CN110565252B - Weft yarn cross mesh knitting structure and knitting method thereof - Google Patents

Abstract

The invention discloses a weft yarn crossed mesh knitting structure and a knitting method thereof, which are formed by knitting yarns A, B and C, wherein the yarns B form any weft insertion tissues with the yarns A and C on two sides of a tissue area in a non-woven yarn clamping mode, the yarns B form a grid unit area through non-weaving, and the yarns are staggered to form a net-shaped structure by needle turning on the edge. The weaving method of the weft yarn crossed mesh knitting organizational structure can enrich the diversity of the weft insertion organizational structure, can adjust the mesh size through the weft yarn spacing distance in the weaving process, breaks through the limitation of the traditional weaving method, and opens up a new path for the weft insertion organization.

Description

Weft yarn cross mesh knitting structure and knitting method thereof

The technical field is as follows:

the invention relates to the field of knitting, in particular to a weft yarn crossed mesh knitting structure and a knitting method thereof.

Background art:

as shown in fig. 2, the weft insertion weave structure in the conventional art is such that weft yarns can be arranged in parallel only in sequence due to the relation of weaving sequence, and the mesh size of the mesh structure has a certain limitation. The traditional effect is single, and the requirements of design development and market diversification cannot be met.

The invention content is as follows:

the invention aims to provide a weft yarn crossed mesh knitting structure which can not only enrich the diversity of weft insertion weave structures, but also adjust the mesh size through the weft yarn spacing distance in the knitting process.

The technical scheme of the invention is that the weft yarn cross mesh knitting structure is provided and is formed by knitting a yarn A, a yarn B and a yarn C, wherein the yarn B forms any weft insertion structure with the yarn A and the yarn C on two sides of a structure area in a non-woven yarn clamping mode, the yarn B forms a grid unit area through non-woven, and the yarn B is turned over at the edge to enable the yarn to form a net structure in a staggered mode.

Preferably, weft yarn a, yarn B and yarn C are knit yarns of different properties. Such as different knit yarns in color, shape, elasticity, etc.

The invention also provides a knitting method of the weft crossing mesh knitting structure, which uses a flat knitting machine with a pair of front and back needle beds extending along the left and right direction and opposite to each other in the front and back direction, wherein the yarn B forms any weft insertion structure with the yarn A and the yarn C on both sides of the structure area in a non-weaving and yarn clamping mode, the yarn B forms a grid unit area through non-weaving, and the yarn B forms a net structure by needle overturning on the edge.

Preferably, step 1: the yarn A is knitted for two rows in the left area, the yarn C is knitted for two rows in the right area, the yarn B is knitted for two rows from left to right by using a needle turning and yarn clamping mode, and the edges of the middle area are knitted for two needles respectively;

step 2: turning over the left side coil to the right side in the two needles on the right side of the crossed reticular tissue area and overlapping;

and step 3: the yarn A is knitted for two rows in the left area, the yarn C is knitted for two rows in the right area, the yarn B is knitted for two rows from right to left in a needle-turning and yarn-clamping mode, and the edges of the middle area are knitted for two needles;

and 4, step 4: turning over the right coils of the two needles on the left side of the crossed reticular tissue area to the left side for overlapping;

and 5: and (4) circulating the steps 1 to 4 to form tissues.

Compared with the prior art, the invention has the following advantages after adopting the scheme: the diversity of the weft insertion organization structure can be enriched, the mesh size can be adjusted through the weft yarn spacing distance in the weaving process, the limitation of the traditional weaving method is broken through, and a new path is opened for the weft insertion organization; the weaving method plays a certain role in better explaining the design concept and improving the quality feeling, artistic value and aesthetic value of the product, provides a wider development space for the development and market of the knitted product, and in addition, in the aspect of industrial practicability, the weaving method can be widely applied to all weft insertion function computerized flat knitting machines; can meet and attract more consumer groups and promote the international influence of the knitting industry in China.

Description of the drawings:

FIG. 1 is a schematic representation of the weft cross mesh knit structure of the present invention.

FIG. 2 is a schematic representation of a prior art weft cross mesh knit stitch construction.

FIG. 3 is a knitting flow chart of the weft cross mesh knitting structure of the present invention.

The specific implementation mode is as follows:

the invention is further illustrated with respect to specific embodiments below:

example 1

A weft cross mesh knitting structure is shown in figure 1 and is formed by knitting a yarn A, a yarn B and a yarn C, wherein the yarn B forms any weft insertion texture with the yarn A and the yarn C on two sides of a texture area in a non-woven yarn clamping mode, the yarn B forms a grid unit area through non-weaving, and needle turning is carried out on the edge to enable the yarns to be staggered to form a net-shaped structure. The weft yarn crossed mesh knitting structure can enrich the diversity of weft insertion weave structures, and can adjust the mesh size through the weft yarn spacing distance in the knitting process, thereby breaking through the limitation of the traditional knitting method and opening up a new path for weft insertion weave. In addition, the woven fabric has richer texture color contrast, and the weft yarn A, the weft yarn B and the weft yarn C are knitting yarns with different properties, such as different colors, shapes, elasticity and the like.

The knitting method is that a flat knitting machine having a pair of front and back needle beds extending in the left-right direction and facing each other in the front-back direction is used, yarn B forms any weft insertion structure with yarn A and yarn C on both sides of a structure area in a non-woven yarn clamping manner, yarn B forms a grid unit area through non-woven, and needle turning is performed on the edge so that the yarns are staggered to form a net structure.

Specifically, as shown in fig. 3, the method is a schematic knitting diagram of yarn a, yarn B and yarn C, and comprises the following steps,

step 1: the yarn A is knitted for two rows in the left area, the yarn C is knitted for two rows in the right area, the yarn B is knitted for two rows from left to right by using a needle turning and yarn clamping mode, and the edges of the middle area are knitted for two needles respectively;

step 2: turning over the left side coil to the right side in the two needles on the right side of the crossed reticular tissue area and overlapping;

and step 3: the yarn A is knitted for two rows in the left area, the yarn C is knitted for two rows in the right area, the yarn B is knitted for two rows from right to left in a needle-turning and yarn-clamping mode, and the edges of the middle area are knitted for two needles;

and 4, step 4: turning over the right coils of the two needles on the left side of the crossed reticular tissue area to the left side for overlapping;

and 5: and (4) circulating the steps 1 to 4 to form tissues. In this embodiment, two rows of yarns a and C are taken as an example, and the number of weaving rows in steps 1 and 3 is increased, so that the effect of increasing the distance between the weft yarns B can be achieved, and the mesh distance is enlarged.

The foregoing is illustrative of the preferred embodiments of the present invention only and is not to be construed as limiting the claims. All the equivalent structures or equivalent process changes made by the description of the invention are included in the scope of the patent protection of the invention.

Claims (1)

1. A method for knitting a weft cross mesh knitting structure, characterized by: the knitting machine is formed by knitting a yarn A, a yarn B and a yarn C, wherein the yarn B forms any weft insertion texture with the yarn A and the yarn C on two sides of a texture area in a non-woven yarn clamping mode, the yarn B forms a grid unit area through non-weaving, and needle overturning is carried out on the edge to enable the yarns to be staggered to form a net-shaped structure, the weft yarn A, the yarn B and the yarn C are knitting yarns with different properties, a flat knitting machine with a front needle bed and a back needle bed which extend along the left-right direction and are opposite to each other in the front-back direction is used, needle overturning is carried out on the edge to enable the yarns to be,

step 1: the yarn A is knitted for two rows in the left area, the yarn C is knitted for two rows in the right area, the yarn B is knitted for two rows from left to right by using a needle turning and yarn clamping mode, and the edges of the middle area are knitted for two needles respectively;

step 2: turning over the left side coil to the right side in the two needles on the right side of the crossed reticular tissue area and overlapping;

and step 3: the yarn A is knitted for two rows in the left area, the yarn C is knitted for two rows in the right area, the yarn B is knitted for two rows from right to left in a needle-turning and yarn-clamping mode, and the edges of the middle area are knitted for two needles;

and 4, step 4: turning over the right coils of the two needles on the left side of the crossed reticular tissue area to the left side for overlapping;

and 5: and (4) circulating the steps 1 to 4 to form tissues.

Images