CN214214982U - Antifouling fabric - Google Patents

Abstract

The utility model discloses an antifouling surface fabric, it relates to textile fabric's field, and it includes the basic unit, has antibiotic first antibiotic layer and the antibiotic layer of second of antibacterial action, first antibiotic layer compound in the basic unit upper surface, the antibiotic layer of second compound in the upper surface of basic unit, first antibiotic layer is formed by first antibiotic warp and first antibiotic weft warp knitting, first antibiotic warp includes antibiotic compound line, first antibiotic weft includes the bamboo charcoal fiber line. The antibacterial fabric has the effect of improving the antibacterial property of the fabric.

Description

Antifouling fabric

Technical Field

The application relates to the field of textile fabrics, in particular to an antifouling fabric.

Background

The fabric is used for making clothes, curtains, sofa cloth and the like, common fabrics comprise pure cotton, hemp, terylene, real silk and the like, and can also be formed by blending and weaving a plurality of raw materials, and furniture or clothes with different styles and materials need to be processed and manufactured by adopting different fabrics.

Chinese patent No. CN202293472U discloses a sofa fabric, which comprises a base fabric layer made of polyester napped filament, and an embossed fabric layer fixed on the base fabric layer, wherein the fabric layer is fixed with the base fabric layer by gluing.

The above prior art solutions have the following drawbacks: the sofa fabric is used for covering various fillers in the sofa manufacturing process, the fabric on the surface of the sofa is inconvenient to clean, and after long-term use, pollutants are easy to attach to the fabric to breed bacteria.

SUMMERY OF THE UTILITY MODEL

In order to improve the antibacterial property of the fabric, the application provides an antifouling fabric.

The application provides an antifouling surface fabric adopts following technical scheme:

an antifouling fabric comprises a base layer, a first antibacterial layer and a second antibacterial layer, wherein the first antibacterial layer and the second antibacterial layer have antibacterial effects, the first antibacterial layer is compounded on the upper surface of the base layer, the second antibacterial layer is compounded on the upper surface of the base layer, the first antibacterial layer is formed by warp knitting of first antibacterial warps and first antibacterial wefts, the first antibacterial warps comprise antibacterial composite threads, and the first antibacterial wefts comprise bamboo charcoal fiber threads.

Through adopting above-mentioned technical scheme, bamboo charcoal fiber line has antibiotic, deodorant effect, can give the antibiotic and deodorant performance of this application, and antibiotic first antibiotic layer and the antibiotic layer of second of effect can improve the antibiotic performance of this application.

The utility model discloses further set up to: the first antibacterial weft further comprises a polypropylene fiber line, and the polypropylene fiber line and the bamboo charcoal fiber line are arranged at intervals.

By adopting the technical scheme, the polypropylene fiber line has high elasticity, and the polypropylene fiber line and the bamboo charcoal fiber line are arranged at intervals, so that the first antibacterial weft line is endowed with better elasticity, and the warp knitting effect of the first antibacterial weft line is further improved.

The utility model discloses further set up to: the antibacterial composite wire comprises an antibacterial moisture-conducting acrylic fiber wire and a first polyester fiber wire, and the antibacterial moisture-conducting acrylic fiber wire and the first polyester fiber wire are mutually wound to form the antibacterial composite wire.

By adopting the technical scheme, the antibacterial wet-conducting acrylic fiber yarn has the antibacterial and mildewproof effects, the first polyester fiber yarn has the high-strength and high-elasticity performance, and the antibacterial composite yarn formed by winding the first polyester fiber yarn and the second polyester fiber yarn has the excellent performances of high strength, high elasticity, antibacterial and mildewproof.

The utility model discloses further set up to: the second antibacterial layer is formed by warp knitting of second antibacterial warps and second antibacterial wefts; the second antibacterial warp comprises a first chitin fiber line and a first lyocell fiber line, and the first chitin fiber line and the first lyocell fiber line are arranged at intervals; the second antibacterial weft comprises second chitosan fiber threads and second lyocell fiber threads, and the second chitosan fiber threads and the second lyocell fiber threads are arranged at intervals.

By adopting the technical scheme, the first chitin fiber yarns and the second chitin fiber yarns have excellent ductility and antibacterial property, so that the application is endowed with excellent ductility and antibacterial property, and the first lyocell fibers and the second lyocell fibers have good hand feeling and easy dyeing, so that the application is endowed with excellent hand feeling and dyeing effect.

The utility model discloses further set up to: the basic unit includes the heat preservation, the heat preservation is formed by heat preservation warp and heat preservation weft warp knitting, heat preservation warp includes second polyester fiber line, heat preservation weft includes soybean fiber line.

Through adopting above-mentioned technical scheme, the better elasticity of this application can be given to the high elasticity performance of second polyester fiber line high strength, and soybean fiber line has good warmth retention to can give the good heat preservation effect of heat preservation.

The utility model discloses further set up to: the base layer further comprises a TPU thin film layer, the TPU thin film layer is compounded on the upper surface of the heat insulation layer, and the TPU thin film layer is compounded on the lower surface of the first antibacterial layer.

By adopting the technical scheme, the TPU film layer can be matched with the thermal insulation layer in wind and cold resistance, so that a better thermal insulation effect is given to the thermal insulation TPU film layer.

The utility model discloses further set up to: the heat preservation warp also comprises a nano antibacterial biological protein fiber line, and the nano antibacterial biological protein fiber line and the second polyester fiber line are arranged at intervals.

By adopting the technical scheme, the nano antibacterial bioprotein fiber yarn has excellent light resistance and performance of no wrinkling and no fluffing, so that the yarn can be endowed with excellent light resistance and stiffness.

The utility model discloses further set up to: the heat-preservation weft yarn also comprises a copper ammonia fiber yarn, and the copper ammonia fiber yarn and the soybean fiber yarn are arranged at intervals.

Through adopting above-mentioned technical scheme, copper ammonia fiber line has good antistatic properties and drapability, when this application is used for making the casement to can give this application good antistatic effect.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the first antibacterial layer and the second antibacterial layer are arranged, so that excellent antibacterial performance can be given to the fabric, and pollutants attached to the fabric after long-term use are reduced.

2. The PU film layer with windproof, cold-proof and heat-insulating properties is matched with the heat-insulating layer with heat-insulating effect, so that better heat-insulating and cold-proof properties are given to the application.

Drawings

Fig. 1 is a schematic view of the entire structure of embodiment 1.

Fig. 2 is a schematic view of the structure of the first antibacterial layer in example 1.

FIG. 3 is a schematic structural view of the antibacterial composite thread in example 1.

Fig. 4 is a schematic structural view of the heat-insulating layer in example 1.

Fig. 5 is a schematic view of the structure of the second antibacterial layer in example 1.

Fig. 6 is a schematic view of the structure of the base layer in example 2.

FIG. 7 is a schematic view of the structure of the heat-insulating layer in example 3.

FIG. 8 is a schematic view of the structure of the heat-insulating layer in example 4.

Description of reference numerals: 1. a first antimicrobial layer; 11. a first antimicrobial warp thread; 111. an antibacterial composite wire; 1111. antibacterial moisture-conducting acrylic fiber yarn; 1112. a first polyester fiber yarn; 12. a first antimicrobial weft; 121. bamboo charcoal fiber thread; 122. a polypropylene fiber yarn; 2. a base layer; 21. a heat-insulating layer; 211. insulating warp threads; 2111. nano antibacterial biological protein fiber thread; 2112. a second polyester fiber yarn; 212. insulating weft yarns; 2121. soybean fiber thread; 2122. copper ammonia fiber wire; 22. a TPU film layer; 3. a second antimicrobial layer; 31. a second antimicrobial warp thread; 311. a first chitin fiber thread; 312. a first lyocell fiber yarn; 32. a second antimicrobial weft; 321. a second chitosan fiber thread; 322. a second lyocell fibre thread.

Detailed Description

The present application is described in further detail below with reference to figures 1-8.

The embodiment of the application discloses an antifouling fabric.

Example 1:

referring to fig. 1, an antifouling surface fabric includes first antibiotic layer 1, basic unit 2 and second antibiotic layer 3, and basic unit 2 is including the heat preservation 21 that has the heat preservation effect, and first antibiotic layer 1 hot pressing or gluing are compound in the upper surface of heat preservation 21, and second antibiotic layer 3 hot pressing or gluing are compound in the lower terminal surface of heat preservation 21, through setting up first antibiotic layer 1 and second antibiotic layer 3 that have the antibacterial action, can synthesize the possibility that reduces this application long-term use back pollutant attached to the surface fabric surface.

Referring to fig. 2 and 3, the first antibacterial layer 1 is formed by warp knitting a first antibacterial warp 11 and a first antibacterial weft 12, the first antibacterial warp 11 includes an antibacterial composite thread 111 having an antibacterial effect, the first antibacterial weft 12 includes bamboo charcoal fiber threads 121 and polypropylene fiber threads 122 arranged at intervals, the bamboo charcoal fiber threads 121 are formed by twisting bamboo charcoal fibers having antibacterial and antibacterial effects, and the polypropylene fiber threads 122 are formed by twisting polypropylene fibers having high elasticity and high strength.

The antibacterial composite wire 111 comprises an antibacterial moisture-conducting acrylic fiber wire 1111 and a first polyester fiber wire 1112, the antibacterial moisture-conducting acrylic fiber wire 1111 is formed by twisting antibacterial moisture-conducting acrylic fibers with antibacterial and anti-wrinkle performances, the antibacterial moisture-conducting acrylic fibers are formed by modifying acrylic fibers by using a high-tech Chitosant activating agent, the first polyester fiber wire 1112 is formed by twisting high-strength and high-elasticity polyester fibers, and the antibacterial composite wire 111 is formed by twisting the antibacterial moisture-conducting acrylic fiber wire 1111 and the first polyester fiber wire 1112 through a twisting machine.

Referring to fig. 4, the insulating layer 21 is formed by warp knitting the insulating warp 211 and the insulating weft 212, the insulating warp 211 includes a second polyester fiber thread 2112 twisted by a high-strength and high-elasticity polyester fiber, and the insulating weft 212 includes a soybean fiber thread 2121 twisted by a soybean fiber having an excellent insulating effect.

Referring to fig. 5, the second antibacterial layer 3 is formed by warp knitting a second antibacterial warp 31 and a second antibacterial weft 32, the second antibacterial warp 31 includes first chitin fiber lines 311 and first lyocell fiber lines 312 arranged at intervals, the second antibacterial weft 32 includes second chitin fiber lines 321 and second lyocell fiber lines 322 arranged at intervals, the first chitin fiber lines 311 and the second chitin fiber lines 321 are formed by twisting chitin fibers with antibacterial and deodorant effects, and the first lyocell fiber lines 312 and the second lyocell fiber lines 322 are formed by twisting lyocell fibers with high strength and easy dyeing.

The implementation principle of the embodiment 1 is as follows: through two rubber groove net area compounding machines with first antibiotic layer 1 hot pressing complex in 2 up end of basic unit, with the second antibiotic layer 3 hot pressing complex in the lower terminal surface of basic unit 1 to make the good antibiotic effect that this application tow sides all had.

Example 2:

referring to fig. 6, the difference between this embodiment and embodiment 1 is that the base layer 2 further includes a thermal TPU film layer 22, the TPU film layer 22 is hot-pressed or adhesively laminated on the lower end surface of the first antibacterial layer 1, the insulating layer 21 is hot-pressed or adhesively laminated on the lower surface of the TPU film layer 22, and the TPU film layer 22 is made of TPU particles through rolling, casting, film blowing, and coating, and has wind and cold resistant effects.

Example 3:

referring to fig. 7, the difference between this embodiment and embodiment 2 is that the thermal insulation warp 211 further includes a nano antibacterial bioprotein fiber line 2111 arranged at an interval with the second polyester fiber line 2112, the nano antibacterial bioprotein fiber line 2111 is formed by twisting nano antibacterial bioprotein fibers, and the nano antibacterial bioprotein fibers are functional protein fibers prepared by adding cellulose and nano antibacterial powder into a keratin solution prepared from wool and the like.

Example 4:

referring to fig. 8, the present embodiment is different from embodiment 3 in that the heat-insulating weft 212 further includes a cuprammonium rayon thread 2122 arranged at an interval from the soybean rayon thread 2121, and the cuprammonium rayon thread 2122 is formed by twisting cuprammonium rayon having an antistatic effect.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. An antifouling fabric is characterized in that: the antibacterial fabric comprises a base layer (2), a first antibacterial layer (1) with an antibacterial effect and a second antibacterial layer (3), wherein the first antibacterial layer (1) is compounded on the upper surface of the base layer (2), the second antibacterial layer (3) is compounded on the upper surface of the base layer (2), the first antibacterial layer (1) is formed by warp knitting of first antibacterial warp yarns (11) and first antibacterial weft yarns (12), the first antibacterial warp yarns (11) comprise antibacterial composite yarns (111), and the first antibacterial weft yarns (12) comprise bamboo charcoal fiber yarns (121).

2. An antifouling fabric according to claim 1, wherein: the first antibacterial weft (12) further comprises a polypropylene fiber line (122), and the polypropylene fiber line (122) and the bamboo charcoal fiber line (121) are arranged at intervals.

3. An antifouling fabric according to claim 1, wherein: the antibacterial composite wire (111) comprises an antibacterial moisture-conducting acrylic fiber wire (1111) and a first polyester fiber wire (1112), and the antibacterial moisture-conducting acrylic fiber wire (1111) and the first polyester fiber wire (1112) are mutually wound to form the antibacterial composite wire (111).

4. An antifouling fabric according to claim 1, wherein: the second antibacterial layer (3) is formed by warp knitting of second antibacterial warp (31) and second antibacterial weft (32); the second antibacterial warp (31) comprises first chitin fiber threads (311) and first lyocell fiber threads (312), and the first chitin fiber threads (311) and the first lyocell fiber threads (312) are arranged at intervals; the second antibacterial weft (32) comprises second chitosan fiber threads (321) and second lyocell fiber threads (322), and the second chitosan fiber threads (321) and the second lyocell fiber threads (322) are arranged at intervals.

5. An antifouling fabric according to claim 1, wherein: the base layer (2) includes heat preservation (21), heat preservation (21) are formed by heat preservation warp (211) and heat preservation weft (212) warp knitting, heat preservation warp (211) include second polyester fiber line (2112), heat preservation weft (212) include soybean fiber line (2121).

6. An antifouling fabric according to claim 5, wherein: the base layer (2) further comprises a TPU thin film layer (22), the TPU thin film layer (22) is compounded on the upper surface of the heat insulation layer (21), and the TPU thin film layer (22) is compounded on the lower surface of the first antibacterial layer (1).

7. An antifouling fabric according to claim 5, wherein: the heat preservation warp (211) also comprises a nano antibacterial bioprotein fiber line (2111), and the nano antibacterial bioprotein fiber line (2111) and the second polyester fiber line (2112) are arranged at intervals.

8. An antifouling fabric according to claim 5, wherein: the heat-preservation weft (212) further comprises copper ammonia fiber threads (2122), and the copper ammonia fiber threads (2122) and the soybean fiber threads (2121) are arranged at intervals.

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