Antiskid wear-resistant polyester fabric

By incorporating a base layer, elastic strips, and an anti-slip layer into polyester fabric, and utilizing the moisture absorption of flax fibers and the elasticity of spandex fibers, the slippage problem of polyester fabric gloves during wear is solved, achieving an anti-slip and wear-resistant effect.

CN224478199UActive Publication Date: 2026-07-10SUZHOU KEMARK TEXTILE TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SUZHOU KEMARK TEXTILE TECH CO LTD
Filing Date
2025-07-14
Publication Date
2026-07-10

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Abstract

The utility model discloses anti -skidding wear -resisting dacron fabric relates to textile technical field, and its technical scheme main points are: the one side of base layer is equipped with a plurality of elastic strips, and the one side of elastic strip is integrally formed with a plurality of supporting blocks, and the both sides of elastic strip are equipped with anti -skid layer one and anti -skid layer two respectively, and anti -skid layer one and a plurality of supporting blocks and elastic strip form a plurality of ventilation space, and the base layer is penetrated and is equipped with a plurality of through -groove, and ventilation space and through -groove intercommunication, and the region of anti -skid layer one and supporting block is opposite and passes through the through -groove along the direction of away from elastic strip, and the elasticity of elastic strip is greater than the elasticity of base layer. The base layer made of flax fiber and polyamide fiber blend can absorb sweat produced by skin in time and remove quickly, can keep the dryness of skin and fabric, and a plurality of elastic strips can form greater resilience after stretching, thereby driving the base layer to be close to the contour of hand, increasing the friction between fabric and skin, thereby improving the anti -skid effect of glove.
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Description

Technical Field

[0001] This utility model relates to the field of textile technology, and more specifically, to anti-slip and wear-resistant polyester fabric. Background Technology

[0002] Polyester fabric is a commonly used synthetic fiber fabric in people's daily lives. Its outstanding features are good wrinkle resistance and shape retention. Therefore, polyester fabric is widely used in clothing, home textiles and outdoor products.

[0003] However, polyester fibers have relatively poor moisture absorption and breathability, which makes gloves made of polyester fabric feel stuffy when worn. They are prone to sweating, and the sweat cannot be evaporated in time and remains on the skin surface. This makes it easy for the gloves to slip due to the sweat when climbing, gripping, and driving, which poses certain safety hazards.

[0004] Therefore, new solutions are needed to address the problem of polyester gloves becoming slippery due to sweat when worn. Utility Model Content

[0005] In view of the shortcomings of the existing technology, the purpose of this utility model is to provide a non-slip and wear-resistant polyester fabric, which improves the non-slip properties of the polyester fabric through a new structural design.

[0006] The above-mentioned technical objective of this utility model is achieved through the following technical solution: the anti-slip and wear-resistant polyester fabric includes a base layer, a plurality of elastic strips are provided on one side of the base layer, a plurality of support blocks are integrally formed on the side of the elastic strips near the base layer, an anti-slip layer one and an anti-slip layer two are respectively provided on both sides of the elastic strips, a plurality of ventilation spaces are formed between the anti-slip layer one, the plurality of support blocks and the elastic strips, a plurality of through grooves are opened through the base layer, the ventilation spaces and the through grooves are interconnected, the area of ​​the anti-slip layer one that abuts against the support blocks extends out of the through grooves in a direction away from the elastic strips, and the elasticity of the elastic strips is greater than the elasticity of the base layer.

[0007] The present invention is further configured such that: the width of the first anti-slip layer is the same as the width of the second anti-slip layer and the width of the elastic strip, and the width of the elastic strip is less than the side length of the through groove.

[0008] The present invention is further configured such that: the side length of the support block is less than the side length of the through groove, the support block and the through groove are arranged symmetrically above and below, and the thickness of the support block is greater than the thickness of the base layer.

[0009] The present invention is further configured such that: both the first anti-slip layer and the second anti-slip layer are thin films made of polyurethane material; the first anti-slip layer and the second anti-slip layer are respectively fixed to both sides of the elastic strip by a heat transfer process; and the side of the support block away from the elastic strip is fixedly connected to the first anti-slip layer.

[0010] The present invention is further configured such that: the elastic strip is made by weaving high-elastic yarn with a raised strip structure, and the plurality of support blocks on the elastic strip are integrally formed by weaving a raised strip structure.

[0011] The present invention is further configured such that: the high-elastic yarn is formed by twisting a first strand and a second strand, wherein the first strand is formed by twisting nylon fiber and the second strand is formed by twisting spandex fiber.

[0012] The present invention is further configured such that: the base layer is made by weaving anti-slip yarn in a plain weave, the anti-slip yarn is formed by twisting a first strand and a third strand, and the third strand is formed by twisting flax fibers.

[0013] In summary, this invention has the following beneficial effects: Flax fiber has excellent moisture absorption and dissipation properties, allowing the base layer to absorb and quickly dissipate sweat produced by the skin. Several interconnected channels and ventilation spaces ensure good airflow between the sides of the base layer and between the elastic strips and the first and second anti-slip layers, further enhancing the overall moisture dissipation effect of the fabric. This helps maintain the dryness of the skin and fabric, preventing the gloves from feeling stuffy or slipping due to sweat. The high elasticity and resilience of spandex and nylon fibers allow the elastic strips to generate significant rebound force after stretching, thus driving the base layer to conform closely to the contours of the hand. The relatively rough surface of flax fiber generates greater friction between the glove and the skin, thereby improving the anti-slip effect of the glove. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the structure of the present invention. Figure 1 ;

[0015] Figure 2 for Figure 1 Enlarged view of point A in the middle;

[0016] Figure 3 This is a schematic diagram of the structure of the present invention. Figure 2 ;

[0017] Figure 4 for Figure 3 Enlarged view of point B in the middle;

[0018] Figure 5 A cross-section of a high-elasticity yarn;

[0019] Figure 6 This is a cross-section of the anti-slip yarn.

[0020] In the diagram: 1. Base layer; 2. Elastic strip; 3. Support block; 4. Anti-slip layer one; 5. Anti-slip layer two; 6. Ventilation space; 7. Through groove; 8. High-elastic yarn; 9. First strand; 10. Second strand; 11. Anti-slip yarn; 12. Third strand. Detailed Implementation

[0021] The present invention will now be described in detail with reference to the accompanying drawings and embodiments.

[0022] Example: This anti-slip and wear-resistant polyester fabric, such as Figure 1 and Figure 6 As shown, the material includes a base layer 1. The base layer 1 is made by feeding anti-slip yarn 11 into an air-jet loom and weaving it using a plain weave. The anti-slip yarn 11 is formed by twisting a first strand 9 and a third strand 12 using a twisting machine. The first strand 9 is formed by twisting nylon fiber using a spinning machine, and the third strand 12 is formed by twisting flax fiber using a spinning machine. Flax fiber has good abrasion resistance, while nylon fiber has higher strength and abrasion resistance than flax fiber. This makes the base layer 1 less prone to wear during long-term use, thus improving its service life. At the same time, flax fiber has excellent moisture absorption and wicking properties, allowing the base layer 1 to absorb and quickly wick away sweat produced by the skin, thereby keeping the skin and the base layer 1 dry and preventing the gloves from slipping due to sweat when worn, thus ensuring the anti-slip effect of the gloves.

[0023] like Figure 1 , Figure 2 and Figure 5 As shown, a number of long elastic strips 2 are provided on one side of the base layer 1. A number of square support blocks 3 are integrally formed on the side of the elastic strips 2 near the base layer 1. The side length of the support blocks 3 is the same as the width of the elastic strips 2. The elastic strips 2 are arranged in an array along the width direction of the base layer 1. The elastic strips 2 are made by feeding high-elastic yarn 8 into an air-jet loom and weaving it with a raised stripe weave. The support blocks 3 on the elastic strips 2 are all integrally formed by the raised stripe weave. The high-elastic yarn 8 is twisted by a twisting machine to form a first strand 9 and a second strand. The first strand 10 is twisted together. The second strand 10 is made by twisting spandex fibers through a spinning machine. Both nylon and spandex fibers have excellent elasticity and elastic recovery. The elasticity and elastic recovery of spandex fibers are greater than those of flax fibers, which makes the elasticity of the elastic strip 2 greater than that of the base layer 1. After being stretched, several elastic strips 2 will form a large rebound force, thereby driving the base layer 1 to fit tightly to the contour of the hand. The surface of the flax fiber is relatively rough, which allows for greater friction between the glove and the skin, thereby improving the anti-slip effect of the glove.

[0024] like Figures 1-4As shown, an anti-slip layer 4 and an anti-slip layer 5 are respectively provided on both sides of the elastic strip 2. The width of the anti-slip layer 4 is the same as the width of the anti-slip layer 5 and the width of the elastic strip 2. Both the anti-slip layer 4 and the anti-slip layer 5 are thin films made of polyurethane material. The anti-slip layer 4 and the anti-slip layer 5 are fixed to both sides of the elastic strip 2 by heat transfer printing process, thereby fixing the side of the support block 3 away from the elastic strip 2 to the anti-slip layer 4. This forms several ventilation spaces 6 with triangular cross sections between the anti-slip layer 4, the support blocks 3 and the elastic strip 2. Several square through slots 7 are opened through the base layer 1 using a laser drilling machine. Several through slots 7 are arranged in an array on the base layer 1.

[0025] like Figures 1-4 As shown, the width of the elastic strip 2 is less than the side length of the groove 7. The support block 3 and the groove 7 are symmetrically arranged vertically, so that the ventilation space 6 and the groove 7 are interconnected. Through several interconnected grooves 7 and ventilation spaces 6, the two sides of the base layer 1 and the elastic strip 2 and the anti-slip layer 1 4 and anti-slip layer 2 5 have good air circulation, which further enhances the overall moisture dissipation effect of the fabric and avoids the fabric from feeling stuffy when worn. The thickness of the support block 3 is greater than the thickness of the base layer 1, so that the area where the anti-slip layer 1 4 and the support block 3 are fixed extends out of the groove 7 in a direction away from the elastic strip 2. The polyurethane material has good anti-slip properties, so that the anti-slip layer 2 5 and the anti-slip layer 1 4 extending out of several grooves 7 can provide good anti-slip effect for the two sides of the fabric, improving the use effect of the fabric.

[0026] The above description is merely a preferred embodiment of this utility model. The protection scope of this utility model is not limited to the above embodiments. All technical solutions falling within the scope of this utility model's concept are protected. It should be noted that for those skilled in the art, any improvements and modifications made without departing from the principle of this utility model should also be considered within the protection scope of this utility model.

Claims

1. A non-slip and wear-resistant polyester fabric, comprising a base layer (1), characterized in that: The base layer (1) has several elastic strips (2) on one side. Several support blocks (3) are integrally formed on the side of the elastic strip (2) close to the base layer (1). Anti-slip layer one (4) and anti-slip layer two (5) are respectively provided on both sides of the elastic strip (2). Several ventilation spaces (6) are formed between the anti-slip layer one (4), the support blocks (3) and the elastic strip (2). Several through grooves (7) are opened through the base layer (1). The ventilation spaces (6) and the through grooves (7) are interconnected. The area where the anti-slip layer one (4) abuts against the support blocks (3) extends out of the through grooves (7) in a direction away from the elastic strip (2). The elasticity of the elastic strip (2) is greater than that of the base layer (1).

2. The anti-slip and wear-resistant polyester fabric according to claim 1, characterized in that: The width of the first anti-slip layer (4) is the same as the width of the second anti-slip layer (5) and the width of the elastic strip (2), and the width of the elastic strip (2) is less than the side length of the through groove (7).

3. The anti-slip and wear-resistant polyester fabric according to claim 1, characterized in that: The side length of the support block (3) is smaller than the side length of the through groove (7). The support block (3) and the through groove (7) are arranged symmetrically on the top and bottom. The thickness of the support block (3) is greater than the thickness of the base layer (1).

4. The anti-slip and wear-resistant polyester fabric according to claim 1, characterized in that: The first anti-slip layer (4) and the second anti-slip layer (5) are both thin films made of polyurethane. The first anti-slip layer (4) and the second anti-slip layer (5) are fixed to both sides of the elastic strip (2) by heat transfer printing process. The side of the support block (3) away from the elastic strip (2) is fixedly connected to the first anti-slip layer (4).

5. The anti-slip and wear-resistant polyester fabric according to claim 1, characterized in that: The elastic strip (2) is made by weaving high elastic yarn (8) with a raised strip structure, and several support blocks (3) on the elastic strip (2) are integrally formed by weaving with a raised strip structure.

6. The anti-slip and wear-resistant polyester fabric according to claim 5, characterized in that: The high-elastic yarn (8) is formed by twisting a first strand (9) and a second strand (10). The first strand (9) is formed by twisting nylon fibers, and the second strand (10) is formed by twisting spandex fibers.

7. The anti-slip and wear-resistant polyester fabric according to claim 6, characterized in that: The base layer (1) is made by weaving anti-slip yarn (11) in a plain weave. The anti-slip yarn (11) is made by twisting a first strand (9) and a third strand (12). The third strand (12) is made by twisting flax fibers.