CN218928848U - Thermal insulation antibacterial polyester taff - Google Patents

Abstract

The utility model discloses a heat-preservation antibacterial polyester taffeta, which relates to the technical field of fabrics and has the technical scheme that: including inlayer and surface course, the inlayer presss from both sides between the surface course and is equipped with the heat preservation, and the array is provided with a plurality of support yarn groups between heat preservation and the surface course, and a plurality of support yarn groups support the heat preservation and form a plurality of archs, form a plurality of heat preservation chambeies between a plurality of archs and the inlayer, and protruding periphery wall has seted up the through-hole with its both sides heat preservation chamber intercommunication, has seted up the bleeder vent that corresponds with support yarn on the surface course. According to the utility model, the acrylic fibers and the bamboo fibers are arranged, so that the acrylic fibers have the effects of heat preservation and heat insulation, and the bamboo fibers have the effects of bacteriostasis and deodorization, so that the effects of heat preservation and bacteriostasis are achieved.

Description

Thermal insulation antibacterial polyester taff

Technical Field

The utility model relates to the technical field of fabrics, in particular to a heat-preservation antibacterial polyester taffeta.

Background

The polyester taffeta has the advantages of light and thin texture, smooth hand feeling, no sticking to hands, uniform filament thickness, difficult breaking, wear resistance and the like, is particularly used for jackets, sleeping bags, tents, shower curtains, tablecloths, chair covers and various high-grade clothing linings, and has very wide application.

When the existing washing tower is manufactured into the water cup sleeve, the washing tower is required to keep the water cup warm to a certain extent, meanwhile, hand sweat can be generated on hands of people when the washing tower is used, sweat on hands with overlong use time is absorbed by the washing tower, a large amount of sweat is reserved on the water cup sleeve, and bacteria on hands of people are many, so that bacteria are easy to breed after the use time of the water cup sleeve is overlong.

There is therefore a need to propose a new solution to this problem.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model aims to provide the heat-insulating antibacterial polyester doffer, the heat-insulating layer is supported to form the bulges through the supporting yarn groups, the heat-insulating cavity is formed between the adjacent bulges, through holes connected with the heat-insulating cavity are formed in two sides of the bulges, and the surface layer is provided with the air holes connected with the supporting yarns, so that sweat can be quickly evaporated by the fabric, and the heat-insulating antibacterial effect of the fabric is ensured.

The technical aim of the utility model is realized by the following technical scheme: the utility model provides a heat preservation antibacterial tower that washes which characterized in that: including inlayer and surface course, it is equipped with the heat preservation to press from both sides between inlayer and the surface course, array is provided with a plurality of support yarn groups between heat preservation and the surface course, a plurality of support yarn group supports the heat preservation and forms a plurality of archs, forms a plurality of heat preservation chamber between a plurality of archs and the inlayer, protruding periphery wall has been seted up the through-hole with its both sides heat preservation chamber intercommunication, set up the bleeder vent that corresponds with support yarn on the surface course.

The utility model is further provided with: the diameter of the air holes is larger than that of the through holes.

The utility model is further provided with: the surface layer is knitted by a plurality of first composite yarns in a warp-weft mode to form a variable square flat structure.

The utility model is further provided with: the change square flat structure is 8-page heald, warp floating point and weft floating point are sinking, and the change square flat structure is circularly organized from left to right from top to bottom as follows: floating, sinking, floating and sinking sinking, floating and floating floating, sinking, floating, sinking and sinking sinking, floating, sinking, floating and sinking.

The utility model is further provided with: the first composite yarn is formed by twisting a plurality of bamboo fibers and a plurality of acrylic fibers.

The utility model is further provided with: the support yarn group comprises a plurality of second composite yarns which are arranged in parallel, the second composite yarns sequentially comprise a core layer, a support layer and a winding layer from inside to outside, the core layer is formed by twisting hemp and a plurality of bamboo fibers, the support layer is arranged outside the core layer through a plurality of special-shaped cross-section fiber parallel wires, and the cross section of the special-shaped cross-section fiber is in a C shape.

The utility model is further provided with: the winding layer comprises winding yarns which are sparsely wound on the outer side of the supporting layer, and the winding yarns are formed by twisting terylene and viscose.

The utility model is further provided with: the inner layer is formed by warp-weft knitting of a third composite yarn, and the third composite yarn is formed by twisting a plurality of acrylon fibers.

The utility model is further provided with: the heat-insulating layer is formed by warp-weft knitting of fourth composite yarns, and the fourth composite yarns are formed by twisting acrylic fibers and a plurality of chinlon.

In summary, the utility model has the following beneficial effects:

when this surface fabric is made into the cup and is used, hot water in the cup passes through the wall of cup and transmits to in the cup, heat preservation chamber between inlayer and the heat preservation keeps warm to the cup, after people sweat when using, sweat gets into through the bleeder vent on the surface course and supports in the sand stream, support the yarn and adsorb the sweat, when the cup was kept away from to the palm, the temperature in the heat preservation chamber passes through the through-hole and transmits the temperature, sweat on the yarn evaporates, the sweat of evaporation is kept away from the cup through breathing freely, the cross-section is the heat preservation to the temperature that the heat preservation chamber was transmitted to the special-shaped cross-section fibre of C font form, thereby make the surface fabric have the effect of heat preservation and heat insulation and guarantee that the surface fabric has antibacterial effect simultaneously.

Drawings

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

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a cross-sectional view of a first composite yarn of the present utility model;

FIG. 4 is a cross-sectional view of a second composite yarn of the present utility model;

FIG. 5 is a cross-sectional view of a third composite yarn of the present utility model;

FIG. 6 is a cross-sectional view of a fourth composite yarn of the present utility model;

FIG. 7 is a cross-sectional view of a variation of the square and flat structure of the present utility model.

In the figure: 1. an inner layer; 2. a surface layer; 3. a heat preservation layer; 4. a protrusion; 5. a heat preservation cavity; 6. a through hole; 7. ventilation holes; 8. a first composite yarn; 9. bamboo fiber; 10. acrylic fiber; 11. a second composite yarn; 12. a core layer; 13. a support layer; 14. hemp; 15. a profiled cross-section fiber; 16. winding yarn; 17. polyester; 18. and (3) sticking glue; 19. a third composite yarn; 20. a fourth composite yarn; 21. nylon fabric.

Detailed Description

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

The utility model provides a heat preservation antibacterial tower of washing, as shown in fig. 1-7, including inlayer 1 and surface course 2, it is equipped with heat preservation 3 to press from both sides between inlayer 1 and the surface course 2, the array is provided with a plurality of supporting yarns between heat preservation 3 and the surface course 2, supporting yarn supports heat preservation 3 and forms a plurality of archs 4, form a plurality of heat preservation chambeies 5 between a plurality of archs 4 and the inlayer 1, protruding 4 periphery wall has seted up the through-hole 6 with its both sides heat preservation chambeies 5 intercommunication, offered the bleeder vent 7 that corresponds with supporting yarn on the surface course 2.

As shown in fig. 1-7, a plurality of bamboo fibers 9 and a plurality of acrylon fibers 10 are taken and put into a twisting machine to twist to form first composite yarns 8, the plurality of first composite yarns 8 are put into a water jet loom to be warp-weft knitted in a form of a variable square flat structure to form a surface layer 2, the variable square flat structure is 8-page healds, the warp floating point and the weft floating point are sinking, and the tissue circulation of the variable square flat structure from left to right is as follows: the fabric has the advantages of being thick, high in tissue structure strength, and good in antibacterial and deodorizing effects, the acrylic fiber 10 has the characteristics of softness and warmth retention, and the surface layer 2 is guaranteed to have higher heat preservation effects and antibacterial and deodorizing effects.

As shown in fig. 1-7, a plurality of ventilation holes 7 are formed in an array on a surface layer 2 through a laser drilling machine, hemp 14 and a plurality of bamboo fibers 9 are placed in a twisting machine to twist to form a core layer 12, polyester 17 is sprayed by a spinneret plate to form special-shaped cross-section fibers 15 with a C-shaped cross section, the special-shaped cross-section fibers 15 are bonded on the peripheral wall of the core layer 12 in parallel to form a supporting layer 13, polyester 17 and viscose 18 are placed in the twisting machine to twist to form winding yarns 16, the manufactured supporting layer 13 and winding yarns 16 are placed in a spindle machine, the twist is controlled, the winding yarns 16 are made to be sparsely wound on the outer side of the supporting layer 13 in a spindle-moving mode to form a winding layer, the whole second composite yarns 11 are obtained, the plurality of second composite yarns 11 are bonded together to obtain the whole supporting yarn group, the supporting yarn group is bonded on the surface layer 2, the supporting yarn group corresponds to the core layer 7, the hemp 14 has the good moisture-releasing effect, the bamboo fibers 9 have the antibacterial and deodorizing effects, the special-shaped cross-section fibers 15 with the C-shaped cross section having good moisture absorption and good moisture absorption effects, the good moisture absorption and good air absorption effects are retained in the fabric, the moisture absorption and the good ventilation effects are guaranteed, the fabric has good moisture absorption and ventilation effects and good thermal insulation effects and can be guaranteed, and the fabric has good ventilation effects and good thermal insulation effects.

As shown in fig. 1-7, acrylic fiber 10 and nylon 21 are put into a twisting machine to twist to form fourth composite yarns 20, the fourth composite yarns 20 are put into a water jet loom to form an insulating layer 3 in a warp-weft knitting mode in a variable square structure mode, a plurality of through holes 6 are formed in the insulating layer 3 in an array mode through a laser puncher, the insulating layer 3 is adhered to a surface layer 2 so that a plurality of supporting yarn groups support the insulating layer 3 to form a plurality of protrusions 4, the acrylic fiber 10 is put into the twisting machine to twist to form third composite yarns 19 through being distributed on two sides of the protrusions 4, the third composite yarns 19 are put into the water jet loom to form an inner layer 1 through being woven in a variable square structure mode, the inner layer 1 is adhered to the protrusions 4 of the insulating layer 3, an insulating cavity 5 is formed between the adjacent protrusions 4, the through holes 6 are communicated with the insulating cavity 5, the supporting yarn groups are connected through the through holes 6, and the temperature in the insulating cavity 5 is transferred into the supporting yarns through the through holes 6 so that sweat on the supporting yarns is quickly evaporated, and the sweat remained on the fabric is slowed down.

As shown in fig. 1-7, when the fabric is manufactured into a cup sleeve for use, hot water in the cup is transferred into the cup sleeve through the wall of the cup, the heat preservation cavity 5 between the inner layer 1 and the heat preservation layer 3 is used for preserving heat of the cup, after sweat is discharged from the palm of a user, the sweat enters into the supporting sand stream through the ventilation holes 7 on the surface layer 2, the supporting yarns adsorb the sweat, when the palm is far away from the cup sleeve, the temperature in the heat preservation cavity 5 transfers the temperature to the yarns through the through holes 6, the sweat on the supporting yarns is evaporated, the evaporated sweat is far away from the cup sleeve through ventilation, and the temperature transferred by the heat preservation cavity 5 is preserved by the special-shaped cross-section fiber 15 with the C-shaped cross section, so that the fabric has heat preservation and insulation effects and meanwhile the antibacterial effect.

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 (8)

1. The utility model provides a heat preservation antibacterial tower that washes which characterized in that: including inlayer (1) and surface course (2), it is equipped with heat preservation (3) to press from both sides between inlayer (1) and surface course (2), array is provided with a plurality of support yarn group between heat preservation (3) and the surface course (2), a plurality of support yarn group supports heat preservation (3) and forms a plurality of archs (4), forms a plurality of heat preservation chamber (5) between a plurality of archs (4) and inlayer (1), through-hole (6) with its both sides heat preservation chamber (5) intercommunication have been seted up to protruding (4) peripheral wall, bleeder vent (7) that correspond with the support yarn have been seted up on surface course (2).

2. The heat preservation and bacteriostasis polyester taff according to claim 1, wherein: the diameter of the ventilation holes (7) is larger than that of the through holes (6).

3. The heat preservation and bacteriostasis polyester taff according to claim 2, wherein: the surface layer (2) is woven by warps and wefts of a plurality of first composite yarns (8) to form a variable square plain structure.

4. A thermal insulation bacteriostatic polyester taff according to claim 3, characterized in that: the first composite yarn (8) is formed by twisting a plurality of bamboo fibers (9) and a plurality of acrylic fibers (10).

5. The heat preservation and bacteriostasis polyester taff according to claim 4, wherein: the support yarn group comprises a plurality of second composite yarns (11) which are arranged in a doubling way, the second composite yarns (11) sequentially comprise a core layer (12), a support layer (13) and a winding layer from inside to outside, the core layer (12) is formed by twisting hemp (14) and a plurality of bamboo fibers (9), the support layer (13) is arranged outside the core layer (12) in a doubling way through a plurality of special-shaped cross-section fibers (15), and the cross section of the special-shaped cross-section fibers (15) is in a C-shaped shape.

6. The heat preservation and bacteriostasis polyester taff according to claim 5, wherein: the winding layer comprises winding yarns (16) which are wound on the outer side of the supporting layer (13) in a sparse mode, and the winding yarns (16) are formed by twisting terylene (17) and viscose (18).

7. The heat preservation and bacteriostasis polyester taff according to claim 6, wherein: the inner layer (1) is formed by warp and weft knitting of a third composite yarn (19), and the third composite yarn (19) is formed by twisting a plurality of acrylon (10).

8. The insulated bacteriostatic polyester taff according to claim 7, wherein: the heat insulation layer (3) is formed by warp and weft knitting of a fourth composite yarn (20), and the fourth composite yarn (20) is formed by twisting acrylic fibers (10) and a plurality of chinlon (21).

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