CN220146877U - Antibacterial grey cloth - Google Patents

Abstract

The utility model discloses antibacterial grey cloth, and relates to the technical field of textiles. The key points of the technical scheme are as follows: the breathable air-permeable fabric comprises an antibacterial layer and a breathable layer, wherein the breathable layer is provided with breathable holes, a plurality of supporting parts are fixedly connected between the breathable layers between every two adjacent breathable holes, a breathable cavity is formed among the adjacent supporting parts, the antibacterial layer and the breathable layer, the breathable cavity is communicated with the breathable holes, one side, close to the breathable layer, of the antibacterial layer is fixedly connected with a plurality of antibacterial velvet, and the antibacterial velvet stretches into the breathable holes through the breathable cavities. According to the utility model, through the arrangement of the bamboo fibers, the bamboo fibers have good antibacterial and antibacterial effects, and have a certain deodorizing effect, so that the overall antibacterial effect of the fabric is ensured.

Description

Antibacterial gray fabric

Technical field

The utility model relates to the technical field of textiles, and more specifically to antibacterial gray fabrics.

Background technique

Gray cloth refers to the native cotton cloth used for printing and dyeing. Most of the underwear worn by people is made of gray cloth.

Underwear generally refers to the tight-fitting lower body trousers. It is a necessity for people to wear and use. It is divided into two types: men's clothing and women's clothing.

In the summer, the weather is hot, and due to the material of the underwear itself, the antibacterial properties of the gray fabric used in underwear fabrics are relatively poor. When people wear underwear to exercise outdoors, a large amount of sweat will be produced on the surface of the human body. Since the underwear fabric is in contact with the human body Surface fit, traditional underwear cannot completely absorb sweat. If sweat adheres to the underwear fabric for a long time, the sweat will not evaporate into the air quickly, which can easily cause a large number of bacteria to occur between the underwear fabric and the surface of the human body. Therefore, a structure is provided to It is necessary to solve the problem of poor antibacterial effect of traditional underwear.

Therefore, a new solution needs to be proposed to solve this problem.

Utility model content

In view of the shortcomings of the existing technology, the purpose of this utility model is to provide antibacterial gray fabrics, which can improve the overall breathability effect of the fabrics through structural settings.

The above technical purpose of the present utility model is achieved through the following technical solution: it includes an antibacterial layer and a breathable layer, the breathable layer is provided with breathable holes, and the breathable layers between adjacent breathable holes are fixedly connected with a plurality of air permeable layers. The support part has a breathable cavity formed between the adjacent support part, the antibacterial layer and the breathable layer. The breathable cavity is connected to the breathable hole. A number of antibacterial velvets are fixedly connected to the side of the antibacterial layer close to the breathable layer. The antibacterial fleece extends into the ventilation holes through the ventilation cavity.

The utility model is further configured such that: the breathable layer and a plurality of through holes are an integrally formed structure, and the breathable layer is partially penetrated into a mesh structure formed by the combs GB1 and GB2.

The utility model is further configured as follows: the comb bar GB1 is a front comb that is worn and emptied to perform a changing warp and flat movement, the comb bar GB2 is a rear comb that is worn and emptied to perform a changing warp and flat movement, and the comb bar GB1 and comb bar GB2 are Symmetrical setup.

The utility model is further configured as follows: the organizational structure of the comb GB1 is 10/12/10/23/21/23∥, and the organizational structure of the comb GB2 is 23/21/23/10/12/10∥ .

The utility model is further configured as follows: the breathable layer is warp-knitted by breathable yarns. The breathable yarns include a core thread and an outer cladding from the inside to the outside. The core thread is twisted by a plurality of polyester fibers. In this way, the outer layer is wrapped around the outer side of the core wire through a number of cotton fibers.

The utility model is further configured as follows: the antibacterial layer is warp-knitted by a number of antibacterial yarns, and the antibacterial yarns include core yarn two, a moisture dispersing layer and a knot layer from the inside to the outside, and the core yarn two is warp-knitted by several antibacterial yarns. It is made of twisted polyester fiber, and the moisture dispersing layer is wound around the outside of core wire 2 through a number of bamboo fibers.

The utility model is further configured such that the knot layer is wound around the outside of the moisture dispersing layer through a plurality of knot lines, and the knot lines are made of polyester fiber.

To sum up, the present utility model has the following beneficial effects:

A number of support parts are fixedly connected to the breathable layer between adjacent breathable holes. A breathable cavity is formed between the adjacent support parts, the antibacterial layer and the breathable layer. The breathable layer is provided with a breathable hole connected to the breathable cavity, and the antibacterial layer is close to A number of antibacterial velvets are fixedly connected to one side of the breathable layer. The antibacterial velvet extends into the breathable holes through the breathable cavity. When the fabric comes into contact with the human body, the breathable holes reduce the contact area with the human body, thereby enhancing the overall breathability effect of the fabric and the human body. The antibacterial thread absorbs sweat from the human body surface to the antibacterial layer to ensure the dryness of the human body surface and prevent sweat from staying between the human body surface and the fabric to breed bacteria.

Description of the drawings

Figure 1 is a schematic structural diagram of the utility model;

Figure 2 is an enlarged view of part A in Figure 1;

Figure 3 is a slice diagram of the breathable yarn in the present utility model;

Figure 4 is a slice diagram of the antibacterial yarn in the present utility model;

Figure 5 is a yarn-laying movement diagram of the comb bar GB1 of the present utility model;

Figure 6 is a yarn-laying movement diagram of the comb bar GB2 of the present utility model.

In the picture: 1. Antibacterial layer; 2. Breathable layer; 3. Support part; 4. Breathable cavity; 5. Breathable holes; 6. Antibacterial velvet; 7. Breathable yarn; 8. Polyester fiber; 9. Cotton fiber; 10 , Antibacterial yarn; 11. Bamboo fiber; 12. Knot thread.

Detailed ways

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

The antibacterial gray fabric, as shown in Figures 1 and 2, includes an antibacterial layer 1 and a breathable layer 2. The breathable layer 2 is provided with breathable holes 5, and the breathable layers 2 between adjacent breathable holes 5 are fixedly connected with a number of The support part 3 has a breathable cavity 4 formed between the adjacent support part 3, the antibacterial layer 1 and the breathable layer 2. The breathable cavity 4 is connected to the breathable hole 5. A number of antibacterial velvets are fixedly connected to the side of the antibacterial layer 1 close to the breathable layer 2. 6. The antibacterial fleece 6 extends into the ventilation hole 5 through the ventilation cavity 4.

As shown in Figure 1, Figure 2 and Figure 3, take a number of polyester fibers 8 and put them into a twisting machine and twist them to form a core thread. The polyester fibers 8 have good strength and good shape retention, which further ensures the core To improve the overall strength of thread 1, two cotton fibers 9 are spirally wound around each other on the outside of core thread 1 through a spindle spinning process to obtain breathable yarn 7. Cotton fiber 9 has good hygroscopicity and is not easy to fluff and pill. To further ensure the moisture absorption effect of the breathable yarn 7, the cotton fiber 9 is kneaded by the carding machine of the wool spinning equipment to form knots, and the knots are processed on the cotton fiber 9 through the wool spinning equipment to obtain the knot line 12. The processed moisture dispersing layer and several knot lines are 12 is put into the spindle machine, so that a number of knot threads 12 are wound around the outside of the moisture dispersing layer in a spindle manner. The cotton fiber 9 has a good moisture absorption effect, making the adjacent support part 3, antibacterial layer 1 and breathable layer 2 A breathable cavity 4 is formed between them to form a channel for air circulation to ensure the overall breathable effect of the fabric.

As shown in Figure 1, Figure 5 and Figure 6, the breathable yarn 7 is put into the warp knitting machine as bar GB1 and bar GB2, and is warp knitted by partially passing through the mesh structure to form the breathable layer 2, where The organizational structure of comb GB1 is: (23/21)×2/(10/12)×2//one pierced and one empty. The organizational structure of comb GB2 is: (10/12)×2/(23/21) ×2//One wear and one empty, through the above-mentioned knitting structure, a number of meshes are integrally formed on the breathable layer 2, thereby forming a number of breathable holes 5 connected to the breathable cavity 4, ensuring the overall breathable effect of the breathable layer 2.

As shown in Figure 1, Figure 2 and Figure 4, a number of polyester fibers 8 are put into a twisting machine and twisted to form core yarn 2, which further ensures the structural strength of core yarn 2. The two fibers are spun through the spindle spinning process. Bamboo fiber 11 is wound around the outside of core yarn 2 to obtain antibacterial layer 1. Bamboo fiber 11 has good antibacterial and antibacterial effects, and has a certain deodorizing effect, which further ensures the overall antibacterial effect of antibacterial yarn 10 and combines several The antibacterial yarn 10 is put into the warp knitting machine and is warp-knitted in the form of a double warp flat weave to form the antibacterial layer 1. The above-mentioned weave has a precise structure, the gaps between the yarns are uniform, the structural strength is high, and it has Very good breathability.

As shown in Figures 1 and 2, a number of bamboo fibers 11 are put into a twisting machine and twisted to form antibacterial velvet 6. Bamboo fibers 11 have good antibacterial and antibacterial effects, and have good deodorizing effects. The antibacterial effect of the antibacterial thread is further ensured, and the antibacterial thread is sizing to increase the strength of the antibacterial thread and avoid breakage. The antibacterial thread is fixed on the antibacterial layer 1 through a flocking machine. When the fabric comes into contact with the human body , the ventilation holes 5 reduce the contact area with the human body, enhance the overall ventilation effect of the two surfaces, and absorb the sweat on the human body surface to the antibacterial layer 1 through the antibacterial thread, ensuring the dryness of the human body surface and preventing sweat from staying on the human body surface and Bacteria can breed between fabrics.

The above are only the preferred embodiments of the present utility model. The protection scope of the present utility model is not limited to the above-mentioned embodiments. All technical solutions falling under the idea of the present utility model belong to the protection scope of the present utility model. It should be pointed out that for those of ordinary skill in the art, several improvements and modifications may be made without departing from the principles of the present utility model, and these improvements and modifications should also be regarded as the protection scope of the present utility model.

Claims (7)

1. Antibacterial grey cloth, its characterized in that: including antibiotic layer (1) and ventilative layer (2), bleeder vent (5) have been seted up on ventilative layer (2), adjacent fixedly connected with a plurality of supporting parts (3) between ventilative layer (2) between bleeder vent (5), it is adjacent be formed with ventilative chamber (4) between supporting part (3), antibiotic layer (1) and ventilative layer (2), ventilative chamber (4) intercommunication bleeder vent (5), one side fixedly connected with a plurality of antibiotic fine hair (6) of antibiotic layer (1) near ventilative layer (2), antibiotic fine hair (6) stretch into in bleeder vent (5) through ventilative chamber (4).

2. The bacteriostatic grey cloth according to claim 1, wherein: the breathable layer (2) and the ventilation holes (5) are of an integrated structure, and the breathable layer (2) forms part of a through mesh tissue through the guide bar GB1 and the guide bar GB 2.

3. The bacteriostatic grey cloth according to claim 2, characterized in that: the guide bar GB1 is in front guide bar-to-air warp-changing flat motion, the guide bar GB2 is in back guide bar-to-air warp-changing flat motion, and the guide bars GB1 and GB2 are symmetrically arranged.

4. A bacteriostatic grey fabric according to claim 3, characterized in that: the organization structure of the guide bar GB1 is 10/12/10/23/21/23 per liter, and the organization structure of the guide bar GB2 is 23/21/23/10/12/10 per liter.

5. The bacteriostatic grey fabric according to claim 4, wherein: the breathable layer (2) is formed by warp knitting of breathable yarns (7), the breathable yarns (7) sequentially comprise a first core wire and an outer wrapping layer from inside to outside, the first core wire is formed by twisting a plurality of polyester fibers (8), and the outer wrapping layer is wound on the outer side of the first core wire through a plurality of cotton fibers (9).

6. The bacteriostatic grey cloth according to claim 1, wherein: the antibacterial layer (1) is formed by warp knitting a plurality of antibacterial yarns (10), the antibacterial yarns (10) sequentially comprise a core wire II, a moisture-dissipation layer and a knot sublayer from inside to outside, the core wire II is formed by twisting a plurality of polyester fibers (8), and the moisture-dissipation layer is wound on the outer side of the core wire II through a plurality of bamboo fibers (11).

7. The bacteriostatic grey fabric of claim 6, wherein: the knot sub-layer is wound on the outer side of the moisture-dissipating layer through a plurality of knot sub-lines (12), and the knot sub-lines (12) are made of polyester fibers (8).