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Method for preparing ozone heterogeneous oxidation solid catalysts

A heterogeneous oxidation, solid catalyst technology, applied in catalyst activation/preparation, physical/chemical process catalysts, metal/metal oxide/metal hydroxide catalysts, etc., can solve the problems of easy loss of catalytic activity, poor toxicity resistance, The problem of low catalyst adsorption, to achieve the effect of improving anti-toxicity and catalytic activity, strong adsorption, and inhibiting melting and precipitation

Inactive Publication Date: 2017-08-18
SICHUAN NORMAL UNIVERSITY
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  • Abstract
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  • Claims
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Problems solved by technology

[0004] In view of the problems of low catalyst adsorption, poor anti-toxicity and easy loss of catalytic activity in the current preparation method of ozone heterogeneous oxidation solid catalyst, a multi-component porous carrier was developed to enhance the adsorption of the catalyst through pore expansion and surface activation. Rare earth metal organic compounds as precursors of catalytic active additives, common transition metal organic compounds and noble metal compounds as precursors of catalytic active centers and multi-component porous carriers through hydrothermal reaction and high temperature calcination to prepare ozone heterogeneous oxidation containing multiple metals The preparation method of solid catalyst to improve the anti-toxicity and catalytic activity of the catalyst is characterized in that component A and deionized water are added into a sealable reactor and stirred to prepare an aqueous solution, and the weight concentration of component A is controlled to be 2% to 6%. After the preparation is completed, add component B under stirring, raise the temperature to 35°C-50°C, continue to stir for 3h-6h, filter, and dry the reaction product at 102°C-106°C to obtain a modified carrier for pore expansion; pore expansion Put the modified carrier into the ultrasonic reactor, add the aqueous solution prepared by C component and deionized water, the weight concentration of C component is 3%~8%, stir and mix evenly, control the ultrasonic power density to 0.3~0.8W / m 3 , frequency 20kHz ~ 30kHz, 40 ℃ ~ 55 ℃, ultrasonic vibration 2h ~ 5h, the ultrasonic surface activation carrier mixture is obtained; the ultrasonic surface activation carrier mixture is transferred to the hydrothermal reaction kettle, and then add D component and deionized water to prepare The aqueous solution, the weight concentration of D component is 40% ~ 55%, by weight, the weight ratio of D component deionized aqueous solution: ultrasonic surface activation carrier mixture = 1: (1.5 ~ 2), control temperature 120 ℃ ~ 180°C, the hydrothermal reaction time is 8h~16h, and then dried to obtain fine particles; the fine particles are burned in a muffle furnace at 600°C~950°C for 3h~8h to obtain a solid catalyst for ozone heterogeneous oxidation

Method used

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Examples

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Effect test

Embodiment 1

[0007] Embodiment 1:1.35g lithium hypochlorite, 1.65g bis(acetylacetonate) beryllium, 140ml deionized water, join volume and be that in the sealable reactor of 500ml, stir and mix evenly, the weight concentration of this aqueous solution is 2.1%, times Lithium chlorate: the weight ratio of bis(acetylacetonate) beryllium=1:1.2; add deionized water to wash to neutral, dry at 103°C to remove moisture, and then sieve 2.75g diatoms of -200 mesh to +400 mesh standard sieve Weight (3 g) of pure, 3.75 g kyanite, 4.75 g illite, 5.75 g sodium borite, 6.75 g aluminum hydroxide, 7.75 g lapis lazuli, lithium hypochlorite and bis(acetylacetonate)beryllium: porous material The weight (31.5g)=1:10.5, heat up to 36°C, continue to stir and react for 3.2h, filter, dry at 103°C and obtain 31g of pore-enlarging modified carrier; in a 500ml ultrasonic reactor, put pore-enlarging modified Carrier 31g, add the aqueous solution that 3.25g monoalkyl ether trimethyl ammonium chloride is dissolved in 100...

Embodiment 2

[0008] Embodiment 2:0.24g lithium hypochlorite, 0.36g bis(acetylacetonate) beryllium, 10ml deionized water, join volume and be that in the sealable reactor of 100ml, stir and mix evenly, the weight concentration of this aqueous solution is 5.7%, times Lithium chlorate: the weight ratio of bis(acetylacetonate) beryllium=1:1.5; add deionized water to wash to neutral, dry at 103°C to remove moisture, and then sieve 1.45g diatoms of -200 mesh to +400 mesh standard sieve Weight of pure, 1.65g kyanite, 1.85g illite, 2.05g sodium borite, 2.25g aluminum hydroxide, 2.45g lapis lazuli, lithium hypochlorite and bis(acetylacetonate)beryllium (0.6g): Porous The weight of the material (11.7g)=1:19.5, heat up to 48°C, continue to stir and react for 5.8h, filter, and dry at 105°C to obtain a pore-expanding modified carrier of 11.5g; put it into a 100ml ultrasonic reactor Modified carrier 11.5g, add the aqueous solution of 2.2g monoalkyl ether trimethyl ammonium chloride and be dissolved in 26...

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Abstract

The invention relates to a method for preparing ozone heterogeneous oxidation solid catalysts, and belongs to the technical field of environmental protection and chemical catalysts. The method includes carrying out pore expansion and modification on carriers which are purification diatom, kyanite, illite, ulexite, aluminum hydroxide and celestine porous materials by the aid of lithium hypochlorite and bis (acetylacetone) beryllium; adding monoalkyl ether trimethyl ammonium chloride into the carriers and carrying surface activation treatment on the carriers under the effects of ultrasonic waves; carrying out hydrothermal reaction on the carriers which are subjected to ultrasonic surface activation, borax, potassium sulfate, tri (hexafluoroacetylacetone) yttrium (III) dihydrate, promethium tricyclic pentadiene, samarium acetylacetone, terbium acetate hydrate rare earth metal organic compounds, vanadium pyruvic acid isonicotinyl hydrazone, cobalt gluconate, ammonium zirconium carbonate and palladium dichloro-tetrammine in hydrothermal reaction kettles under the effect of chlorinated methylacryloyl oxo-ethyl trimethylammonium which is an emulsifier; drying reaction products to remove moisture; burning the reaction products in muffle furnaces at the certain temperatures to obtain the ozone heterogeneous oxidation solid catalysts. The monoalkyl ether trimethyl ammonium chloride is used as a surfactant. The borax and the potassium sulfate are used as composite mineralizers, the tri (hexafluoroacetylacetone) yttrium (III) dihydrate, the promethium tricyclic pentadiene, the samarium acetylacetone and the terbium acetate hydrate rare earth metal organic compounds are used as catalytic active auxiliary precursors, the vanadium pyruvic acid isonicotinyl hydrazone, the cobalt gluconate, the ammonium zirconium carbonate and the palladium dichloro-tetrammine are used as catalytic active central components, the vanadium pyruvic acid isonicotinyl hydrazone is a common transition metal organic compound, and the palladium dichloro-tetrammine is a precious metal compounds.

Description

technical field [0001] The invention relates to a preparation method of a solid catalyst for ozone heterogeneous oxidation, which belongs to the technical fields of environmental protection and chemical catalysts. Background technique [0002] Ozone oxidation technology utilizes the strong oxidation ability of ozone, which can oxidize and decompose many organic pollutants, and is widely used in wastewater treatment. Ozone catalytic oxidation technology is divided into ozone homogeneous catalytic oxidation and ozone heterogeneous catalytic oxidation. Ozone homogeneous catalytic oxidation has catalysts that are difficult to separate, recycle and reuse, and the low utilization rate of ozone leads to high water treatment operation costs. Ozone heterogeneous catalytic oxidation technology has the advantages of easy separation and recovery of catalysts and reusable use, high ozone utilization rate, and high removal rate of organic pollutants, which reduces water treatment. The ad...

Claims

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Application Information

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IPC IPC(8): B01J23/89B01J20/20B01J20/28B01J20/30C02F1/28C02F1/78B01J32/00C02F101/30
CPCB01J20/06B01J20/12B01J20/20C02F1/281C02F1/725C02F1/78B01J20/28016B01J23/8946B01J37/084B01J37/086B01J37/088B01J37/10C02F2101/30C02F2305/023B01J2220/42B01J35/50B01J35/40
Inventor 朱明石小阳王希雅
Owner SICHUAN NORMAL UNIVERSITY
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