CN217145118U - Antibacterial and antistatic polyester fabric - Google Patents

Antibacterial and antistatic polyester fabric Download PDF

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Publication number
CN217145118U
CN217145118U CN202220552039.4U CN202220552039U CN217145118U CN 217145118 U CN217145118 U CN 217145118U CN 202220552039 U CN202220552039 U CN 202220552039U CN 217145118 U CN217145118 U CN 217145118U
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layer
antistatic
floating
sinking
fibers
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何金涛
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Wujiang Changjiang Textile Co ltd
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Wujiang Changjiang Textile Co ltd
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Abstract

The utility model discloses an antibacterial antistatic polyester fabric relates to fabrics technical field, aims at solving the surface fabric and does not have good antistatic effect, and its technical scheme main points are: including two surface courses that mutual symmetry set up, be equipped with the antistatic layer between two surface courses, one side that two surface courses are close to each other all is equipped with protruding net, be formed with a plurality of caves between protruding net and the surface course, the through-hole has been seted up on the sunken, the both sides of antistatic layer are equipped with a plurality of archs and stretch into in the cave, be equipped with electrically conductive fine hair in the arch and stretch into in the through-hole, through adopting the copper fibre, the copper fibre has fine electrically conductive effect, the electrically conductive effect of antistatic layer has been guaranteed, can derive static, the antistatic effect of whole surface fabric has been guaranteed.

Description

Antibacterial and antistatic polyester fabric
Technical Field
The utility model relates to a fabrics technical field, more specifically says, it relates to an antibacterial antistatic polyester fabric.
Background
The fabric is a material for making clothes, and as one of three elements of the clothes, the fabric can not only explain the style and the characteristics of the clothes, but also directly control the expression effects of the color and the shape of the clothes.
When the existing fabric is used for manufacturing the clothes, the clothes are worn on the body of people and are easy to rub against the body, so that static electricity is easy to generate on the clothes, and further inconvenience is easy to bring to wearers and other people.
Therefore, a new solution is needed to solve this problem.
SUMMERY OF THE UTILITY MODEL
Not enough to prior art exists, the utility model aims to provide an antibacterial antistatic polyester fabric reaches the purpose of preventing static through setting up of structure.
The above technical purpose of the present invention can be achieved by the following technical solutions: the utility model provides an antibacterial antistatic polyester fabric, includes two surface courses that mutual symmetry set up, two be equipped with antistatic layer between the surface course, two one side that the surface course is close to each other all is equipped with protruding net, be formed with a plurality of caves between protruding net and the surface course, the through-hole has been seted up on the sunken, antistatic layer's both sides are equipped with a plurality of archs and stretch into in the cave, be equipped with electrically conductive fine hair in the arch and stretch into in the through-hole.
Through adopting above-mentioned technical scheme, one side that two surface courses are close to each other all is equipped with protruding net for be formed with a plurality of caves between protruding net and the surface course, seted up the through-hole on the cave, guaranteed the ventilation effect of surface course, the both sides of antistatic layer are equipped with a plurality of archs, the arch stretches into in the cave, and is equipped with electrically conductive fine hair in the arch and stretches into the through-hole, make the antistatic layer be close the outside more, strengthened electrically conductive effect, guaranteed the antistatic effect of whole surface fabric.
The utility model discloses further set up to: the antistatic layer is the papaw yarn layer, the antistatic layer is woven through a plurality of compound yarn longitude and latitude and is formed, the surface course is the integrated into one piece structure with protruding net, the surface course is plain weave, protruding net is the change mesh tissue, the mesh of protruding net is 1 through the radical, the traction latitude radical of protruding net is 3.
Through adopting above-mentioned technical scheme, the antistatic layer is the papaw yarn layer for antistatic layer and protruding integrated into one piece structure, guaranteed the wholeness of whole antistatic layer, and surface course and protruding net be integrated into one piece structure, have guaranteed the wholeness of surface course, thereby have guaranteed the intensity of surface course.
The utility model discloses further set up to: the mesh change organization is 11 pages of healds, the warp floating points are floating points, the weft floating points are sinking points, and the mesh change organization is organized from left to right and from bottom to top in a circulating manner: the method comprises the steps of sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating and sinking.
Through adopting above-mentioned technical scheme, set up and change mesh tissue for the wholeness of surface course has been guaranteed to surface course and protruding net formation integrated into one piece structure.
The utility model discloses further set up to: the first composite yarn sequentially comprises a first core layer, a supporting layer and a coating layer from inside to outside, wherein the first core layer is formed by twisting a plurality of first core wires, and the first core wires are formed by twisting hollow fibers and chinlon.
By adopting the technical scheme, the hollow fiber has good fluffy feeling, and the chinlon has good elasticity, so that the strength of the first core layer is ensured.
The utility model discloses further set up to: the supporting layer is wound on the outer side of the core layer through a plurality of viscose fibers, the coating layer is wound on the outer side of the supporting layer through a plurality of conductive yarns, and the conductive yarns are formed by twisting copper fibers and cuprammonium fibers.
Through adopting above-mentioned technical scheme, viscose has the effect of fine moisture absorption moisturizing, and viscose is moist, plays fine antistatic effect, and copper fiber has fine electrically conductive effect, and copper ammonia fiber soft handle.
The utility model discloses further set up to: the surface course that shows is woven through a plurality of second compound yarn longitude and latitude and is formed, second compound yarn from inside to outside includes sandwich layer two, enhancement layer and surrounding layer in proper order, sandwich layer two forms through the twisting of a plurality of first heterotypic cross-section fibre, the fibrous cross-section in first heterotypic cross-section is the trilobal type.
By adopting the technical scheme, the trilobal special-shaped section fiber has good fluffy feeling, and the strength of the second core layer is ensured.
The utility model discloses further set up to: the reinforced layer is wound on the outer side of the core layer II through a plurality of bamboo charcoal fibers, the outer cladding layer is wound on the outer side of the reinforced layer through a plurality of outer cladding yarns, the outer cladding yarns are formed by twisting second special-shaped cross-section fibers and ice silk fibers, and the cross section of the second special-shaped cross-section fibers is flat.
By adopting the technical scheme, the bamboo charcoal fiber has a good antibacterial and deodorizing effect, the flat special-shaped cross section fiber has a good wear-resisting effect, and the surface of the ice silk fiber is softer, so that the ice silk fiber is more comfortable to wear.
To sum up, the utility model discloses following beneficial effect has:
one side that two surface courses are close to each other all is equipped with protruding net for be formed with a plurality of caves between protruding net and the surface course, seted up the through-hole on the sunken, guaranteed the ventilation effect of surface course, the both sides of antistatic layer are equipped with a plurality of archs, and the arch stretches into in the cave, and is equipped with electrically conductive fine hair in the arch and stretches into the through-hole, makes the antistatic layer be close the outside more, has strengthened electrically conductive effect, has guaranteed the antistatic effect of whole surface fabric.
Drawings
Fig. 1 is a schematic structural view of the present invention;
fig. 2 is a cross-sectional view of a first composite yarn of the present invention;
fig. 3 is a cross-sectional view of a second composite yarn of the present invention;
fig. 4 is an organization chart of the mesh-changing organization of the present invention.
In the figure: 1. a surface layer; 2. an antistatic layer; 3. a convex net; 4. a through hole; 5. a protrusion; 6. conductive velvet; 7. a first composite yarn; 8. a hollow fiber; 9. nylon; 10. viscose fibers; 11. copper fibers; 12. copper ammonia fiber; 13. a second composite yarn; 14. a first profiled cross-section fiber; 15. bamboo charcoal fiber; 16. a second profiled cross-section fiber; 17. and (4) ice silk fibers.
Detailed Description
The present invention will be described in detail with reference to the accompanying drawings and examples.
The utility model provides an antibacterial antistatic polyester fabric, as shown in figure 1, including two surface courses 1 that mutual symmetry set up, be equipped with antistatic layer 2 between two surface courses 1, one side that two surface courses 1 are close to each other all is equipped with protruding net 3, is formed with a plurality of caves between protruding net 3 and the surface course 1, has seted up through-hole 4 on the sunken, and the both sides of antistatic layer 2 are equipped with a plurality of archs 5 and stretch into sunken in, are equipped with electrically conductive fine hair 6 on the arch 5 and stretch into in through-hole 4.
As shown in fig. 1 and fig. 2, a polyester fiber is spun by a spinneret plate to form a hollow fiber 8, the hollow fiber 8 and a nylon 9 are put into a twisting machine to be twisted to form a core wire I, a plurality of core wires I are put into the twisting machine to be twisted to form a core layer I, a processed core layer I and a plurality of viscose fibers 10 are put into a spindle walking machine to be wound on the outer side of the core layer I in a spindle walking manner to form a supporting layer, a copper fiber 11 and a copper ammonia fiber 12 are put into the twisting machine to be twisted to form a conductive yarn, the processed supporting layer and a plurality of conductive yarns are put into the spindle walking machine to be wound on the outer side of the supporting layer in a spindle walking manner to form a coating layer, so as to obtain a whole first composite yarn 7, a plurality of first composite yarns 7 are put into a water jet loom to be woven in a plain weave manner to form an antistatic layer 2, and the warp and weft feeding amount of the antistatic layer 2 is controlled to form a warp and weft layer, make the equal a plurality of archs 5 of integrated into one piece in both sides of antistatic layer 2, utilize the raising machine for form electrically conductive fine hair 6 on the arch 5 of antistatic layer 2 one side.
As shown in fig. 1, 3 and 4, a first special-shaped cross-section fiber 14 with a trilobal cross section is formed by spinning polyester with a spinneret plate, a second core layer is formed by twisting a plurality of first special-shaped cross-section fibers 14 in a twisting machine, the processed second core layer and a plurality of bamboo charcoal fibers 15 are put in a spindle winder, a plurality of bamboo charcoal fibers 15 are wound on the outer side of the core layer in a spindle winding mode to form a reinforcing layer, a second special-shaped cross-section fiber 16 with a flat cross section is formed by spinning polyester with the spinneret plate, the second special-shaped cross-section fiber 16 and a plurality of ice silk fibers 17 are put in the twisting machine to be twisted to form an outer covering yarn, the processed reinforcing layer and the plurality of outer covering yarns are put in the spindle winder, a plurality of outer covering yarns are wound on the outer side of the reinforcing layer in a spindle winding mode to form an outer covering layer, the whole second composite yarn 13 is obtained, 1 second composite yarn 13 is used as a mesh warp and 3 second composite yarns 13 are used as a weft traction, and a plurality of second composite yarn 13 are sent into the internal longitude and latitude of hydraulic loom together according to the plain weave structure one on the other and are woven, in order to make the mesh appear in the surface through floating better this moment, during the reeding, penetrate the mesh in same dent with the warp of plain weave structure, its plain weave structure forms surface course 1, and make the protruding net 3 of one side integrated into one piece of surface course 1, protruding net 3 is the mesh weave that changes, it is 11 pages of mesh weave to be heald and float through the floating point, the floating point is sunken, it is from left to right to change mesh weave from the bottom to top tissue circulation: sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating, forming a plurality of the layers 1, sinking, 3, and the through holes 4 of the laser perforating machine, and the through holes are symmetrically arranged on one side of the through-hole 1, the through-hole, two layers, 2, and (3) the protrusions 5 on the antistatic layer 2 extend into the depressions, the conductive velvet 6 on the protrusions 5 extend into the through holes 4, and the two surface layers 1 and the antistatic layer 2 are sewn to obtain the fabric.
The clothing is made to this surface fabric, one side that two 1 mutual nears of surface course all is equipped with protruding net 3, make to be formed with a plurality of caves between protruding net 3 and the surface course 1, through-hole 4 has been seted up on the cave, the ventilation effect of surface course 1 has been guaranteed, the both sides of antistatic layer 2 are equipped with a plurality of archs 5, antistatic layer 2 weaves through 7 longitude and latitude of a plurality of first compound yarns and forms, copper fibre 11 on the first compound yarn 7 has fine electrically conductive effect, make arch 5 have fine electrically conductive effect, arch 5 stretches into in the cave, and the electrically conductive fine hair 6 that sets up on arch 5 stretches into in the through-hole 4, make antistatic layer 2 be close the outside more, electrically conductive fine hair 6 is close the outside more, the electrically conductive effect has been strengthened, the antistatic effect of whole surface fabric has been guaranteed.
It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (7)

1. An antibacterial antistatic polyester fabric is characterized in that: including two surface courses (1) that mutual symmetry set up, two be equipped with antistatic layer (2), two between surface course (1) one side that is close to each other in surface course (1) all is equipped with protruding net (3), be formed with a plurality of caves between protruding net (3) and surface course (1), through-hole (4) have been seted up on the sunken, the both sides of antistatic layer (2) are equipped with a plurality of archs (5) and stretch into in the sunken, be equipped with electrically conductive fine hair (6) on arch (5) and stretch into in through-hole (4).
2. A bacteriostatic antistatic polyester fabric according to claim 1, which is characterized in that: antistatic layer (2) are the seersucker layer, antistatic layer (2) are woven through a plurality of first compound yarn (7) longitude and latitude and are formed, surface course (1) and protruding net (3) are the integrated into one piece structure, surface course (1) is plain weave, protruding net (3) are the change mesh tissue, the mesh warp radical of protruding net (3) is 1, the weft radical that pulls of protruding net (3) is 3.
3. A bacteriostatic antistatic polyester fabric as claimed in claim 2, which is characterized in that: the mesh change organization is 11 pages of healds, the warp floating points are floating points, the weft floating points are sinking points, and the mesh change organization is organized from left to right and from bottom to top in a circulating manner: the method comprises the steps of sinking, floating, sinking, floating, sinking, floating, sinking, floating, sinking, floating and sinking.
4. A bacteriostatic antistatic polyester fabric as claimed in claim 2, which is characterized in that: the first composite yarn (7) sequentially comprises a first core layer, a supporting layer and a coating layer from inside to outside, wherein the first core layer is formed by twisting a plurality of first core wires, and the first core wires are formed by twisting hollow fibers (8) and chinlon (9).
5. A bacteriostatic antistatic polyester fabric according to claim 4, which is characterized in that: the supporting layer is wound on the outer side of the core layer through a plurality of viscose fibers (10), the coating layer is wound on the outer side of the supporting layer through a plurality of conductive yarns, and the conductive yarns are formed by twisting copper fibers (11) and copper ammonia fibers (12).
6. A bacteriostatic antistatic polyester fabric according to claim 1, which is characterized in that: surface course (1) is woven through a plurality of second composite yarn (13) longitude and latitude and is formed, second composite yarn (13) from interior to exterior includes sandwich layer two, enhancement layer and surrounding layer in proper order, sandwich layer two forms through a plurality of first heterotypic cross-section fibre (14) twists, the cross-section of first heterotypic cross-section fibre (14) is the trilobal type.
7. A bacteriostatic antistatic polyester fabric according to claim 6, characterized in that: the reinforced layer is wound on the outer side of the second core layer through a plurality of bamboo charcoal fibers (15), the outer covering layer is wound on the outer side of the reinforced layer through a plurality of outer covering yarns, the outer covering yarns are formed by twisting second special-shaped cross-section fibers (16) and ice silk fibers (17), and the cross section of the second special-shaped cross-section fibers (16) is flat.
CN202220552039.4U 2022-03-14 2022-03-14 Antibacterial and antistatic polyester fabric Active CN217145118U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202220552039.4U CN217145118U (en) 2022-03-14 2022-03-14 Antibacterial and antistatic polyester fabric

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202220552039.4U CN217145118U (en) 2022-03-14 2022-03-14 Antibacterial and antistatic polyester fabric

Publications (1)

Publication Number Publication Date
CN217145118U true CN217145118U (en) 2022-08-09

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ID=82692874

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202220552039.4U Active CN217145118U (en) 2022-03-14 2022-03-14 Antibacterial and antistatic polyester fabric

Country Status (1)

Country Link
CN (1) CN217145118U (en)

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