CN213772384U - Breathable fabric with antibacterial effect - Google Patents

Abstract

The utility model discloses a ventilative surface fabric with antibiotic effect, include: long stapled cotton fibers, spandex fibers, and antibacterial fibers; a plurality of long staple cotton fibers are mutually wound and twisted to form yarns, and a plurality of spandex fibers are mutually wound and twisted to form silk threads; a plurality of yarns and a plurality of silk yarns 3 are woven in a penetrating way in a horizontal and vertical alternating way to form plain weave fabric with meshed through holes; the antibacterial threads 2 are arranged on the plain weave fabric in a transverse-vertical alternating mode through the mesh through holes, the antibacterial threads are partially exposed on the top surface and the bottom surface of the plain weave fabric, the fabric has softness and elasticity and also has certain air permeability, the antibacterial threads are arranged in the mesh through holes of the plain weave fabric in a transverse-vertical alternating mode and are uniformly penetrated so as to enable the fabric to have antibacterial capacity, and the antibacterial threads are partially exposed on the top surface and the bottom surface of the plain weave fabric, so that the contact surface between the antibacterial threads and the outside (particularly skin) is increased, and the antibacterial utilization rate of the antibacterial threads is improved.

Description

Breathable fabric with antibacterial effect

Technical Field

The utility model relates to a ventilative surface fabric equipment technical field, concretely relates to ventilative surface fabric with antibiotic effect.

Background

The appearance of new fabrics in recent years is greatly popular and sought after by consumers with various added excellent performances on the premise of meeting basic wearing and comfort, such as: the anti-bacterial fabric has the antibacterial function, which can block disease propagation and is always valued for sanitation and cleanness keeping, and also exists as the basic characteristic of a high-grade fabric, particularly close-fitting clothes or articles, and can directly protect human bodies from interference and infection. At present, the antibacterial function is mainly used in the aspects of underwear, socks, home textiles, bedding, towels and the like.

However, in the past decades, it has become popular at home and abroad to use silver-ion antibacterial fibers, i.e., silver-based antibacterial fibers such as silver-based antibacterial nylon, silver-based antibacterial polyester, silver-based antibacterial polypropylene, etc. However, silver ions are expensive, the addition ratio is continuously reduced by manufacturers, the expected effect is rarely achieved, and once the silver ions contact the skin and enter the human body through the skin, the silver ions bring cumulative damage to the human body; the antibacterial effect of the silver ions is affected by light and heat, and the silver ions are easy to reduce and reduce the antibacterial effect after long-term use; in addition, the antibacterial fiber prepared by the copper ion antibacterial method can carry light blue, the color of the fabric is influenced, the processing and the use of the fabric are not facilitated, the air permeability and the flexibility of the fabric are poor, the antibacterial fiber is less in contact with the outside, and the antibacterial performance utilization rate is low, so that the additional cost of the fabric structure is low, the fabric structure is colorless, and the zinc ions with good antibacterial and mildew-proof effects are utilized, so that the fabric has the characteristics of air permeability, flexibility, antibacterial and antiviral effects and the like.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a ventilative surface fabric with antibiotic effect to solve the gas permeability of antibiotic surface fabric, compliance is poor, and antibiotic fibre contacts the external world few, leads to the problem that antibiotic performance utilization rate is low.

In order to solve the technical problem, the utility model adopts the following technical scheme:

a breathable fabric with an antibacterial effect, comprising: long stapled cotton fibers, spandex fibers, and antibacterial fibers;

a plurality of the long stapled cotton fibers are mutually wound and twisted to form yarns, and a plurality of the spandex fibers are mutually wound and twisted to form silk threads;

a plurality of yarns and a plurality of silk threads 3 are alternately woven in a penetrating manner in a horizontal and vertical direction to form plain weave fabric with meshed through holes;

the antibacterial fibers are mutually wound and twisted to form antibacterial wires, the antibacterial wires 2 are arranged on the plain weave fabric in a horizontally-vertically alternating mode through the mesh through holes, and the antibacterial wires are partially exposed on the top surface and the bottom surface of the plain weave fabric.

The further technical scheme is as follows: the antibacterial fiber is plant fiber rich in zinc ions.

The further technical scheme is as follows: the antibacterial fiber is a modified natural fiber attached with zinc ions.

The further technical scheme is as follows: the antibacterial thread is prepared by mutually winding and twisting a plurality of natural plant fibers;

or, the modified natural fiber is prepared by mutually winding and twisting a plurality of modified natural fibers;

or the plant fiber is prepared by mixing a plurality of plant fibers and a plurality of long stapled cotton fibers, and mutually winding and twisting;

or the modified natural fibers and the long stapled cotton fibers are mixed and mutually wound and twisted to prepare the modified natural fiber;

or the plant fiber is prepared by mixing a plurality of plant fibers, a plurality of modified natural fibers and a plurality of long staple cotton fibers, and mutually winding and twisting the plant fibers, the modified natural fibers and the long staple cotton fibers.

The further technical scheme is as follows: elastic fibers are clamped in the antibacterial wire.

The further technical scheme is as follows: the thickness of the yarn is 40S, and the thickness of the silk thread is 20D/piece.

Compared with the prior art, the utility model discloses can reach one of following beneficial effect at least:

1. the utility model provides a breathable fabric with antibacterial effect, utilize long staple cotton fiber and spandex fibre to twist into yarn and silk thread, through setting up yarn and silk thread are adjacent, and wear to weave in turn anyhow and be the plain weave surface fabric that has netted through-hole, combine the compliance that long staple cotton fiber itself possessed and the elasticity that spandex fibre itself possessed, make plain weave surface fabric have compliance and elasticity simultaneously, certain gas permeability also has in addition, the antibiotic line that just evenly wears to be equipped with in turn anyhow in plain weave surface fabric's netted through-hole makes it possess antibacterial ability, and the part of antibiotic line exposes on plain weave surface fabric's top surface and bottom surface, increase the contact surface of antibiotic line and external (especially and skin), improve the antibiotic utilization ratio of antibiotic line.

2. The antibacterial thread in the fabric contains zinc ions which are low in cost, colorless and good in mildew-proof effect, and on the premise of not changing the color of the fabric, the zinc ions enter the interior of bacteria to react and combine with cellular enzymes of the bacteria, so that the activity of the cellular enzymes and the reproduction and regeneration of the bacteria are inhibited, and the effect of killing the bacteria is achieved.

Drawings

Fig. 1 is a schematic structural view of the plain weave fabric of the present invention.

Fig. 2 is a schematic structural diagram of a in fig. 1 according to the present invention.

Fig. 3 is a schematic structural view of the breathable fabric with antibacterial effect of the present invention.

Fig. 4 is a schematic structural view of the antibacterial thread of the present invention 1.

Reference numerals: 1. a yarn; 10. long staple cotton fibers; 2. an antimicrobial thread; 20. an antimicrobial fiber; 3. a silk thread; 30. spandex fibers; 13. and (5) plain weave fabric.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1:

embodiment 1 referring to fig. 1, fig. 2, fig. 3 and fig. 4, an embodiment of a breathable fabric with antibacterial effect includes: long stapled cotton fiber 10, spandex fiber 30, and antibacterial fiber 20;

a plurality of the long stapled cotton fibers 10 are mutually wound and twisted to form a yarn 1, and a plurality of the spandex fibers 30 are mutually wound and twisted to form a silk thread 3;

a plurality of yarns 1 and a plurality of silk threads 3 are alternately woven in a penetrating manner in a horizontal and vertical direction to form a plain weave fabric 13 with meshed through holes;

the antibacterial fibers 20 are mutually wound and twisted to form the antibacterial wires 2, the antibacterial wires 2 are arranged on the plain weave fabric 13 in a horizontally-vertically alternating manner through the mesh through holes, and parts of the antibacterial wires 2 are exposed on the top surface and the bottom surface of the plain weave fabric.

The breathable fabric with the antibacterial effect has the following structure: the yarn 1 and the silk thread 3 are twisted by combing long stapled cotton fiber 10 (the length is not less than 1 cm) and spandex fiber 30, the yarn 1 and the silk thread 3 are adjacently arranged side by side, then, the yarns 1 and the silk threads 3 which are adjacently arranged side by side are interwoven (vertically and horizontally alternately penetrated and woven) through a loom to form a plain fabric 13 with reticular through holes (please refer to fig. 2), and the softness of the long stapled cotton fiber 10 and the elasticity of the spandex fiber 30 are combined, so that the plain weave fabric 13 has both softness and elasticity and also has certain air permeability, the antibacterial threads 2 are alternately and uniformly arranged in the reticular through holes of the plain weave fabric 13 in a penetrating way in a transverse and vertical way so as to ensure that the plain weave fabric has antibacterial capability, and the part of the antibacterial thread 2 is exposed on the top surface and the bottom surface of the plain weave fabric 13, so that the contact surface of the antibacterial thread 2 with the outside (particularly with the skin) is increased, and the antibacterial utilization rate of the antibacterial thread 2 is improved.

Preferably, the antibacterial fiber 20 is made of plant fiber rich in zinc ions, such as beans, peanuts, millet, radish, Chinese cabbage fiber, and the like, and the antibacterial fiber 20 may be one or more of them.

The antibacterial fiber 20 is made of plant fiber rich in zinc ions, and the raw materials are simple and easy to obtain and convenient to process, but the content of the zinc ions in the fabric is probably less.

Preferably, the antibacterial fiber 20 is a modified natural fiber to which zinc ions are attached.

The antibacterial fiber 20 is a modified natural fiber attached with zinc ions, the plant fiber containing zinc ions is extracted from a plant extract rich in zinc elements, and the plant fiber containing zinc ions is permanently added to the natural fiber through a modification process to obtain the modified natural fiber, so that the raw material cost is reduced.

Since the surface of the bacteria has negative charges, zinc ions with positive charges are adsorbed on the surface of the bacteria, thereby breaking the electrolyte balance of the bacteria, and causing the bacteria to die due to damaged cell walls. The zinc element enters the interior of the bacteria to react and combine with cellular enzyme of the bacteria, and inhibits the cellular enzyme activity and the reproduction and regeneration of the bacteria, thereby achieving the effect of killing the bacteria. The zinc element is subjected to a replacement reaction in the modification process, so that the zinc element cannot fall off in the fiber fabric, and is safe and harmless. The zinc element can also neutralize and eliminate peculiar smell generated by the body, keeps the skin clean all the time, and silver ions, copper ions and zinc ions have antibacterial effect, so the zinc ions are adopted, and once the silver ions contact the skin and enter the human body through the skin, the accumulated damage to the human body can be caused; the antibacterial effect of the silver ions is affected by light and heat, and the silver ions are easy to reduce and reduce the antibacterial effect after long-term use; in addition, the antibacterial fiber prepared by the copper ion antibacterial method carries light blue, which affects the color of the fabric and is not beneficial to the processing and use of the fabric.

Example 4:

on the basis of the above embodiment, embodiment 4 shows an embodiment in which the antibacterial thread 2 is made by winding and twisting a plurality of natural plant fibers;

or, the modified natural fiber is prepared by mutually winding and twisting a plurality of modified natural fibers;

or, the plant fiber is prepared by mixing a plurality of plant fibers and a plurality of long stapled cotton fibers 10, and mutually winding and twisting the plant fibers and the long stapled cotton fibers;

or, the modified natural fibers and the long stapled cotton fibers 10 are mixed and twisted with each other to obtain the modified natural fibers;

or the plant fiber is prepared by mixing, mutually winding and twisting a plurality of plant fibers, a plurality of modified natural fibers and a plurality of long stapled cotton fibers 10;

firstly, the antibacterial thread 2 is prepared by mutually winding and twisting a plurality of heaven plant fibers, and the raw materials are simple and easy to obtain and convenient to process;

secondly, the modified natural fiber fabric is prepared by mutually winding and twisting a plurality of modified natural fibers, so that the content of zinc ions in the fabric is improved, and the antibacterial capacity is improved;

thirdly, the modified natural fiber is prepared by mixing and mutually winding and twisting a plurality of modified natural fibers and a plurality of long stapled cotton fibers 10, and the softness is improved on the basis of the first step;

fourthly, a plurality of modified natural fibers and a plurality of long stapled cotton fibers 10 are mixed and mutually wound and twisted to obtain the yarn; on the basis of the second step, the flexibility is improved;

the antibacterial yarn is prepared by mixing and mutually winding and twisting a plurality of plant fibers, a plurality of modified natural fibers and a plurality of long stapled cotton fibers 10, so that the cost is reduced, and the softness of the antibacterial yarn 2 is improved;

example 5:

on the basis of the above embodiment, embodiment 5 shows an embodiment in which elastic fibers are further sandwiched in the antibacterial thread 2.

Elastic fibers are clamped in the antibacterial thread 2, so that the elasticity of the antibacterial thread 2 is improved.

Example 6:

on the basis of the above embodiment, embodiment 6 shows an embodiment in which the thickness of the yarn 1 is 40S and the thickness of the wire 3 is 20D/thread.

In addition, in order to ensure certain structural strength, the long stapled cotton fiber 10 and the spandex fiber 30 can be twisted into the yarn 1 and the silk thread 3, and multiple strands of yarn drawing are respectively carried out to strengthen the line strength.

The appearances of the same phrase in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the scope of the invention to effect such feature, structure, or characteristic in connection with other embodiments.

Although the invention has been described herein with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this invention. More specifically, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, other uses will also be apparent to those skilled in the art.

Claims (6)

1. The utility model provides a breathable fabric with antibacterial effect which characterized in that includes: long stapled cotton fiber (10), spandex fiber (30) and antibacterial fiber (20);

a plurality of the long stapled cotton fibers (10) are mutually wound and twisted to form yarns (1), and a plurality of the spandex fibers (30) are mutually wound and twisted to form silk threads (3);

a plurality of yarns (1) and a plurality of silk threads (3) are alternately woven in a penetrating way in a horizontal and vertical direction to form a plain weave fabric (13) with meshed through holes;

the antibacterial fibers (20) are mutually wound and twisted to form the antibacterial wires (2), the antibacterial wires (2) are arranged on the plain weave fabric (13) in a horizontally-vertically alternating mode through the meshed through holes, and parts of the antibacterial wires (2) are exposed on the top surface and the bottom surface of the plain weave fabric (13).

2. The breathable fabric with the antibacterial effect according to claim 1, characterized in that: the antibacterial fiber (20) is made of plant fiber rich in zinc ions.

3. The breathable fabric with the antibacterial effect according to claim 2, characterized in that: the antibacterial fiber (20) is a modified natural fiber attached with zinc ions.

4. The breathable fabric with the antibacterial effect according to claim 3, characterized in that: the antibacterial thread (2) is prepared by mutually winding and twisting a plurality of natural plant fibers;

or, the modified natural fiber is prepared by mutually winding and twisting a plurality of modified natural fibers;

or a plurality of plant fibers and a plurality of long stapled cotton fibers (10) are mixed and mutually wound and twisted to prepare the fiber material;

or a plurality of modified natural fibers and a plurality of long stapled cotton fibers (10) are mixed and mutually wound and twisted to prepare the fiber material;

or the plant fiber is prepared by mixing, mutually winding and twisting a plurality of plant fibers, a plurality of modified natural fibers and a plurality of long stapled cotton fibers (10).

5. The breathable fabric with the antibacterial effect according to claim 4, characterized in that: elastic fibers are also clamped in the antibacterial wire (2).

6. The breathable fabric with the antibacterial effect according to claim 4, characterized in that: the thickness of the yarn (1) is 40S, and the thickness of the silk threads (3) is 20D/piece.

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