CN220332192U - Thermal oxford - Google Patents

Abstract

The utility model discloses a warm oxford fabric, and relates to the technical field of fabrics. The key points of the technical scheme are as follows: the thermal insulation device comprises an outer surface layer and an inner surface layer, wherein a supporting part is fixedly connected to one side, close to the inner surface layer, of the outer surface layer, a thermal insulation cavity is formed between the adjacent supporting parts and the outer surface layer and between the adjacent supporting parts and the inner surface layer, a containing groove communicated with the thermal insulation cavity is formed in the inner surface layer, which is close to the outer surface layer, a plurality of thermal insulation wires are fixedly connected in the containing groove, and a plurality of thermal insulation balls are fixedly connected on the thermal insulation wires. According to the utility model, the acrylic fiber has a good heat preservation effect through the arrangement of the acrylic fiber, so that the whole heat preservation property of the fabric is ensured.

Description

Thermal oxford

Technical Field

The utility model relates to the technical field of fabrics, in particular to a warm oxford fabric.

Background

Oxford is also called oxford, and is a fabric with various functions and wide application, wherein many trousers are made of oxford.

The trousers are generally formed by sewing a waist, a crotch and two trouser legs, and are used as a part of daily wearing of people, so that the trousers have good decorative effect and the effect of protecting the legs.

In daily use of the conventional trousers, when people need to resist cold in cold weather, the conventional trousers generally enhance the overall warmth retention property of the fabric by increasing the thickness of the fabric, but the wearing process of the trousers is not portable enough after the fabric is simply thickened, so that a structure is arranged to solve the problem of poor warmth retention effect of the conventional oxford fabric.

There is therefore a need to propose a new solution to this problem.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model aims to provide the warmth-keeping oxford fabric, and the integral warmth-keeping effect of the fabric is improved through the arrangement of the structure.

The technical aim of the utility model is realized by the following technical scheme: the warmth-keeping oxford fabric comprises an outer surface layer and an inner surface layer, wherein a supporting part is fixedly connected to one side, close to the inner surface layer, of the outer surface layer, a warmth-keeping cavity is formed between the supporting part, the outer surface layer and the inner surface layer, a containing groove communicated with the warmth-keeping cavity is formed in the inner surface layer, close to the outer surface layer, a plurality of warmth-keeping threads are fixedly connected in the containing groove, and a plurality of warmth-keeping balls are fixedly connected on the warmth-keeping threads.

The utility model is further provided with: one side of the outer surface layer, which is close to the inner surface layer, is fixedly connected with a plurality of thermal velvet, and the central axis of the thermal velvet and the central axis of the thermal line are arranged in a staggered manner.

The utility model is further provided with: the supporting part is integrally formed on the outer surface layer, and the outer surface layer is woven into a convex strip tissue through the warp and weft knitting of the first composite yarn.

The utility model is further provided with: the warp tissue points of the raised line tissue are floating, the weft tissue points of the raised line tissue are sinking, the tissue circulation of the raised line tissue is sequentially arranged from left to right as floating, sinking, floating, sinking floating, sinking, floating, sinking, and floating, and the floating, sinking, floating, sinking and floating.

The utility model is further provided with: the first composite yarn comprises a first core wire and an outer wrapping layer positioned on the outer ring, wherein the first core wire is formed by twisting a plurality of polyester fibers, and the outer wrapping layer is formed by mutually and spirally interweaving a plurality of acrylic fibers on the outer side of the first core wire.

The utility model is further provided with: the inner surface layer is formed by warp-weft knitting of a plurality of second composite yarns, and the second composite yarns comprise a core wire II and an outer layer positioned on the outer ring.

The utility model is further provided with: the second core wire is formed by twisting a plurality of polyester fibers, and the outer layer is formed by twisting a plurality of polypropylene fibers.

In summary, the utility model has the following beneficial effects:

one side of the outer surface layer, which is close to the inner surface layer, is fixedly connected with a supporting part, a thermal insulation cavity is formed between the adjacent supporting part and the outer surface layer and between the adjacent supporting part and the inner surface layer, a containing groove communicated with the thermal insulation cavity is formed in the inner surface layer, which is close to the outer surface layer, the volume of static air stored between the fabrics is increased, a plurality of thermal insulation wires are fixedly connected in the containing groove, a plurality of thermal insulation balls are fixedly connected on the thermal insulation wires, and the thermal insulation balls are used for continuously supplying heat to the fabrics, so that the overall thermal insulation effect of the fabrics is ensured.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a diagram of the tissue of the ribs of the present utility model;

FIG. 3 is a cut-away view of a first composite yarn of the present utility model;

fig. 4 is a cut-away view of a second composite yarn of the present utility model.

In the figure: 1. an outer surface layer; 2. an inner surface layer; 3. a support part; 4. a thermal cavity; 5. a receiving groove; 6. a thermal insulation wire; 7. a thermal ball; 8. thermal velvet; 9. a first composite yarn; 10. polyester fiber; 11. acrylic fiber; 12. a second composite yarn; 13. a polypropylene fiber.

Detailed Description

The present utility model will be described in detail below with reference to the accompanying drawings and examples.

The thermal oxford fabric is shown in fig. 1 and 2, and comprises an outer surface layer 1 and an inner surface layer 2, wherein one side, close to the inner surface layer 2, of the outer surface layer 1 is fixedly connected with a supporting part 3, a thermal cavity 4 is formed between the adjacent supporting part 3 and the outer surface layer 1 and the inner surface layer 2, a containing groove 5 communicated with the thermal cavity 4 is formed in the inner surface layer 2, the volume for storing static air between fabrics is increased, a plurality of thermal threads 6 are fixedly connected in the containing groove 5, the thermal threads 6 are fixedly connected with the inner surface layer 2 in a sewing mode through yarns by using a sewing machine, a plurality of thermal balls 7 are fixedly connected on the thermal threads 6, the thermal balls 7 and the thermal threads 6 are integrally formed by twisting through a twisting machine, the thermal balls 7 are arranged, the cavity inside the fabric is enlarged, the overall fluffy effect of the fabric is enhanced, a plurality of flocks 8 are fixedly connected to one side, close to the inner surface layer 2, the central axis of the flocks 8 and the central axis of the thermal threads 6 are arranged, the flocks 8 and the flocks on the threads 6 are staggered, the flocks on the threads 6 are fluffy, the thermal threads are further more, and the thermal effect of the fabric is enhanced, and further thermal effects of the fabric are enhanced.

As shown in fig. 1 and fig. 3, a plurality of polyester fibers 10 are put into a twisting machine to be twisted to form a first core wire, the polyester fibers 10 have good strength and good elasticity, the structural strength of the first core wire is ensured, a plurality of acrylic fibers 11 are spirally wound on the outer side of the first core wire through a spindle spinning process to obtain a first composite yarn 9, the acrylic fibers 11 have good heat retention, and the heat retention effect of the first composite yarn 9 is ensured.

As shown in fig. 1 and 2, a plurality of first composite yarns 9 are put into a water jet loom to be warp-weft woven in a raised line structure mode to form an outer surface layer 1, the warp structure points of the raised line structure are floating, the weft structure points of the raised line structure are sinking, the structure circulation of the raised line structure is sequentially arranged from left to right to be floating, sinking, floating, sinking and floating, supporting part 3 is formed on one side of the outer surface layer 1, which is close to the inner surface layer 2, a thermal cavity 4 is formed between the adjacent supporting part 3 and the outer surface layer 1 and the inner surface layer 2, the cavity inside the fabric is further enlarged by arranging the thermal cavity 4, and heat loss is reduced by utilizing the characteristics of air heat conduction difference, so that the thermal effect between the fabrics is further enhanced.

As shown in fig. 1 and fig. 4, a plurality of polyester fibers 10 are put into a twisting machine to twist to form a core wire II, so that the integral structural strength of the core wire II is further ensured, a plurality of polypropylene fibers 13 are put into the twisting machine to twist to form an outer layer, the outer layer is wound on the outer side of the core wire II through a spindle spinning process to obtain a second composite yarn 12, the polypropylene fibers 13 have good heat preservation effect and strong heat storage capacity, the heat preservation of the second composite yarn 12 is further ensured, and a plurality of second composite yarns 12 are put into a water jet loom to be warp and weft knitted to form an inner surface layer 2.

After trousers are made of the fabric, one side, close to the outer surface layer 1, of the inner surface layer 2 is pressed out of the accommodating groove 5 through a hot press and is communicated with the thermal insulation cavity 4, so that more cavities can be formed between the inner surface layer 2 and the outer surface layer 1, the overall fluffy effect of the fabric is enhanced, the overall thermal insulation effect of the fabric is improved, the overall thermal insulation effect of the fabric can be guaranteed through the arrangement of the thermal insulation threads 6, and finally the inner surface layer 2 and the outer surface layer 1 are sewn together through a sewing machine to obtain the fabric.

The above description is only a preferred embodiment of the present utility model, and the protection scope of the present utility model is not limited to the above examples, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. It should be noted that modifications and adaptations to the present utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims (7)

1. The warmth-keeping oxford fabric is characterized in that: including extexine (1) and inlayer (2), one side fixedly connected with supporting part (3) that extexine (1) is close to inlayer (2), is adjacent form cold-proof chamber (4) between supporting part (3) and extexine (1) and inlayer (2), accommodating groove (5) that communicate cold-proof chamber (4) have been seted up on extexine (1) are close to inlayer (2), fixedly connected with a plurality of cold-proof lines (6) in accommodating groove (5), fixedly connected with a plurality of cold-proof balls (7) on cold-proof line (6).

2. The thermal oxford as claimed in claim 1, wherein: one side of the outer surface layer (1) close to the inner surface layer (2) is fixedly connected with a plurality of thermal velvet (8), and the central axis of the thermal velvet (8) and the central axis of the thermal line (6) are arranged in a staggered mode.

3. The thermal oxford as claimed in claim 2, wherein: the supporting part (3) is integrally formed on the outer surface layer (1), and the outer surface layer (1) is woven into a convex strip structure through the warp and weft knitting of the first composite yarn (9).

4. A thermal oxford as claimed in claim 3, wherein: the warp tissue points of the raised line tissue are floating, the weft tissue points of the raised line tissue are sinking, the tissue circulation of the raised line tissue is sequentially arranged from left to right as floating, sinking, floating, sinking floating, sinking, floating, sinking, and floating, and the floating, sinking, floating, sinking and floating.

5. A thermal oxford as claimed in claim 3, wherein: the first composite yarn (9) comprises a first core wire and an outer wrapping layer positioned on the outer ring, the first core wire is formed by twisting a plurality of polyester fibers (10), and the outer wrapping layer is formed by mutually and spirally interweaving a plurality of acrylic fibers (11) on the outer side of the first core wire.

6. The thermal oxford as claimed in claim 5, wherein: the inner surface layer (2) is formed by warp and weft knitting of a plurality of second composite yarns (12), and the second composite yarns (12) comprise a core wire II and an outer layer positioned on an outer ring.

7. The thermal oxford as claimed in claim 6, wherein: the second core wire is formed by twisting a plurality of polyester fibers (10), and the outer layer is formed by twisting a plurality of polypropylene fibers (13).