CN112195554A - Novel super-rebound hollow-strip knitted fabric and processing method and application thereof - Google Patents

Abstract

The invention discloses a novel super-rebound hollow knitted fabric and a processing method and application thereof, belonging to the field of woven fabric processing. Novel super kick-back hole strip knitted vamp has solved the problem that traditional vamp material homogeneity exists, through designing the fragile position of vamp and the difficult loss position that wears, adopts suitable material and the novel super kick-back hole strip knitted vamp that the mode of weaving made to prolong vamp life, and is wear-resisting, guarantees the comfort level.

Description

Novel super-rebound hollow-strip knitted fabric and processing method and application thereof

Technical Field

The invention relates to the field of woven fabric processing, in particular to a novel super-rebound hollow rib knitted fabric and a processing method and application thereof.

Background

With the continuous development of material technology, the fly-woven fabric appears and has developed and matured application. The computer is used for designing and programming, the yarns are integrally woven into the fly-woven fabric according to the setting of the computer, the stretch parts of clothes or bags, such as cuffs and necklines of a jacket, are loose and deformed after a long time due to the fact that the elasticity of the fabric is not large enough, and the whole vamp is generally selected to adopt the same fabric in the field of woven fabric processing in the current market. Because the foot of the person of dress is different to the extrusion condition of dragging of the different positions of vamp when daily life takes exercise with the motion, consequently vamp homogenization can cause the easy damage position loss condition of vamp serious than other positions, if the vamp texture is harder can cause the person of dress to experience badly, the softer shoes life that can subtract of vamp texture, whole piece vamp adopts same kind of fabric can't reach the equilibrium in the two aspects of use experience and life.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention aims to provide a novel super-rebound hollow rib knitted fabric and a processing method and application thereof.

The purpose of the invention is realized by the following technical scheme:

the invention provides a novel super-rebound hollow knitted fabric, which is formed by knitting a knitting material through a knitting machine in a one-step forming manner, wherein the knitting material comprises an elastic knitting material and other knitting materials, the novel super-rebound hollow knitted fabric is at least two layers, the outer layer is the elastic knitting material or other knitting materials, the inner layer is the elastic knitting material, and the knitted fabric is structurally divided into a convex part and a concave part.

The elastic woven material texture is soft than other woven materials, and elasticity is big, at the inlayer of novel super kick-back hole strip knitted fabric, possesses pliability and elasticity, improves the cladding nature of shoes face wearer's foot when being applied to the vamp, increases wearer's comfort level, is applied to clothing cuff, collarband department and provides bigger tensile elasticity, clothing non-deformable. Other weaving materials texture is harder, and elasticity is little, at the outer layer of novel super kick-back hole strip knitted fabric, makes the knitted fabric have wear-resisting, the characteristics of preapring for an unfavorable turn of events shape concurrently. The elastic knitted material is used alone or the elastic knitted material is combined with other knitted materials, the knitted fabric has at least two layers, and due to the fact that the adopted knitted materials and the knitting modes are different, the weave structure of the knitted fabric produces different effects, namely the widths and the heights of the convex parts and the concave parts of the knitted fabric can show different effects along with the change of the knitted materials.

Further, the elastic knitted material comprises at least one of spandex, spandex coated materials and high-elasticity polyester fibers. The spandex is not used independently under the common condition, the spandex cladding material is mostly adopted to clad the spandex elastic core-spun yarn, the spandex cladding material is the elastic core-spun yarn composed of natural fibers and has good touch and appearance, a small amount of spandex is added to produce the high-quality elastic core-spun yarn, and the elasticity of the elastic core-spun yarn is adjusted according to the application requirement of knitted fabrics.

Further, the other woven material includes at least one of filament-based yarns, staple-based yarns, and monofilaments. The filament yarns are smooth and uniform, have luster, are closely and regularly arranged, have high fiber strength utilization coefficient and high bending rigidity; staple yarns include, but are not limited to, split ring yarns, open end spun yarns, and self-twisted yarns; the single filament has a fineness greater than that of a single filament in a multifilament and is a single filament produced by a single-hole spinneret in the production of chemical fibers.

Further, the other woven material includes a thermal fuse.

Further, the combination of the weaving material includes at least one of covering yarn and mixed yarn.

Further, the knitting machine is a weft-knitting computerized flat knitting machine.

Further, the novel ultra-rebound hollow strip knitted fabric needs to be subjected to heating treatment. The heating temperature does not exceed 180 ℃. Heating the knitted fabric which does not use the thermal fuse to ensure that the knitted material is heated to shrink to a more ideal fabric effect; the heat treatment of the knitted fabric using the thermal fuse melts the thermal fuse to bond the knitted material to a desired fabric effect.

The invention also provides a processing method of the novel super-rebound hollow knitted fabric, the knitted fabric is knitted by a weft computer flat knitting machine, at least two yarn mouths are used, the materials used by the yarn mouths comprise at least one elastic knitting material and other knitting materials, and the knitting process is as follows:

a first part: the surface weaving and the bottom weaving are respectively combined with the floating line weaving;

a second part: performing front knitting left shift or right shift one needle for needle turning to back and back knitting left shift or right shift one needle for needle turning to front, and knitting with floating thread knitting combination respectively;

and a third part: and taking the first part and the second part as a weaving cycle, and weaving for a plurality of times to form the novel ultra-rebound hollow strip knitted fabric.

Further, the processing method of the novel super-rebound hollow knitted fabric is characterized in that the knitted fabric is knitted by a weft computer flat knitting machine, at least two yarn mouths are used, the materials used by the yarn mouths comprise at least one elastic knitting material and other knitting materials, and the knitting process of the knitted fabric is as follows:

a first part: performing surface weaving and bottom weaving;

a second part: and taking the first part as a weaving cycle, and weaving for a plurality of times to form the novel ultra-rebound hollow strip knitted fabric.

The invention also provides the application of the novel super-rebound knitted fabric in the stretching part of the vamp, the clothing or the bag, aiming at the problems of low elasticity and material homogenization of the stretching part of the vamp, the clothing or the bag.

Compared with the prior art, the invention has the beneficial effects that:

the invention relates to a novel super-rebound hollow rib knitted fabric which is formed and knitted by a knitted material at one time by a weft computerized flat knitting machine through programming in advance. If the fabric is hard, the elasticity of the product is poor, the wearer feels uncomfortable, if the fabric is soft, the wear resistance of the product is poor, the product is easy to wear, and the service life of the product is shortened.

Drawings

FIG. 1 is a diagram of an embodiment 1 of the present invention;

FIG. 2 is a diagram of an embodiment 2 of the present invention;

FIG. 3 is a schematic view of a knitting structure of embodiment 1 of the present invention;

FIG. 4 is a diagram of an embodiment 3 of the present invention;

FIG. 5 is a pictorial representation of entity 4 of the present invention;

fig. 6 is a schematic view of a knitting structure in embodiment 2 of the present invention.

The reference numbers in the figures are: 1-a protruding structure; 2-a recessed structure; 2(1) a recessed structure; 2, (2) a protruding structure.

Detailed Description

The present invention will now be described in detail with reference to the accompanying drawings.

The invention provides a novel super-rebound hollow strip knitted fabric which is formed by one-step forming and knitting of an elastic knitted material and other knitted materials through a knitting machine, wherein the knitting material combination mode comprises at least one of covering stitch yarn and mixed yarn, the knitted fabric is provided with at least two layers, the outer layer is made of the elastic knitted material or other knitted materials, the inner layer is made of the elastic knitted material, and the knitted fabric is structurally divided into a convex part and a concave part.

The elastic weaving material comprises at least one of spandex, spandex coating materials and high-elasticity polyester fibers. The spandex is not used independently under the common condition, the spandex cladding material is mostly adopted to clad the spandex elastic core-spun yarn, the spandex cladding material is the elastic core-spun yarn composed of natural fibers and has good touch and appearance, a small amount of spandex is added to produce the high-quality elastic core-spun yarn, and the elasticity of the elastic core-spun yarn is adjusted according to the application requirement of knitted fabrics. The elastic weaving material is flexible and elastic, improves the wrapping property of the shoe surface on the foot of a wearer when being applied to the vamp, increases the comfort level of the wearer, provides larger stretching elasticity when being applied to the sleeve opening and the collar of the clothes, and ensures that the clothes are not easy to deform.

Other woven materials include at least one of filament-based yarns, staple-based yarns, and monofilaments. The filament yarns are smooth and uniform, have luster, are closely and regularly arranged, have high fiber strength utilization coefficient and high bending rigidity; staple yarns include, but are not limited to, split ring yarns, open end spun yarns, and self-twisted yarns; the single filament has a fineness greater than that of a single filament in a multifilament and is a single filament produced by a single-hole spinneret in the production of chemical fibers. Other weaving materials texture is harder, and elasticity is little, at the outer layer of novel super kick-back hole strip knitted fabric, makes the knitted fabric have wear-resisting, the characteristics of preapring for an unfavorable turn of events shape concurrently. Other woven materials include thermal fuses which are woven in the knit sandwich by means of a covering yarn during the weaving process.

The knitting material and the knitting mode are different, the structure of the knitted fabric produces different effects, namely, the widths and the heights of the convex parts and the concave parts of the knitted fabric can show different effects along with the change of the knitting material.

Example 1

Fig. 1 is a diagram of a novel ultra-rebound hollow strip knitted fabric object 1, wherein the object 1 comprises a convex structure 1 formed by knitting other knitting materials with harder outer textures and a concave structure 2 formed by knitting elastic knitting materials with softer inner textures. Fig. 2 is a diagram of a novel ultra-resilient hollow knitted fabric object 2, the object 2 is made of an elastic knitted material only and comprises a concave structure 2(1) and a convex structure 2 (2).

The object 1 and the object 2 have multiple weaving modes, wherein one weaving mode is as shown in the weaving structure schematic diagram of the embodiment 1, A, B shows a yarn nozzle, in the object 1, the material used by the yarn nozzle A is other weaving materials, and the yarn nozzle B is an elastic weaving material; in substance 2, yarn feeder a and yarn feeder B are both made of elastic knitting materials, the arrow direction represents the working direction of the yarn feeder, and the needles on the needle bed are named as 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 and 18 from left to right.

In the 1 row on the horizontal axis, the yarn A nozzle works rightwards, surface knitting is carried out on the 1-5 needle rows, the 7-11 needle rows and the 13-17 needle rows on the vertical axis, and the knitting needle rows are floating threads on the 6, 12 and 18 needle rows.

In 2 rows, the yarn nozzle B works rightwards, floating knitting is carried out at 1-5 needle rows, 7-11 needle rows and 13-17 needle rows, and bottom knitting is carried out at 6, 12 and 18 needle rows.

In 3 rows, the yarn nozzle B works leftwards, floating knitting is carried out at 1-5 needle rows, 7-11 needle rows and 13-17 needle rows, and surface knitting is carried out at 6, 12 and 18 needle rows.

In 4 rows, the yarn nozzle A works leftwards, bottom knitting is carried out at 1-5 needle rows, 7-11 needle rows and 13-17 needle rows, and floating threads are arranged at 6, 12 and 18 needle rows.

1. 2 weaving rows form a run of the yarn nozzle A and the yarn nozzle B, 3 and 4 weaving rows form a return stroke of the yarn nozzle A, B, namely 1-4 weaving rows form one weaving cycle, 5-8 weaving rows correspond to 1-4 weaving rows, namely 5-8 weaving rows form the second weaving cycle, 11-14 weaving rows form the third weaving cycle, and 15-18 weaving rows form the fourth weaving cycle.

9. In 10 weaving rows, 6, 12 and 18 needle rows carry out translation needle overturning action on a bottom layer surface layer, and the action is to translate the bottom weaving and the surface weaving of the 6, 12 and 18 needle rows of the 6 and 7 weaving rows to the left by one needle position together, overturn the needle of the original surface weaving to the bottom layer, and overturn the needle of the original bottom weaving to the surface layer. The specific needle turning action is as follows:

in 9 rows, the front knitting moves left one needle and turns over to the back in 6, 12 and 18 needle rows, namely the back needle bed moves one needle position to the right, the face knitting of 6, 12 and 18 needle rows in 7 rows moves the front needle bed coil to the knitting needle corresponding to the back needle bed to turn over; in 10 rows, the back knitting is performed with the 6, 12, 18 rows of needles, the back needle bed moves two needle positions to the left, the bottom knitting of the 6, 12, 18 rows of needles in 6 rows is performed with the needle reversing operation, the back needle bed loops are moved to the knitting needles corresponding to the front needle bed, and the back needle bed returns to the non-needle reversing knitting state.

19. In the 20 weaving rows, the 6, 12 and 18 knitting needle rows perform the translation needle-turning action of the bottom surface layer, and the action is to translate the bottom weaving and the surface weaving of the 6, 12 and 18 knitting needle rows of the 16 and 17 weaving rows to the right by one needle position together, turn the needle of the original surface weaving to the bottom layer, and turn the needle of the original bottom weaving to the surface layer. The specific needle turning action is as follows:

in the 19 rows, the front knitting moves a needle to the right and turns over to the back, namely the back needle bed moves a needle position to the left, the surface knitting of the 6, 12 and 18 rows of the 17 rows moves the front needle bed coil to the knitting needle corresponding to the back needle bed; in the 20 rows, the back knitting moves one needle to the right and the needle turning is performed in the 6, 12 and 18 needle rows, that is, the back needle bed moves two needle positions to the right, the bottom knitting of the 6, 12 and 18 needle rows in the 16 rows performs the needle turning, the back needle bed coil is moved to the knitting needle corresponding to the front needle bed, and the back needle bed is returned to the non-needle-turning knitting state.

The differences between the 1-10 knitted rows and the 11-20 knitted rows are that the 9-10 knitted rows perform the actions of moving one needle position to the right of the back needle bed and moving two needle positions to the left of the back needle bed, the 19-20 knitted rows perform the actions of moving one needle position to the left of the back needle bed and moving two needle positions to the right of the back needle bed, the 1-10 knitted rows and the 11-20 knitted rows are complete knitting cycles, and the knitting actions of the 1-10 knitted rows and the 11-20 knitted rows are alternately knitted for a plurality of knitting cycles to form the novel ultra-rebound hole strip knitted fabric.

The material 1 and the material 2 are obtained by heating after weaving, and the heating temperature is not more than 180 ℃. The vamp which does not use the thermal fuse is heated, so that the woven material is heated to shrink to a more ideal fabric effect; the heat treatment of the upper using the thermal fuse melts the thermal fuse to bond the woven material to the desired textile effect. If a hot fuse is used, the hot fuse is woven in the interlayer of the knitted fabric through the knitting materials of the covering yarn feeder, the yarn feeder A and the yarn feeder B, and the hot fuse is heated and melted to bond the knitting materials. In the object 1, the other knitted materials are knitted into the convex structures 1 and the elastic knitted materials are knitted into the concave structures 2 to form the crater strip structure together, the object 2 is knitted from the elastic knitted materials, the difference between the concave structures 2(1) and the convex structures 2(2) is smaller than that of the object 1, and the elastic knitted materials used in the concave structures 2(1) have elasticity larger than that of the convex structures 2 (2).

Example 2

Fig. 4 is a diagram showing a new ultra-rebound hollow rib fabric object 3 partially knitted with an empty needle by using an elastic knitting material. Fig. 5 is a diagram of a new type ultra-rebound hollow knitted fabric object 4 with a partially-bottomed needle made of an elastic knitted material.

The objects 3 and 4 are various knitting manners, one of which is shown in the knitting structure schematic diagram of the embodiment 2 and fig. 6, A, B represents a yarn nozzle, in the objects 3 and 4, the materials used by the yarn nozzle A and the yarn nozzle B are elastic knitting materials, the arrow direction represents the working direction of the yarn nozzle, and the needles on the needle bed are named as 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 and 18 from left to right.

In 1 weaving row, the yarn nozzle A works rightwards, surface weaving is carried out on 1-3 needle rows, 7-9 needle rows and 13-15 needle rows, and bottom weaving is carried out on 4-6 needle rows, 10-12 needle rows and 16-18 needle rows.

In 2 weaving rows, the yarn B nozzle works rightwards, surface weaving is carried out at 1-3 needle rows, 7-9 needle rows and 13-15 needle rows, and bottom weaving is carried out at 4-6 needle rows, 10-12 needle rows and 16-18 needle rows.

In 3 rows, the yarn nozzle B works leftwards, surface knitting is carried out on 1-3 needle rows, 7-9 needle rows and 13-15 needle rows, and bottom knitting is carried out on 4-6 needle rows, 10-12 needle rows and 16-18 needle rows.

In 4 rows, the yarn nozzle A works leftwards, surface knitting is carried out on 1-3 needle rows, 7-9 needle rows and 13-15 needle rows, and bottom knitting is carried out on 4-6 needle rows, 10-12 needle rows and 16-18 needle rows.

1. 2 weaving rows form a run of the yarn nozzle A and the yarn nozzle B, 3 and 4 weaving rows form a return stroke of the yarn nozzle A, B, namely 1-4 weaving rows form one weaving cycle, 5-8 weaving rows are consistent with 1-4 weaving rows, namely 5-8 weaving rows form the second weaving cycle, 9-12 weaving rows form the third weaving cycle, and 13-16 weaving rows form the fourth weaving cycle. Knitting is carried out for a plurality of knitting cycles by knitting actions of 1-4 rows to form the novel ultra-rebound hollow strip knitted fabric.

The material 3 and the material 4 are obtained by heating treatment after weaving, and the heating temperature is not more than 180 ℃. The vamp which does not use the thermal fuse is heated, so that the woven material is heated to shrink to a more ideal fabric effect; the heat treatment of the upper using the thermal fuse melts the thermal fuse to bond the woven material to the desired textile effect. If a hot fuse is used, the hot fuse is woven in the interlayer of the knitted fabric through the knitting materials of the covering yarn feeder, the yarn feeder A and the yarn feeder B, and the hot fuse is heated and melted to bond the knitting materials. The object 3 and the object 4 are both knitted by using elastic knitted materials, the object 3 is partially empty-knitted, and the object 4 is partially empty-knitted, so that the object 4 has a compact concave structure 2(1) and a compact convex structure 2 (2).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims (10)

1. The utility model provides a novel super kick-back hole strip knitted fabric, its characterized in that, novel super kick-back hole strip knitted fabric is woven through weaving machine one shot forming by weaving the material and is formed, it includes elasticity woven materials and other woven materials to weave the material, novel super kick-back hole strip knitted fabric is two-layer at least, and the material is woven or other woven materials for elasticity to the skin, and the inlayer is elasticity woven materials, and knitted fabric structurally divide into bulge and sunk part.

2. The novel ultra-rebound crater knitted fabric of claim 1, wherein the elastic knitted material comprises at least one of spandex, spandex coating material and high-elasticity polyester fiber.

3. The novel ultra-rebound crater knitted fabric according to claim 1, wherein the other knitted material comprises at least one of filament-based yarns, staple-based yarns and monofilaments.

4. The novel ultra-rebound crater knitted fabric according to claim 1, characterized in that the further knitted material comprises a thermal fuse.

5. The knitted fabric of claim 1, wherein the knitted material comprises at least one of a covering yarn and a mixed yarn in a combined manner.

6. The novel ultra-rebound crater knitted fabric according to claim 1, wherein the knitting machine is a weft computerized flat knitting machine.

7. The novel knitted fabric with ultra-rebound hollow bars as claimed in claim 1, wherein the novel knitted fabric with ultra-rebound hollow bars is subjected to heat treatment.

8. A method for processing a novel ultra-rebound hollow knitted fabric according to any one of claims 1 to 7, wherein the knitted fabric is knitted by a weft computer flat knitting machine, at least two yarn mouths are used, the material used by the yarn mouths comprises at least one elastic knitting material and other knitting materials, and the knitting process is as follows:

a first part: the surface weaving and the bottom weaving are respectively combined with the floating line weaving;

a second part: performing front knitting left shift or right shift one needle for needle turning to back and back knitting left shift or right shift one needle for needle turning to front, and knitting with floating thread knitting combination respectively;

and a third part: and taking the first part and the second part as a weaving cycle, and weaving for a plurality of times to form the novel ultra-rebound hollow strip knitted fabric.

9. A method for processing a novel ultra-rebound hollow knitted fabric according to any one of claims 1 to 7, wherein the knitted fabric is knitted by a weft computer flat knitting machine, at least two yarn mouths are used, the material used by the yarn mouths comprises at least one elastic knitting material and other knitting materials, and the knitting process is as follows:

a first part: performing surface weaving and bottom weaving;

a second part: and taking the first part as a weaving cycle, and weaving for a plurality of times to form the novel ultra-rebound hollow strip knitted fabric.

10. Use of a novel ultra-resilient knitted fabric according to any one of claims 1 to 7 in a stretch position in a shoe upper, garment or bag.

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