes, and the final-channel drawing adopts self-leveling drawing equipment.

S7, preparing a twistless roving: and (5) preparing the wool tops subjected to drawing into non-twist slub by adopting non-twist slub equipment.

S8, preparing a core-spun composite yarn: the core yarn and the roving are made into the antibacterial composite knitting yarn by adopting core yarn production equipment, the core yarn and the cladding fiber have opposite twisting directions, and the twisting degree of the core yarn and the twisting degree of the cladding fiber are controlled according to 0.45-0.6:1.

Further, the antibacterial composite knitting yarn prepared by the knots is subjected to count design. In the step S1, the selected antibacterial fiber may be a moxa cotton fiber, and the blend fiber mixed with the antibacterial fiber selected in the core yarn may be a natural fiber or a chemical synthetic fiber such as cotton, wool, cashmere, terylene, chinlon, acrylon, etc. And the coated fiber can be 66S-110SZ common Australian wool, balano wool, mercerized Australian wool or shrink-proof Australian wool and the like. The design ensures that the content of the final finished product of the moxa cotton fiber is not less than 30 percent; the coated fiber in this example was selected to be 70S mercerized australia wool. The core yarn was produced according to a 55% cotton, 40% Ai Caomian, 5%70S mercerized Australian wool 20Nm/1 blend design. The fineness of the finally prepared antibacterial composite knitting yarn is 60Nm/1.

Further, in step S2, the fineness of the prepared blended yarn is 20Nm/1, the twisting direction is S, and the twist degree can be selected according to actual needs, and in this embodiment, is selected to be 200 twists/m.

Further, in the step S3, the mixed solution of the sum and the wool comprises 3 to 4 percent of sum and the wool oil, 0.5 to 0.7 percent of antistatic agent, 0.5 to 1 percent of yarn reinforcing agent and water; the addition agent is prepared by mixing wool fiber with water in an amount of 20-22% by weight. In particular to this example, the wool blend solution included 3.5% and wool oil, 0.6% antistatic agent, 0.8% yarn enhancer, and water.

Further, in step S4, the carding equipment used is a wool spinning roller type carding machine; compared with a cotton spinning cover plate type carding machine, the wool spinning roller type carding machine is changed from hard holding with great damage to fibers to elastic holding of fibers with low strength and easy carding, such as wool, down and the like.

The wool spinning roller type carding machine comprises a wool bucket, a licker-in, a pre-carding cylinder, a main cylinder, doffers and a wool stripping device which are sequentially arranged on a frame; the pre-carding system is characterized in that three groups of working rolls and stripping roll combinations are arranged on the pre-carding cylinder, a transfer roll is arranged between the pre-carding cylinder and the main cylinder, and a cover plate is arranged on the main cylinder; the pre-carding system is composed of 3 pairs of working rolls, 84 carding cover plates, and 30 main carding systems are composed of working cover plates.

The carding machine is held for elasticity for the carding machine except that the feed roller holds, has still increased 3 pairs of working rolls's pre-carding system, and the carding apron reduces to 84 from original 106, and main carding system adopts 30 working apron, and apron four-point gauge is 9, 10, 12 english silk respectively. Tin Lin Zhuaisu can be reduced by 100 revolutions per minute compared with a carding machine, and the carding is softer and less damaged.

The carding process takes main fibers of raw materials as selection basis, and according to the length of the main fibers of 45-50mm of the raw materials, the process parameters are as follows:

the group of working rolls and the hair stripping rolls close to the licker-in are a first group, the group of working rolls and the hair stripping rolls close to the main cylinder are a third group, and the middle working rolls and the hair stripping rolls are a second group; the working rolls in the first group have a gauge of 20-22 filament, the dehairing rolls have a gauge of 21-22 filament, the working rolls in the second group have a gauge of 18-20 filament, the dehairing rolls have a gauge of 22 filament, and the working rolls in the third group have a gauge of 16-18 filament and the dehairing rolls have a gauge of 22 filament. The large-gauge pre-carding pre-combs the bundled fibers to form finer bundled fibers, so that the fibers are easier to comb, the fiber damage caused by carding is reduced, the fiber length can be increased by 5mm, the short velvet content is reduced, and an important effect on improving the quality of yarns is achieved.

Further, in step S5, a small pitch pin plate gill box is used in the gill process. The two small-roller-distance needle plate gill boxes are adopted, so that the drafting distance (the lowest adjustable length is 24 mm) can be effectively reduced, the front and back hooks of the fibers can be effectively eliminated, the fibers are more straightened, parallel and separated, the fibers are elastically held, the accidental drafting is reduced, and the fibers cannot be broken. In addition, the 2-channel needle carding process is selected, and because the needle carding process is overlong, the number of the wool grains in the wool tops is increased due to the striking of the needle plate, the quality control of the wool tops is not facilitated, the straightness of the fibers can be ensured by 2-channel needle carding, and the number of the wool grains can be prevented from increasing.

Further, the evenness of the wool tops manufactured through 2-channel needle carding is poor and does not compound production requirements, and in order to avoid that the wool tops are increased due to overlong needle carding procedures and influence product quality, 2 drawing procedures are selected, and the final drawing is of an auto-leveling machine type, so that on one hand, uneven weight of the wool tops is greatly reduced, the uneven weight of the wool tops is controlled within 1.5%, on the other hand, the straightening, parallel and separation degree of wool top fibers is ensured, and the generation of wool tops is reduced.

Further, in step S7, the roving produced by the roving frame has a larger width than the strands of the roving produced by the roving frame before the spinning frame, and has a good effect of improving the problem of poor filament coating of the core spun yarn. The roving equipment and the drafting gauge are adjusted to be smaller, the front area is 25mm, and the total gauge is 110mm; the draft multiple is designed to be smaller and controlled to be between 5.5 and 7.5 times; the tension of each yarn guiding area is widened to 1X; the bundling device is small in size, and fiber cohesion is increased; the speed of the rubbing board is increased to 110-120m/min, the evenness is controlled below 5%, and the weight unevenness is controlled below 1.0%.

Further, the core-spun yarn production equipment comprises a core yarn twisting device 1 and a core-spun yarn device 2;

the core yarn 6 is twisted by the core yarn twisting device 1, the twisted core yarn 6 is fed into the core-spun yarn device 2, the outside of the core yarn 6 is covered with the spun yarn, and the twisting direction of the spun yarn is opposite to the twisting direction of the core yarn 6. Because of the opposite twisting directions, the prepared single-strand core-spun yarn can balance the influence caused by the twisting directions, and the phenomenon that the single yarn is inclined when used for weaving sweaters is avoided. .

The core yarn twisting device 1 comprises a yarn storage disc 3, wherein a hollow spindle rod 21 is arranged on the yarn storage disc 3, and a core yarn roll 4 is arranged on the hollow spindle rod 21. After the core yarn 6 is led out from the core yarn roll 4, the core yarn penetrates into the hollow spindle 21 from the upper part of the hollow spindle rod 21 and penetrates out from the lower part of the hollow spindle rod.

The core-spun yarn device 2 comprises a ring twisting and winding device 9, a drafting device and a roving feeding device 11; the drafting device comprises a rear roller 13, a middle roller 14 and a front roller 15, wherein the rear roller 13 is close to the roving feeding device 11, and the front roller 15 is close to the ring twisting and winding device; the middle roller 14 is provided with a rubber ring 16; the roving feeding device 11 is provided with a roving roll; a first yarn guiding device is arranged between the ring twisting and winding device 9 and the drafting device. The first yarn guiding device is a fourth yarn guiding hook.

A second yarn guiding device is arranged above the yarn storage disc 3, and the core yarn 6 led out from the core yarn roll 4 passes through the hollow spindle rod 21 to the lower part of the yarn storage disc 1, is guided by the second yarn guiding device and is fed into the front roller 15. The second yarn guiding device comprises a first yarn guiding hook 5, a second yarn guiding hook 7 and a third yarn guiding hook 8.

The working process of the wool spinning composite yarn production equipment is as follows: after being led out from the core yarn roll 4, the core yarn 6 passes through the hollow spindle rod 21 from top to bottom, passes out from the lower part of the yarn storage disc 3, and passes through the first yarn guide hook 5, the second yarn guide hook 7 and the third yarn guide hook 8 in sequence. During unwinding of the core yarn 6 from the core yarn roll 4, the core yarn 6 moves along the outside of the yarn storage disc 3 and has a twisting effect on the core yarn 6.

The twisted core yarn is guided to a draft device. The roving 12 is drawn out from the roving feeding device 11 and enters a drafting device, the drafting device comprises a front roller, a middle roller and a rear roller, and a rubber ring is arranged on the middle roller to form two drafting zones. The roving may be drawn to form a spun yarn. On the side of the front roller close to the middle roller, the twisted core yarn 6 is fed to the drafting device. The yarn formed is guided to the ring-spindle disappointing device by a second yarn guiding device, namely a fourth yarn guiding hook. The yarn is twisted and wound in the ring twisting and winding device 9 to form composite core-spun yarn 17, namely the antibacterial composite knitting yarn, and the twisting direction is opposite to the twisting direction of the core yarn.

The antibacterial composite knitting yarn prepared was tested and the results were as follows:

and (3) performing a performance test on the prepared antibacterial composite knitting yarn:

the foregoing describes in detail preferred embodiments of the present invention. It should be understood that numerous modifications and variations can be made in accordance with the concepts of the invention by one of ordinary skill in the art without undue burden. Therefore, all technical solutions which can be obtained by logic analysis, reasoning or limited experiments based on the prior art by the person skilled in the art according to the inventive concept shall be within the scope of protection defined by the claims.

Claims (7)

1. The spinning process for preparing the antibacterial composite knitting yarn is characterized by comprising the following steps of:

s1, selecting raw materials: selecting wool fibers as cladding fibers and antibacterial fibers as raw materials of core yarns;

s2, preparing core yarns: preparing the antibacterial fiber and the blend fiber into blend yarn serving as core yarn;

s3, mixing: opening and mixing wool fibers serving as coated fibers, spraying a wool mixing solution on wool, and performing wool mixing treatment;

s4, carding: preparing the wool fibers subjected to the blending into raw strips through a carding process;

s5, needle comb: the prepared raw strips are made into needle-combed wool tops through a 2-needle-combing process;

s6, drawing: 2 drawing processes are carried out on the prepared needle combed sliver, and self-leveling drawing equipment is selected for final drawing;

s7, preparing a twistless roving: the wool tops after drawing are made into non-twist slub by non-twist slub equipment;

s8, preparing a core-spun composite yarn: the core yarn and the roving are made into the antibacterial composite knitting yarn by adopting core yarn production equipment, the core yarn and the cladding fiber have opposite twisting directions, and the twisting degree of the core yarn and the twisting degree of the cladding fiber are controlled according to 0.45-0.6:1.

2. The process for preparing the antibacterial composite knitted yarn according to claim 1, wherein in the step S3, the sum-wool mixed solution comprises 3% -4% of sum-wool oil, 0.5% -0.7% of antistatic agent, 0.5% -1% of yarn reinforcing agent and water; the addition agent is prepared by mixing wool fiber with water in an amount of 20-22% by weight.

3. The process for preparing antibacterial composite knitted yarn according to claim 1, wherein in step S4, the carding equipment used is a wool spinning roller type carding machine; the wool spinning roller type carding machine comprises a wool bucket, a licker-in, a pre-carding cylinder, a main cylinder, doffers and a wool stripping device which are sequentially arranged on a frame; the pre-carding system is characterized in that three groups of working rolls and stripping roll combinations are arranged on the pre-carding cylinder, a transfer roll is arranged between the pre-carding cylinder and the main cylinder, and a cover plate is arranged on the main cylinder; the pre-carding system comprises 3 pairs of working rolls, 84 carding cover plates, 30 working cover plates are adopted by the main carding system, and four-point gauge distances of the cover plates are respectively 9, 10 and 12 English filaments;

the group of working rolls and the hair stripping rolls close to the licker-in are a first group, the group of working rolls and the hair stripping rolls close to the main cylinder are a third group, and the middle working rolls and the hair stripping rolls are a second group; the working rolls in the first group have a gauge of 20-22 filament, the dehairing rolls have a gauge of 21-22 filament, the working rolls in the second group have a gauge of 18-20 filament, the dehairing rolls have a gauge of 22 filament, and the working rolls in the third group have a gauge of 16-18 filament and the dehairing rolls have a gauge of 22 filament.

4. The process for preparing an antibacterial composite knitted yarn according to claim 1, wherein in step S5, a small-pitch needle plate gill machine is used in the gill process.

5. The process for preparing the antibacterial composite knitted yarn according to claim 1, wherein in the step S7, the roving equipment and the drafting gauge are adjusted to be smaller (front area 25mm, total gauge 110 mm); the draft multiple is designed to be smaller and controlled to be between 5.5 and 7.5 times; the tension of each yarn guiding area is widened to 1X; the speed of the rubbing board is increased to 110-120m/min, the evenness is controlled below 5%, and the weight unevenness is controlled below 1.0%.

6. The process for preparing the antibacterial composite knitted yarn by spinning according to claim 1, wherein the core-spun yarn production equipment comprises a core yarn twisting device (1) and a core-spun yarn device (2);

the core yarn twisting device (1) comprises a yarn storage disc (3), wherein a hollow spindle rod (21) is arranged on the yarn storage disc (3), and a core yarn roll (4) is arranged on the hollow spindle rod (21);

the core-spun spinning device (2) comprises a ring twisting and winding device (9), a drafting device and a roving feeding device (11); the drafting device comprises a rear roller (13) close to the roving feeding device (11), a middle roller (14) and a front roller (15) close to the ring twisting and winding device; the middle roller (14) is provided with a rubber ring (16); the roving feeding device (11) is provided with a roving roll; a first yarn guiding device is arranged between the ring twisting and winding device (9) and the drafting device;

the second yarn guiding device is arranged above the yarn storage disc (3), and the core yarn (6) led out from the core yarn roll (4) passes through the hollow spindle rod (21) to the lower part of the yarn storage disc (1) and is guided by the second yarn guiding device and fed into the front roller (15).

7. The process for preparing the antibacterial composite knitted yarn according to claim 1, wherein the mercerized wool fiber is 70S mercerized australia wool.