CN220742339U

CN220742339U - Antistatic oxford

Info

Publication number: CN220742339U
Application number: CN202322104932.8U
Authority: CN
Inventors: 顾培恋; 周昀达; 顾炳荣
Original assignee: Suzhou Panjiu Textile Technology Co ltd
Current assignee: Suzhou Panjiu Textile Technology Co ltd
Priority date: 2023-08-07
Filing date: 2023-08-07
Publication date: 2024-04-09
Anticipated expiration: 2033-08-07

Abstract

The utility model discloses antistatic oxford fabric, and relates to the technical field of textiles. The key points of the technical scheme are as follows: the anti-static fabric comprises an inner layer and an outer layer which are fixedly connected with each other, wherein one side of the outer layer, which is close to the inner layer, is fixedly connected with a plurality of moisture absorption sheets, a ventilation space exists between every two adjacent moisture absorption sheets, and one side of the inner layer, which is close to the outer layer, is fixedly connected with a conductive part which abuts against the moisture absorption sheets.

Description

Antistatic oxford

Technical Field

The utility model relates to the technical field of textiles, in particular to antistatic oxford.

Background

Oxford is woven by polyester fibers in a certain tissue mode, and the polyester fibers have good structural strength and shape retention, so that the oxford is commonly used for manufacturing clothes and the like.

In order to ensure the stability of the clothing fabric during use, the clothing fabric is manufactured by adopting double-layer fabrics, the double-layer fabrics can generate friction mutually during use to generate static electricity, the generated static electricity can enable the double-layer fabrics to be adsorbed together, sweat inside the fabrics is difficult to be emitted, and therefore the structure is arranged to solve the problem that the antistatic performance inside the double-layer fabrics is poor.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model aims to provide the antistatic oxford fabric, and the aim of improving the overall antistatic performance of the fabric is fulfilled by the arrangement of the structure.

The technical aim of the utility model is realized by the following technical scheme: the antistatic oxford comprises an inner layer and an outer layer which are fixedly connected with each other, wherein one side of the outer layer, which is close to the inner layer, is fixedly connected with a plurality of moisture absorption sheets, ventilation spaces exist between the adjacent moisture absorption sheets, and one side of the inner layer, which is close to the outer layer, is fixedly connected with a conductive part which is propped against the moisture absorption sheets.

The utility model is further provided with: the conductive part is arranged as a fluff layer, and graphene fibers exist in the conductive part.

The utility model is further provided with: the outer layer is provided with a plurality of through holes, and the through holes are positioned between adjacent moisture absorption sheets.

The utility model is further provided with: the moisture absorption sheet and the outer layer are integrally formed, the outer layer is formed by flower-forming tissues, the ground tissues of the flower-forming tissues are the outer layer, and the flower tissues of the flower-forming tissues are the moisture absorption sheet.

The utility model is further provided with: the moisture absorption piece is woven by moisture absorption yarns, and the moisture absorption yarns comprise moisture absorption yarn cores and moisture absorption cladding yarns spirally wound on the outer sides of the moisture absorption yarn cores.

The utility model is further provided with: the moisture-absorbing yarn core is formed by twisting viscose fibers, and the moisture-absorbing cladding yarn is formed by twisting polyester fibers.

The utility model is further provided with: the inner layer and the outer layer are woven by antistatic yarns, the antistatic yarns comprise antistatic core yarns I and antistatic core yarns II, the antistatic core yarns I are formed by twisting graphene fibers, and the antistatic core yarns II are formed by twisting polyester fibers II.

In summary, the utility model has the following beneficial effects: the setting of hygroscopic piece and conductive part has reduced the gluey area between inlayer and the skin, has reduced the phenomenon that produces static owing to friction between inlayer and the skin, and the setting of through-hole provides the inside passageway of outside air entering surface fabric, and the electric conductivity of air is relatively poor for the electric charge that the surface fabric inside produced can be stable discharge to the air in, has strengthened the electric conductivity when the surface fabric was used.

Drawings

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

FIG. 2 is a cross-sectional view of the present utility model;

FIG. 3 is a cut-away view of an absorbent yarn according to the present utility model;

FIG. 4 is a slice view of the antistatic yarn in the present utility model.

In the figure: 1. an inner layer; 2. an outer layer; 3. an absorbent sheet; 4. a conductive portion; 5. a through hole; 6. an absorbent yarn; 7. viscose fiber; 8. polyester fiber I; 9. an antistatic yarn; 10. a graphene fiber; 11. polyester fiber II.

Detailed Description

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

This antistatic oxford, as shown in fig. 1 and 2, including inlayer 1 and skin 2 of mutual fixed connection, inlayer 1 and skin 2 are sewed together through the sewing machine, the one side fixedly connected with of skin 2 being close to inlayer 1 is a plurality of hygroscopic pieces 3, hygroscopic piece 3 can be better when using absorption user's body surface and the moisture in the air, reduce because the inside too dry phenomenon that produces static of surface fabric, there is ventilative space between the adjacent hygroscopic piece 3, ventilative space's setting provides the inside space of outside air entering surface fabric, the air is the bad conductor of electricity, thereby in the direction air that the charge that makes the inside production of surface fabric can be better, inlayer 1 is close to the one side fixedly connected with and hygroscopic piece 3 offseting conductive part 4, conductive part 4's setting has increased the area of contact of inlayer 1 with skin 2 and air, the antistatic property when using of surface fabric has been strengthened.

As shown in fig. 1, fig. 2 and fig. 4, the conductive part 4 is set as the fluff layer, the inner layer 1 is placed in the roughening machine to be roughened to form the conductive part 4, the contact area between the inner layer 1 and the outside is increased by the conductive part 4, so that charges generated by the inner layer 1 can be better guided into the ventilation space, the antistatic performance of the fabric during use is enhanced by reducing the charge quantity of the inner layer 1, the graphene fiber 10 exists in the conductive part 4, the charge drainage performance of the graphene fiber 10 is better, the antistatic performance of the fabric during use is enhanced by utilizing the characteristics of the graphene fiber 10, the conductive part 4 is set as the fluff layer, and air in the ventilation space can better blow fluff and enter the conductive part 4, so that the antistatic performance of the fabric during use is enhanced.

As shown in fig. 1 and 2, a plurality of through holes 5 are formed along the thickness direction of the outer layer 2 through a laser perforating machine, the through holes 5 are positioned between the adjacent moisture absorption sheets 3, the space of the fabric for the outside air to flow through is enlarged through the arrangement of the through holes 5, the air quantity inside the fabric is increased, the conductive part 4 can better contact with the outside air and conduct out the accumulated charges inside the conductive part, and the antistatic performance of the fabric during use is ensured.

As shown in fig. 1 and 2, the moisture absorbing sheet 3 and the outer layer 2 are integrally formed, the outer layer 2 is formed by a flower-forming tissue, the ground tissue of the flower-forming tissue is the outer layer 2, the flower tissue of the flower-forming tissue is the moisture absorbing sheet 3, and the moisture absorbing sheet 3 is naturally formed by the outer layer 2 during weaving through the flower-forming tissue, so that the stability of the structure during manufacturing and using is ensured.

As shown in fig. 2 and 3, the moisture absorbing sheet 3 is woven by the moisture absorbing yarn 6, the moisture absorbing yarn 6 comprises a moisture absorbing yarn core and a moisture absorbing cladding yarn spirally wound on the outer side of the moisture absorbing yarn core, the moisture absorbing yarn core and the moisture absorbing cladding yarn are processed by a spindle spinning process to form the moisture absorbing yarn 6, the moisture absorbing yarn core is formed by twisting viscose fibers 7 by a twisting machine, the viscose fibers 7 have good moisture retention and moisture regain, the moisture absorbing sheet 3 can be stably in a wet state by utilizing the arrangement of the viscose fibers 7, the antistatic performance of the fabric in use is optimized by reducing the time of the fabric in a dry state, the moisture absorbing cladding yarn is formed by twisting polyester fibers 8 by the twisting machine, the polyester fibers 8 have good structural strength and shape retention, and the overall performance of the fabric in use is reinforced by the arrangement of the polyester fibers 8.

As shown in fig. 1, 2 and 4, the inner layer 1 and the outer layer 2 are woven by the antistatic yarn 9, the antistatic yarn 9 comprises an antistatic core yarn one and an antistatic core yarn two, the antistatic core yarn one and the antistatic core yarn two are twisted by a twisting machine to form the antistatic yarn 9, the antistatic core yarn one is formed by twisting graphene fibers 10 by the twisting machine, the antistatic performance of the fabric in use is enhanced by utilizing good conductivity of the graphene fibers 10, and the antistatic core yarn two is formed by twisting polyester fibers 11 by the twisting machine.

As shown in fig. 1 to 4, when the fabric is required to be manufactured, the antistatic yarn 9 and the hygroscopic yarn 6 are put into an air-jet loom and woven into the outer layer 2 and the hygroscopic piece 3 in a pattern weaving mode, a plurality of through holes 5 are formed along the thickness direction of the outer layer 2 through a laser perforating machine, the antistatic yarn 9 is put into the air-jet loom and woven into the inner layer 1, the inner layer 1 is put into a napping machine and napped into the conductive part 4, one side of the inner layer 1 forming the conductive part 4 is placed upwards, one side of the outer layer 2 forming the hygroscopic piece 3 is placed towards the inner layer 1, and finally the inner layer 1 and the outer layer 2 are sewn together through a sewing machine.

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

1. Antistatic oxford fabric, including inlayer (1) and skin (2) of fixed connection each other, its characterized in that: one side of the outer layer (2) close to the inner layer (1) is fixedly connected with a plurality of moisture absorption sheets (3), ventilation spaces exist between the adjacent moisture absorption sheets (3), and one side of the inner layer (1) close to the outer layer (2) is fixedly connected with a conductive part (4) propped against the moisture absorption sheets (3).

2. The antistatic oxford according to claim 1, wherein: the conductive part (4) is arranged as a fluff layer, and graphene fibers (10) are arranged in the conductive part (4).

3. The antistatic oxford according to claim 1, wherein: the outer layer (2) is provided with a plurality of through holes (5), and the through holes (5) are positioned between the adjacent moisture absorption sheets (3).

4. The antistatic oxford according to claim 1, wherein: the moisture absorption sheet (3) and the outer layer (2) are integrally formed, the outer layer (2) is formed by flower forming tissues, the ground tissues of the flower forming tissues are the outer layer (2), and the flower tissues of the flower forming tissues are the moisture absorption sheet (3).

5. The antistatic oxford according to claim 1, wherein: the moisture absorption piece (3) is formed by weaving moisture absorption yarns (6), and the moisture absorption yarns (6) comprise moisture absorption yarn cores and moisture absorption wrapping yarns spirally wound on the outer sides of the moisture absorption yarn cores.

6. The antistatic oxford according to claim 5, wherein: the moisture-absorbing yarn core is formed by twisting viscose fibers (7), and the moisture-absorbing cladding yarn is formed by twisting polyester fibers (8).

7. The antistatic oxford according to claim 1, wherein: the inner layer (1) and the outer layer (2) are woven by antistatic yarns (9), the antistatic yarns (9) comprise antistatic core yarns I and antistatic core yarns II, the antistatic core yarns I are formed by twisting graphene fibers (10), and the antistatic core yarns II are formed by twisting polyester fibers (11).