CN218577164U - Thermal insulation antistatic polyester fabric - Google Patents

Abstract

The utility model discloses a heat preservation antistatic polyester fabric relates to polyester fabric weaving technical field, and its technical scheme main points are: including nexine and surface course, the one side array that the surface course is close to the nexine is provided with a plurality of archs, and a plurality of through-holes have been seted up to the array on the nexine, is provided with mercerized wool in the through-hole, and mercerized wool extends and keeps away from the nexine towards the one side that the surface course was kept away from to the nexine, is provided with the adsorbed layer between nexine and the surface course, and the adsorbed layer laminates with mercerized wool, and the bleeder vent of being connected with the arch is seted up to the adsorbed layer array, forms thermal-insulated chamber between surface course and the nexine. The utility model discloses a set up numb and polyamide fibre on the surface course, the numb is difficult for producing static, and the polyamide fibre has good warmth retention, has guaranteed the antistatic effect of whole surface fabric heat preservation.

Description

Thermal insulation antistatic polyester fabric

Technical Field

The utility model relates to a woven technology field of dacron, more specifically says, it relates to a heat preservation antistatic dacron.

Background

Polyester fibers, commonly known as "dacron". The PET fiber is a synthetic fiber obtained by spinning polyester formed by polycondensation of organic dibasic acid and dihydric alcohol, is called PET fiber for short, and belongs to a high molecular compound. Invented in 1941, is the first major variety of current synthetic fibers. The polyester fiber has the advantages of good crease resistance and shape retention, high strength and elastic recovery capability. It is firm and durable, has the functions of resisting wrinkle, preventing ironing and preventing hair from sticking.

The staff of filling station is at the during operation, and is very high to staff's dress requirement because of oil is inflammable and explosive thing, needs the clothing can not produce static, when refueling if produce static and take place combustion-supporting very probably, explode even, when some areas winter especially, weather is cold air too dry, and the staff of filling station produces static more easily, leads to the dangerous emergence of filling station higher.

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 a antistatic dacron keeps warm, through be provided with the arch in the adsorbed one side of surface course orientation, set up the bleeder vent that corresponds with the arch on the adsorbed layer, set up the through-hole with the dislocation of breather axis on the surface course, set up the thermal mercerized wool of transmission in the through-hole for the surface course of fabric can play thermal-insulated heat retaining effect, guarantees simultaneously that the surface course of surface course keeps certain humidity and can prevent that static from taking place.

The above technical purpose of the present invention can be achieved by the following technical solutions: the utility model provides a heat preservation antistatic polyester fabric, including nexine and surface course, the one side array that the surface course is close to the nexine is provided with a plurality of archs, a plurality of through-holes have been seted up to the array on the nexine, be provided with mercerized wool in the through-hole, mercerized wool extends and keeps away from the nexine towards the one side that the surface course was kept away from to the nexine, be provided with the adsorbed layer between nexine and the surface course, the adsorbed layer laminates with mercerized wool, the bleeder vent of being connected with the arch is seted up to the adsorbed layer array, form thermal-insulated chamber between surface course and the nexine.

The utility model discloses further set up to: the axis of the through hole is parallel to the axis of the vent hole, and the aperture of the vent hole is smaller than that of the through hole.

The utility model discloses further set up to: the adsorption layer is woven by a plurality of adsorption yarns in a warp-weft mode to form a honeycomb structure.

The utility model discloses further set up to: the honeycomb is organized for 8 pages of healds and is floated for the warp floating point, the latitude floating point is sunken, the honeycomb is organized from left to right top-down's tissue circulation and is: <xnotran> , , , , , , , . </xnotran>

The utility model discloses further set up to: the adsorption yarn is formed by twisting a plurality of polypropylene fibers and a plurality of viscose.

The utility model discloses further set up to: the surface course is woven through first compound yarn longitude and latitude and is formed, first compound yarn by interior and outer winding layer in cold-proof layer outside including cold-proof core, supporting layer and winding in proper order, cold-proof core passes through polyamide fibre and the formation of twisting of ramie, the supporting layer passes through the cross-section and forms in the sandwich layer outside for a plurality of heterotypic cross-section fibre parallel lines settings of C word shape.

The utility model discloses further set up to: the winding layer comprises winding yarns wound outside the heat preservation layer, and the winding yarns are formed by twisting mulberry silk and viscose.

The utility model discloses further set up to: the inlayer is woven through a plurality of second compound yarn longitude and latitude and is formed, second compound yarn is through a plurality of spandex and a plurality of bamboo fiber twisting formation.

To sum up, the utility model discloses following beneficial effect has:

when this cloth makeed into the clothes and wear, set up sparse mercerized wool in the through-hole of nexine, mercerized wool can be fine transmission heat and transmission moisture, when the staff perspires, the nexine passes through mercerized wool in the through-hole, the sweat vapour absorption that gives out the people's health, intercommunication through-hole and adsorbed layer, sweat vapour is adsorbed on the adsorbed layer, heat in the sweat of the thermal-insulated chamber that forms keeps warm to the evaporation on the surface course and the adsorbed layer reaches thermal-insulated effect, the arch is connected with the bleeder vent on the adsorbed layer, make the adsorbed layer in sweat vapour, transport to the surface course through the arch on, keep certain humidity with the surface course, the effect of surface fabric antistatic has been guaranteed.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a cross-sectional view of an absorbent yarn of the present invention;

fig. 3 is a cross-sectional view of a first composite yarn of the present invention;

fig. 4 is a cross-sectional view of a second composite yarn of the present invention;

fig. 5 is a cross-sectional view of the honeycomb structure of the present invention.

In the figure: 1. an inner layer; 2. a surface layer; 3. a protrusion; 4. mercerizing wool; 5. an adsorption layer; 6. air holes are formed; 7. a heat insulation cavity; 8. adsorbing the yarn; 9. polypropylene fiber; 10. gluing; 11. a first composite yarn; 12. nylon; 13. hemp; 14. a profiled cross-section fiber; 15. mulberry silk; 16. a second composite yarn; 17. spandex; 18. bamboo fiber.

Detailed Description

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

The utility model provides a heat preservation antistatic polyester fabric, as shown in fig. 1-5, including nexine 1 and surface course 2, the one side array that surface course 2 is close to nexine 1 is provided with a plurality of archs 3, a plurality of through-holes have been seted up to the array on nexine 1, be provided with mercerized wool 4 in the through-hole, mercerized wool 4 extends and keeps away from nexine 1 towards the one side that surface course 2 was kept away from to nexine 1, be provided with adsorbed layer 5 between nexine 1 and the surface course 2, adsorbed layer 5 and the laminating of mercerized wool 4, adsorbed layer 5 array is seted up the bleeder vent 6 of being connected with arch 3, form thermal-insulated chamber 7 between surface course 2 and the nexine 1.

As shown in fig. 1-5, a plurality of polypropylene fibers 9 and a plurality of viscose 10 are put into a twisting machine to be twisted to form the absorbent yarns 8, the polypropylene fibers 9 and the viscose 10 both have good moisture absorption, the absorbent yarns 8 are put into a water-jet textile machine to be woven into the absorbent layer 5 through a honeycomb structure, the honeycomb structure is 8 pages of healds and floats through floating points, the floats through weft are sunken, and the structure cycle of the honeycomb structure from left to right and from top to bottom is as follows: <xnotran> , , , , , , , , , , 12 13 , 12 , 13 , C 14, 14 , , C 14 , 15 10 , 15 , 10 , , , 11, 11 2, 2 1 3, 17 18 16, 16 1, 1 , 5 6, 5 2 6 , </xnotran> Then, sparse mercerized wool 4 is adhered in the through hole, the surface layer 2 is adhered on the adsorption layer 5, and the protrusions 3 on the surface layer 2 correspond to the air holes 6.

As shown in fig. 1-5, when the fabric is made into a garment to be worn, sparse mercerized wool 4 is arranged in the through hole of the lining 1, the mercerized wool 4 can well transfer heat and transfer moisture, when a worker sweats, the lining 1 absorbs sweat vapor emitted by a human body through the mercerized wool 4 in the through hole, the sweat vapor is adsorbed on the adsorption layer 5 through the communication between the through hole and the adsorption layer 5, the heat in the evaporated sweat is preserved through a heat insulation cavity 7 formed between the bulge 3 on the surface layer 2 and the adsorption layer 5, so that the fabric achieves a heat insulation effect, the bulge 3 is connected with an air vent 6 on the adsorption layer 5, the sweat vapor in the adsorption layer 5 is transported to the surface layer 2 through the bulge 3, the surface layer 2 is kept at a certain humidity, and the antistatic effect of the fabric is ensured.

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 modifications and embellishments within the scope of the present disclosure may be made by those skilled in the art without departing from the principles of the present disclosure.

Claims (8)

1. A heat-preservation antistatic polyester fabric is characterized in that: including nexine (1) and surface course (2), the one side array that surface course (2) are close to nexine (1) is provided with a plurality of archs (3), a plurality of through-holes have been seted up in nexine (1) last array, be provided with mercerized wool (4) in the through-hole, surface course (2) one side extension and keep away from nexine (1) are kept away from towards nexine (1) in mercerized wool (4), be provided with between nexine (1) and surface course (2) adsorbed layer (5), adsorbed layer (5) and mercerized wool (4) laminating, bleeder vent (6) of being connected with arch (3) are seted up to adsorbed layer (5) array, form thermal-insulated chamber (7) between surface course (2) and nexine (1).

2. The heat-insulating antistatic polyester fabric according to claim 1, wherein: the axes of the through holes are parallel to the axes of the vent holes, and the aperture of the vent holes (6) is smaller than that of the through holes.

3. The heat-insulating antistatic polyester fabric according to claim 2, wherein: the adsorption layer (5) is woven by a plurality of adsorption yarns (8) in a warp-weft mode to form a honeycomb structure.

4. The heat-insulating antistatic polyester fabric according to claim 3, wherein: the honeycomb structure is 8 pages of healds, the warp floating point is floating, the weft floating point is sinking, and the structure circulation of the honeycomb structure from left to right from top to bottom is as follows: <xnotran> , , , , , , , . </xnotran>

5. The heat-insulating antistatic polyester fabric according to claim 4, wherein: the adsorption yarn (8) is formed by twisting a plurality of polypropylene fibers (9) and a plurality of viscose (10).

6. The heat-insulating antistatic polyester fabric according to claim 1, wherein: surface course (2) are woven through first compound yarn (11) longitude and latitude and are formed, first compound yarn (11) by interior and outer winding layer in cold-proof core, supporting layer and winding in the cold-proof layer outside in proper order, cold-proof core passes through polyamide fibre (12) and hemp (13) twisting formation, the supporting layer passes through the cross-section and forms in the sandwich layer outside for a plurality of heterotypic cross-section fibre (14) doubling settings of C word shape.

7. The heat-insulating antistatic polyester fabric according to claim 6, wherein: the winding layer comprises winding yarns wound on the outer side of the heat-insulation layer, and the winding yarns are formed by twisting mulberry silk (15) and viscose (10).

8. The heat-insulating antistatic polyester fabric of claim 1, wherein: the inner layer (1) is formed by warp and weft weaving of a plurality of second composite yarns (16), and the second composite yarns (16) are formed by twisting a plurality of spandex (17) and a plurality of bamboo fibers (18).

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