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Method for preparing textile fiber/graphene/Bi2WO6 composite environmental catalytic material

A technology of textile fibers and catalytic materials, which is applied in the field of preparation of textile fibers/graphene/Bi2WO6 composite environmental catalytic materials, can solve the problems of high processing cost, large loss of tearing strength, changing porous structure, etc., and achieves accelerated photocatalytic degradation. The effect of reaction, improving photocatalytic activity, and easy industrial production

Inactive Publication Date: 2016-11-09
DONGHUA UNIV +1
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

Adsorption and biological treatment are commonly used in industry. The adsorption method only transfers toxic pollutants from the liquid phase to the solid phase, but does not completely eliminate organic pollutants. The biological treatment cycle is long and the equipment occupies a large area. Biological toxicity can not be effectively removed
In contrast, advanced oxidation technologies can directly degrade dyes and other organic substances by producing strong oxidizing active species, and even completely mineralize them, which has attracted widespread attention. However, these advanced oxidation technologies also have certain limitations, such as easy to bring Secondary pollution, high treatment cost, unsuitable for large-flow wastewater treatment, and the priority removal of toxic target pollutants in the presence of a large number of organic / inorganic compounds is quite difficult, so it is very difficult to design and develop an efficient removal of toxic target pollutants in actual wastewater systems The catalytic system is of great significance
[0003] In order to construct high-efficiency micro-nano structures on the surface of textile fibers and overcome the adverse effects of the use of adhesives on the performance of catalytic fibers, the researchers tried to use the sol-gel finishing method to prepare catalytic functional fibers. The research results showed that the catalytic fibers prepared by this method The fiber has certain catalytic properties, but there are the following problems: (1) the curing of the gel must be carried out at high temperature, which has an impact on the physical and mechanical properties of the textile fiber, such as a large loss of tear strength; (2) the sol- The gel method prepares an amorphous nano-photocatalyst with no photocatalytic performance, so it needs to be converted to the desired crystal form through a certain way, and the crystallinity of the crystal phase needs to be improved to reduce lattice defects; (3) high temperature Sintering is currently the most common method for transforming from amorphous phase to fixed shape and increasing crystallinity, but the calcination temperature generally needs to be 300°C or above to achieve it. Obviously, conventional textile fibers cannot withstand such a high temperature. This is the sol-gel method. Common problems when applied to organic-loaded substrates; (4) direct contact between photocatalysts and fibers will cause photooxidative degradation of fibers, resulting in a decrease in the physical and mechanical properties of textile fibers
The low-temperature method is to use the precursor as the precursor to prepare a stable sol through sol-gel technology, and then synthesize it on the surface of the fiber in situ, and realize the transformation of the nano-photocatalyst from the amorphous state to the fixed state on the fiber in boiling water at 100 ° C. The catalytic functional fiber prepared by the method has good net performance and is convenient to use, but there are problems such as textile fiber being degraded by photooxidation and large loss of strength.
Improving the photocatalytic performance by further increasing the loading of metal oxides on fiber materials will cause serious agglomeration of metal oxides, affect the effective specific surface area available for catalytic materials, and change the porous structure of textile fibers / metal oxide materials. , which is not conducive to the enrichment of organic pollutants on the surface of fiber materials, and will also affect the catalytic performance of catalytic materials

Method used

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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  • Method for preparing textile fiber/graphene/Bi2WO6 composite environmental catalytic material
  • Method for preparing textile fiber/graphene/Bi2WO6 composite environmental catalytic material

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0026] (1) Add 230mL of concentrated sulfuric acid and 3g of sodium nitrate into a beaker, cool in an ice-water bath, add 10g of graphite powder while stirring, and after mixing evenly, grind 30g of potassium permanganate into fine powder and slowly add it, and stir and react for 1 hour at 0°C to obtain Graphite intercalation compound; after heating up to 35°C and continuing to react for 30 minutes, add 460mL of deionized water and continue to react for 30 minutes; then add 1400mL of deionized water and 30ml of 30% hydrogen peroxide in sequence, the solution changes from brick red to bright yellow, and continue to react After 10 minutes, filter, wash with 2% dilute hydrochloric acid, and then wash with deionized water several times (8000rpm, 30min), vacuum dry at 50°C to obtain graphene oxide, redisperse graphene oxide in water, and ultrasonicate for 30min. drying the dispersion in a vacuum oven at 40°C to obtain graphene oxide;

[0027] (2) Select hemp fiber as a carrier, use...

Embodiment 2

[0030] (1) Add 240mL of concentrated sulfuric acid and 4.5g of sodium nitrate into a beaker, cool in an ice-water bath, add 10g of graphite powder while stirring, after mixing evenly, grind 40g of potassium permanganate and add slowly, stir and react at 0°C for 1.5h , to obtain a graphite intercalation compound; after heating up to 40°C and continuing to react for 45 minutes, add 530 mL of deionized water and continue to react for 37 minutes; then add 1600 mL of deionized water and 45 mL of 30% hydrogen peroxide in sequence, the solution changes from brick red to bright yellow, After continuing to react for 18 minutes, filter, wash with 3% dilute hydrochloric acid, then centrifuge (8000rpm, 37min) with deionized water several times, dry at 60°C in vacuum to obtain graphene oxide, redisperse graphene oxide in water, and ultrasonically 340min, dry the dispersion in a vacuum oven at 50°C to obtain graphene oxide; mL

[0031] (2) Select cotton fiber as a carrier, use acetone solut...

Embodiment 3

[0034] (1) Add 250mL of concentrated sulfuric acid and 6g of sodium nitrate into a beaker, cool in an ice-water bath, add 10g of graphite powder while stirring, and after mixing evenly, grind 50g of potassium permanganate into fine powder and add slowly, then stir and react for 2 hours at 0°C to obtain Graphite intercalation compound; after heating up to 45°C and continuing to react for 60 minutes, add 600mL of deionized water and continue to react for 45 minutes; then add 1800mL of deionized water and 60ml of 30% hydrogen peroxide in sequence, the solution changes from brick red to bright yellow, and continue to react After 25 minutes, filter, wash with 4% dilute hydrochloric acid, then wash with deionized water several times (8000rpm, 45min), vacuum dry at 70°C to obtain graphene oxide, redisperse graphene oxide in water, and ultrasonicate for 50min. Dry the dispersion in a vacuum oven at 60°C to obtain graphene oxide;

[0035] (2) Select silk fiber as a carrier, use acetone...

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Abstract

The invention relates to a method for preparing a textile fiber / graphene / Bi2WO6 composite environmental catalytic material. The method comprises the steps: dipping textile fibers into a saturated dispersion solution of graphene oxide, then, carrying out baking, carrying out washing, then, putting the textile fibers into a reducer solution, carrying out a reaction for 0.5 to 1 hour at the temperature of 50 DEG C to 80 DEG C, carrying out washing, and carrying out baking, so as to obtain textile fiber / graphene; and adding the textile fiber / graphene into a solution of Bi(NO3)3 and Na3PO4, carrying out stirring, then, adding Na2WO4 and urea into the solution, carrying out a hydrothermal reaction for 3 to 8 hours at the temperature of 120 DEG C to 180 DEG C, carrying out cooling, then, carrying out washing, and carrying out baking, thereby obtaining the textile fiber / graphene / Bi2WO6 composite environmental catalytic material. The method disclosed by the invention is simple and is adaptable to industrial production; and the obtained composite material has a relatively good environment purification effect.

Description

technical field [0001] The invention belongs to the field of preparation of environmental catalytic materials, in particular to a textile fiber / graphene / Bi 2 WO 6 A method for preparing a composite environmental catalytic material. Background technique [0002] Environmental resources are an important basis for the survival and development of human society. The governance and protection of the environment has been running through the history of the development of human industrial society and is directly related to the sustainable development of human society. Water shortage is an important issue facing society today, and the treatment of industrial wastewater has always been the top priority in the environmental field. In recent years, the treatment of some low-concentration toxic pollutants in actual wastewater, such as conjugated dyes, chlorinated aromatic compounds, polybrominated diphenyl ethers, antibiotics, etc., has become the focus of international research. Adsor...

Claims

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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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B01J31/34C02F1/30C02F1/72
CPCC02F1/30C02F1/725B01J31/34C02F2305/10C02F2101/308B01J35/33B01J35/39Y02W10/37
Inventor 刘保江张俊徐顺环
Owner DONGHUA UNIV
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