CN112588293A

CN112588293A - Novel catalyst for degrading dioxin and preparation method thereof

Info

Publication number: CN112588293A
Application number: CN202011465761.6A
Authority: CN
Inventors: 唐志诚; 赵海军; 吴军伟
Original assignee: Jiangsu Baimaoyuan Environmental Protection Technology Co ltd; Lanzhou Institute of Chemical Physics LICP of CAS
Current assignee: Jiangsu Baimaoyuan Environmental Protection Technology Co ltd; Lanzhou Institute of Chemical Physics LICP of CAS
Priority date: 2020-12-13
Filing date: 2020-12-13
Publication date: 2021-04-02

Abstract

The invention provides a novel catalyst with high activity and high stability and a preparation method thereof, which are used for catalytic oxidation degradation of waste incineration dioxin. The catalyst mainly comprises two parts of an active component and a carrier, wherein the active component is a transition metal oxide V₂O₅，WO₃，Fe₂O₃In mass, V₂O₅Content of 0.5-10%, WO₃0.1-8% of Fe₂O₃The content is 0.1-6%; the catalyst carrier is made of TiO₂And SiO₂Composition by mass of TiO₂50-95% of SiO₂The content is 5-20%. The catalyst does not contain noble metal, and the preparation cost is lowThe preparation method is simple, the activation temperature is low, the elimination efficiency of dioxin pollutants is high, the elimination rate of the catalyst at 180 ℃ is nearly 70%, and the elimination efficiency at 220 ℃ is over 90%.

Description

Novel catalyst for degrading dioxin and preparation method thereof

Technical Field

The invention belongs to the field of research on key technology for preparing catalysts, and relates to a catalyst for catalytic oxidative degradation of dioxin pollutants in waste incineration flue gas and a preparation method thereof.

Background

Dioxin is a chloro-oxygenated tricyclic aromatic compound, has the characteristics of stable chemical property, good thermal stability, difficult biodegradation and the like, can be accumulated in organisms and in the environment for a long time, and has the effects of carcinogenesis, teratogenesis and mutagenesis on the organisms.

At present, most of waste incineration dioxin treatment adopts an activated carbon adsorption technology, but the activated carbon adsorption technology has the defects of high operation cost and incomplete low-concentration dioxin treatment, and the concentration of dioxin in treated flue gas mostly exceeds the national standard. In addition, the activated carbon adsorption only seals dioxin in activated carbon pore channels, the dioxin is not really eliminated from the environment, and the activated carbon after adsorbing the dioxin has the risk of secondary pollution. Compared with the activated carbon adsorption technology, the method for eliminating dioxin through catalytic oxidation is used for directly decomposing and converting dioxin in flue gas into water, carbon dioxide and hydrogen chloride which are non-toxic or have small toxicity, and the method for eliminating dioxin through catalytic oxidation has the characteristics of high reaction efficiency, low later-stage operation cost, easiness in engineering and the like. But the biggest problem facing the elimination of dioxin by catalytic oxidation at present is the preparation and production of high-performance catalysts.

Disclosure of Invention

The invention aims to provide a novel catalyst with high activity and high stability and a preparation method thereof, aiming at the defect that a high-performance dioxin decomposition catalyst is lacked in the prior art, the novel catalyst is used for catalytic oxidation degradation of refuse-incinerated dioxin, and the catalyst can efficiently eliminate refuse-incinerated dioxin pollutants.

The novel catalyst for degrading dioxin mainly comprises two parts, namely an active component and a catalyst carrier; the active component is transition metal oxide V₂O₅，WO₃，Fe₂O₃In mass, V₂O₅Content of 0.5-10%, WO₃0.1-8% of Fe₂O₃The content is 0.1-6%; the catalyst carrier is made of TiO₂And SiO₂Composition by mass of TiO₂50-95% of SiO₂The content is 5-20%.

The novel catalyst for degrading dioxin is prepared by loading an active component precursor dissolved in an acid solution on the surface of a carrier, and then aging, drying and calcining the carrier.

The novel catalyst for degrading dioxin is characterized in that the acidic solution is an oxalic acid solution with the mass fraction of 10-20%.

The novel catalyst for the degradation of dioxin according to the invention, said V₂O₅The precursor comprises ammonium metavanadate, vanadyl oxalate and vanadyl sulfate; WO₃The precursor comprises ammonium metatungstate, ammonium paratungstate and Fe₂O₃The precursor comprises ferric nitrate and ferric sulfate.

The preparation method of the novel catalyst for degrading dioxin comprises the following steps:

(1) firstly, V is firstly₂O₅Dissolving the precursor in a certain amount of oxalic acid solution, and keeping the molar ratio of oxalic acid to vanadium not less than 2;

(2) in the above-mentioned compound containing V₂O₅Adding WO into oxalic acid solution of precursor₃Fully stirring the precursor at 40-70 ℃ to dissolve the precursor;

(3) adding Fe into the oxalic acid solution₂O₃Fully stirring the precursor at 40-70 ℃ to dissolve the precursor;

(4) adding catalyst carrier TiO into oxalic acid solution containing vanadium, tungsten and iron precursors₂And SiO₂Keeping the temperature and stirring for 5-10 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with active component precursor₂And SiO₂Drying the mixture in a blast drying oven for 12-36 hours at 80-150 ℃;

(6) and calcining the dried catalyst precursor in a muffle furnace at the temperature of 400-600 ℃ for 5-20 hours to obtain the catalyst for degrading the dioxin after the calcination is finished.

The inventionCatalyst for degradation of dioxins, process for its preparation and use of TiO₂And SiO₂The concentration in the oxalic acid solution is 0.5-1.5 g/mL.

Compared with the prior dioxin catalyst technology, the catalyst of the invention has the following advantages:

(1) the catalyst does not contain noble metals, the preparation cost of the catalyst is lower, the price of 1 kg of noble metal precursor is hundreds of thousands, the price of 1 kg of active component vanadium precursor used in the invention is only 600 yuan, and the content of noble metals in the catalyst is about 1/10 of that of non-noble metals, so the cost of the non-noble metal catalyst is far lower than that of the noble metal catalyst;

(2) on one hand, the dioxin catalytic elimination reaction is a temperature sensitive reaction, the reaction activity of the catalyst is low at low temperature, and the catalytic performance is continuously increased along with the rise of the reaction temperature, so that the lower the reaction temperature of the dioxin at a certain elimination efficiency is, the better the reaction activity of the catalyst is; on the other hand, when the reaction temperature exceeds 300 ℃, the rate of synthesis of dioxin increases, resulting in a decrease in the efficiency of dioxin removal. The catalyst has strong oxidation-reduction performance and rich surface acidity, can efficiently eliminate dioxin pollutants generated by waste incineration, and can reduce the concentration of the dioxin pollutants to 0.1ng/m at low temperature³The following; )

(3) The preparation method of the catalyst is simple, and due to the complexation of the alkaline solvent, the active components vanadium, tungsten and iron can be uniformly dispersed on the surface of the carrier without agglomeration, so that the surface of the catalyst has higher reaction activity sites;

(4) the catalyst is a powder catalyst, has small particle size, and is convenient to form a cloverleaf, honeycomb or plate type monolithic catalyst by adding a forming auxiliary agent according to the actual application requirement.

Detailed Description

The catalyst of the present invention will be further described with reference to the following embodiments.

Example 1

(1) Firstly, 6.1g of ammonium metavanadate is dissolved in 150mL of oxalic acid solution with the concentration of 13 percent, and the solution is stirred to be completely dissolved;

(2) adding 4.0g of ammonium paratungstate into the oxalic acid solution, and then fully stirring at 40 ℃ to dissolve the ammonium paratungstate;

(3) continuously adding 1.2g of ferric sulfate into the oxalic acid solution, and fully stirring at 40 ℃ to dissolve the ferric sulfate;

(4) adding 79g of TiO into oxalic acid solution containing vanadium, tungsten and iron precursors₂And 10g SiO₂Keeping the temperature and continuing stirring for 5 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with active component precursor₂And SiO₂Drying the mixture in a forced air drying oven for 12 hours at the drying temperature of 80 ℃;

(6) and calcining the dried catalyst precursor in a muffle furnace at 400 ℃ for 5 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

Example 2

(1) Firstly, 8.5g of vanadyl oxalate is dissolved in 120mL of oxalic acid solution with the concentration of 18 percent, and the solution is stirred to be completely dissolved;

(2) adding 5.0g of ammonium metatungstate into the oxalic acid solution, and then fully stirring at 60 ℃ to dissolve the ammonium metatungstate;

(3) continuously adding 3.5g of ferric sulfate into the oxalic acid solution, and fully stirring at 60 ℃ to dissolve the ferric sulfate;

(4) adding 65g TiO into oxalic acid solution containing vanadium, tungsten and iron precursors₂And 18.5g SiO₂Keeping the temperature and continuing stirring for 7 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with active component precursor₂And SiO₂Drying the mixture in a forced air drying oven for 20 hours at the drying temperature of 100 ℃;

(6) and calcining the dried catalyst precursor in a muffle furnace at 500 ℃ for 8 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

Example 3

(1) Firstly, dissolving 4.3g of vanadyl sulfate in 140mL of oxalic acid solution with the concentration of 20%, and stirring to completely dissolve the vanadyl sulfate;

(2) adding 8.0g of ammonium metatungstate into the oxalic acid solution, and fully stirring at 70 ℃ to dissolve the ammonium metatungstate;

(3) 2.3g of ferric nitrate is continuously added into the oxalic acid solution, and the mixture is fully stirred at the temperature of 70 ℃ to be dissolved;

(4) 70g TiO is added into oxalic acid solution containing vanadium, tungsten and iron precursors₂And 22g SiO₂Keeping the temperature and continuing stirring for 10 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with active component precursor₂And SiO₂Drying the mixture in a forced air drying oven for 15 hours at the drying temperature of 120 ℃;

(6) and calcining the dried catalyst precursor in a muffle furnace at 550 ℃ for 10 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

Example 4

(1) Firstly, dissolving 3.8g of vanadyl oxalate in 100mL of oxalic acid solution with the concentration of 15%, and stirring to completely dissolve the vanadyl oxalate;

(2) adding 5.0g of ammonium metatungstate into the oxalic acid solution, and fully stirring at 50 ℃ to dissolve the ammonium metatungstate;

(3) continuously adding 5.5g of ferric nitrate into the oxalic acid solution, and fully stirring at 50 ℃ to dissolve the ferric nitrate;

(4) adding 80g TiO into oxalic acid solution containing vanadium, tungsten and iron precursors₂And 15g SiO₂Keeping the temperature and continuing stirring for 7 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with active component precursor₂And SiO₂Drying the mixture in a forced air drying oven for 36 hours at the drying temperature of 80 ℃;

(6) and calcining the dried catalyst precursor in a muffle furnace at 450 ℃ for 20 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

Example 5

(1) Firstly, dissolving 2.5g of ammonium metavanadate in 150mL of 10% oxalic acid solution, and stirring to completely dissolve the ammonium metavanadate solution;

(2) adding 10.0g of ammonium paratungstate into the oxalic acid solution, and then fully stirring at 40 ℃ to dissolve the ammonium paratungstate;

(3) continuously adding 8.5g of ferric nitrate into the oxalic acid solution, and fully stirring at 40 ℃ to dissolve the ferric nitrate;

(4) adding 90g TiO into oxalic acid solution containing vanadium, tungsten and iron precursors₂And 5g SiO₂Keeping the temperature and continuing stirring for 10 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with active component precursor₂And SiO₂Drying the mixture in a forced air drying oven for 24 hours at the drying temperature of 120 ℃;

(6) and calcining the dried catalyst precursor in a muffle furnace at 400 ℃ for 15 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

Example 6

(1) Firstly, dissolving 9.5g of vanadyl sulfate in 120mL of oxalic acid solution with the concentration of 20%, and stirring to completely dissolve the vanadyl sulfate;

(2) adding 3.0g of ammonium paratungstate into the oxalic acid solution, and then fully stirring at 45 ℃ to dissolve the ammonium paratungstate;

(3) continuously adding 5.5g of ferric sulfate into the oxalic acid solution, and fully stirring at 45 ℃ to dissolve the ferric sulfate;

(4) 60g of TiO is added into oxalic acid solution containing vanadium, tungsten and iron precursors₂And 35g SiO₂Keeping the temperature and continuing stirring for 8 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with active component precursor₂And SiO₂Drying the mixture in a forced air drying oven for 12 hours at the drying temperature of 150 ℃;

(6) and calcining the dried catalyst precursor in a muffle furnace at 600 ℃ for 7 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

Comparative example 1

Dissolving 10.5g of vanadyl sulfate and 6.0g of ammonium metatungstate in 120mL of 15% oxalic acid solution at 40 ℃, and stirring to completely dissolve the vanadyl sulfate and the ammonium metatungstate; adding 95g TiO into oxalic acid solution containing vanadium and tungsten precursor₂Keeping the temperature and continuing stirring for 10 hours to age the catalyst; then TiO loaded with active component precursor₂Drying the mixture in a forced air drying oven for 15 hours at the drying temperature of 100 ℃; and finally, calcining the dried catalyst precursor in a muffle furnace at 450 ℃ for 7 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

Comparative example 2

Dissolving 4.5g of vanadyl sulfate and 3.5g of ferric nitrate in 150mL of 10% oxalic acid solution at 50 ℃, and stirring to dissolve; adding 90g of SiO into oxalic acid solution containing vanadium and iron precursors₂Keeping the temperature and continuing stirring for 10 hours to age the catalyst; then loading the SiO loaded with the active component precursor₂Drying the mixture in a forced air drying oven for 10 hours at the drying temperature of 150 ℃; and finally, calcining the dried catalyst precursor in a muffle furnace at 550 ℃ for 5 hours to obtain the dioxin degradation catalyst, wherein the test result of the dioxin pollutant elimination performance is shown in table 1.

The catalyst of the invention has dioxin pollutant elimination performance test:

because the o-dichlorobenzene and dioxin have similar structural properties, the simulated pollutant used in the reaction performance detection of the catalyst is the o-dichlorobenzene. In the reaction performance test process, the concentration of o-dichlorobenzene is 1500ppm, and the space velocity is as follows: 4000h^-1Air is the balance gas.

The results of the tests on the reaction performance of the catalysts in table 1 show that the novel catalysts prepared by the invention have higher elimination efficiency on the dioxin simulant o-dichlorobenzene and low activation temperature of the catalysts, the elimination rate of dioxin pollutants of the catalysts prepared in examples 5 and 6 is nearly 70% at 180 ℃, and the elimination efficiency is over 90% at 220 ℃. The results show that the catalyst and the preparation method thereof have very large application potential in the elimination of the dioxin generated in the waste incineration.

In order to illustrate the superiority and advancement of the catalyst and the preparation method thereof, the catalyst prepared by two different methods is arranged and compared by an activity test, and the catalyst prepared by the method has higher reaction performance.

TABLE 1 results of tests for eliminating Dioxin contaminants

Claims

1. A novel catalyst for degrading dioxin is characterized in that: the catalyst mainly comprises an active component and a catalyst carrier;

wherein the active component comprises a transition metal oxide V₂O₅、WO₃And Fe₂O₃The catalyst carrier is TiO₂And SiO₂。

2. The novel catalyst for the degradation of dioxin according to claim 1, characterized in that: active ingredient by mass, V₂O₅Content of 0.5-10%, WO₃0.1-8% of Fe₂O₃The content is 0.1-6%.

3. The novel catalyst for the degradation of dioxin according to claim 1, characterized in that: catalyst support by mass, TiO₂50-95% of SiO₂The content is 5-20%.

4. The method for preparing a novel catalyst for the degradation of dioxin according to claim 1, characterized in that: the method comprises the following steps:

(1) firstly, V is put in₂O₅Dissolving the precursor in a certain amount of oxalic acid solution;

(2) the above-mentioned compound containing V₂O₅Adding WO into oxalic acid solution of precursor₃Fully stirring the precursor at 40-70 ℃ to dissolve the precursor;

(3) continuously adding Fe into the oxalic acid solution₂O₃Fully stirring the precursor at 40-70 ℃ to dissolve the precursor;

(4) adding catalyst carrier TiO₂And SiO₂Keeping the temperature and stirring for 5-10 hours to age the catalyst;

(5) after the aging is finished, TiO loaded with an active component precursor₂And SiO₂Drying the mixture in a blast drying oven for 12-36 hours at 80-150 ℃;

5. The method for preparing a novel catalyst for the degradation of dioxin according to claim 4, characterized in that: the mol ratio of oxalic acid to vanadium is more than or equal to 2.

6. The method for preparing a novel catalyst for the degradation of dioxin according to claim 4, characterized in that: the mass fraction of oxalic acid in the oxalic acid solution is 10-20%.

7. The method for preparing a novel catalyst for the degradation of dioxin according to claim 4, characterized in that: v in step (1)₂O₅The precursor comprises ammonium metavanadate, vanadyl oxalate or vanadyl sulfate; WO₃The precursor comprises ammonium metatungstate or ammonium paratungstate, Fe₂O₃The precursor comprises ferric nitrate or ferric sulfate.

8. A process as claimed in claim 4The preparation method of the novel catalyst for degrading dioxin is characterized by comprising the following steps: TiO in the step (4)₂And SiO₂The concentration in the oxalic acid solution is 0.5-1.5 g/mL.