CN109763235B - Superfine high-density yarn-dyed fabric containing graphene modified fibers and preparation method thereof - Google Patents
Superfine high-density yarn-dyed fabric containing graphene modified fibers and preparation method thereof Download PDFInfo
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- CN109763235B CN109763235B CN201811485680.5A CN201811485680A CN109763235B CN 109763235 B CN109763235 B CN 109763235B CN 201811485680 A CN201811485680 A CN 201811485680A CN 109763235 B CN109763235 B CN 109763235B
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Abstract
The invention relates to a superfine high-density yarn-dyed fabric containing graphene modified fibers and a preparation method thereof, wherein the method comprises the following steps: weaving warp yarns and weft yarns by adopting a water jet loom with a photoelectric weft feeling device to prepare superfine high-density yarn-dyed fabric, wherein the weft yarns comprise pure spun yarns A, a white board is arranged on one side of a running path of the pure spun yarns A in the water jet loom, and the white board faces a photoelectric probe of the photoelectric weft feeling device; the prepared superfine high-density yarn-dyed fabric weft contains pure spun yarns A, the fineness of the pure spun yarns A is 20-30D, and the superfine high-density yarn-dyed fabric weft is composed of graphene modified fibers. The preparation method is simple, the white board or the blackboard is arranged on one side of the weft running path in the water-jet loom, so that the color difference between weft and a detection background is increased, the problem of poor detection sensitivity of the photoelectric weft detecting device on black filaments is solved, the weft breakage stopping rate is improved under the condition of not reducing the speed of the loom, and the weft breakage and weft lack defective rate is reduced; the prepared superfine high-density yarn-dyed fabric has the effects of permanent static resistance and far infrared physical therapy.
Description
Technical Field
The invention belongs to the technical field of yarn-dyed fabrics, and relates to a superfine high-density yarn-dyed fabric containing graphene modified fibers and a preparation method thereof.
Background
The yarn-dyed fabric is one of the traditional dominant industries in the cotton textile industry, has various varieties and stable pattern and color, and is an important raw material for shirts, coats and downstream industries. Aiming at the characteristics of long production process, multiple equipment, various varieties and high requirements of yarn-dyed fabrics, at present, quality problems exist in the production process of the yarn-dyed fabrics, for example, the quality problems of yarns expressed on the yarn-dyed fabrics mainly include defects of neps, yarn defects, poor joints, hairiness, foreign fibers and the like, the quality problems expressed in the production process include more warping broken ends, oil yarns, broken yarns, wrong counts and the like, and sizing broken ends, weaving broken ends and the like exist on weaving fabrics, so how to control the quality of the yarn-dyed fabrics becomes a long-term research of enterprises and a problem of improving the core competitiveness.
The superfine high-density yarn-dyed fabric has the characteristics of wind resistance, velvet resistance, light weight, thinness, softness and the like, and is widely used by people, however, when some modified polymer fibers (such as graphene modified fibers or carbon fibers and the like) with special functions are used for preparing fabrics, the phenomena of weft breakage and weft lack easily occur in the weaving process due to low strength of thin yarns and high tension of high-density woven fabrics, and the weaving machine with the photoelectric weft feeler in the prior art is lower in sensitivity to the yarns with weft breakage and weft lack, so that the defective rate is higher, and the production difficulty is high.
In the prior art, conventional chemical fibers are usually used as warp yarns and weft yarns to prepare yarn-dyed fabric, but the fibers have serious static electricity due to extremely high resistance, have no shielding to harmful radiation, and have no far infrared physiotherapy and antibacterial effects. At present, in order to prepare fabrics with functions of static resistance, far infrared and the like, the fabrics are mostly prepared by adding auxiliary agents and carrying out after-treatment, but the fabrics prepared by the method have poor washing resistance effect, and in addition, metal wires are added in the raw materials to avoid static electricity generation, but the prepared fabrics have hard hand feeling and poor clothing effect, so that the further application of the fabrics is limited.
Therefore, the method for researching that the fabric has good hand feeling, the defective rate in the yarn-dyed fabric production process can be obviously reduced, and the prepared product has the permanent antistatic and far infrared physiotherapy effects has very important significance.
Disclosure of Invention
The invention aims to overcome the problems in the prior art and provide a method which has good fabric hand feeling, can obviously reduce the defective rate in the production process of yarn-dyed fabric and can make products with permanent antistatic and far infrared physiotherapy effects. According to the invention, the superfine high-density yarn-dyed fabric is prepared by adopting the graphene modified fiber filaments, so that the fabric hand feeling is obviously improved, the fabric has the functions of permanent static electricity prevention, far infrared physiotherapy and the like, and the white board or the blackboard is arranged on one side of the weft running path in the water jet loom in the preparation process, so that the color difference between weft yarns and a detection background is increased, the detection sensitivity of the photoelectric weft detecting device is improved, the weft breakage and stopping rate is greatly improved under the condition of not reducing the speed of the loom, and the weft breakage and weft lack defective rate is reduced.
In order to achieve the purpose, the invention adopts the following technical scheme:
the superfine high-density yarn-dyed fabric containing the graphene modified fibers comprises pure spun yarns A, wherein the fineness of the pure spun yarns A is 20-30D, and the pure spun yarns A are composed of the graphene modified fibers. In the prior art, common yarns with the fineness of 20-30D have high strength, broken weft detection is not generally needed in the production process, in order to solve the problems that the existing superfine high-density yarn-dyed fabric has poor static resistance and does not have the functions of far infrared and the like, the superfine high-density yarn-dyed fabric is prepared by selecting the graphene modified fibers, but the strength difference of the graphene modified fibers with the fineness of 20-30D is easy to cause broken weft and lack weft, in addition, the fiber color is darker, and the sensitivity of the existing broken weft detection device to black filaments is often poorer, so that the defective percentage is easily higher in the weaving process, the blank is arranged in a water jet loom in the weaving process, the color difference between the weft yarns composed of the graphene modified fibers and a detection background is increased, the detection sensitivity is improved, and the use of the weft yarns composed of the graphene modified fibers for preparing the superfine high-density yarn-dyed fabric is possible, and can be mass produced.
As a preferred technical scheme:
according to the superfine high-density yarn-dyed fabric containing the graphene modified fibers, the electrostatic half-life period of the superfine high-density yarn-dyed fabric before and after 10 times of washing is less than 2s, the far infrared emissivity is greater than 0.83, and the temperature rise of far infrared irradiation is greater than or equal to 1.35 ℃. The static half-life period of the fabric woven by the common chemical fiber is generally more than 30 seconds, the far infrared emissivity is less than 0.2, and the far infrared irradiation temperature rise is less than 0.5 ℃. The superfine high-density yarn-dyed fabric prepared by the method has better antistatic performance and far infrared physiotherapy effect.
According to the superfine high-density yarn-dyed fabric containing the graphene modified fibers, the warp density of the superfine high-density yarn-dyed fabric is more than or equal to 210 pieces/inch, the weft density is more than or equal to 190 pieces/inch, the width of the door is 130-170 cm, and the gram weight is 35-45 g/m2;
The warp yarn is pure spun yarn B, and the weft yarn is pure spun yarn A and pure spun yarn B or pure spun yarn A and pure spun yarn C; if the weft yarns are all the pure spun yarns A, the cost performance is low, the market acceptance is problematic, and meanwhile, the pure spun yarns A are all black, so that the color limitation on product dyeing is high, therefore, the pure spun yarns A and B or the pure spun yarns A and C are preferably used as the weft yarns together;
the fineness of the pure spun yarn B or the pure spun yarn C is 20-25D, and the pure spun yarn B or the pure spun yarn C is composed of white unmodified fibers; the pure spun yarns A and the pure spun yarns B or the pure spun yarns A and the pure spun yarns C in the weft yarns are alternately arranged according to the quantity ratio of 1: 6-12; the quantity ratio of the two is higher than 1:12, the antibacterial antistatic far infrared effect is not good and is lower than 1:6, all indexes are not improved much, and the influence on the cost and the color is increased;
the mass content of the pure spun yarn A in the superfine high-density yarn-dyed fabric is 4.6% -10%, the mass content of the pure spun yarn A can be adjusted according to practical application, but the adjustment range is not too large, the mass content is too high, the production cost is increased easily, the dyeing performance is affected easily, the mass content is too low, and the effects of antibiosis, electricity resistance, far infrared and the like cannot be met.
According to the superfine high-density yarn-dyed fabric containing the graphene modified fibers, the white unmodified fibers are polyester fibers, nylon fibers or viscose fibers, and the breaking strength of the white unmodified fibers is 4.8-6.0 cN/dtex. The type of the white unmodified fiber of the present invention is not limited thereto, and other fibers capable of producing an ultra-fine highly-dense colored woven fabric are also applicable to the present invention.
According to the superfine high-density yarn-dyed fabric containing the graphene modified fibers, the graphene modified fibers are nylon-based graphene modified fibers, and the white unmodified fibers are nylon fibers. Because nylon is stronger than terylene, the hand feeling is better than terylene, so the invention is more preferably nylon, and the white unmodified fiber is not only limited to nylon fiber, but also can select terylene fiber or other fibers.
According to the superfine high-density yarn-dyed fabric containing the graphene modified fibers, the content of graphene in the nylon-based graphene modified fibers is 5-15 wt%, the content of graphene can be adjusted according to practical application, but the adjustment range is not too large, the high strength is rapidly reduced due to the high content, various performance effects are reduced due to the low content, and the breaking strength of the nylon-based graphene modified fibers is 2.4-2.8 cN/dtex.
According to the superfine high-density yarn-dyed fabric containing the graphene modified fiber, the nylon-based graphene modified fiber is prepared by implanting graphene components in a nylon spinning process by adopting a graphene carbon compounding method.
The invention also provides a method for preparing the superfine high-density yarn-dyed fabric containing the graphene modified fibers, which is characterized in that a water jet loom with a photoelectric weft feeler is adopted to weave warp yarns and weft yarns to prepare the superfine high-density yarn-dyed fabric, the weft yarns contain pure spun yarns A, a white board is arranged on one side of the running path of the pure spun yarns A in the water jet loom, and the white board faces to a photoelectric probe of the photoelectric weft feeler.
According to the invention, the blank board (detecting the broken ends of the weft yarns formed by the graphene modified fibers) matched with the photoelectric probe is arranged in the water jet loom, so that the photoelectric weft detecting blind area of the loom of the superfine graphene modified filament (with the fineness of 20D and black color) is solved, the weaving difficulty of the superfine high-rigidity low-strength graphene fibers in superfine high-density yarn-dyed fabric products is perfectly solved, and the application of the graphene modified fibers in superfine high-density fabrics becomes possible.
According to the method, the weft yarns are the pure spun yarn A and the pure spun yarn B or the pure spun yarn A and the pure spun yarn C, the fineness of the pure spun yarn B or the pure spun yarn C is 20-25D and both consist of white unmodified fibers, a blackboard is installed on one side of the running path of the pure spun yarn B or the pure spun yarn C in the water jet loom and faces to a photoelectric probe of the photoelectric weft detecting device, and meanwhile, the blackboard matched with the photoelectric probe (detecting broken ends of common nylon weft yarns) is installed in the water jet loom, so that the defective rate is further reduced.
According to the method, the distance between the white board or the blackboard and the corresponding photoelectric probe is 4mm, and the white board or the blackboard and the corresponding yarn are kept parallel; the hydraulic loom is opened at an angle of 80 degrees by fingers, closed at an angle of 220 degrees by fingers, opened at an angle of 100 degrees by clamps, closed at an angle of 320 degrees by clamps, and switched at an angle of 300 degrees by valves; the weaving adopts a double-beat-up weft feeding process to distinguish the colors of the pure yarn A and the pure yarn B, the beating-up speed is 550 revolutions, the stop rate of broken weft reaches more than 99.96 percent, and the defective rate of broken weft and missing weft is lower than 0.05 percent.
The invention mechanism is as follows:
because the prior art usually adopts common fibers to prepare the superfine high-density fabric, the prepared fabric can not meet the effects of fabric static resistance, far infrared and the like, further development of the fabric is limited, the graphene modified fibers have higher static resistance and far infrared effects, the problem can be solved by the fabric prepared from the graphene modified fibers, however, the breaking strength of the filaments of the graphene modified fibers is lower, yarn breakage is easy to occur in the weaving process, meanwhile, because the color of an original bottom plate arranged on one side of the running path of pure-spun yarns in the existing water-jet loom is black, when the yarns consisting of the graphene modified fibers are taken as weft yarns, the color of the yarns is darker and almost close to black, the common photoelectric weft-detecting device is insensitive to the black fibers, the weft breakage is not easy to be found in high-speed weaving (the weft breakage rate is only 81.1% on average), and further the defective rate (10-15%) is greatly improved, however, the method of reducing weft breakage by reducing the speed (200-300 revolutions) greatly increases the weaving cost and the order delivery time. The invention adopts the double beating-up and weft-feeding process, adds a white board in the space at one side of the running path of the weft containing graphene modified fibers of the water jet loom, which is opposite to the photoelectric probe of the photoelectric weft-detecting device, increases the color difference between the weft and the detection background, perfectly solves the problem of poor detection sensitivity of the black filament, meanwhile, a blackboard is added in the space at one side of the running path of the weft yarn containing the white unmodified fibers of the water-jet loom, which is opposite to the photoelectric probe of the photoelectric weft-detecting device, so that the color difference between the weft yarn and the detection background is increased, the invention distinguishes the weft yarn as the detection background containing the yarn consisting of the graphene modified fibers and the yarn consisting of the white unmodified fibers, and the two yarns do not influence each other, therefore, the method improves the weft breaking stopping rate (reaching 99.96 percent) without reducing the speed of the vehicle, and ensures that the defective rate of weft breaking and weft missing is lower than 0.05 percent.
Has the advantages that:
(1) the preparation method of the superfine high-density yarn-dyed fabric containing the graphene modified fibers is simple in process, and on the basis of the existing equipment, the white board is arranged on one side of the running path of the inner weft of the water jet loom, so that the problem of poor detection sensitivity of a photoelectric weft detecting device on black filaments in the prior art is solved, the weft breakage stopping rate is greatly improved under the condition of not reducing the speed of the loom, the weft breakage and weft missing defective rate is reduced, and the industrial production is realized;
(2) the superfine high-density yarn-dyed fabric containing the graphene modified fibers has good fabric hand feeling, has the effects of permanent static resistance and far infrared physiotherapy, and has a wide application prospect.
Drawings
FIGS. 1 and 2 are schematic diagrams showing the relationship between the relative positions of a white board and a blackboard, a photoelectric weft feeler and weft yarns, which are added in a water jet loom, according to the present invention;
the device comprises a photoelectric probe 1, a yarn 2 consisting of nylon-based graphene modified fibers, a white board 3, a yarn 4 consisting of nylon fibers and a blackboard 5.
Detailed Description
The invention will be further illustrated with reference to specific embodiments. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.
Example 1
The preparation method of the superfine high-density yarn-dyed fabric containing the graphene modified fibers weaves warp yarns and weft yarns by adopting a water jet loom with a photoelectric weft feeler and a double-beating-up weft feeding process to prepare the superfine high-density yarn-dyed fabric.
The warp yarn is pure yarn B, the pure yarn B is composed of white nylon fibers, the breaking strength of the nylon fibers is 4.8cN/dtex, and the fineness of the pure yarn B is 20D;
the pure spun yarns A and the pure spun yarns B in the weft yarns are alternately arranged according to the quantity ratio of 1:6, the pure spun yarns A are composed of nylon-based graphene modified fibers, the nylon-based graphene modified fibers are prepared by implanting graphene components in a nylon spinning process by adopting a ene-carbon composite method, the content of graphene in the nylon-based graphene modified fibers is 5wt%, the breaking strength of the nylon-based graphene modified fibers is 2.6cN/dtex, and the fineness of the pure spun yarns A is 20D;
a white board 3 is arranged on one side of a running path of the nylon-based graphene modified fiber in the water jet loom, the white board 3 faces a photoelectric probe 1 of the photoelectric weft feeler, the distance between the photoelectric probe 1 and the nylon-based graphene modified fiber 2 is 2mm, and the distance between the nylon-based graphene modified fiber 2 and the white board 3 is 2mm, as shown in fig. 1; a blackboard 5 is arranged on one side of a running path of the nylon fiber in the water-jet loom, the blackboard 5 faces a photoelectric probe 1 of the photoelectric weft feeler, the distance between the photoelectric probe 1 and the nylon fiber 4 is 2mm, and the distance between the nylon fiber 4 and the blackboard 5 is 2mm, as shown in figure 2; the water jet loom is opened at an angle of 80 degrees by fingers, closed at an angle of 220 degrees by fingers, opened at an angle of 100 degrees by clamps, closed at an angle of 320 degrees by clamps, and switched at an angle of 300 degrees by valves.
The weaving beating-up speed is 550 revolutions, the broken weft stop rate is 99.96, and the broken weft and miss defective rate is 0.05%.
The nylon-based graphene modified fiber in the superfine high-density yarn-dyed fabric containing the graphene modified fiber prepared by the invention has the mass content of 4.6%, the warp density of 218 pieces/inch, the weft density of 190 pieces/inch, the width of a door of 150cm and the gram weight of 40g/m2. The superfine high-density yarn-dyed fabric containing the graphene modified fibers has the electrostatic half-life period of 1.5s before and after 10 times of washing, the far infrared emissivity of 0.88 and the far infrared irradiation temperature rise of 1.4 ℃.
Example 2
The preparation method of the superfine high-density yarn-dyed fabric containing the graphene modified fibers is basically the same as that in the embodiment 1, namely, a water jet loom with a photoelectric weft feeler is adopted to weave warp yarns and weft yarns by adopting a double beating-up weft feeding process to prepare the superfine high-density yarn-dyed fabric. The difference lies in that:
the warp yarn is pure yarn B, the pure yarn B is composed of white polyester fibers, the breaking strength of the polyester fibers is 6.0cN/dtex, and the fineness of the pure yarn B is 20D;
the weft yarns are formed by alternately arranging pure spun yarns A and pure spun yarns C according to the quantity ratio of 1:8, the fineness of the pure spun yarns A is 25D, the pure spun yarns A are composed of nylon-based graphene modified fibers, the breaking strength of the nylon-based graphene modified fibers is 2.8cN/dtex, and the content of graphene in the nylon-based graphene modified fibers is 10 wt%; the pure yarn C is composed of white nylon fibers, the breaking strength of the nylon fibers is 4.8cN/dtex, and the fineness of the pure yarn C is 20D.
The weaving beating-up speed is 550 revolutions, the weft breaking stopping rate is 99.98 percent, and the defective rate of weft breaking and weft missing is 0.03 percent.
The mass content of the nylon-based graphene modified fibers in the prepared superfine high-density yarn-dyed fabric containing the graphene modified fibers is 5.5%, the density of warp yarns is 220 per inch, the density of weft yarns is 215 per inch, the width of a door is 170cm, and the gram weight is 35g/m2. The superfine high-density yarn-dyed fabric containing the graphene modified fibers has the electrostatic half-life period of 1.2s before and after 10 times of washing, the far infrared emissivity of 0.91 and the far infrared irradiation temperature rise of 1.4 ℃.
Example 3
The preparation method of the superfine high-density yarn-dyed fabric containing the graphene modified fibers is basically the same as that in the embodiment 1, namely, a water jet loom with a photoelectric weft feeler is adopted to weave warp yarns and weft yarns by adopting a double beating-up weft feeding process to prepare the superfine high-density yarn-dyed fabric. The difference lies in that:
the warp yarn is pure spun yarn B and consists of white polyester fiber, the breaking strength of the polyester fiber is 6.0cN/dtex, and the fineness of the pure spun yarn B is 20D;
the pure spun yarns A and the pure spun yarns C in the weft yarns are alternately arranged according to the quantity ratio of 1:12, the fineness of the pure spun yarns A is 30D, the pure spun yarns A are composed of nylon-based graphene modified fibers, the breaking strength of the nylon-based graphene modified fibers is 2.4cN/dtex, and the content of graphene in the nylon-based graphene modified fibers is 15 wt%; the pure yarn C consists of white viscose, the breaking strength of the viscose is 5.1cN/dtex, and the fineness of the pure yarn C is 25D.
The weaving beating-up speed is 550 revolutions, the weft breakage stopping rate is 99.97 percent, and the defective rate of weft breakage and weft loss is 0.02 percent.
Nylon-based graphene modified fiber in prepared superfine high-density yarn-dyed fabric containing graphene modified fiberThe fiber content is 10%, the warp density is 210 pieces/inch, the weft density is 190 pieces/inch, the width is 130cm, and the gram weight is 45g/m2. The superfine high-density yarn-dyed fabric containing the graphene modified fibers has the electrostatic half-life period of 1.0s before and after 10 times of washing, the far infrared emissivity of 0.84 and the far infrared irradiation temperature rise of 1.35 ℃.
The test proves that the preparation method is simple, the color difference between weft yarns and a detection background is increased by arranging the white board or the blackboard at one side of the weft yarn running path in the water jet loom, the problem of poor detection sensitivity of the photoelectric weft yarn detecting device on black filaments is solved, the weft breakage stopping rate is greatly improved under the condition of not reducing the speed of the loom, the weft breakage and weft lack defective rate is reduced, the industrial production is realized, and the prepared superfine high-density yarn-dyed fabric also has the effects of permanent static electricity prevention and far infrared physiotherapy and has great application prospect.
Claims (7)
1. The preparation method of the superfine high-density yarn-dyed fabric containing the graphene modified fibers is characterized by comprising the following steps of: weaving warp yarns and weft yarns by adopting a water jet loom with a photoelectric weft feeling device to prepare superfine high-density yarn-dyed fabric, wherein the weft yarns are pure yarn A and pure yarn B or pure yarn A and pure yarn C, a white board is arranged on one side of a running path of the pure yarn A in the water jet loom, the white board faces a photoelectric probe of the photoelectric weft feeling device, the fineness of the pure yarn A is 20-30D, and the pure yarn A is composed of nylon-based graphene modified fibers; a blackboard is arranged on one side of the running path of the pure spinning yarn B or the pure spinning yarn C in the water-jet loom, and faces to a photoelectric probe of the photoelectric weft feeler;
the color of the pure spun yarn A is black;
the pure spun yarn B or the pure spun yarn C is composed of white unmodified fibers;
the distance between the white board or the blackboard and the corresponding photoelectric probe is 4 mm;
the pure spun yarns A and the pure spun yarns B or the pure spun yarns A and the pure spun yarns C in the weft yarns are alternately arranged according to the quantity ratio of 1: 6-12;
the content of graphene in the nylon-based graphene modified fiber is 5-15 wt%, and the breaking strength of the nylon-based graphene modified fiber is 2.4-2.8 cN/dtex;
the weaving adopts a double-beating-up and weft-feeding process, the beating-up speed is 550 revolutions, the weft-breaking stopping rate reaches more than 99.96 percent, and the defective rate of weft-breaking and weft-missing is lower than 0.05 percent.
2. The method for preparing the superfine high-density yarn-dyed fabric containing the graphene modified fibers according to claim 1, wherein the water jet loom is opened at an angle of 80 degrees, closed at an angle of 220 degrees, opened at an angle of 100 degrees, closed at an angle of 320 degrees, and switched at an angle of 300 degrees.
3. The method for preparing the superfine high-density yarn-dyed fabric containing the graphene modified fibers according to claim 1, wherein the electrostatic half-life period of the superfine high-density yarn-dyed fabric before and after 10 times of washing is less than 2s, the far infrared emissivity is greater than 0.83, and the temperature rise of far infrared irradiation is greater than or equal to 1.35 ℃.
4. The preparation method of the superfine high-density yarn-dyed fabric containing the graphene modified fibers according to claim 1, wherein the warp density of the superfine high-density yarn-dyed fabric is more than or equal to 210 pieces/inch, the weft density is more than or equal to 190 pieces/inch, the width of the door is 130-170 cm, and the gram weight is 35-45 g/m2;
The warp yarn is pure spinning yarn B;
the fineness of the pure spun yarn B or the pure spun yarn C is 20-25D;
the mass content of the pure spinning yarn A in the superfine high-density yarn-dyed fabric is 4.6-10%.
5. The preparation method of the superfine high-density yarn-dyed fabric containing the graphene modified fibers according to claim 4, wherein the white unmodified fibers are polyester fibers, nylon fibers or viscose fibers, and the breaking strength of the white unmodified fibers is 4.8-6.0 cN/dtex.
6. The method for preparing the superfine high-density yarn-dyed fabric containing the graphene modified fibers according to claim 5, wherein the white unmodified fibers are nylon fibers.
7. The method for preparing the superfine high-density yarn-dyed fabric containing the graphene-modified fiber according to claim 1, wherein the nylon-based graphene-modified fiber is prepared by implanting graphene components in a nylon spinning process by using an olefin-carbon compounding method.
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| CN201614448U (en) * | 2009-12-17 | 2010-10-27 | 江苏万工科技集团有限公司 | Weft detection device for air-jet looms |
| CN205775081U (en) * | 2016-02-26 | 2016-12-07 | 济南圣泉集团股份有限公司 | A kind of composite material |
| CN106884219B (en) * | 2017-03-07 | 2019-07-16 | 杭州高烯科技有限公司 | Graphene/nylon 6 fabric and preparation method thereof with permanent anti-ultraviolet function |
| CN107119372A (en) * | 2017-06-12 | 2017-09-01 | 南通强生石墨烯科技有限公司 | Efficiently permanent graphene uvioresistant fabric and preparation method thereof |
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