Nano copper oxide cellulose fiber having strong bacteriostasis and washing-resisting performance

A nano-copper oxide and cellulose fiber technology, applied in the direction of biochemical fiber treatment, fiber treatment, plant fiber, etc., can solve problems such as no nano-copper oxide modified cellulose fiber, etc., and achieve the effect of improving adhesion performance and antibacterial

Inactive Publication Date: 2018-04-06
钱景
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, there is no literature report on nano-copper oxide modified cellulose fibers

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0012] (1) Put the cotton fiber in a sodium hydroxide solution with a mass fraction of 10%, with a bath ratio of 1:50, react at 70°C for 180 minutes, wash repeatedly with deionized water until neutral, and obtain sodium hydroxide modified after drying Cotton fiber; then disperse the above-mentioned sodium hydroxide modified cotton fiber in ethanol with a bath ratio of 1:50, condense and reflux for 60 minutes under nitrogen protection at 80°C, add alcohol ether sulfosuccinic acid monoester disodium salt, and stir at a constant speed for 60 minutes Finally, add azobisisoheptanonitrile and dibenzoyl peroxide, continue to stir and react for 1 hour, wash with ethanol and deionized water repeatedly after filtration, and obtain anionized cotton fibers after vacuum drying; the alcohol ether sulfosuccinate The mass ratio of acid monoester disodium salt and sodium hydroxide modified cotton fiber is 1:1, and the quality of described azobisisoheptanonitrile is 0.01% of sodium hydroxide mod...

Embodiment 2

[0014] (1) Put the ramie fibers in a sodium hydroxide solution with a mass fraction of 13%, with a bath ratio of 1:50, react at 70°C for 180 minutes, wash repeatedly with deionized water until neutral, and obtain sodium hydroxide modified after drying Ramie fiber; then disperse the above-mentioned sodium hydroxide modified ramie fiber in ethanol, bath ratio 1:50, condense and reflux for 60 minutes under nitrogen protection at 80°C, add alcohol ether sulfosuccinic acid monoester disodium salt, and stir at a constant speed for 60 minutes Finally, add azobisisoheptanonitrile and dibenzoyl peroxide, continue to stir and react for 1-12h, filter and wash repeatedly with ethanol and deionized water, and obtain anionized ramie fibers after vacuum drying; the alcohol ether sulfonate The mass ratio of succinic acid monoester disodium salt and sodium hydroxide modified ramie fiber is 1:1, and the quality of described azobisisoheptanonitrile is 0.2% of sodium hydroxide modified ramie fiber...

Embodiment 3

[0016](1) Put the Modal fiber in a sodium hydroxide solution with a mass fraction of 18%, with a bath ratio of 1:50, react at 70°C for 180 minutes, wash repeatedly with deionized water until neutral, and obtain sodium hydroxide modification after drying Modal fiber; then disperse the above sodium hydroxide modified Modal fiber in ethanol with a bath ratio of 1:50, condense and reflux for 60 minutes under nitrogen protection at 80°C, add alcohol ether sulfosuccinic acid monoester disodium salt, and stir at a constant speed for 60 minutes Finally, add azobisisoheptanonitrile and dibenzoyl peroxide, continue to stir and react for 12 hours, wash repeatedly with ethanol and deionized water after filtration, and obtain anionized Modal fibers after vacuum drying; the alcohol ether sulfosuccinate The mass ratio of acid monoester disodium salt and sodium hydroxide modified Modal fiber is 1:3, and the quality of described azobisisoheptanonitrile is 0.4% of sodium hydroxide modified Modal...

the structure of the environmentally friendly knitted fabric provided by the present invention; figure 2 Flow chart of the yarn wrapping machine for environmentally friendly knitted fabrics and storage devices; image 3 Is the parameter map of the yarn covering machine
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PUM

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Abstract

The invention discloses nano copper oxide cellulose fiber having strong bacteriostasis and washing-resisting performance. A preparation method comprises the following steps: cellulose fiber anionization, chitosan modification, nano copper oxide modification, and chitosan coating in order. The nano copper oxide particles are coated between two layers of chitosan, a chitosan / nano copper oxide / chitosan composite functional layer is prepared, chitosan and nano copper oxide perform synergistic antibacterial effect, and adhesion performance, bacteriostasis and washing-resisting performance of the nano copper oxide particles are greatly increased.

Description

technical field [0001] The invention relates to a nano-copper oxide cellulose fiber with strong antibacterial and washable properties, which belongs to the field of textile materials and functional nanometer materials. Background technique [0002] Since the 1990s, with the improvement of measurement and characterization techniques, nanomaterials and nanotechnology have developed rapidly. Nanomaterials refer to materials with a size of 1-100nm. Different from bulk materials, they have unique optoelectronic properties and have been widely studied and applied in various fields such as electronics, materials, medicine, biology, machinery, textiles, printing and dyeing. As far as the textile field is concerned, the combination of nanomaterials and textiles can effectively improve the inherent defects of textiles, expand the scope of application of textiles, and increase the added value of textiles. A large number of research results show that the use of organic or inorganic nan...

Claims

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Application Information

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IPC IPC(8): D06M11/38D06M13/256D06M15/03D06M101/06
CPCD06M11/38D06M13/256D06M15/03D06M16/00D06M2101/06
Inventor 钱景
Owner 钱景
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