TUBULAR DOUBLE-NEEDLE BED WARP KNITTING MACHINE

Abstract

A tubular double-needle bed warp knitting machine includes a let-off mechanism, a knitting element, and a take-up and batching device. The knitting element includes guide needles in a circular pattern, two circular needle beds arranged internally and externally, knitting needles in a circular pattern along the internal and external needle beds, and knitting components that move in coordination with the knitting needles. Some of the guide needles form loops on the internal and external circular needle beds, while other guide needles alternately form loops on the internal and external circular needle beds to connect sections of the two fabric pieces to create a three-dimensional tubular fabric. The formed three-dimensional tubular fabric exits the knitting area through the traction of the take-up and batching device. The tubular double-needle warp knitting machine simplifies production processes of tubular double-needle warp knitted fabrics and leverages the advantages of tubular fabrics to optimize product performance.

Description

BACKGROUND OF THE INVENTION

1. Technical Field

The invention belongs to the technical field of textile processing and textile machinery, and particularly relates to a tubular double-needle bed warp knitting machine.

2. Description of Related Art

Traditional double-needle bed warp knitting machines consist of two parallel needle beds with the needle backs relative to each other. They are composed of a knitting element, a let-off mechanism, a guide bar shogging system, a take-up and batching device, an integrated control system, and auxiliary devices. The double-needle bed warp knitting machine can knit separately on the front and back needle beds using one or multiple guide bars, and then connect two fabric pieces partially or fully through certain guide bars. Compared to weft knitting machines, double-needle bed warp knitting machines are characterized by high production efficiency, a wide range of product types, and diverse patterns. The main products of double-needle bed warp knitting machines include underwear products, plush products, warp knitted spacer fabrics, and warp knitted tubular fabrics.

The production process of tubular knitted fabrics is flexible, and it offers a variety of organizational structures and shapes. It not only reduces waste and loss of raw materials due to cutting but also avoids the impact of seams on structure and properties of fabrics, which significantly improves the production efficiency and reduces the costs. Due to its unique properties, tubular knitted fabrics greatly enrich the variety and application range of knitted products, finding extensive use in automotive, medical, firefighting, oil transportation, aerospace, and other fields.

BRIEF SUMMARY OF THE INVENTION

Technical Issues

The technical issues to be settled by the invention is that the tubular wrap knitted fabric produced by conventional double-needle bed warp knitting machines is knitted in a single plane, which limits its structure and restricts its application. The technology of combination tubular fabrics with double-needle warp knitting machines is not yet mature.

Technology Solutions

The object of the invention is to provide a tubular double-needle bed warp knitting machine, in order to overcome the limitations of traditional double-needle warp knitting machines, simplify the production process of three-dimensional fabrics, shorten the production cycle, reduce the loss and waste of raw materials, and leverage the advantages of tubular fabrics to improve the range of applications for warp knitted products, making them suitable for a broader market.

To achieve the above invention objects, the technical scheme adopted in the present invention is as follows:

One object of the present disclosure is to provide a tubular double-needle bed warp knitting machine, comprising a let-off mechanism, a knitting element, and a take-up and batching device. The knitting element includes guide needles arranged in a circular pattern, two circular needle beds arranged internally and externally, knitting needles arranged in a circular pattern along the internal and external needle beds, and knitting components that move in coordination with the knitting needles.

Furthermore, the knitting needles are latch needles, and the knitting components that move in coordination with the knitting needles include a knocking-over bar and a sinker, with the backs of the latch needles on the two circular needle bed are opposite to each other. The guide needles are used to add yarns, and the latch needles hook the introduced yarns in and form the loops, with the knocking-over bar and the sinker coordinating with the movement of the latch needles.

Furthermore, some of the guide needles undergo periodic expansion, contraction, and arc lateral movement along the radial direction to form loops on the internal and external circular needle beds, while the remaining guide needles undergo synchronous expansion, contraction, and arc lateral movement along the radial direction to alternately form loops on the internal and external circular needle beds, connecting partial or all sections of the two fabric pieces to create a three-dimensional tubular fabric. The formed three-dimensional tubular fabric gradually exits the knitting area through the traction of the take-up and batching device.

Furthermore, the guide needles are arranged in three concentric circles: inner, middle, and outer. The three circles of guide needles undergo synchronized periodic expansion, contraction, and arc lateral movement. The outer circle of guide needles forms loops with the external circular needle bed, the inner circle of guide needles forms loops with the internal circular needle bed, and the middle circle of guide needles alternately moves on the internal and external circular needle beds to connect partial or all sections of the two fabric pieces.

Furthermore, the let-off mechanism includes warp beams, guide reeds, and tension rods. The warp beams are equipped with pan heads, and there are a pair of warp beams in each of the four directions, each pair of which is equipped with a pair of guide reeds and a pair of tension rods.

A second object of the present disclosure is to provide a preparation method of the three-dimensional tubular fabric using the above-mentioned tubular double-needle warp knitting machine, comprising the following steps:

• • S1: When the knitting needles rise to the highest position, the three circles of guide needles expand. When the knitting needles descend, the three circles of guide needles contract to their original position. During this expansion-contraction cycle, the outer circle of guide needles and the middle circle of guide needles participate in the yarn laying proces, while the inner circle guide needles does not participate in the yarn laying proces.

S2: The knitting needles rise to the highest position again, and the three circles of guide needles contract. When the knitting needles descend again, the three circles of guide needles expand to their original position. During this contraction-expansion cycle, the inner circle of guide needles and the middle circle of guide needles participate in the yarn laying proces, while the outer circle of guide needles does not participate in the yarn laying proces.

S3: Repeat S1 to S2.

Furthermore, before S1, the interval distance between the external circular needle bed and the internal circular needle bed is adjusted according to the thickness requirements of the fabric.

Furthermore, the yarns used are made from natural fibers or chemical fibers.

Furthermore, the natural fibers can be cotton or blending fibers.

Furthermore, the chemical fibers can be polyester, polypropylene, nylon, acrylic, or viscose.

The invention has the following specific advantages:

Compared to ordinary warp knitting machines and circular knitting machines, the tubular double-needle warp knitting machine of the present invention has significant advantages. It has high production efficiency and breaks through the limitations of traditional double-needle warp knitting machines. It simplifies the production process of tubular double-needle warp knitted fabrics and leverages the advantages of tubular fabrics to optimize product performance. This makes warp knitted products suitable for a broader market and applicable in various fields, such as automotive, medical, firefighting, construction, transportation, military defense, aerospace, and more.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a schematic diagram of the knitting element of the tubular double-needle warp knitting machine.

FIG. 2 is a detailed view of the knitting element of the tubular double-needle warp knitting machine.

FIG. 3 is a schematic diagram of the let-off mechanism of the tubular double-needle warp knitting machine.

FIG. 4 demonstrates the shogging motion of the guide bar in the tubular double-needle warp knitting machine.

Among the figures, 1-1 represents the external circular needle bed, 1-2 represents the internal circular needle bed, 1-3 represents the outer needle, 1-4 represents the inner needle, 1-5 represents the guide needle, 1-6 represents the yarns, 1-7 represents the knocking-over bar, 1-8 represents the sinker, 2-1 represents the warp beam, 2-2 represents the pan head, 2-3 represents the guide reed, and 2-4 represents the tension rod.

DETAILED DESCRIPTION OF THE INVENTION

In order to make the above purposes, features and advantages of the invention clearer and easily understood, the specific embodiments of the invention will be further described below in conjunction with specific drawings.

Embodiment 1

As shown in FIG. 1-FIG. 3, a tubular double-needle warp knitting machine includes a let-off mechanism, a knitting element, and a take-up and batching device. The knitting element includes guide needles 1-5 arranged in a circular pattern, an external circular needle bed 1-1 and an internal circular needle bed 1-2 arranged externally and internally, outer needles 1-3, inner needles 1-4 arranged along the external and internal circular needle beds, and knocking-over bars 1-7 and sinkers 1-8 corresponding to the knitting needles. The back of the two latch needles on the two circular needle beds is opposite to each other. The thickness of the fabric is adjustable and can be regulated by adjusting the interval distance between the internal and external needle beds.

The guide needles 1-5 are used to add yarns 1-6, and the latch needles (1-3, 1-4) hook the introduced yarns in and form the loops, with the knocking-over bar (1-7) and the sinker (1-8) coordinating with the movement of the latch needles (1-2, 1-3). The guide needles (1-5) are arranged in three concentric circles: inner, middle, and outer (GB1, GB2, GB3). The three circles of guide needles undergo synchronized periodic expansion, contraction, and arc lateral movement.

The let-off mechanism includes warp beams 2-1, pan heads 2-2, guide reeds 2-3, and tension rods 2-4. Each of the four directions has a pair of warp beams 2-1, and each pair of warp beams 2-1 is equipped with a pair of guide reeds 2-3 and a pair of tension rods 2-4 below them to ensure even tension of yarn 1-6. Each warp beam is individually controlled, making the operation convenient, and the amount of warp feeding can be precisely controlled. Yarns 1-6 of specified lengths are fed from the pan heads 2-2 on the four warp beams 2-1 in different directions and pass through guide reeds 2-3 and tension rods 2-4 before being delivered to the knitting element. The number and positions of the pan heads 2-2 can be adjusted according to specific needs.

The outer circle of guide needle GB1 forms loops on the external circular needle bed 1-1, and the inner circle of guide needle GB3 forms loops on the internal circular needle bed 1-2. The yarns 1-6 output from the tension rod 2-4 are separately looped on the internal and external circular needle beds (1-1, 1-2) to knit pieces. The middle circle of guide needle GB2 alternately moves on the internal and external circular needle beds to connect the partial or all sections of the two fabric pieces. The formed three-dimensional tubular fabric is gradually removed from the knitting area through the traction of the take-up and batching device, while new yarns are continuously fed in.

The tubular double-needle warp knitting machine of the present invention is suitable for knitting cotton yarns, blended yarns, and other natural fibers, as well as polyester, polypropylene, nylon, acrylic, viscose, and other chemical fibers.

As shown in FIG. 4, during the knitting process, the movement of guide needles 1-5 (GB1, GB2, GB3) includes circular contraction, expansion, and arc lateral movement, specifically:

S1: When the knitting needles rise to the highest position, the guide needles start to swing outwards from position a to the outer circular knitting needle bed machine 1-1 (Step 1);

S2: When the guide needles swing into the position, the knitting needles start to descend, and the guide needles undergo a contraction motion (Step 2), until the guide needles return to position a. During this process, only GB1 and GB2 participate in loop formation, and GB3 performs only radial contraction and expansion swinging without loop formation;

S3: The knitting needles rise again to the highest position, the guide needles swing into the inner circular needle bed 1-2 for contraction motion (Step 3);

S4: When the guide needles swing into the position, the knitting needles start to descend, and the guide needles undergo an expansion motion, until the guide needles return to position a. During this process, only GB2 and GB3 participate in loop formation, and GB3 performs only radial expansion and contraction swinging without loop formation;

S5: Repeat S1 to S4.

Many specific details are expounded in the above description to provide a comprehensive understanding of the invention, but the invention can also be implemented in other ways different from those described here. Any modifications, equivalent replacements, and improvements that can be made by those skilled in the art within the spirit and principles of the present invention should be included in the scope of protection of the present invention.

Claims

1. A tubular double-needle bed warp knitting machine, comprising a let-off mechanism, a knitting element, and a take-up and batching device, wherein the knitting element includes guide needles arranged in a circular pattern, two circular needle beds arranged internally and externally, knitting needles arranged in a circular pattern along the internal and external needle beds, and knitting components that move in coordination with the knitting needles; The guide needles are arranged in three concentric circles: inner, middle, and outer. The three circles of guide needles undergo synchronized periodic expansion, contraction, and arc lateral movement. The outer circle of guide needles forms loops with the external circular needle bed, the inner circle of guide needles forms loops with the internal circular needle bed, and the middle circle of guide needles alternately moves on the internal and external circular needle beds to connect partial or all sections of the two fabric pieces.

2. The tubular double-needle bed warp knitting machine according to claim 1, wherein the knitting needles are latch needles, and the knitting components that move in coordination with the knitting needles include a knocking-over bar and a sinker, with the backs of the latch needles on the two circular needle beds are opposite to each other. The guide needles are used to add yarns, and the latch needles hook the introduced yarns in and form the loops, with the knocking-over bar and the sinker coordinating with the movement of the latch needles.

3. The tubular double-needle bed warp knitting machine according to claim 1, wherein some of the guide needles are used to form loops on the internal and external circular needle beds, while the remaining guide needles alternately form loops on the internal and external circular needle beds to connect partial or all sections of the two fabric pieces to create a three-dimensional tubular fabric. The formed three-dimensional tubular fabric gradually exits the knitting area through the traction of the take-up and batching device.

4. The tubular double-needle bed warp knitting machine according to claim 1, wherein the let-off mechanism includes warp beams, guide reeds, and tension rods. The warp beams are equipped with pan heads, and there are a pair of warp beams in each of the four directions, each pair of which is equipped with a pair of guide reeds and a pair of tension rods.

5. A preparation method of the three-dimensional tubular fabric, using the tubular double-needle warp knitting machine according to claim 1 for knitting. The guide needles are used to add yarns, and the latch needles hook the introduced yarns in and form the loops, with the knocking-over bar and the sinker coordinating with the movement of the latch needles. The method comprises the following steps: S1: When the knitting needles rise to the highest position, the three circles of guide needles expand. When the knitting needles descend, the three circles of guide needles contract to their original position. During this expansion-contraction cycle, the outer circle of guide needles and the middle circle of guide needles participate in the yarn laying proces, while the inner circle guide needles does not participate in the yarn laying proces.S2: The knitting needles rise to the highest position again, and the three circles of guide needles contract. When the knitting needles descend again, the three circles of guide needles expand to their original position. During this contraction-expansion cycle, the inner circle of guide needles and the middle circle of guide needles participate in the yarn laying proces, while the outer circle of guide needles does not participate in the yarn laying proces.S3: Repeat S1 to S2.

6. A preparation method of the three-dimensional tubular fabric according to claim 5, wherein that before S1, it includes adjusting the interval distance between the external circular needle bed and the internal circular needle bed based on the thickness requirements of the fabric.

7. A preparation method of the three-dimensional tubular fabric according to claim 5, wherein the yarns used are made from natural fibers or chemical fibers.

8. A preparation method of the three-dimensional tubular fabric according to claim 5, wherein the chemical fibers can be polyester, polypropylene, nylon, acrylic, or viscose.