CN214449107U - Humidity-sensitive color-changing heating cloth and textile thereof - Google Patents
Humidity-sensitive color-changing heating cloth and textile thereof Download PDFInfo
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- CN214449107U CN214449107U CN202023217338.2U CN202023217338U CN214449107U CN 214449107 U CN214449107 U CN 214449107U CN 202023217338 U CN202023217338 U CN 202023217338U CN 214449107 U CN214449107 U CN 214449107U
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Abstract
The utility model discloses a moisture sensitive cloth that generates heat that discolours, including the layer next to the shin that sets gradually, waterproof ventilative layer, moisture absorption generate heat the layer, the moisture sensitive discoloration layer, be connected through the elasticity yarn between the adjacent layer, the layer next to the shin is formed for cotton fiber, coffee charcoal dacron and kendir fibre blending, and waterproof ventilative layer is nylon superfine fiber layer, and the moisture absorption generates heat the layer and generates heat fibre and cotton fiber blending for the moisture absorption and form, and the moisture sensitive discoloration layer is moisture sensitive discoloration fibre, dacron fibre and admire the sial fibre blending and forms. The utility model discloses still disclose a fabrics. The utility model discloses a cloth that generates heat is discolourd to humidity sensitive adopts unique fibre and structural grouping, has the response simultaneously and discolours, the moisture absorption generates heat, prevents the function of rainwater contact skin, antibiotic, cold-proof, health care. By adopting various plant source fibers and the mutual matching and synergistic effect of all layer groups, the finally obtained humidity-sensitive color-changing heating cloth is comfortable, healthy and environment-friendly.
Description
Technical Field
The utility model relates to the technical field of cloth, especially, relate to a humidity sensitive color-changing heating cloth.
Background
When a user encounters sudden heavy rain at night, the rain water is not easy to fall on the body in the road overtaking process, the rain water can penetrate through the common fabric and contact with the skin, the cold rain water can be cool, and the user is easy to catch a cold if the time for changing clothes is long. In addition, in the process of hurrying to drive a road, people and vehicles are not noticed easily to be unexpected due to hurry, and the common fabric has no warning function.
In view of this, the market needs a fabric which can prevent rainwater from contacting the skin, can generate heat in rainy days, and has a warning function.
SUMMERY OF THE UTILITY MODEL
In view of this, the utility model aims at providing a prevent rainwater contact skin, can generate heat, have warning function's cloth in rainy day.
The utility model provides a moisture sensitive cloth that generates heat that discolours, including the layer next to the shin, waterproof ventilative layer, moisture absorption layer, the moisture sensitive discoloration layer that sets gradually, just the layer next to the shin waterproof ventilative layer the moisture absorption generate heat the layer with be connected through the elasticity yarn between the adjacent layer of moisture sensitive discoloration layer, the layer next to the shin is cotton fiber, coffee charcoal dacron and apocynum venetum fibre blending and forms, waterproof ventilative layer is nylon microfiber layer, the moisture absorption generates heat the layer and generates heat fibre and cotton fiber blending and form for the moisture absorption, the moisture sensitive discoloration layer is moisture sensitive discoloration fibre, dacron fibre and admire the sial fibre blending and forms.
Preferably, the core layer of the elastic yarn is made of copper ammonia fiber, and the surface layer of the elastic yarn is made of nylon.
Preferably, the moisture absorption exothermic fibers are selected from one or more of cuprammonium fibers, crosslinked acrylate fibers, polypropylene modified acrylic fibers, phase change energy storage fibers, exothermic acrylic fibers, EKS fibers, softwarum fibers, thermogrear fibers, N38 fibers, warmsensor fibers, RENAISS fibers and MOIS CARE high-temperature absorption exothermic fibers.
Preferably, the mass part ratio of the moisture absorption heating fibers to the cotton fibers in the moisture absorption heating layer is (1-6): 10.
Preferably, the moisture-sensitive color-changing fibers, the polyester fibers and the Museille fibers in the moisture-sensitive color-changing layer are in a mass ratio of (3-4) to (5) (1-2).
Preferably, the moisture-sensitive color-changing fiber changes color in an environment with a humidity of more than 40%.
The utility model also provides a fabrics uses according to above-mentioned arbitrary technical scheme humidity sensitive cloth that generates heat that discolours make and form.
The utility model has the advantages that:
the humidity-sensitive color-changing heating cloth adopts unique fiber and structure combination, and the humidity-sensitive color-changing fiber has unique humidity-sensitive color-changing function and reminds pedestrians and drivers to avoid the humidity-sensitive color-changing cloth; the moisture absorption and heating fibers can absorb moisture and generate heat, so that a human body feels warm; the waterproof breathable layer prevents rainwater from contacting the skin and can allow heat to enter the skin contact layer; the coffee carbon terylene, the apocynum venetum fiber and the mulcel fiber have the functions of bacteriostasis and sterilization, can prevent the breeding of bacteria, also have the function of releasing far infrared rays or negative ions and have the health care function; adjacent two layers among the close-fitting layer, the waterproof breathable layer, the moisture absorption heating layer and the moisture sensitive color changing layer are connected through elastic yarns, so that the large displacement among all layers of the cloth is avoided, the strength of the cloth is improved, the whole cloth becomes a whole, and the elastic yarns enable the cloth to be close-fitting; the moisture-sensitive color-changing heating cloth has the functions of sensing color change, absorbing moisture, heating, preventing rainwater from contacting skin, resisting bacteria, keeping warm and protecting health. Meanwhile, various plant source fibers are adopted, and the layer groups are matched and cooperated with each other, so that the finally obtained humidity-sensitive color-changing heating cloth is comfortable, healthy and environment-friendly.
Drawings
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention.
Fig. 1 is a schematic structural view of a humidity-sensitive color-changing heating cloth of the present invention;
description of reference numerals:
1-next-to-skin layer, 2-waterproof breathable layer, 3-hygroscopic heating layer, 4-moisture-sensitive color-changing layer and 5-elastic yarn.
Detailed Description
In order to further understand the present invention, the following description will be made in conjunction with the drawings in the embodiments of the present invention, and the technical solution in the embodiments of the present invention is clearly and completely described, and obviously, the described embodiments are only a part of the embodiments of the present invention, but not all embodiments, and based on the embodiments in the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1, the utility model provides a moisture sensitive cloth that generates heat that discolours, including the layer 1 next to the shin that sets gradually, waterproof ventilative layer 2, the moisture absorption generates heat layer 3, moisture sensitive discoloration layer 4, and layer 1 next to the shin, waterproof ventilative layer 2, the moisture absorption generates heat and is connected through stretch yarn 5 between layer 3 and the adjacent each layer of moisture sensitive discoloration layer 4, layer 1 next to the shin is cotton fiber, coffee charcoal dacron and apocynum venetum fibre blending form, waterproof ventilative layer 2 is nylon microfiber layer, moisture absorption generates heat layer 3 and forms for moisture absorption heating fiber and cotton fiber blending, moisture sensitive discoloration layer 4 is moisture sensitive discoloration fiber, dacron fiber and the blending of admire's fibre form.
Furthermore, the core layer of the elastic yarn 5 is made of copper ammonia fiber, and the surface layer is made of nylon.
The copper ammonia fiber is made up by using high-grade wood pulp and cotton linter pulp as raw material, dissolving them in copper ammonia solution of copper complex salt solution formed from copper tetraammine hydroxide to obtain spinning solution, mixing, filtering and defoaming, and spinning. The water method is to spin on a funnel by taking water as a coagulating bath. Then the cellulose is completely regenerated by acid bath, and then the copper ammonia rayon is obtained by water washing, oiling and drying. According to experiments, the copper ammonia fiber lining cloth can rapidly absorb moisture in air, can keep 30% of moisture at most, and can rapidly volatilize the moisture into the air again, so that the feeling of stuffiness and wetness cannot be generated, and the copper ammonia fiber lining cloth can be called as a respiratory fiber.
The chinlon has good comprehensive properties including mechanical property, heat resistance, wear resistance, chemical resistance and self-lubricity, and has low friction coefficient, certain flame retardance and easy processing. The most outstanding advantage is that the wear resistance is higher than that of all other fibers, 10 times higher than that of cotton and 20 times higher than that of wool, and when the fiber is stretched to 3-6%, the elastic recovery rate can reach 100%; can withstand ten thousand times of bending without breaking. The strength of the fiber is 1-2 times higher than that of cotton, 4-5 times higher than that of wool, and 3 times higher than that of viscose fiber.
The sandwich layer of the elastic yarn 5 is made of copper ammonia fiber, the surface layer is made of nylon, the advantages of the copper ammonia fiber and the nylon are combined, moisture absorption and moisture removal are achieved, the mechanical property, the wear resistance and the elasticity are good, the adjacent layers are connected through the elastic yarn, large displacement between the layers of the cloth is avoided, the strength of the cloth is improved, the whole cloth is made to be a whole, and the elastic yarn enables the cloth to be close to the skin.
The apocynum venetum fiber is a natural far infrared emission material, can emit far infrared light waves of 8-15 micrometers, can permeate into skin and subcutaneous tissues, generates a resonance absorption effect with water molecules in tissue cells, and can improve human microcirculation. The far infrared ray enables the cloth to have the function of keeping warm, the warmth retention is 2 times of that of the full cotton cloth below 8 ℃, the air permeability is 2.5 times of that of the pure cotton fabric above 21 ℃, and the cloth is characterized by being warm in winter and cool in summer in solitary. The apocynum venetum fiber has the softness of cotton, the luster of silk and the refreshing property of hemp. The apocynum venetum fiber has good antibacterial activity, has obvious inhibition effect on candida albicans, staphylococcus aureus, escherichia coli, pseudomonas aeruginosa and the like, and has better prevention and treatment effect on skin diseases, bedsore and eczema.
The coffee carbon modified terylene (hereinafter referred to as coffee carbon terylene) is a microporous structure prepared by blending and spinning ultrafine coffee carbon powder particles and polyester, and has special functions of heat storage and preservation, bacteriostasis and deodorization, emission of negative ions, ultraviolet resistance and the like. The coffee carbon terylene is green and environment-friendly in the production process, waste coffee residues are utilized and calcined at the temperature of more than 1000 ℃ to ensure that crystals of the coffee residues are in the optimal state with pores, the latest nanotechnology is applied to micronization and grinding into 100-plus-300 nm nanometer powder, and the powder is added into the terylene fiber to produce the coffee carbon terylene fiber.
The embodiment forms cotton fiber, coffee carbon dacron and apocynum venetum fibre blending as next to the shin layer 1, has comfortable feeling, is fit for pressing close to skin, and can go the peculiar smell, "warm in winter and cool in summer", antibacterial, emission far infrared effect, is of value to health.
In the embodiment, the mass ratio of the cotton fibers, the coffee carbon terylene and the apocynum venetum fibers is 3 (5-10) to 5-10. For example, the weight ratio of the cotton fiber, the coffee carbon terylene and the apocynum venetum fiber is (3:6:10), (3:6:8), (3:10:5), (3:8:8), (3:9:9) and the like.
In this embodiment, the blending manner of the cotton fiber, the coffee carbon polyester fiber and the apocynum fiber is not limited, for example, the warp yarn is the cotton fiber, and the weft yarn is the blending of the coffee carbon polyester fiber and the apocynum fiber; for example, the warp yarns are cotton fibers and coffee carbon terylene, and the weft yarns are apocynum venetum fibers for blending; for example, the warp yarns are apocynum fibers, and the weft yarns are coffee carbon terylene and cotton fibers for blending and the like.
The waterproof breathable layer 2 of the embodiment is a nylon superfine fiber layer, and has good waterproof breathability and good hand feeling. The diameter of the nylon fiber in the nylon superfine fiber layer is 2-10 microns.
The moisture absorption exothermic fiber of the embodiment is selected from one or more of cuprammonium fiber, cross-linked acrylate fiber, polypropylene modified acrylic fiber, phase change energy storage fiber, exothermic acrylic fiber, EKS fiber, softwarm fiber, thermogrear fiber, N38 fiber, warmsensor fiber, RENAISS fiber and MOIS CARE high temperature absorption exothermic fiber.
The phase change energy storage fiber of the embodiment can be PVA/paraffin phase change energy storage fiber or phase change energy storage fiber produced by Shandong Hailongkungji. The phase change energy storage fiber of the Syngnathus company has the functions of heat storage and heat release bidirectional temperature regulation, and can be mutually converted into solid and liquid states in the temperature change, thereby achieving the effects of heat absorption and heat release, making corresponding response on skin to the change of the external temperature, and having the buffer effect on the temperature change. The fiber has excellent heat insulating performance. The fiber has the functions of high heat storage and high heat release, and the heat storage capacity of the fiber reaches more than 10J/g; has excellent skin-friendly property, moisture absorption and air permeability, and moisture absorption and moisture discharge property.
The EKS fiber is a brand new material which can generate heat automatically and warm the body, is a synthetic fiber developed by Toyo textile (Japan) company, introduces amino and carboxyl hydrophilic groups onto polyacrylic acid molecules through a crosslinking reaction, belongs to a chemical synthetic heating material, and has the characteristics of extremely strong hygroscopicity and moisture desorption, can absorb water or water vapor into the fiber and simultaneously convert the water or the water vapor into heat (commonly called as 'adsorption heat'), wherein the moisture absorption capacity of the fiber is 3.5 times that of cotton, and the moisture absorption and heat productivity of the fiber is about 2 duds of wool and down.
MOIS CARE high moisture absorption exothermic fiber is a high moisture absorption exothermic fiber developed by Dongyo textile company. The fiber can continuously absorb and release moisture for a long time corresponding to the change of environmental conditions, and has the outstanding characteristic of emitting heat while absorbing moisture. The MOIS CARE high-moisture-absorption heating fiber has high moisture absorption which is about 7 times higher than that of cotton and nylon, and can repeatedly carry out moisture absorption and release (breathing) type circulation for a long time according to the environment, so that adsorption heat is generated while moisture absorption is carried out. The MOIS CARE high-moisture-absorption heating fiber is characterized in that: 1. possesses strong hygroscopicity: the moisture absorption performance of MOIS CARE is 2.5 times of that of wool and more than 5 times of that of cotton. 2. Moisture absorption and desorption: the MOIS CARE has very high moisture absorption and release performance, can circularly absorb and release moisture along with the change of air, and can be used as a moisture control material. 3. Moisture absorption heat generating property: the moisture is absorbed in the fiber and simultaneously generates heat, commonly called as 'adsorption heat', the average adsorption heat per gram of dry fiber is larger, and the MOIS CARE moisture absorption and heat generation performance is more than 3 times of that of wool and more than 4 times of that of down. 4. Deodorization: the ammonia gas with 690ppm of about 500mL can be eliminated to zero in 10 minutes, the odor processability caused by the salt base property of the ammonia gas and amine can be eliminated, and the fiber can be processed by common fiber processing machinery. 5. Anti-mould performance: the MOIS CARE high moisture absorption heating fiber has strong mould inhibiting performance.
The RENAISS fiber is a sea-island structure composed of acrylic fibers with a drainage function and hydrophilic acetate fibers which are processed by special chemical processing, moisture can be absorbed by the hydrophilic acetate fibers which are processed by the special chemical processing, and therefore, the RENAISS fiber generates heat and is a fiber with excellent heat preservation.
The Softwarm fiber is developed by Dongli corporation, is a fiber capable of heating and keeping warm and has soft touch, is compounded by superfine denier anti-pilling acrylic fiber and artificial viscose, and belongs to a physical synthetic heating material.
Thermogear fiber is a moisture absorption heating fiber developed by Japan, is compounded by superfine denier anti-pilling acrylic fiber and copper ammonia wire, and belongs to a physical synthesis heating material.
The N38 fiber is developed by Toyo textile, has good hygroscopicity, is prepared by using polyacrylic acid as a raw material and performing super-hydrophilization and high crosslinking on macromolecules by a modification technology, belongs to a chemically synthesized heating material, and has antibacterial, deodorizing and mildew-proof properties.
Furthermore, the mass part ratio of the moisture absorption heating fibers to the cotton fibers in the moisture absorption heating layer 3 is (1-6): 10.
By adopting the technical scheme, when the cloth meets rainwater, the cloth can generate heat, and cold rainwater is prevented from invading the body to cause the human body to catch a cold.
Further, the mass part ratio of the humidity-sensitive color-changing fibers, the polyester fibers and the Museille fibers in the humidity-sensitive color-changing layer 4 is (3-4): 5 (1-2).
In the embodiment, the weight ratio of the moisture-sensitive allochroic fibers, the polyester fibers and the Museille fibers is (3-4): 5 (1-2). For example, the moisture-sensitive color-changing fiber, the polyester fiber and the Museille fiber have the mass ratio of (3:5:1), (3:5:2), (4:5:1) and (4:5: 2).
In this embodiment, the blending manner of the humidity-sensitive color-changing fiber, the polyester fiber and the mosel fiber is not limited, for example, the warp is the humidity-sensitive color-changing fiber, and the weft is the blending of the polyester fiber and the mosel fiber; for example, the warp yarns are polyester fibers, and the weft yarns are blended by the humidity-sensitive allochroic fibers and the Mussel fibers; for example, the warp yarns are the humidity-sensitive allochroic fiber and the Museille fiber, and the weft yarns are polyester fiber for blending, and the like.
Raw materials of Mussel (mulcel) fiber are from natural bamboo and cotton, the excellent quality of cotton and the characteristics that the bamboo is free from insects, moths and corrosion in the growth process are fully considered in research and development, the bamboo has natural antibacterial and bacteriostatic substances, various impurities in the two raw materials are removed, and the two raw materials are jointly subjected to depolymerization and purification to extract the bamboo-cotton composite fiber prepared from cellulose. The Musaier fiber integrates the excellent performances of bamboo and cotton, and well makes up the defects of pure cotton and pure bamboo fiber. Has the characteristics of comfort, good hand feeling, easy dyeing and the like of natural fiber cotton, and has the advantages of static resistance, outstanding moisture absorption and air permeability, unique natural antibacterial and mite-inhibiting, odor-resistant and moth-proof, ultraviolet-resistant effects and natural health. The implementation adopts a cellulose fiber new product Musailel (mulcel) bamboo cotton composite fiber independently developed by Jinying textile Limited company in Zhang hong Kong City, which is detected by authoritative institutions of the national cotton textile product quality supervision and inspection center and the test center of China textile science research institute, and has an antibacterial value of 5.7 and a bactericidal value of 2.7 for staphylococcus aureus; the bacteriostasis value to the coliform bacteria reaches 5.9, and the sterilization value is 2.9; the bacteriostasis value of the antibacterial agent to candida albicans reaches 5.4, and the sterilization value is 2.6; the mite-expelling rate is as high as 95.32%.
The humidity-sensitive color-changing fiber is prepared from humidity-sensitive color-changing fiber developed by Donghua university, the preparation method of the humidity-sensitive color-changing fiber is shown in Chinese patent CN104910566B, and the color of the fiber is changed from purple to pink under the environment that the humidity is more than 40%. The moisture-sensitive color-changing fiber has a similar microcapsule structure and has the advantages of good heat resistance and stable performance.
In the embodiment, the humidity-sensitive color-changing layer 4 is formed by blending the humidity-sensitive color-changing fiber, the polyester fiber and the Museille fiber, has the characteristics of good heat resistance, good color-changing stability and good hand feeling, has the functions of bacteriostasis and mite prevention, and changes the color of the fiber from purple to pink under the environment with the humidity of more than 40 percent. The humidity-sensitive color-changing layer 4 is positioned on the outermost layer of the whole cloth, so that the humidity of the cloth can be sensed conveniently according to the color of the cloth.
The utility model also provides a fabrics uses the humidity sensitive cloth that generates heat that discolours according to above-mentioned arbitrary technical scheme to make and form.
The utility model discloses a theory of operation: the user meets sudden heavy rain at night, and the in-process of overtaking a road is not skilful the rainwater and drenches on one's body, and the rainwater at first gets into humidity-sensitive discoloration layer 4, and humidity is changed into pink by purple among the cloth when exceeding 40% RH, and overtaking a road in-process pedestrian and driver see the pink of making eye, promptly dodge, also remind oneself rain ratio or time of drenching a rain simultaneously greatly. The rainwater further gets into moisture absorption layer 3 that generates heat, and moisture absorption fibre that generates heat absorbs the rainwater and produces the heat. Because the temperature of rain is generally reduced compared with that before rain, the heat generated by the moisture-absorbing heating fibers can penetrate through the waterproof breathable layer 2 and the skin layer 1 to keep the body warm. The third layer is waterproof ventilative layer 2, owing to possess waterproof function, the rainwater can not get into waterproof ventilative layer 2, but the heat that the layer 3 produced of moisture absorption generates heat can pass waterproof ventilative layer 2, further gets into layer 1 next to the shin. The coffee carbon terylene and the apocynum venetum fiber in the layer next to the skin 1 and the Mutecell fiber in the moisture-sensitive color changing layer 4 have the antibacterial and bacteriostatic effects, so that the cloth is kept sanitary and is beneficial to health. In addition, the utility model also has the functions of generating far infrared rays, anions and preventing mites, and the utility model discloses a cloth possesses the functions of humidity-sensitive color change and moisture absorption and heating, and promotes human health.
The humidity-sensitive color-changing heating cloth adopts unique fiber and structure combination, and the humidity-sensitive color-changing fiber has unique humidity-sensitive color-changing function and reminds pedestrians and drivers to avoid the humidity-sensitive color-changing cloth; the moisture absorption and heating fibers can absorb moisture and generate heat, so that a human body feels warm; the waterproof breathable layer prevents rainwater from contacting the skin and can allow heat to enter the skin contact layer; the coffee carbon terylene, the apocynum venetum fiber and the mulcel fiber have the functions of bacteriostasis and sterilization, can prevent the breeding of bacteria, also have the function of releasing far infrared rays or negative ions and have the health care function; adjacent two layers among the close-fitting layer, the waterproof breathable layer, the moisture absorption heating layer and the moisture sensitive color changing layer are connected through elastic yarns, so that the large displacement among all layers of the cloth is avoided, the strength of the cloth is improved, the whole cloth becomes a whole, and the elastic yarns enable the cloth to be close-fitting; the moisture-sensitive color-changing heating cloth has the functions of sensing color change, absorbing moisture, heating, preventing rainwater from contacting skin, resisting bacteria, keeping warm and protecting health. Meanwhile, various plant source fibers are adopted, and the layer groups are matched and cooperated with each other, so that the finally obtained humidity-sensitive color-changing heating cloth is comfortable, healthy and environment-friendly.
The humidity-sensitive color-changing heating cloth of the utility model can be used for textiles such as coats, T-shirts, leggings and the like.
It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.
Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.
Claims (5)
1. The utility model provides a moisture sensitive cloth that generates heat that discolours, its characterized in that, is including the layer next to the shin, waterproof ventilative layer, the moisture absorption layer that generates heat, the moisture sensitive layer that changes color that sets gradually, just the layer next to the shin waterproof ventilative layer the moisture absorption generate heat the layer with be connected through the elasticity yarn between the adjacent each layer of moisture sensitive layer that changes color, the layer next to the shin is cotton fiber, coffee charcoal dacron and apocynum venetum fibre blending and forms, waterproof ventilative layer is nylon microfiber layer, the moisture absorption layer that generates heat is the moisture absorption and generates heat fibre and cotton fiber blending and forms, the moisture sensitive layer that changes color is the blending of moisture sensitive fiber, dacron fibre and musel fibre and forms.
2. The humidity-sensitive color-changing heating fabric as claimed in claim 1, wherein the core layer of the elastic yarn is copper ammonia fiber, and the surface layer is nylon.
3. The moisture-sensitive color-changing heating fabric according to claim 1, wherein the moisture-absorbing heating fibers are selected from one of cuprammonium fibers, crosslinked acrylate fibers, polypropylene modified acrylic fibers, phase change energy storage fibers, heating acrylic fibers, EKS fibers, softwarm fibers, thermogray fibers, N38 fibers, warmsensor fibers, RENAISS fibers and MOIS CARE high-temperature-absorption heating fibers.
4. The moisture-sensitive color-changing heating fabric according to claim 1, wherein the moisture-sensitive color-changing fibers change color in an environment with a humidity of more than 40%.
5. A textile, characterized in that it is made of the moisture-sensitive color-changing heat-generating cloth according to any one of claims 1 to 4.
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202023217338.2U CN214449107U (en) | 2020-12-28 | 2020-12-28 | Humidity-sensitive color-changing heating cloth and textile thereof |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202023217338.2U CN214449107U (en) | 2020-12-28 | 2020-12-28 | Humidity-sensitive color-changing heating cloth and textile thereof |
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| Publication Number | Publication Date |
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| CN214449107U true CN214449107U (en) | 2021-10-22 |
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| CN202023217338.2U Expired - Fee Related CN214449107U (en) | 2020-12-28 | 2020-12-28 | Humidity-sensitive color-changing heating cloth and textile thereof |
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| Country | Link |
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| CN (1) | CN214449107U (en) |
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