Heat-generating bacteriostatic anti-mite fabric

By using a six-way weave structure and specific fiber blending technology, the heat-generating, antibacterial, and anti-mite fabric prepared solves the problem of insufficient antibacterial, anti-mite, and warmth retention properties of underwear fabrics, achieving highly efficient antibacterial, anti-mite, and warmth retention effects.

CN117626514BActive Publication Date: 2026-07-14NINGBO DAQIAN TEXTILE

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
NINGBO DAQIAN TEXTILE
Filing Date
2023-12-04
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing underwear fabrics are insufficient in terms of antibacterial and anti-mite properties, and their warmth retention needs to be improved.

Method used

The fabric design employs a six-way structure, combining high-performance polyester filament, recycled viscose fiber, and combed cotton fiber in a Siro blended yarn, as well as a heat-generating and mite-resistant viscose fiber and polyester fiber in a Siro blended yarn. Through special fiber blending and wet spinning processes, heat-generating, antibacterial, and mite-resistant fabrics are prepared.

Benefits of technology

The fabric has moisture-wicking, heat-generating, mite-proof, antibacterial, and warmth-retaining properties, and is comfortable and soft, which enhances the fabric's heat-locking performance.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a heating bacteriostatic anti-mite fabric, and six paths are taken as one cycle according to the arrangement order from the upper needle disc to the lower needle cylinder, and the first path is in turn: floating thread organization, upper needle disc loop organization, lower needle cylinder tuck organization, floating thread organization; the second path is in turn: floating thread organization, floating thread organization, lower needle cylinder loop organization, lower needle cylinder loop organization; the third path is in turn: upper needle disc tuck organization, upper needle disc loop organization, floating thread organization, floating thread organization; the fourth path is in turn: upper needle disc loop organization, floating thread organization, floating thread organization, lower needle cylinder tuck organization; the fifth path is in turn: floating thread organization, floating thread organization, lower needle cylinder loop organization, lower needle cylinder loop organization; and the sixth path is in turn: upper needle disc loop organization, upper needle disc tuck organization, floating thread organization, floating thread organization. The fabric has the effects of moisture absorption, heating, antibiosis and anti-mite, is combined with high-performance polyester filaments and a special organization structure, and has the functions of warm-keeping and temperature locking, and is comfortable, soft and skin-friendly.
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Description

Technical Field

[0001] This invention relates to the field of antibacterial and anti-mite fabric technology, and in particular to a heat-generating antibacterial and anti-mite fabric. Background Technology

[0002] With the improvement of living standards and quality of life, people have put forward various functional requirements for textiles and clothing. In recent years, the unpredictable climate has led to a surge in illnesses due to infrequent clothing replacement, placing higher demands on the warmth retention function of clothing, especially underwear. In addition, there are also certain requirements for underwear fabrics in terms of antibacterial and dust mite resistance.

[0003] Therefore, there is an urgent need for a fabric that can generate heat, has antibacterial properties, and prevents mites. Summary of the Invention

[0004] The purpose of this invention is to address the shortcomings of existing technologies by providing a heat-generating, antibacterial, and anti-mite fabric.

[0005] To achieve the above objectives, the technical solution adopted by the present invention is as follows:

[0006] A heat-generating, antibacterial, and anti-mite fabric is provided. The fabric is arranged in a six-row cycle. Following the arrangement from the upper needle plate to the lower needle cylinder, the first row consists of: float stitch, upper needle plate loop stitch, lower needle cylinder tuck stitch, and float stitch; the second row consists of: float stitch, float stitch, lower needle cylinder loop stitch, and lower needle cylinder loop stitch; the third row consists of: upper needle plate tuck stitch, upper needle plate loop stitch, float stitch, and float stitch; the fourth row consists of: upper needle plate loop stitch, float stitch, float stitch, and lower needle cylinder tuck stitch; the fifth row consists of: float stitch, float stitch, lower needle cylinder loop stitch, and lower needle cylinder loop stitch; and the sixth row consists of: upper needle plate loop stitch, upper needle plate tuck stitch, float stitch, and float stitch.

[0007] Furthermore, the first and fourth paths use high-performance polyester filaments.

[0008] Furthermore, the single fiber fineness of the high-performance polyester filament is 3.12 to 3.33 dtex.

[0009] Furthermore, the second and fifth yarns are made of Siro blended yarn of recycled viscose fiber and combed cotton fiber.

[0010] Furthermore, the Siro blended yarn of regenerated viscose fiber and combed cotton fiber has a fiber content of 20-30% regenerated viscose fiber and 70-80% combed cotton fiber.

[0011] Furthermore, in the Siro blended yarn of regenerated viscose fiber and cotton fiber, the single fiber fineness of the regenerated viscose fiber is 1.2 to 1.55 dtex, and the single fiber fineness of the cotton fiber is 1.1 to 1.25 dtex.

[0012] Furthermore, the third and sixth threads are made of Siro blended yarn of heat-generating and mite-resistant viscose fiber and polyester fiber.

[0013] Furthermore, the Siro blended yarn of the heat-generating mite-resistant viscose fiber and polyester fiber has a fiber content of 50-60% heat-generating mite-resistant viscose fiber and 40-50% polyester fiber.

[0014] Furthermore, in the Siro blended yarn of the heat-generating mite-resistant viscose fiber and polyester fiber, the single fiber fineness of the heat-generating mite-resistant viscose fiber is 1.2 to 1.55 dtex, and the single fiber fineness of the polyester fiber is 0.8 to 1.0 dtex.

[0015] Furthermore, the heat-generating and mite-proof viscose fiber is obtained by mixing viscose fiber spinning solution, water-soluble chitosan quaternary ammonium salt, and mite-proof agent, followed by wet spinning process, spinning, coagulation, washing, oiling, and drying.

[0016] The present invention adopts the above technical solution and has the following technical effects compared with the prior art:

[0017] The heat-generating, antibacterial, and anti-mite fabric of this invention uses a Siro blend of heat-generating and anti-mite viscose fiber and polyester fiber to give the fabric moisture-absorbing and heat-generating functions as well as anti-mite effects. A Siro blend of recycled viscose fiber and cotton fiber gives the fabric antibacterial effects. Combined with high-performance polyester filaments and a special weave structure, the fabric has a heat-retaining function and is comfortable, soft, and skin-friendly. The fabric of this invention has a fabric weave structure with a smooth and skin-friendly front and a napped back, which further enhances the fabric's heat-retaining and heat-locking performance. Attached Figure Description

[0018] Figure 1 This is a triangular arrangement diagram of the heat-generating, antibacterial, and anti-mite fabric of the present invention.

[0019] Figure 2 This is a front view of the heat-generating, antibacterial, and anti-mite fabric of Embodiment 1 of the present invention;

[0020] Figure 3 This is a reverse view of the heat-generating, antibacterial, and anti-mite fabric of Embodiment 1 of the present invention. Detailed Implementation

[0021] The present invention will be further described below with reference to the accompanying drawings and specific embodiments, but this is not intended to limit the invention. It should be noted that, unless otherwise specified, the embodiments and features described in the embodiments of the present invention can be combined with each other.

[0022] Example 1

[0023] This embodiment provides a heat-generating, antibacterial, and anti-mite fabric, including a front layer and a reverse layer;

[0024] The aforementioned heat-generating, antibacterial, and anti-mite fabric is arranged in a six-row cycle. The six-row sequence, from the upper needle plate to the lower needle cylinder, is as follows: First row: float stitch, upper needle plate loop stitch, lower needle cylinder tuft stitch, float stitch; Second row: float stitch, float stitch, lower needle cylinder loop stitch, lower needle cylinder loop stitch; Third row: upper needle plate tuft stitch, upper needle plate loop stitch, float stitch, float stitch; Fourth row: upper needle plate loop stitch, float stitch, float stitch, lower needle cylinder tuft stitch; Fifth row: float stitch, float stitch, lower needle cylinder loop stitch, lower needle cylinder loop stitch; Sixth row: upper needle plate loop stitch, upper needle plate tuft stitch, float stitch, float stitch.

[0025] The first and fourth paths use high-performance polyester filaments, with a single fiber fineness of 3.12 to 3.33 dtex.

[0026] The second and fifth yarns use Siro blended yarn of recycled viscose fiber and combed cotton fiber, wherein the fiber content of the Siro blended yarn of recycled viscose fiber and combed cotton fiber is 10% recycled viscose fiber and 90% combed cotton fiber.

[0027] Preferably, in the Siro blended yarn of recycled viscose fiber and combed cotton fiber, the fineness of the recycled viscose fiber is 1.2 to 1.55 dtex, and the fineness of the combed cotton fiber is 1.1 to 1.25 dtex.

[0028] The third and sixth yarns use Siro blended yarn of heat-generating mite-resistant viscose fiber and polyester fiber, wherein the fiber content of the Siro blended yarn of heat-generating mite-resistant viscose fiber and polyester fiber is 50% heat-generating mite-resistant viscose fiber and 50% polyester fiber.

[0029] Preferably, in the Siro blended yarn of heat-generating mite-resistant viscose fiber and polyester fiber, the single fiber fineness of the heat-generating mite-resistant viscose fiber is 1.2 to 1.55 dtex, and the single fiber fineness of the polyester fiber is 0.8 to 1.0 dtex.

[0030] The aforementioned heat-generating and mite-proof viscose fiber is obtained by mixing viscose fiber spinning solution, water-soluble chitosan quaternary ammonium salt, and mite-proof agent, followed by wet spinning process, spinning, coagulation, washing, oiling, and drying.

[0031] Example 2

[0032] This embodiment provides a heat-generating, antibacterial, and anti-mite fabric, including a front layer and a reverse layer;

[0033] The aforementioned heat-generating, antibacterial, and anti-mite fabric is arranged in a six-row cycle. The six-row sequence, from the upper needle plate to the lower needle cylinder, is as follows: First row: float stitch, upper needle plate loop stitch, lower needle cylinder tuft stitch, float stitch; Second row: float stitch, float stitch, lower needle cylinder loop stitch, lower needle cylinder loop stitch; Third row: upper needle plate tuft stitch, upper needle plate loop stitch, float stitch, float stitch; Fourth row: upper needle plate loop stitch, float stitch, float stitch, lower needle cylinder tuft stitch; Fifth row: float stitch, float stitch, lower needle cylinder loop stitch, lower needle cylinder loop stitch; Sixth row: upper needle plate loop stitch, upper needle plate tuft stitch, float stitch, float stitch.

[0034] The first and fourth paths use high-performance polyester filaments, with a single fiber fineness of 3.12 to 3.33 dtex.

[0035] The second and fifth yarns use Siro blended yarn of recycled viscose fiber and combed cotton fiber, wherein the fiber content of the Siro blended yarn of recycled viscose fiber and combed cotton fiber is 20% recycled viscose fiber and 80% cotton fiber.

[0036] Preferably, in the Siro blended yarn of recycled viscose fiber and combed cotton fiber, the fineness of the recycled viscose fiber is 1.2 to 1.55 dtex, and the fineness of the combed cotton fiber is 1.1 to 1.25 dtex.

[0037] The third and sixth yarns use Siro blended yarn of heat-generating mite-resistant viscose fiber and polyester fiber, wherein the fiber content of the Siro blended yarn of heat-generating mite-resistant viscose fiber and polyester fiber is 60% heat-generating mite-resistant viscose fiber and 40% polyester fiber.

[0038] Preferably, in the Siro blended yarn of heat-generating mite-resistant viscose fiber and polyester fiber, the single fiber fineness of the heat-generating mite-resistant viscose fiber is 1.2 to 1.55 dtex, and the single fiber fineness of the polyester fiber is 0.8 to 1.0 dtex.

[0039] The aforementioned heat-generating and mite-proof viscose fiber is obtained by mixing viscose fiber spinning solution, water-soluble chitosan quaternary ammonium salt, and mite-proof agent, followed by wet spinning process, spinning, coagulation, washing, oiling, and drying.

[0040] The antibacterial properties of the heat-generating antibacterial and anti-mite fabrics described in Examples 1 and 2 were tested according to the oscillation method in the evaluation of antibacterial properties of textiles in GB / T20944. The antibacterial rates are shown in Table 1.

[0041] Table 1

[0042] Staphylococcus aureus E. coli Candida albicans Example 1 98.0% 99.8% 98.9% Example 2 99.5% 99.9% 99.4%

[0043] The anti-mite activity of the heat-generating antibacterial and anti-mite fabrics described in Examples 1 and 2 was evaluated in accordance with GB / T24253-2009. Dust mites were selected for testing, and the results are shown in Table 2.

[0044] Table 2

[0045] Approach-Avoidance Ratio Inhibition rate Example 1 97.0% 94.7% Example 2 98.5% 96.8%

[0046] The above description is merely a preferred embodiment of the present invention and does not limit the implementation and protection scope of the present invention. Those skilled in the art should realize that any equivalent substitutions and obvious changes made based on the content and illustrations of the present invention should be included within the protection scope of the present invention.

Claims

1. A heat-generating, antibacterial, and anti-mite fabric, characterized in that, The heat-generating, antibacterial, and anti-mite fabric is arranged in a six-row cycle. The six-row sequence, from the upper needle plate to the lower needle cylinder, is as follows: First row: float stitch, upper needle plate loop stitch, lower needle cylinder tuft stitch, float stitch; Second row: float stitch, float stitch, lower needle cylinder loop stitch, lower needle cylinder loop stitch; Third row: upper needle plate tuft stitch, upper needle plate loop stitch, float stitch, float stitch; Fourth row: upper needle plate loop stitch, float stitch, float stitch, lower needle cylinder tuft stitch; Fifth row: float stitch, float stitch, lower needle cylinder loop stitch, lower needle cylinder loop stitch; Sixth row: upper needle plate loop stitch, upper needle plate tuft stitch, float stitch, float stitch. The first and fourth yarns use high-performance polyester filaments; the second and fifth yarns use Siro blended yarn of recycled viscose fiber and combed cotton fiber; and the third and sixth yarns use Siro blended yarn of heat-generating and mite-resistant viscose fiber and polyester fiber.

2. The heat-generating, antibacterial, and anti-mite fabric according to claim 1, characterized in that, The single fiber fineness of the high-performance polyester filament is 3.12~3.33 dtex.

3. The heat-generating, antibacterial, and anti-mite fabric according to claim 1, characterized in that, The Siro blended yarn of regenerated viscose fiber and combed cotton fiber has a fiber content of 10-20% regenerated viscose fiber and 80-90% combed cotton fiber.

4. The heat-generating, antibacterial, and anti-mite fabric according to claim 1, characterized in that, In the Siro blended yarn of regenerated viscose fiber and combed cotton fiber, the single fiber fineness of the regenerated viscose fiber is 1.2~1.55 dtex, and the single fiber fineness of the combed cotton fiber is 1.1~1.25 dtex.

5. The heat-generating, antibacterial, and anti-mite fabric according to claim 1, characterized in that, The Siro blended yarn of heat-generating anti-mite viscose fiber and polyester fiber has a blending ratio of 50-60% heat-generating anti-mite viscose fiber and 40-50% polyester fiber.

6. The heat-generating, antibacterial, and anti-mite fabric according to claim 5, characterized in that, In the Siro blended yarn of heat-generating and mite-resistant viscose fiber and polyester fiber, the single fiber fineness of the heat-generating and mite-resistant viscose fiber is 1.2~1.55 dtex, and the single fiber fineness of the polyester fiber is 0.8~1.0 dtex.

7. The heat-generating, antibacterial, and anti-mite fabric according to claim 5, characterized in that, The heat-generating and mite-proof viscose fiber is obtained by mixing viscose fiber spinning solution, water-soluble chitosan quaternary ammonium salt, and mite-proof agent, followed by wet spinning process, spinning, coagulation, washing, oiling, and drying.