CN220374065U - Antibacterial deodorizing polyester fabric - Google Patents

Abstract

The utility model discloses antibacterial deodorizing polyester fabric, and relates to the technical field of polyester fabrics. The key points of the technical scheme are as follows: the sweat-absorbing layer and the antibacterial layer are sequentially arranged from top to bottom, a plurality of placing grooves are formed in the side, close to the sweat-absorbing layer, of the antibacterial layer in an inward sinking mode, the sweat-absorbing layer is fixedly connected in the placing grooves, and the sweat-absorbing layer between the adjacent placing grooves arches to form a ventilation cavity with the antibacterial layer. The ramie fiber provided by the utility model has natural antibacterial and bacteriostatic effects, and has high moisture absorption and dispersion speed, so that the drying speed of sweat in the fabric is increased, and the breeding and reproduction of bacteria in the fabric are reduced.

Description

Antibacterial deodorizing polyester fabric

Technical Field

The utility model relates to the technical field of polyester fabrics, in particular to a bacteriostatic deodorizing polyester fabric.

Background

Polyester fabric is a chemical fiber garment fabric which is very much used in daily life. Its advantages are high crease resistance and shape retention.

Along with development of science and technology and economic conditions, people pay more and more attention to health, particularly feet are contacted with the outside, meanwhile, socks are generally made of textiles, are a good living place for various microorganisms such as bacteria and fungi, are an important transmission source for diseases, socks in the current market can be formed by processing chemical fiber fabrics for improving portability and durability, have no antibacterial capability or poor antibacterial capability, sweat on the feet can not be absorbed in time in the movement process, and bacteria are more easily bred, so that the structure is provided for solving the problem of poor antibacterial effect of the chemical fiber fabrics.

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 antibacterial deodorizing polyester fabric.

The technical aim of the utility model is realized by the following technical scheme: the antibacterial deodorizing polyester fabric comprises a sweat-absorbing layer and an antibacterial layer which are sequentially arranged from top to bottom, wherein one side, close to the sweat-absorbing layer, of the antibacterial layer is inwards sunken to form a plurality of placing grooves, the sweat-absorbing layer is fixedly connected in the placing grooves, and the sweat-absorbing layer arches between adjacent placing grooves and forms an air permeable cavity with the antibacterial layer.

The utility model is further provided with: one side of the antibacterial layer, which is close to the sweat absorbing layer, is fixedly connected with a plurality of antibacterial lines, and the antibacterial lines are filled in the ventilation cavity.

The utility model is further provided with: the cross section of the placing groove is isosceles trapezoid.

The utility model is further provided with: the antibacterial layer and the sweat-absorbent layer are both arranged into square and flat tissues, and the weaving pores of the antibacterial layer are larger than those of the sweat-absorbent layer.

The utility model is further provided with: the antibacterial layer is formed by knitting polyester yarns and ramie yarns which are alternately arranged.

The utility model is further provided with: the sweat absorbing layer is formed by weaving moisture absorbing elastic yarns, and the moisture absorbing elastic yarns comprise elastic cores and first and second strands which are alternately wound on the outer sides of the elastic cores.

The utility model is further provided with: the elastic core is formed by twisting a plurality of spandex fibers, the first folded yarn is formed by twisting a plurality of viscose fibers, and the second folded yarn is formed by twisting a plurality of ramie fibers.

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

the sweat-absorbing layer has reduced the area of contact of sweat-absorbing layer and body surface for the air can be followed and circulated in the clearance between sweat-absorbing layer and the body surface and quickened the evaporation rate of body surface and sweat-absorbing layer, even sweat-absorbing layer and body surface area's reduction sweat can reach stable transmission effect equally under the surface tension effect of water, and ventilative chamber has improved the ventilation effect of surface fabric, thereby further improves the drying rate of surface fabric and reaches the purpose that reduces bacterial growth.

Drawings

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

FIG. 2 is an enlarged schematic view of FIG. 1 at A;

FIG. 3 is a cut-away view of the absorbent elastic yarn of the present utility model.

In the figure: 1. a sweat-absorbing layer; 2. a bacteriostatic layer; 3. a placement groove; 4. a ventilation chamber; 5. a bacteriostasis line; 6. moisture-absorbing elastic yarn; 7. spandex fiber; 8. viscose fiber; 9. ramie fiber.

Detailed Description

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

This antibacterial deodorization dacron, as shown in fig. 1 and 2, including sweat-absorbing layer 1 and antibacterial layer 2 that set gradually from top to bottom, sweat-absorbing layer 1 can realize the quick absorption to body surface sweat, make the body surface keep dry and comfortable state, antibacterial layer 2 can restrain the growth and the multiplication of antibacterial, antibacterial layer 2 is close to sweat-absorbing layer 1's one side inwards sunken to be formed with a plurality of standing grooves 3, sweat-absorbing layer 1 fixed connection is in standing groove 3, be located sweat-absorbing layer 1 arch and antibacterial layer 2 between adjacent standing grooves 3 and form ventilative chamber 4, the setting of standing groove 3 has increased sweat-absorbing layer 1 and antibacterial layer 2's area of contact, guarantee sweat-absorbing layer 1 and antibacterial layer 2 connection's stability, sweat-absorbing layer 1 arch simultaneously, reduce sweat-absorbing layer 1 and body surface's area of contact, make the air can follow the clearance between sweat-absorbing layer 1 and the body surface in the speed of evaporating speed that the surface is accelerated, even sweat-absorbing layer 1 and body surface area's reduction sweat-absorbing layer 1 is the surface tension effect that sweat-absorbing layer 1's surface is still can steadily carried out under the surface tension effect of water and the surface, thereby the dry surface fabric that the ventilation speed of ventilation is further improved has been reached.

As shown in fig. 1 and 2, the antibacterial layer 2 is close to one side integrated into one piece of sweat-absorbing layer 1 and has a plurality of antibacterial lines 5, antibacterial line 5 fills in ventilative intracavity 4, antibacterial line 5 is that antibacterial layer 2 cuts the fine hair and handles the formation, increase antibacterial layer 2 and sweat-absorbing layer 1's area of contact through antibacterial line 5, strengthen the holistic antibacterial effect of surface fabric, antibacterial line 5 can support sweat-absorbing layer 1 simultaneously, make press on sweat-absorbing layer 1 after can support sweat-absorbing layer 1 through antibacterial line 5 arch, guarantee the ventilation effect of surface fabric, the cross-sectional shape of standing groove 3 is isosceles trapezoid, isosceles trapezoid's lateral wall slope sets up and makes sweat-absorbing layer 1 fixed connection in standing groove 3 time area is bigger, the inclined plane of standing groove 3 can lead sweat-absorbing layer 1 simultaneously, make sweat-absorbing layer 1 keep away from one side of antibacterial layer 2 smoother, improve the comfort level when sweat-absorbing layer 1 and human contact.

As shown in fig. 1, the antibacterial layer 2 and the sweat-absorbent layer 1 are both arranged into square and flat structures, and the weaving holes of the antibacterial layer 2 are larger than those of the sweat-absorbent layer 1, so that the exchange channels of air at two sides of the antibacterial layer 2 are larger, the evaporation and drying speeds of sweat are accelerated, the weaving density of the sweat-absorbent layer 1 is large, the contact area of the sweat-absorbent layer 1 and the body surface is larger in unit area, and the rapid attraction of the sweat-absorbent layer 1 to sweat is ensured.

As shown in fig. 1, the antibacterial layer 2 is formed by weaving alternately arranged polyester yarns and ramie yarns, wherein the polyester yarns are used as warp yarns, the ramie yarns are used as weft yarns, the antibacterial layer 2 is obtained by weaving according to a square and flat structure through a water jet loom, the structural strength of the polyester yarns is high, deformation is not easy to occur, the ramie yarns have natural antibacterial effect, the air permeability of the ramie yarns is good, and the sanitation of the antibacterial layer 2 is ensured.

As shown in fig. 1 and 3, the sweat-absorbent layer 1 is woven by a moisture-absorbent elastic yarn 6, the moisture-absorbent elastic yarn 6 comprises an elastic core and a first strand and a second strand which are alternately wound on the outer side of the elastic core, the elastic core is formed by twisting a plurality of spandex fibers 7, the first strand is formed by twisting a plurality of viscose fibers 8, and the second strand is formed by twisting a plurality of ramie fibers 9.

As shown in fig. 3, the spandex fiber 7 is twisted by a twisting machine to obtain an elastic core, the viscose fiber 8 is twisted by the twisting machine to obtain a first folded yarn, the ramie fiber 9 is twisted by the twisting machine to obtain a second folded yarn, the first folded yarn and the second folded yarn are spirally wound on the outer side of the elastic core in a spindle-moving mode to obtain the moisture-absorbing elastic yarn 6, the elasticity and elastic restoring force of the spandex fiber 7 are good, the spandex fiber 6 can be quickly restored to an initial state after the external force applied to the moisture-absorbing elastic yarn 6 is lost, the hygroscopicity of the viscose fiber 8 is good, the quick adsorption of sweat on the body surface is ensured, meanwhile, the antistatic effect of the viscose fiber 8 is good, the static electricity in the fabric is reduced, and the comfort of the fabric in use is improved.

As shown in fig. 1-3, twisted moisture-absorbing elastic yarns 6 are woven according to a square and flat structure through a water-jet loom to obtain a sweat-absorbing layer 1, the woven antibacterial layer 2 is cut into a plurality of antibacterial threads 5 through a velvet cutting machine, then hot-pressed on one side through a hot press to form a plurality of placing grooves 3, glue solution is smeared on the inner walls of the placing grooves 3 to bond the sweat-absorbing layer 1 in the placing grooves 3, and the length of the sweat-absorbing layer 1 between the adjacent placing grooves 3 is larger than that of the antibacterial layer 2.

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. Antibacterial deodorization dacron, including sweat-absorbing layer (1) and antibacterial layer (2) that set gradually from top to bottom, its characterized in that: one side of the antibacterial layer (2) close to the sweat-absorbing layer (1) is inwards sunken to form a plurality of standing grooves (3), the sweat-absorbing layer (1) is fixedly connected in the standing grooves (3), and the sweat-absorbing layer (1) between adjacent standing grooves (3) arches to form a ventilation cavity (4) with the antibacterial layer (2).

2. The antibacterial deodorizing polyester fabric according to claim 1, wherein: one side of the antibacterial layer (2) close to the sweat absorbing layer (1) is fixedly connected with a plurality of antibacterial lines (5), and the antibacterial lines (5) are filled in the ventilation cavity (4).

3. The antibacterial deodorizing polyester fabric according to claim 2, wherein: the section of the placing groove (3) is isosceles trapezoid.

4. A bacteriostatic deodorant polyester fabric according to claim 3, characterized in that: the antibacterial layer (2) and the sweat-absorbent layer (1) are both arranged into square and flat structures, and the weaving holes of the antibacterial layer (2) are larger than those of the sweat-absorbent layer (1).

5. The antibacterial deodorizing polyester fabric according to claim 2, wherein: the antibacterial layer (2) is formed by knitting polyester yarns and ramie yarns which are alternately arranged.

6. The antibacterial deodorizing polyester fabric according to claim 4, wherein: the sweat absorbing layer (1) is formed by weaving moisture absorbing elastic yarns (6), and the moisture absorbing elastic yarns (6) comprise elastic cores and first strands and second strands which are alternately wound on the outer sides of the elastic cores.

7. The antibacterial deodorizing polyester fabric according to claim 6, wherein: the elastic core is formed by twisting a plurality of spandex fibers (7), the first folded yarn is formed by twisting a plurality of viscose fibers (8), and the second folded yarn is formed by twisting a plurality of ramie fibers (9).