CN102091616B

CN102091616B - Preparation method of ruthenium-containing composite catalyst used for catalytic oxidation of zero-valent mercury

Info

Publication number: CN102091616B
Application number: CN 201010568759
Authority: CN
Inventors: 瞿赞; 晏乃强; 吴忠标; 莫建松; 刘越
Original assignee: Shanghai Jiaotong University; Zhejiang University ZJU; Zhejiang Tianlan Environmental Protection Technology Co Ltd
Current assignee: Shanghai Jiaotong University; Zhejiang University ZJU; Zhejiang Tianlan Environmental Protection Technology Co Ltd
Priority date: 2010-12-02
Filing date: 2010-12-02
Publication date: 2012-12-26
Anticipated expiration: 2030-12-02
Also published as: CN102091616A

Abstract

The invention discloses a preparation method of a ruthenium-containing composite catalyst used for catalytic oxidation of zero-valent mercury. The ruthenium-containing composite catalyst with high efficiency is prepared by using titanium dioxide and other porous materials as carriers, selecting elements, such as manganese, cobalt, copper and the like as catalyst main components, and adopting a ruthenium element as a catalysis enhancing component and molybdenum and cerium elements as auxiliary components. The catalyst prepared in the invention is used for catalytically oxidizing Hg<0> in flue gas into Hg<2+> under the action of HCl or less other oxidizing agents to ensure that the Hg<2+> can be absorbed and removed by a wet desulphurization system at the downstream, thus the purpose of controlling emission of mercury in the flue gas is achieved.

Description

The preparation method who contains the ruthenium composite catalyst who is used for the nonvalent mercury catalytic oxidation

Technical field

What the present invention relates to is a kind of Preparation of Catalyst of smoke catalytic technical field, specifically is a kind of preparation method who contains the ruthenium composite catalyst who is used for the nonvalent mercury catalytic oxidation.

Background technology

Mercury is a kind of toxic pollutant, and is because it has characteristics such as bioaccumulation property and difficult degraded, also very big to the harm of environment.In recent years, the mercury pollution problem receives increasing concern.In February, 2009, whole world council of United Nations Environment Programme holds in Nairobi, and participant various countries minister agrees to negotiate with regard to drafting the international treaties of administering mercury pollution, and international community has reached unprecedented height to the concern of global mercury pollution problem.Mercury emissions source in the environment generally is divided into natural source and artificial source, and the anthropogenic discharge who causes mercury pollution mainly is the burning of fossil fuel, mercury ore and the smelting of other metals and the application in the electrical equipment industry etc.Wherein, the discharge capacity of mercury accounts for the very big proportion of artificial mercury emission in the coal-fired flue-gas, so the mercury emissions in the control coal-fired flue-gas is very crucial.

Mercury in the coal-fired flue-gas mainly exists with three kinds of forms: nonvalent mercury (Hg ⁰), mercury oxide (Hg ²⁺) and particle mercury (Hg ^p).Wherein, Hg ²⁺And Hg ^pCan pass through existing Air Pollution Control Board control equipment (APCDs), like electrostatic precipitator (ESP), the removals such as (WFGD) of wet desulphurization equipment.At present, ESP, WFGD equipment have obtained in China coal-burning power plant using widely, if can effectively utilize existing APCDs to carry out fume mercury-removing, just need not increase extra removal of mercury equipment, thereby significantly reduce the cost of fume mercury-removing.Yet the Hg0 in the flue gas is volatile, is insoluble in water, is not easy by effective removal.And, according to coal-fired different in kind, Hg ⁰Ratio in the flue gas total mercury is generally 20～80%, therefore finds one Hg0 is converted into Hg fast ²⁺Or Hg ^pEffective way, the removal of mercury ability of giving full play to existing APCDs is very crucial, this also becomes the focus of current research.

Take suitable ancillary method to realize Hg ⁰To Hg ²⁺Efficient conversion, to make full use of desulfurizer efficient absorption Hg ²⁺Method be to control Hg at present ⁰Most economical feasible approach, and become the research focus gradually.But Hg ⁰To Hg ²⁺Efficient conversion be key and the difficult point place of high-efficiency mercury removal, the researcher does not obtain maturation method for transformation efficiently as yet at present.Confirmed that at present (Selective catalytic reduction, SCR) catalyst can promote significantly that HCl is to Hg in the flue gas to SCR ⁰Oxidation, thereby help to improve the clearance of mercury.Through changing each operational factor of SCR such as NO concentration, NH ₃Discoveries such as/NO, temperature and coal: during chlorinity 400～600ppm, it is best that the oxygenation efficiency of mercury can reach; But sulfide can significantly reduce the mercury oxidation rate, because SO ₂And SO ₃Cause the oxygenation efficiency of mercury to reduce with the active sites of chloride competition catalyst surface; SO in addition ₂And SO ₃Can make the catalyst poisoning inactivation with the sulphate form deposition at catalyst surface.The catalyst that for this reason, must combine the oxidation characteristics developing special of nonvalent mercury.

The catalyst of the nonvalent mercury of research catalysis at present oxidation has been obtained certain progress, and wherein the SCR catalyst has obtained paying attention to the transformation of nonvalent mercury.When HCl content was higher in the flue gas, this type catalyst strengthened the effect of nonvalent mercury catalyzed conversion, and the product that is produced is (like HgCl ₂) will be by carried away by air movement.But the existence of sulfur dioxide in flue gas has the obvious suppression effect to general transition-metal catalyst, and single metal oxides is difficult to bring into play effective catalytic action mostly, and the temperature range of reacting required is high and narrow, generally need be higher than 250 ℃.One Chinese patent application 200510024939.2 (flue gas hydrargyrum-removing method by catalytic oxidation) has proposed to utilize transition metal oxides such as iron, cobalt, nickel, copper as active component catalytic oxidation nonvalent mercury; This method considers to utilize oxygen or the Lattice Oxygen of catalyst in the flue gas to be converted into mercury oxide to nonvalent mercury, and is adsorbed on catalyst surface.But, do not consider the influence of factor such as hydrogen chloride and sulfur dioxide in the flue gas in this patent.Generally contain a certain amount of HCl in the actual flue gas, the catalytic oxidation product of nonvalent mercury is mainly HgCl when HCl exists ₂And, when sulfur dioxide exists this type activity of such catalysts is suppressed highly significant.In addition, patents such as U.S. Patent application US2003170159, PCT patent application WO2006009079 are reported part noble metal or catalyst of transition metal oxide, but these patents are paid close attention to seldom the sulfur resistance of catalyst.Research shows that the oxide with certain ruthenium that mixes in the catalyst can significantly improve the transformation of catalyst to nonvalent mercury, and the anti-sulfur dioxide effect of catalyst is significantly improved.

Summary of the invention

The present invention is directed to the above-mentioned deficiency that prior art exists; A kind of preparation method who contains the ruthenium composite catalyst who is used for the nonvalent mercury catalytic oxidation is provided; With ruthenium element as the catalysis enhancement component; Molybdenum and Ce elements are helper component, process efficient composite catalyst through the method for doping treatment, make it under different temperature, be equipped with advantages of high catalytic activity and sulfur resistance.This catalyst is under the effect of HCl or other small amounts agent, with the Hg in the flue gas ⁰Catalytic oxidation is Hg ²⁺, make it to be absorbed and remove by the wet desulfurization system in downstream, realize the purpose of mercury emissions control in the flue gas.

The present invention realizes that through following technical scheme it is carrier that the present invention adopts titanium dioxide and other porous material, and selecting elements such as manganese, cobalt, copper for use is the catalyst major constituent; Ruthenium element is as the catalysis enhancement component, and molybdenum and Ce elements are helper component, process efficient composite catalyst.

The preparation method who the present invention relates to may further comprise the steps:

The first step, add to add deionized water after the ruthenium element presoma is as predecessor and stir and obtain dipping solution that the total content of predecessor is in the dipping solution: 0.01g/mL-0.50g/mL after catalyst major constituent, helper component mixed;

Described catalyst major constituent is meant: a kind of or its combination in the nitrate of manganese, cobalt or copper, carbonate, oxalates or the acetate.

Described helper component is meant: a kind of or its combination in the nitrate of molybdenum or cerium, carbonate, oxalates or the acetate.

Described ruthenium element presoma is meant: a kind of or its combination in nitric acid ruthenium, carbonic acid ruthenium, oxalic acid ruthenium or the ruthenium acetate.

Second goes on foot, catalyst carrier is immersed stir dipping in the dipping solution and after Separation of Solid and Liquid, will carry out preliminary treatment through the catalyst carrier of dipping, after sintering makes catalyst.

Described catalyst carrier is the silicate of titanium dioxide, aluminium oxide, silica, crystalline state or in alumino-silicate, imvite or the active carbon one or more, and this catalyst carrier is spherical, graininess, tabular or cellular.

Described preliminary treatment is meant any one in the following dual mode:

A) under 40 ℃～100 ℃ temperature, dried 5-24 hour;

B) use the mould press forming.

Described sintering is meant: adopt Muffle furnace to be 1～30 ℃/minute with heating rate and rise to 300 ℃ of roasting 0.5～2h; Rise to 400 ℃ of roasting 0.5～4h with 1～30 ℃/minute speed again presoma is fully decomposed, with 1～2 ℃/minute cooldown rate catalyst is cooled to normal temperature at last.

What the present invention relates to that method for preparing obtains contains the ruthenium composite catalyst; Wherein: the mass percentage content of manganese, cobalt or copper is 1%-10%; The mass percentage content of ruthenium element is 0.05%-2%, and the mass percentage content of molybdenum or Ce elements is 0.5%-5%.

Utilize method for preparing contain ruthenium composite type metallic oxide catalyst to the catalytic oxidation ability of nonvalent mercury much larger than single component catalyst; And can be under the temperature (100～450 ℃) of broad and higher sulfur dioxide concentration the efficiently catalyzing and oxidizing nonvalent mercury, prevent the catalyst poisoning inactivation.

The specific embodiment

Elaborate in the face of embodiments of the invention down, present embodiment provided detailed embodiment and concrete operating process, but protection scope of the present invention is not limited to following embodiment being to implement under the prerequisite with technical scheme of the present invention.

Embodiment 1

With Powdered TiO ₂Be carrier, utilize immersion process for preparing Mn/TiO ₂, Ru/TiO ₂And Ru-Mn/TiO ₂Catalyst.

Configuration dipping solution: A, get the manganese nitrate solution of 2g 30%, add deionized water and be diluted to 20ml; B, the manganese nitrate solution of getting 2g 30%, 0.2g ruthenic chloride add deionized water and are diluted to 20ml; C, the manganese nitrate solution of getting 2g 30%, 0.2g ruthenic chloride, the 0.5g ammonium molybdate adds deionized water and is diluted to 20ml;

Utilize powdery TiO ₂As catalyst carrier, take by weighing 3 parts, every part of 30g; Pour it in above-mentioned 3 kinds of solution dipping and stirring respectively, soak and after 1 hour unnecessary maceration extract is poured out, and with the TiO behind the single-steeping ₂Powder is dried in 60-70 ℃ baking oven, it is poured into respectively in the residual dipping solution afterwards again, and fully stirs, and makes maceration extract all by TiO ₂Carrier blots.

TiO behind the dipping ₂Under 60-80 ℃ temperature, dried 4-6 hour again, rise to 300 ℃ of roasting 1h with 5 ℃/minute of heating rates in the transposition Muffle furnace; Rise to 400 ℃ of roasting 4h with 2 ℃/minute speed again presoma nitrate is fully decomposed, with 2 ℃/minute cooldown rate catalyst is cooled to normal temperature again.Be called catalyst A 1, B1 and C1 successively through the prepared catalyst of said method.A1 is the one pack system Mn catalyst, Mn/TiO ₂The B1 catalyst is the Ru-Mn/TiO that mixes with Ru separately ₂Composite catalyst; C1 is the Ru-Mo-Mn/TiO that molybdenum mixes ₂Composite catalyst.Wherein, catalyst C1 is one of target catalyst proposed by the invention, and catalyst A 1 only is used for the contrast experiment with catalyst B 1.

The catalyst that present embodiment prepares, manganese, ruthenium and molybdenum element content are respectively 0.60%, 0.32% and 0.88%, and catalyst is worn into 40-60 purpose particle, and its particle diameter is 250-420 μ m, and specific area is 45-47m ²/ g.

The influence of doping molybdenum element: get above-mentioned A1, B1, C1 catalyst 0.5g respectively, it is inserted in the tubular fixed-bed reactor, feeding contains nonvalent mercury 100 μ g/m ³With oxidant HCl concentration be the simulated flue gas of 3ppm, the content of sulfur dioxide is 500ppm.Temperature is that 350 ℃, air speed are 50000h ^-1Condition under, when catalyst reaches stably catalyzed stage, utilize the A1 catalyst to the catalytic oxidation efficient of nonvalent mercury be 93%, the B1 catalyst is 97% to the oxidation efficiency of nonvalent mercury, the C1 catalyst reaches 99% to the transformation efficiency of nonvalent mercury.This result shows, compares with the one pack system Mn catalyst, and with Ru, Mn is compound can improve activity of such catalysts to a certain extent, and after molybdenum was doped to the Ru-Mn composite catalyst, activity of such catalysts can significantly improve.

Temperature effect: other condition is constant, only the operating temperature of reactor is reduced to 150 ℃, and catalyst A 1, B1, C1 reduce to 57%, 66% and 92% respectively to the catalytic conversion efficiency of nonvalent mercury at this moment.Thus it is clear that, under lower temperature, have advantages of high catalytic activity equally according to the obtained catalyst C1 of the present invention.

The sulfur dioxide influence: when other condition is constant (operating temperature still is 150 ℃), when in simulated flue gas, adding the sulfur dioxide of 500ppm, then catalyst A 1, B1, C1 reduce to 48%, 61% and 94% respectively to the catalytic conversion efficiency of nonvalent mercury.Thus it is clear that, have extraordinary anti-sulfur dioxide ability according to the obtained catalyst C1 of the present invention.

Embodiment 2

Metallic elements such as 1wt%Ru, Mn, Cu are loaded to titanium dioxide get on, metal oxide precursor is respectively RuCl ₃, Cu (NO ₃) 3H ₂O and Mn (NO ₃) ₂, and the SCR catalyst and (0.5wt%Ru+1.0wt%V)/TiO ₂Catalyst is as reference.Experiment condition is: temperature is 150 ℃, and air speed is 7.96 * 10 ⁵h ^-1, the HCl concentration of adding is 3ppm.When adding SO ₂When making an experiment, its concentration is 500ppm.Under the situation that does not add sulfur dioxide, catalyst 1%wt Ru/TiO ₂, 1%wtMn/TiO ₂, 1%wt Cu/TiO ₂, (0.5wt%Ru+1.0wt%)/TiO ₂And the nonvalent mercury catalytic oxidation efficient of SCR is respectively: 71%, 67%, 63%, 68% and 21%.When adding 500ppm SO ₂Situation under, the nonvalent mercury catalytic oxidation efficient of each catalyst is followed successively by: 55%, 23%, 26%, 37% and 29%.

The catalyst that present embodiment prepares is worn into 40-60 purpose particle before test, each metal element content is 1%, and its particle diameter is 250-420 μ m, and specific area is 45-47m ²/ g.

Embodiment 3

Through in the process of dipping, adding different RuCl ₃Amount make the Ru/TiO of five kinds of (0.05wt%, 0.2wt%, 0.50wt%, 1.00wt% and 2.00wt%) different Ru load capacity ₂Catalyst is put into fixed bed reactors, is 350 ℃ in temperature, and air speed is 7.96 * 10 ⁵h ^-1, the HCl concentration of adding is 3ppm.The catalyst of investigating different Ru load capacity is at no SO ₂And have 500ppm SO ₂Different condition under, the catalytic oxidation efficient of nonvalent mercury, and with blank titanium dioxide as reference.When the load capacity of Ru is 0wt%, 0.05wt%, 0.20wt%, 0.50wt%, 1.00wt% and 2.00wt%; Under the situation that does not add sulfur dioxide, the catalytic oxidation efficient of nonvalent mercury is respectively: 5%, 58%, 86%, 94%, 99% and 99%.After adding 500ppm sulfur dioxide, the catalyst of each load capacity is respectively the catalytic oxidation efficient of nonvalent mercury: 3%, 42%, 72%, 82%, 88% and 94%.

The catalyst that present embodiment prepares is worn into 40-60 purpose particle before test, its particle diameter is 250-420 μ m, and specific area is 45-47m ²/ g.

Embodiment 4

1wt%Ru/TiO with preparation ₂Catalyst and 1wt%Ru/ α-Al ₂O ₃Catalyst is 150 ℃ and 350 ℃ in temperature respectively, and air speed is 7.96 * 10 ⁵h ^-1, make an experiment under the condition of adding 1ppm, 2ppm, 3ppm, 5ppm and 10ppmHCl.When temperature is 150 ℃, 1wt%Ru/ α-Al ₂O ₃Nonvalent mercury catalytic oxidation efficient under 5 different HCl concentration is followed successively by from low to high: 4%, 7%, 8%, 10% and 15%; 1wt%Ru/TiO ₂Nonvalent mercury catalytic oxidation efficient under 5 different HCl concentration is followed successively by from low to high: 35%, 60%, 71%, 80% and 88%.When temperature is 350 ℃, 1wt%Ru/ α-Al ₂O ₃Nonvalent mercury catalytic oxidation efficient under 5 different HCl concentration is followed successively by from low to high: 21%, 37%, 50%, 58% and 66%; 1wt%Ru/TiO ₂Nonvalent mercury catalytic oxidation efficient under 4 different HCl concentration (1ppm, 2ppm, 3ppm and 5ppm) is followed successively by from low to high: 67%, 95%, 99% and 99%.The catalyst that present embodiment prepares is worn into 40-60 purpose particle before test, the titania support catalyst particle size is 250-420 μ m, and specific area is 45-47m ²/ g, alumina carrier catalyst particle size are 250-420 μ m, and specific area is 0.5-1.2m ²/ g.

Claims

1. a preparation method who contains the ruthenium composite catalyst who is used for the nonvalent mercury catalytic oxidation is characterized in that, may further comprise the steps:

The first step, add that the ruthenium element presoma adds deionized water and stirs as predecessor after catalyst major constituent, helper component mixed and obtain dipping solution that the total content of predecessor is in the dipping solution: 0.01g/mL-0.50g/mL;

Second goes on foot, catalyst carrier is immersed stir dipping in the dipping solution and after Separation of Solid and Liquid, will carry out preliminary treatment through the catalyst carrier of dipping, after sintering makes catalyst;

Described catalyst major constituent is meant: a kind of or its combination in the nitrate of manganese, cobalt or copper, carbonate, oxalates or the acetate;

Described helper component is meant: a kind of or its combination in the nitrate of molybdenum or cerium, carbonate, oxalates or the acetate;

Wherein: the mass percentage content of manganese, cobalt or copper is 1%-10%, and the mass percentage content of ruthenium element is 0.05%-2%, and the mass percentage content of molybdenum or Ce elements is 0.5%-5%;

Described preliminary treatment is meant any one in the following dual mode:

A) under 40 ℃～100 ℃ temperature, dried 5-24 hour;

B) use the mould press forming,

Described sintering is meant: adopt Muffle furnace to be 1～30 ℃/minute with heating rate and rise to 300 ℃ of roasting 0.5-2h; Rise to 400 ℃ of roasting 0.5-4h with 1～30 ℃/minute speed again presoma is fully decomposed, with 1～2 ℃/minute cooldown rate catalyst is cooled to normal temperature at last.

2. the preparation method who contains the ruthenium composite catalyst who is used for the nonvalent mercury catalytic oxidation according to claim 1 is characterized in that, described ruthenium element presoma is meant: a kind of or its combination in nitric acid ruthenium, carbonic acid ruthenium, oxalic acid ruthenium or the ruthenium acetate.

3. the preparation method who contains the ruthenium composite catalyst who is used for the nonvalent mercury catalytic oxidation according to claim 1; It is characterized in that; Described catalyst carrier is the silicate of titanium dioxide, aluminium oxide, silica, crystalline state or in alumino-silicate, imvite or the active carbon one or more, and this catalyst carrier is spherical, graininess, tabular or cellular.

4. the said method of one of an employing such as claim 1-3 makes contains the ruthenium composite catalyst; It is characterized in that; Wherein: the mass percentage content of manganese, cobalt or copper is 1%-10%; The mass percentage content of ruthenium element is 0.05%-2%, and the mass percentage content of molybdenum or Ce elements is 0.5%-5%.