CN218928802U - Breathable terylene oxford - Google Patents

Abstract

The utility model discloses a breathable terylene oxford fabric, relates to the technical field of textile, and aims to solve the problem that the surface of dustproof clothes is blocked by dust to influence the breathable effect, and the technical scheme is as follows: the utility model provides a ventilative dacron oxford spins, includes ventilative layer and barrier layer, and a plurality of ventilation slots have been seted up on the barrier layer surface, and ventilation slot inside all bonds has a plurality of dust cloth, and a plurality of gas outlets have been seted up on the barrier layer surface, ventilative layer and barrier layer bond and a plurality of gas outlets all communicate with the ventilation slot, and dust cloth is close to the ventilation slot and keeps away from the opening of ventilative layer one end. The breathable terylene oxford fabric has the technical effect of enhancing the breathable capacity of the fabric by using the terylene fiber and the spandex fiber.

Description

Breathable terylene oxford

Technical Field

The utility model relates to the technical field of textile, in particular to breathable terylene oxford textile.

Background

The polyester is a fiber-forming polymer prepared by taking refined terephthalic acid (PTA) or dimethyl terephthalate (DMT) and ethylene glycol (MEG) as raw materials through esterification or transesterification and polycondensation, and the fiber prepared through spinning and post-treatment has the greatest advantage of good crease resistance and shape retention.

The dust-proof clothing is the dacron system clothes that need whole dress in powder metallurgy workshop powder process, the gap on dust-proof clothing surface is less, can effectually prevent that the dust from getting into the clothes inside and with the health contact, simultaneously in order to guarantee the comfort level of dress, dust-proof clothing also can possess certain ventilation effect, but prior art's dust-proof clothing, after powder metallurgy workshop live time is long, the air vent on dust-proof clothing surface can be stopped up to various industrial dust that floats in the air, and because dust-proof clothing elasticity itself is less, the dust of jam is difficult to be automatic by the health jitters down, therefore prior art's dust-proof clothing exists can be by the dust jam bleeder vent in powder metallurgy workshop cause the problem that the clothes gas permeability descends.

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

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide the breathable terylene oxford fabric which achieves the technical effects of increasing the dustproof effect of the dustproof clothing and improving the breathability through the arrangement of the structure.

The technical aim of the utility model is realized by the following technical scheme: the utility model provides a ventilative dacron oxford spins, includes ventilative layer and barrier layer, a plurality of ventilation slots have been seted up on the barrier layer surface, the ventilation slot is inside all to bond a plurality of dustproof cloth, a plurality of gas outlets have been seted up on the barrier layer surface, ventilative layer with the barrier layer bonds and a plurality of the gas outlet all with the ventilation slot intercommunication, dustproof cloth is close to the ventilation slot is kept away from the opening of ventilative layer one end.

The utility model is further provided with: the ventilation layer surface integrated into one piece has a plurality of ventilative strips, and a plurality of gas outlets are all seted up a plurality of on the ventilative strip, a plurality of ventilative strips of complaining all stretch into in the ventilation groove, ventilative strip possesses the orientation the elastic deformation performance of ventilation groove inner wall deformation.

The utility model is further provided with: the dustproof cloth is formed into a heavy flat structure through warp and weft knitting of a plurality of dustproof yarns, and the dustproof yarns are twisted by polyester fibers and nylon fibers.

The utility model is further provided with: the barrier layer is woven through warps and wefts of the first composite yarns and the second composite yarns to form a reinforced twill weave, the reinforced twill weave is 8-page heald, warp floating points are floating, weft floating points are sinking, and the reinforced twill weave is circularly formed by the weave from left to right from bottom to top: floating, sinking, floating, sinking sinking, floating, sinking, floating and sinking sinking, floating and sinking sinking, floating and sinking floating, sinking, floating, sinking sinking, floating, sinking, floating and sinking sinking, floating, sinking, floating and sinking.

The utility model is further provided with: the first composite yarn is formed by twisting polyester fibers and a plurality of spandex fibers wound around the polyester fibers, the second composite yarn is formed by twisting a plurality of spandex special-shaped cross-section fibers and a plurality of polyester fibers wound around the spandex special-shaped cross-section fibers, and the cross section of the spandex special-shaped cross-section fibers is round and hollow.

The utility model is further provided with: the breathable layer is knitted through a plurality of third compound yarn warps and wefts to form raised line tissues, the raised line tissues are 8-page healds, warp floating points are floating, weft floating points are sinking, and the raised line tissues are circularly: and the device comprises a floating, sinking and sinking.

The utility model is further provided with: the third composite yarn is formed by a core yarn and a cladding yarn, the core yarn is formed by twisting a plurality of terylene special-shaped section fibers, the cladding yarn is formed by twisting terylene fibers and spandex fibers, and the cross section of the terylene special-shaped section fibers is C-shaped.

In summary, the utility model has the following beneficial effects: set up ventilative layer and barrier layer, ventilative layer is used for guaranteeing the ventilation effect on surface of fabric, the barrier layer is used for blockking inside the dust entering surface fabric in the surface of surface fabric, a plurality of ventilation slots have been seted up on the barrier layer surface, ventilation slot makes the inside air current of surface fabric can flow out through ventilation slot, all bond a plurality of dustproof cloth in ventilation slot inside, dustproof cloth can block outside dust entering ventilation slot, a plurality of gas outlets are seted up on the barrier layer surface, ventilative layer and barrier layer bond and the gas outlet all communicates with ventilation slot, make the inside air current of surface fabric blow to dustproof cloth through the gas outlet blowout and through ventilation slot, blow away the dust on dustproof cloth surface, dustproof cloth is close to ventilation slot keep away from the opening of ventilative layer one end, make the dust of reserving on dustproof cloth surface be blown out in the surface fabric under the air current that the slight motion of health produced more easily, thereby reached and guaranteed that the surface fabric can not be blocked by the dust in the dust workshop and guaranteed the technical effect of surface fabric air permeability.

Drawings

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

FIG. 2 is a schematic view of the weave architecture of the reinforcement twill weave of the present utility model;

FIG. 3 is an organizational chart of the rib organization of the present utility model;

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

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

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

FIG. 7 is a cross-sectional view of a third composite yarn of the present utility model;

in the figure: 1. a barrier layer; 2. a dust-proof cloth; 3. a ventilation groove; 4. a ventilation layer; 5. a ventilation strip; 6. an air outlet; 7. polyester fiber; 8. nylon fiber; 9. a dust-proof yarn; 10. spandex fiber; 11. a first composite yarn; 12. spandex special-shaped cross-section fiber; 13. a second composite yarn; 14. polyester special-shaped section fiber; 15. a core yarn; 16. covering yarn; 17. and a third composite yarn.

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 ventilative dacron oxford, as shown in fig. 1, including ventilative layer 4 and barrier layer 1, a plurality of ventilation slots 3 have been seted up on barrier layer 1 surface, and ventilation slot 3 is inside all to bond a plurality of dust cloth 2, and a plurality of gas outlets 6 have been seted up on barrier layer 1 surface, ventilative layer 4 and affiliated barrier layer 1 bonding and a plurality of gas outlets 6 all communicate with ventilation slot 3, and dust cloth 2 is close to ventilation slot 3 and keeps away from the opening of ventilative layer 4 one end.

As shown in fig. 1 to 7, the polyester fiber 7 and the nylon fiber 8 are put into a twisting machine to form the dustproof yarn 9, and the polyester fiber 7 and the nylon fiber 8 have high tenacity and high fiber strength, so that the formed dustproof yarn 9 has high yarn strength, can effectively block impact of dust on the yarn, a plurality of dustproof yarns 9 are put into a shuttle loom, and are woven into the dustproof cloth 2 by warps and wefts to form a flattened structure, wherein the flattened structure has a certain weaving density, gaps on the surface of a fabric are reduced, and the dustproof effect of the dustproof cloth 2 is enhanced.

As shown in fig. 1 to 7, the polyester fiber 7 and the spandex fibers 10 are placed in a twisting machine to form a first composite yarn 11, the spandex fibers 10 have good elastic deformation performance, the first composite yarn 11 has strong elastic deformation performance and certain toughness, the spandex fibers 10 are placed on a spinneret plate to form spandex special-shaped cross-section fibers 12, the cross section of the spandex special-shaped cross-section fibers 12 is round hollow, an elastic cavity is formed in the round hollow spandex special-shaped cross-section fibers 12, the elastic deformation modulus of the spandex fibers 10 is increased, the elastic deformation performance of the spandex fibers 10 is further enhanced, the spandex special-shaped cross-section fibers 12 are placed in the twisting machine, the formed yarns and the terylene fibers 7 are sequentially placed in the ring twisting machine, the obtained yarns are finally placed in the twisting machine to form a second composite yarn 13, the second composite yarn 13 has strong elastic deformation performance, and the fiber surface wear resistance is high.

As shown in fig. 1 to 7, the first composite yarn 11 and the second composite yarn 13 are put into a shuttle loom for warp and weft knitting to form a barrier layer 1 and form a reinforced twill weave, the reinforced twill weave is 8-page healds, the warp and weft floating points are floating, the weft floating points are sinking, and the weave circulation of the reinforced twill weave from left to right from bottom to top is as follows: floating, sinking sinking, floating, sinking, floating, sinking, floating floating, sinking, floating, sinking and sinking, through the setting of weaving the structure for barrier layer 1 surface possesses strong elastic deformation performance, can effectually guarantee the fibrous gap increase on surface in the surface of surface fabric reactivation in-process, has increased the ventilation effect of surface fabric to a certain extent.

As shown in fig. 1-7, a plurality of polyester fibers 7 are placed on a spinneret plate to form polyester profiled cross-section fibers 14, the cross section of the polyester profiled cross-section fibers 14 is in a shape of a C, a containing cavity is formed in the polyester profiled cross-section fibers 14 in the shape, dirt collecting capacity of the polyester fibers 7 can be improved to a certain extent, the fibers have certain dust absorbing capacity, the polyester profiled cross-section fibers 14 are placed in a twisting machine to form core yarns 15, the core yarns 15 can absorb dust, the polyester fibers 7 and spandex fibers 10 are placed in the twisting machine to form cladding yarns 16, the cladding yarns 16 have certain fiber strength and elasticity, the cladding yarns 16 and the core yarns 15 are placed in a ring twisting machine to form third composite yarns 17, and the third composite yarns 17 have certain dust absorbing capacity and certain toughness.

As shown in fig. 1 to 7, a plurality of third composite yarns 17 are put into a shuttle loom to be warp and weft knitted to form an air permeable layer 4 and form a raised line structure, the raised line structure is 8-page healds, warp floating points are floating, weft floating points are sinking, and the raised line structure is circularly formed by the structure from left to right, from bottom to top: the air permeable layer 4 is formed by integrally forming a plurality of air permeable strips 5 through the arrangement of the braiding structure, the distance between the air permeable layer 4 and the barrier layer 1 is reduced, and the air permeable effect of the air permeable layer 4 on the barrier layer 1 is increased.

As shown in fig. 1-7, a plurality of ventilation grooves 3 matched with the ventilation strips 5 in size are formed in the surface of the barrier layer 1 through a gold stamping process, the dustproof cloth 2 is cut into strip-shaped adhesive tapes and enters the ventilation grooves 3 and approaches to the opening of one adhesive end, the ventilation layer 4 is placed in a laser drilling machine, a plurality of air outlets 6 are formed in the surface of the ventilation strips 5, and finally the ventilation layer 4 and the barrier layer 1 are adhered and the ventilation strips 5 are inserted into the corresponding ventilation grooves, so that the fabric can be obtained.

When the fabric is made into a dustproof garment, dust can be blocked by the dustproof cloth 2 and is retained in the ventilation groove 3, when a human body moves, the fabric and air on one surface of the human body can be extruded, as the sectional area of the air outlet 6 is far larger than the size of a braided gap, most of the air can be sprayed out of the air outlet 6 and enter the ventilation groove 3, the surface of the dustproof cloth 2 is blown to the surface of the dustproof cloth 2 through the ventilation groove 3, so that the retained dust on the surface of the dustproof cloth 2 is blown away, the surface of the fabric is not blocked by the dust, and the ventilation continuous capability of the outer surface of the dustproof garment is ensured, and the technical effect of enhancing the ventilation capability of the fabric of the dustproof garment is achieved

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 (7)

1. The utility model provides a ventilative dacron oxford, its characterized in that: including ventilative layer (4) and barrier layer (1), a plurality of ventilation slots (3) have been seted up on barrier layer (1) surface, a plurality of dustproof cloth (2) have all been bonded to ventilation slot (3) inside, a plurality of gas outlets (6) have been seted up on barrier layer (1) surface, ventilative layer (4) with barrier layer (1) bond and a plurality of gas outlets (6) all with ventilation slot (3) intercommunication, dustproof cloth (2) are close to ventilation slot (3) are kept away from the opening of ventilative layer (4) one end.

2. The breathable oxford fabric of claim 1, wherein: the surface integrated into one piece of ventilative layer (4) has a plurality of ventilative strips (5), and is a plurality of gas outlet (6) all set up a plurality of on ventilative strip (5), a plurality of ventilative strip (5) all stretch into in ventilation groove (3), ventilative strip (5) possess the orientation ventilation groove (3) inner wall deformation's elastic deformation performance.

3. The breathable oxford fabric of claim 1, wherein: the dustproof cloth (2) is formed into a heavy flat structure through warp and weft knitting of a plurality of dustproof yarns (9), and the dustproof yarns (9) are twisted by polyester fibers (7) and nylon fibers (8).

4. The breathable oxford fabric of claim 1, wherein: the barrier layer (1) is woven by warps and wefts of the first composite yarn (11) and the second composite yarn (13) to form a reinforced twill weave.

5. The breathable oxford fabric of claim 4, wherein: the first composite yarn (11) is formed by twisting polyester fibers (7) and a plurality of spandex fibers (10) wound around the polyester fibers (7), the second composite yarn (13) is formed by twisting a plurality of spandex special-shaped cross-section fibers (12) and a plurality of polyester fibers (7) wound around the spandex special-shaped cross-section fibers (12), and the cross section of the spandex special-shaped cross-section fibers (12) is round and hollow.

6. The breathable oxford fabric of claim 1, wherein: the breathable layer (4) is woven into a convex strip structure through a plurality of third composite yarns (17) in a warp-weft knitting mode.

7. The breathable oxford fabric of claim 6, wherein: the third composite yarn (17) is formed by a core yarn (15) and a cladding yarn (16), the core yarn (15) is formed by twisting a plurality of terylene special-shaped section fibers (14), the cladding yarn (16) is formed by twisting terylene fibers (7) and spandex fibers (10), and the cross section of the terylene special-shaped section fibers (14) is in a C shape.

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