CN214522481U - Wear-resistant fabric - Google Patents

Abstract

The utility model discloses a wear-resisting fabric, its field that relates to textile fabric, it includes wearing layer and CORDURA surface course, CORDURA surface course compound in the wearing layer lower surface, the wearing layer is warp-knitted by wear-resisting warp and wear-resisting weft and is formed, wear-resisting warp is including wear-resisting compound line and the close skin line that has the wearability, wear-resisting compound line with close skin line is interval arrangement each other, close skin line is one of soybean fiber line, Lyocell fiber line, the lyocell bamboo fiber line. This application has the effect that improves the wearability of surface fabric.

Description

Wear-resistant fabric

Technical Field

The application relates to the field of textile fabrics, in particular to a wear-resistant fabric.

Background

The fabric is a material for making clothes, different functional clothes and different styles can be made by yarns with different properties and different weaving processes, and the fabric is usually woven by using cotton yarns, linen yarns and other yarns at present.

Chinese patent publication No. CN202064096U discloses a fabric, wherein warps and wefts are respectively made of kapok fibers and ramie fibers, wherein the diameter of the kapok fibers is 5.12 μm, the diameter of the ramie fibers is 13.61 μm, the warp density is 32.4 pieces/cm, and the weft density is 25.2 pieces/cm.

The above prior art solutions have the following drawbacks: in the long-term use process of the fabric, the fabric is easy to abrade due to friction between the fabric and limbs and washing of a washing machine, and the kapok fiber and the ramie fiber have good antibacterial, moisture absorption and light and soft performances, but the abrasion resistance woven by the kapok fiber and the ramie fiber is not good, so that the fabric is easy to abrade after long-term use.

SUMMERY OF THE UTILITY MODEL

In order to improve the wearability of surface fabric, this application provides a wear-resisting surface fabric.

The application provides a wear-resisting surface fabric adopts following technical scheme:

the wear-resistant fabric comprises a wear-resistant layer and a CORDURA surface layer, wherein the CORDURA surface layer is compounded on the lower surface of the wear-resistant layer, the wear-resistant layer is formed by warp knitting of wear-resistant warps and wear-resistant wefts, the wear-resistant warps comprise wear-resistant composite threads with wear resistance and skin-friendly threads, the wear-resistant composite threads and the skin-friendly threads are arranged at intervals, and the skin-friendly threads are one of soybean fiber threads, lyocell fiber threads and lyocell bamboo fiber threads.

Through adopting above-mentioned technical scheme, the CORDURA surface course has the characteristics of softness, strong, the wearability is strong to endowed this application good wearability and durability, and the wearing layer is including the wear-resisting compound line that has the abrasive action, makes this application tow sides all have good wear-resisting effect, and soybean fiber line, lyocell bamboo fiber line all have good skin-friendly nature and feel, thereby endows this application good skin-friendly effect.

The utility model discloses further set up to: the wear-resistant composite wire comprises a polyester fiber wire and a polyhexamethylene adipamide fiber wire, wherein the polyester fiber wire and the polyhexamethylene adipamide fiber wire are mutually twisted and wound to form the wear-resistant composite wire.

By adopting the technical scheme, the polyester fiber yarn and the polyhexamethylene adipamide fiber yarn are intertwined with each other. The wear resistance of the wear-resistant composite wire is enhanced, so that the wear-resistant composite wire has a better wear-resistant effect.

The utility model discloses further set up to: the wear-resistant weft comprises a fine denier acrylic fiber line and an antibacterial composite line, wherein the fine denier acrylic fiber line and the antibacterial composite line are arranged at intervals.

By adopting the technical scheme, the fine denier acrylic fiber yarn has smooth hand feeling and anti-pilling performance, and can endow the yarn with excellent anti-pilling performance and good hand feeling.

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

By adopting the technical scheme, the antibacterial moisture-conducting acrylic fiber yarn has a good antibacterial and mildew-proof effect, and the chitin fiber has excellent ductility and antibacterial property, so that the application can be endowed with the excellent antibacterial effect and ductility.

The utility model discloses further set up to: the linear density of the wear-resistant warp threads is 40, and the linear density of the wear-resistant weft threads is 60.

Through adopting above-mentioned technical scheme, wear-resisting warp and wear-resisting weft's linear density is different for wear-resisting layer surface forms vertical protruding stripe, can strengthen the decorative effect of this application on the one hand, and the other party is because wear-resisting warp includes wear-resisting compound line, makes wear-resisting compound line play better wear-resisting effect.

The utility model discloses further set up to: a COOLMAX surface layer with moisture absorption and sweat releasing performance is compounded between the wear-resistant layer and the CORDURA surface layer.

By adopting the technical scheme, the COOLMAX surface layer has excellent moisture absorption and sweat release effects and is not deformed after being washed, so that the application is endowed with excellent stiffness and moisture absorption and sweat release effects.

The utility model discloses further set up to: the wearing layer with it has the antistatic layer to compound between COOLMAX surface course, the antistatic layer is formed by antistatic warp and antistatic weft warp knitting, antistatic warp includes the copper ammonia fiber line, antistatic weft includes first polypropylene fiber line.

Through adopting above-mentioned technical scheme, copper ammonia fiber line has good antistatic function, and first polypropylene fiber line has good elasticity, can give this application good antistatic effect when playing good weaving effect after both warp knitting.

The utility model discloses further set up to: antistatic warp still includes second polypropylene fiber line, antistatic weft still includes flax fiber line, second polypropylene fiber line with copper ammonia fiber line is mutual interval arrangement, flax fiber line with first polypropylene fiber line is mutual interval arrangement.

Through adopting above-mentioned technical scheme, second polypropylene fiber line has good elasticity, and copper ammonia fiber line and the mutual interval arrangement of second polypropylene fiber line can play better weaving effect, and the flax fiber line has antistatic, anti ultraviolet's effect, and when first polypropylene fiber line and flax fiber line both interval arrangements can play better weaving effect, can give this application good antistatic and anti ultraviolet's effect.

The utility model discloses further set up to: the antistatic warp threads further comprise second polypropylene fiber threads, the antistatic weft threads further comprise flax fiber threads, and the second polypropylene fiber threads and the cuprammonium rayon threads are twisted to form the antistatic warp threads; the first polypropylene fiber line and the flax fiber line are twisted to form the antistatic weft line.

Through adopting above-mentioned technical scheme, second polypropylene fiber line and copper ammonia fiber line twist, first polypropylene fiber line and flax fiber line twist for antistatic weft and antistatic warp are compound line and both have good antistatic properties and elasticity, make antistatic weft and antistatic warp both can play better weaving effect, and the compactness of antistatic layer is better.

The utility model discloses further set up to: the antistatic warp threads further comprise second polypropylene fiber threads, the antistatic weft threads further comprise flax fiber threads, and the cuprammonium fiber threads are spirally wound on the second polypropylene fiber threads to form the antistatic warp threads; the flax fiber thread is spirally wound on the first polypropylene fiber thread and the antistatic weft, and the twisting directions of the copper ammonia fiber thread and the flax fiber thread are the same.

By adopting the technical scheme, the twisting direction of the copper ammonia fiber thread is the same as that of the flax fiber thread, so that the antistatic layer is loose and soft in hand feeling.

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

1. the setting of wearing layer and CORDURA surface course for the positive and negative all have good wear-resisting effect of this application.

And 2, the arrangement of the COOLMAX surface layer endows the application with excellent moisture absorption and sweat releasing effects.

3. The setting of antistatic layer has given this application good antistatic effect.

Drawings

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

Fig. 2 is a schematic structural view of the wear-resistant layer in example 1.

Fig. 3 is a schematic structural view of the abrasion-resistant composite wire in example 1.

FIG. 4 is a schematic structural view of the antibacterial composite thread in example 1.

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

FIG. 6 is a schematic structural view of an antibacterial composite wire in example 2.

Fig. 7 is a schematic structural view of the wear-resistant layer in example 3.

FIG. 8 is a schematic view showing the structure of antistatic warp threads in example 4.

FIG. 9 is a schematic view showing the structure of the antistatic weft in example 4.

FIG. 10 is a schematic view showing the structure of antistatic warp threads in example 5.

FIG. 11 is a schematic view showing the structure of the antistatic weft in example 5.

Description of reference numerals: 1. a wear layer; 11. wear-resistant warps; 111. wear-resistant composite wires; 1111. a polyester fiber yarn; 1112. polyhexamethylene adipamide fiber yarn; 112. a skin-friendly line; 12. wear-resistant weft yarns; 121. fine denier acrylic fiber yarn; 122. an antibacterial composite wire; 1221. a chitin fiber thread; 1222. antibacterial moisture-conducting acrylic fiber yarn; 2. a CORDURA finish; 3. a COOLMAX surface layer; 4. an antistatic layer; 41. antistatic warp threads; 411. copper ammonia fiber wire; 412. a second polypropylene fiber yarn; 42. antistatic weft yarns; 421. a first polypropylene fiber yarn; 422. flax fiber thread.

Detailed Description

The present application is described in further detail below with reference to figures 1-11.

The embodiment of the application discloses a wear-resistant fabric.

Example 1:

referring to fig. 1, the wear-resistant fabric comprises a wear-resistant layer 1, an antistatic layer 4 hot-pressed or glued to the lower end face of the wear-resistant layer 1, a COOLMAX surface layer 3 hot-pressed or glued to the lower end face of the antistatic layer 4, and a CORDURA surface layer 2 hot-pressed or glued to the lower surface of the COOLMAX surface layer 3.

The CORDURA surface layer 2 is formed by processing a soft, durable, wear-resistant and excellent-tearing-resistant CORDURA fabric, and the CORDURA fabric which is sold by Hehui textile Limited in Wujiang is sold with the product number JC022 is adopted in the application. The COOLMAX surface layer 3 is knitted by COOLMAX fibers, and the COOLMAX fibers are cross-shaped and provided with four grooves, so that the COOLMAX surface layer 3 has excellent moisture absorption and sweat releasing performance, and the COOLMAX fabric sold by Shanghai Changjie textile Limited is CJ-100335.

Referring to fig. 2 and 3, the wear-resistant layer 1 is formed by warp knitting of wear-resistant warp yarns 11 and wear-resistant weft yarns 12, the wear-resistant warp yarns 11 include wear-resistant composite yarns 111 and skin-friendly yarns 112 arranged at intervals, the wear-resistant composite yarns 111 are formed by twisted winding of polyester fiber yarns 1111 and polyhexamethylene adipamide fiber yarns 1112, the polyester fiber yarns 1111 are formed by twisting high-strength and high-elasticity polyester fibers, the polyhexamethylene adipamide fiber yarns 1112 are formed by twisting high-strength and high-elasticity polyhexamethylene adipamide fibers, the polyhexamethylene adipamide fibers are formed by preparing resin thick by using adipic acid and hexamethylenediamine and then spinning the resin thick by a melting method, the skin-friendly yarns 112 are any one of soybean fiber yarns, lyocell fiber yarns and lyocell fiber yarns, the soybean fiber yarns are formed by twisting soybean fibers with soft hand feeling, the lyocell fiber yarns are formed by twisting lyocell fibers with smooth hand feeling, the lyocell bamboo fiber is formed by twisting lyocell fiber with smooth hand feeling.

Referring to fig. 2 and 4, the wear-resistant weft 12 includes a fine denier acrylic fiber line 121 and an antibacterial composite line 122 which are arranged at intervals, the fine denier acrylic fiber line 121 is formed by twisting acrylic fibers with fine hand feeling and excellent pilling resistance, the antibacterial composite line 122 is formed by twisting a chitin fiber line 1221 and an antibacterial moisture-conducting acrylic fiber line 1222, the chitin fiber line 1221 is formed by twisting chitin fibers with antibacterial and deodorant effects, the antibacterial moisture-conducting acrylic fiber line 1222 is formed by twisting antibacterial moisture-conducting acrylic fibers, and the antibacterial moisture-conducting acrylic fibers are fibers with antibacterial and antifungal effects which are prepared by modifying acrylic fibers with a high-tech Chitosante activator.

Referring to fig. 5, the antistatic layer 4 is formed by warp knitting antistatic warp yarns 41 and antistatic weft yarns 42, the antistatic warp yarns 41 include copper ammonia fiber yarns 411 and first polypropylene fiber yarns 421 which are arranged at intervals, the antistatic weft yarns 42 include first polypropylene fiber yarns 421 and flax fiber yarns 422 which are arranged at intervals, the first polypropylene fiber yarns 421 and the second polypropylene fiber yarns 412 are formed by twisting high-elasticity polypropylene fibers, the copper ammonia fiber yarns 411 are formed by processing copper ammonia fibers with an antistatic effect, and the flax fiber yarns 422 are formed by processing flax fibers with an antistatic effect and good suspension property.

The implementation principle of the embodiment 1 is as follows: COOLMAX surface course 3 that will have the moisture absorption perspire effect passes through two gluey groove guipure compounding machine hot pressing and compounds in CORDURA surface course 2 up end, will have antistatic layer 4 hot pressing complex in COOLMAX surface course 3's up end, compound wearing layer 1 hot pressing in antistatic layer 4's up end, CORDURA surface course 2 and wearing layer 1 all have good wearability and compliance, make the anti-both sides of this application all have good wearability.

Example 2:

referring to fig. 6, the difference between this embodiment and embodiment 1 is that the antibacterial composite wire 122 is formed by winding a chitin fiber wire 1221 and an antibacterial moisture-conducting acrylic fiber wire 1222, wherein the chitin fiber wire 1221 is spirally and tightly wound around the antibacterial moisture-conducting acrylic fiber wire 1222, and the chitin fiber wire 1221 can completely wrap the antibacterial moisture-conducting acrylic fiber wire 1222 inside the chitin fiber wire 1221 for protection, so that the antibacterial composite wire 122 can have a better antibacterial effect.

Example 3:

referring to fig. 7, the difference between this embodiment and embodiment 1 is that the linear density of the wear-resistant warp 11 is 40, the linear density of the wear-resistant weft 12 is 60, and the wear-resistant layer 1 is woven by the wear-resistant warp 11 and the wear-resistant weft 12 with different linear densities, and a plurality of longitudinal convex stripes arranged parallel to the wear-resistant warp 11 are formed on the surface of the wear-resistant layer 1.

Example 4:

referring to fig. 8 and 9, the present embodiment is different from embodiment 1 in that the antistatic warp threads 41 are twist-wound with the cuprammonium fiber threads 411 and the second polypropylene fiber threads 412, and the antistatic weft threads 42 are twist-wound with the first polypropylene fiber threads 421 and the flax fiber threads 422.

Example 5:

referring to fig. 10 and 11, the present embodiment is different from embodiment 1 in that the antistatic warp yarn 41 is formed by spirally winding the second polypropylene fiber yarn 412 in a S-twist lay direction with the cuprammonium fiber yarn 411, and the antistatic weft yarn 42 is formed by spirally winding the first polypropylene fiber yarn 421 in a S-twist lay direction with the flax fiber yarn 422.

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 (10)

1. A wear-resistant fabric is characterized in that: including wearing layer (1) and CORDURA surface course (2), CORDURA surface course (2) compound in wearing layer (1) lower surface, wearing layer (1) is warp-knitted by wear-resisting warp (11) and wear-resisting weft (12) and is formed, wear-resisting warp (11) are including wear-resisting compound line (111) and the close skin line (112) that have the wearability, wear-resisting compound line (111) with close skin line (112) interval arrangement each other, close skin line (112) are one of soybean fiber line, Lyocell fiber line, lyocell bamboo fiber line.

2. The wear-resistant fabric according to claim 1, wherein: the wear-resistant composite wire (111) comprises a polyester fiber wire (1111) and a polyhexamethylene adipamide fiber wire (1112), and the polyester fiber wire (1111) and the polyhexamethylene adipamide fiber wire (1112) are twisted with each other to form the wear-resistant composite wire (111).

3. The wear-resistant fabric according to claim 1, wherein: the wear-resistant weft (12) comprises a fine denier acrylic fiber wire (121) and an antibacterial composite wire (122), wherein the fine denier acrylic fiber wire (121) and the antibacterial composite wire (122) are arranged at intervals.

4. The wear-resistant fabric according to claim 3, wherein: the antibacterial composite wire (122) comprises a chitin fiber wire (1221) and an antibacterial moisture-conducting acrylic fiber wire (1222), and the chitin fiber wire (1221) and the antibacterial moisture-conducting acrylic fiber wire (1222) are mutually wound to form the antibacterial composite wire (122).

5. The wear-resistant fabric according to claim 1, wherein: the linear density of the wear-resistant warp (11) is 40, and the linear density of the wear-resistant weft (12) is 60.

6. The wear-resistant fabric according to claim 1, wherein: a COOLMAX surface layer (3) with moisture absorption and sweat releasing performance is compounded between the wear-resistant layer (1) and the CORDURA surface layer (2).

7. The wear-resistant fabric according to claim 6, wherein: wearing layer (1) with it has antistatic layer (4) to compound between COOLMAX surface course (3), antistatic layer (4) are formed by antistatic warp (41) and antistatic weft (42) warp knitting, antistatic warp (41) include copper ammonia fiber line (411), antistatic weft (42) include first polypropylene fiber line (421).

8. The wear-resistant fabric according to claim 7, wherein: antistatic warp (41) still includes second polypropylene fiber line (4312), antistatic weft (42) still includes flax fiber line (422), second polypropylene fiber line (4312) with copper ammonia fiber line (411) is interval arrangement each other, flax fiber line (422) with first polypropylene fiber line (421) are interval arrangement each other.

9. The wear-resistant fabric according to claim 8, wherein: the antistatic warp (41) further comprises a second polypropylene fiber wire (4312), the antistatic weft (42) further comprises a flax fiber wire (422), and the second polypropylene fiber wire (4312) and the cuprammonium fiber wire (411) are twisted to form the antistatic warp (41); the first polypropylene fiber line (421) and the flax fiber line (422) are twisted to form the antistatic weft (42).

10. The wear-resistant fabric according to claim 9, wherein: the antistatic warp (41) further comprises a second polypropylene fiber wire (4312), the antistatic weft (42) further comprises a flax fiber wire (422), and the cuprammonium fiber wire (411) is spirally wound on the second polypropylene fiber wire (4312) to form the antistatic warp (41); the flax fiber thread (422) is spirally wound on the first polypropylene fiber thread (421) and the antistatic weft (42), and the twisting directions of the copper ammonia fiber thread (411) and the flax fiber thread (422) are the same.

Images