阅读说明：本技术 一种保暖抑菌功能纤维面料的生产方法 (Production method of fiber fabric with warm-keeping and bacteriostatic functions ) 是由 沈庆丰 沈伟峰 郑文渊 施晓峰 于 2020-12-01 设计创作，主要内容包括：本发明公开了一种保暖抑菌功能纤维面料的生产方法,纤维面料由以下重量份数的原料组分混纺而成：山羊绒纤维10-20份、远红外纤维4-10份、竹纤维3-9份、大豆蛋白纤维12-22份、石墨烯粘胶纤维6-14份、罗布麻纤维5-15份、兔毛纤维5-10份、纳米抗菌再生蛋白纤维2-6份和抗菌纤维2-4份,本发明生产方法简单,得到的纤维面料具有优异的保暖、抗菌、抑菌、防潮防霉性能,采用该纤维面料制成的服装具有更好的市场前景以及更高的经济价值。(The invention discloses a production method of a warm-keeping and bacteriostatic functional fiber fabric, which is formed by blending the following raw material components in parts by weight: 10-20 parts of cashmere fiber, 4-10 parts of far infrared fiber, 3-9 parts of bamboo fiber, 12-22 parts of soybean protein fiber, 6-14 parts of graphene viscose fiber, 5-15 parts of apocynum venetum fiber, 5-10 parts of rabbit hair fiber, 2-6 parts of nano antibacterial regenerated protein fiber and 2-4 parts of antibacterial fiber.)

1. A warm-keeping and bacteriostatic functional fiber fabric is characterized in that: the fiber fabric is formed by blending the following raw material components in parts by weight: 10-20 parts of cashmere fiber, 4-10 parts of far infrared fiber, 3-9 parts of bamboo fiber, 12-22 parts of soybean protein fiber, 6-14 parts of graphene viscose fiber, 5-15 parts of apocynum venetum fiber, 5-10 parts of rabbit hair fiber, 2-6 parts of nano antibacterial regenerated protein fiber and 2-4 parts of antibacterial fiber.

2. The warm-keeping bacteriostatic functional fiber fabric according to claim 1, characterized in that: the fiber fabric is formed by blending the following raw material components in parts by weight: 15 parts of cashmere fiber, 7 parts of far infrared fiber, 6 parts of bamboo fiber, 17 parts of soybean protein fiber, 10 parts of graphene viscose fiber, 10 parts of apocynum venetum fiber, 8 parts of rabbit hair fiber, 4 parts of nano antibacterial regenerated protein fiber and 3 parts of antibacterial fiber.

3. The warm-keeping bacteriostatic functional fiber fabric according to claim 1, characterized in that: the antibacterial fiber is nano bamboo charcoal antibacterial fiber which is composed of nano bamboo charcoal, nano silver and terylene.

4. The production method for achieving the warm-keeping and bacteriostatic functional fiber fabric of claim 1 is characterized by comprising the following steps of: the production method comprises the following steps:

A. firstly, respectively immersing cashmere fibers, far infrared fibers, bamboo fibers, soybean protein fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers, nano antibacterial regenerated protein fibers and antibacterial fibers into an antibacterial softening liquid for pretreatment;

B. drying the pretreated fiber for later use;

C. mixing far infrared fiber, bamboo fiber, soybean protein fiber and nano antibacterial regenerated protein fiber, and feeding into a spinning machine to obtain warp;

D. mixing cashmere fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers and antibacterial fibers, and feeding the mixture into a spinning machine to prepare warp yarns;

E. and respectively feeding the warp yarns and the weft yarns into a interweaving machine to be interwoven into a fiber fabric.

5. The production method of the warm-keeping bacteriostatic functional fiber fabric according to claim 4, characterized in that: the antibacterial softening liquid is prepared by mixing 30% of triethanolamine stearate quaternary ammonium salt, 20% of almond oil amidopropyl amine oxide, 30% of marine actinomycetes and 20% of nano titanium dioxide.

6. The production method of the warm-keeping bacteriostatic functional fiber fabric according to claim 4, characterized in that: and in the step B, the drying temperature is 70-90 ℃ and the drying time is 20-30 min.

Technical Field

The invention relates to the technical field of functional fiber fabric production, in particular to a production method of a warm-keeping and bacteriostatic functional fiber fabric.

Background

With the continuous development of science and technology, textile fabrics meeting different requirements of people are in a large number, so as to meet the requirements of consumers, and play an increasingly important role in daily life of people.

Most of fabrics owned in the current market only have the characteristics of some comfort functions, the effect is single, and the wide use requirements of users cannot be obtained.

Disclosure of Invention

The invention aims to provide a production method of a warm-keeping and bacteriostatic functional fiber fabric, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the fiber fabric with the functions of keeping warm and inhibiting bacteria is formed by blending the following raw material components in parts by weight: 10-20 parts of cashmere fiber, 4-10 parts of far infrared fiber, 3-9 parts of bamboo fiber, 12-22 parts of soybean protein fiber, 6-14 parts of graphene viscose fiber, 5-15 parts of apocynum venetum fiber, 5-10 parts of rabbit hair fiber, 2-6 parts of nano antibacterial regenerated protein fiber and 2-4 parts of antibacterial fiber.

Preferably, the fiber fabric is formed by blending the following raw material components in parts by weight: 15 parts of cashmere fiber, 7 parts of far infrared fiber, 6 parts of bamboo fiber, 17 parts of soybean protein fiber, 10 parts of graphene viscose fiber, 10 parts of apocynum venetum fiber, 8 parts of rabbit hair fiber, 4 parts of nano antibacterial regenerated protein fiber and 3 parts of antibacterial fiber.

Preferably, the antibacterial fiber is nano bamboo charcoal antibacterial fiber, and the nano bamboo charcoal antibacterial fiber is composed of nano bamboo charcoal, nano silver and terylene.

Preferably, the production method comprises the following steps:

A. firstly, respectively immersing cashmere fibers, far infrared fibers, bamboo fibers, soybean protein fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers, nano antibacterial regenerated protein fibers and antibacterial fibers into an antibacterial softening liquid for pretreatment;

B. drying the pretreated fiber for later use;

C. mixing far infrared fiber, bamboo fiber, soybean protein fiber and nano antibacterial regenerated protein fiber, and feeding into a spinning machine to obtain warp;

D. mixing cashmere fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers and antibacterial fibers, and feeding the mixture into a spinning machine to prepare warp yarns;

E. and respectively feeding the warp yarns and the weft yarns into a interweaving machine to be interwoven into a fiber fabric.

Preferably, the antibacterial softening liquid is prepared by mixing 30% of triethanolamine stearate quaternary ammonium salt, 20% of almond oil amidopropyl amine oxide, 30% of marine actinomycetes and 20% of nano titanium dioxide.

Preferably, the drying temperature in the step B is 70-90 ℃ and the drying time is 20-30 min.

Compared with the prior art, the invention has the beneficial effects that: the production method is simple, the obtained fiber fabric has excellent heat preservation, antibacterial, bacteriostatic, moisture-proof and mildew-proof performances, and clothes made of the fiber fabric have better market prospect and higher economic value; the added antibacterial fiber has long antibacterial and bacteriostatic time, so that the antibacterial efficiency of the fiber fabric is improved; in addition, the fabric prepared by the invention has a good thermal inductance and thermal insulation function, the thickness of the fabric is not increased, and the attractiveness and comfort of clothes made of the fabric are improved on the premise of thermal insulation.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides the following technical scheme: the fiber fabric with the functions of keeping warm and inhibiting bacteria is formed by blending the following raw material components in parts by weight: 10-20 parts of cashmere fiber, 4-10 parts of far infrared fiber, 3-9 parts of bamboo fiber, 12-22 parts of soybean protein fiber, 6-14 parts of graphene viscose fiber, 5-15 parts of apocynum venetum fiber, 5-10 parts of rabbit hair fiber, 2-6 parts of nano antibacterial regenerated protein fiber and 2-4 parts of antibacterial fiber.

The first embodiment is as follows:

the fiber fabric is formed by blending the following raw material components in parts by weight: 10 parts of cashmere fiber, 4 parts of far infrared fiber, 3 parts of bamboo fiber, 12 parts of soybean protein fiber, 6 parts of graphene viscose fiber, 5 parts of apocynum venetum fiber, 5 parts of rabbit hair fiber, 2 parts of nano antibacterial regenerated protein fiber and 2 parts of antibacterial fiber.

In this embodiment, the antibacterial fiber is a nano bamboo charcoal antibacterial fiber, and the nano bamboo charcoal antibacterial fiber is composed of nano bamboo charcoal, nano silver and terylene.

The production method of this example includes the following steps:

A. firstly, respectively immersing cashmere fibers, far infrared fibers, bamboo fibers, soybean protein fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers, nano antibacterial regenerated protein fibers and antibacterial fibers into an antibacterial softening liquid for pretreatment;

B. drying the pretreated fiber for later use;

C. mixing far infrared fiber, bamboo fiber, soybean protein fiber and nano antibacterial regenerated protein fiber, and feeding into a spinning machine to obtain warp;

D. mixing cashmere fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers and antibacterial fibers, and feeding the mixture into a spinning machine to prepare warp yarns;

E. and respectively feeding the warp yarns and the weft yarns into a interweaving machine to be interwoven into a fiber fabric.

In the embodiment, the antibacterial softening liquid is prepared by mixing 30% of triethanolamine stearate quaternary ammonium salt, 20% of almond oil amidopropyl amine oxide, 30% of marine actinomycetes and 20% of nano titanium dioxide.

In this example, the drying temperature in step B was 70 ℃ and the drying time was 20 min.

Example two:

the fiber fabric is formed by blending the following raw material components in parts by weight: 20 parts of cashmere fiber, 10 parts of far infrared fiber, 9 parts of bamboo fiber, 22 parts of soybean protein fiber, 14 parts of graphene viscose fiber, 15 parts of apocynum venetum fiber, 10 parts of rabbit hair fiber, 6 parts of nano antibacterial regenerated protein fiber and 4 parts of antibacterial fiber.

In this embodiment, the antibacterial fiber is a nano bamboo charcoal antibacterial fiber, and the nano bamboo charcoal antibacterial fiber is composed of nano bamboo charcoal, nano silver and terylene.

The production method of this example includes the following steps:

A. firstly, respectively immersing cashmere fibers, far infrared fibers, bamboo fibers, soybean protein fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers, nano antibacterial regenerated protein fibers and antibacterial fibers into an antibacterial softening liquid for pretreatment;

B. drying the pretreated fiber for later use;

C. mixing far infrared fiber, bamboo fiber, soybean protein fiber and nano antibacterial regenerated protein fiber, and feeding into a spinning machine to obtain warp;

D. mixing cashmere fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers and antibacterial fibers, and feeding the mixture into a spinning machine to prepare warp yarns;

E. and respectively feeding the warp yarns and the weft yarns into a interweaving machine to be interwoven into a fiber fabric.

In the embodiment, the antibacterial softening liquid is prepared by mixing 30% of triethanolamine stearate quaternary ammonium salt, 20% of almond oil amidopropyl amine oxide, 30% of marine actinomycetes and 20% of nano titanium dioxide.

In this example, the drying temperature in step B was 90 ℃ and the drying time was 30 min.

Example three:

the fiber fabric is formed by blending the following raw material components in parts by weight: 12 parts of cashmere fiber, 6 parts of far infrared fiber, 4 parts of bamboo fiber, 15 parts of soybean protein fiber, 7 parts of graphene viscose fiber, 7 parts of apocynum venetum fiber, 6 parts of rabbit hair fiber, 3 parts of nano antibacterial regenerated protein fiber and 3 parts of antibacterial fiber.

In this embodiment, the antibacterial fiber is a nano bamboo charcoal antibacterial fiber, and the nano bamboo charcoal antibacterial fiber is composed of nano bamboo charcoal, nano silver and terylene.

The production method of this example includes the following steps:

A. firstly, respectively immersing cashmere fibers, far infrared fibers, bamboo fibers, soybean protein fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers, nano antibacterial regenerated protein fibers and antibacterial fibers into an antibacterial softening liquid for pretreatment;

B. drying the pretreated fiber for later use;

C. mixing far infrared fiber, bamboo fiber, soybean protein fiber and nano antibacterial regenerated protein fiber, and feeding into a spinning machine to obtain warp;

D. mixing cashmere fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers and antibacterial fibers, and feeding the mixture into a spinning machine to prepare warp yarns;

E. and respectively feeding the warp yarns and the weft yarns into a interweaving machine to be interwoven into a fiber fabric.

In the embodiment, the antibacterial softening liquid is prepared by mixing 30% of triethanolamine stearate quaternary ammonium salt, 20% of almond oil amidopropyl amine oxide, 30% of marine actinomycetes and 20% of nano titanium dioxide.

In this example, the drying temperature in step B was 75 ℃ and the drying time was 22 min.

Example four:

the fiber fabric is formed by blending the following raw material components in parts by weight: 15 parts of cashmere fiber, 7 parts of far infrared fiber, 6 parts of bamboo fiber, 17 parts of soybean protein fiber, 10 parts of graphene viscose fiber, 10 parts of apocynum venetum fiber, 8 parts of rabbit hair fiber, 4 parts of nano antibacterial regenerated protein fiber and 3 parts of antibacterial fiber.

In this embodiment, the antibacterial fiber is a nano bamboo charcoal antibacterial fiber, and the nano bamboo charcoal antibacterial fiber is composed of nano bamboo charcoal, nano silver and terylene.

The production method of this example includes the following steps:

A. firstly, respectively immersing cashmere fibers, far infrared fibers, bamboo fibers, soybean protein fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers, nano antibacterial regenerated protein fibers and antibacterial fibers into an antibacterial softening liquid for pretreatment;

B. drying the pretreated fiber for later use;

C. mixing far infrared fiber, bamboo fiber, soybean protein fiber and nano antibacterial regenerated protein fiber, and feeding into a spinning machine to obtain warp;

D. mixing cashmere fibers, graphene viscose fibers, apocynum venetum fibers, rabbit hair fibers and antibacterial fibers, and feeding the mixture into a spinning machine to prepare warp yarns;

E. and respectively feeding the warp yarns and the weft yarns into a interweaving machine to be interwoven into a fiber fabric.

In the embodiment, the antibacterial softening liquid is prepared by mixing 30% of triethanolamine stearate quaternary ammonium salt, 20% of almond oil amidopropyl amine oxide, 30% of marine actinomycetes and 20% of nano titanium dioxide.

In this example, the drying temperature in step B was 80 ℃ and the drying time was 25 min.

Experimental example:

the fiber fabric prepared by the embodiments of the invention is subjected to performance test, and the obtained data is as follows:

	antibacterial ratio (%)	Warming effect
			Example one	98.4	Long warm-keeping time
Example two	98.6	Long warm-keeping time
			EXAMPLE III	98.7	Long warm-keeping time
Example four	98.7	Long warm-keeping time

In conclusion, the production method is simple, the obtained fiber fabric has excellent heat preservation, antibacterial, bacteriostatic, moisture-proof and mould-proof performances, and the clothes made of the fiber fabric have better market prospect and higher economic value; the added antibacterial fiber has long antibacterial and bacteriostatic time, so that the antibacterial efficiency of the fiber fabric is improved; in addition, the fabric prepared by the invention has a good thermal inductance and thermal insulation function, the thickness of the fabric is not increased, and the attractiveness and comfort of clothes made of the fabric are improved on the premise of thermal insulation.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.