CN109464904A - Coke oven flue gas low-temp desulfurization method of denitration - Google Patents
Coke oven flue gas low-temp desulfurization method of denitration Download PDFInfo
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- B01D53/02—Separation of gases or vapours; Recovering vapours of volatile solvents from gases; Chemical or biological purification of waste gases, e.g. engine exhaust gases, smoke, fumes, flue gases, aerosols by adsorption, e.g. preparative gas chromatography
- B01D53/04—Separation of gases or vapours; Recovering vapours of volatile solvents from gases; Chemical or biological purification of waste gases, e.g. engine exhaust gases, smoke, fumes, flue gases, aerosols by adsorption, e.g. preparative gas chromatography with stationary adsorbents
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- B01D53/34—Chemical or biological purification of waste gases
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- B01D53/74—General processes for purification of waste gases; Apparatus or devices specially adapted therefor
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Abstract
The present invention relates to a kind of method of coke oven flue gas desulphurization denitration, mainly solves the problem of that existing coke oven flue gas desulphurization denitration operating cost is high and generate secondary pollution.The coke oven flue gas of sulfur compound and nitrogen oxides that the present invention is drawn by using coke oven flue, into the denitrating tower comprising denitrating catalyst, the method adsorbed again after catalysis reduction, remove the nitrogen oxides and sulfide in coke oven flue gas, nitrogen oxides in effluent and sulfide after regeneration carry out the technical solution of salt manufacturing processing, preferably solves the above problem, this method can be used in the industrial production of coking flue gas desulfurization and denitrification.
Description
Technical field
The invention belongs to desulphurization denitration technical fields, and in particular to a kind of coke oven flue gas desulfurization denitration method.
Background technique
SO2And NOXIt is the important atmosphere pollution in China, excessive discharge will cause haze, acid rain and photochemical fog
Deng serious harm ecological environment and human health.The burning of fossil fuel is SO2And NOXMain source.Coal be China most
Important natural energy source, as the second largest coal field in China, carbonization of coal is one of industrial coal field primary pollution source, burnt
Kiln gas is the important pollution sources of atmosphere.
Current coke oven flue gas desulfuration field is using more for ammonia process, lime/lime stone method, Dual alkali, magnesium oxide method etc.
For the Wet Flue Gas Desulfurization Technique and semi-dry desulphurization technology of representative.Wet desulphurization absorption rate is high, but such as lime/lime
Stone-gypsum, Dual alkali contain small hydrophilic ionic in magnesium oxide method slurries, are taken out of by flue gas, and are emitted into big
In gas, while these particle surfaces are easily absorbing sulfur dioxide, sulfur trioxide, hydrogen chloride, hydrogen fluoride, nitrogen oxides, nocuousness
Organic matter and bacterium etc. cause atmosphere suspended particles (usually said PM100, PM10, PM2.5 etc.) content to dramatically increase,
And cause haze and atmospheric photochemical reaction phenomenon, cause serious environmental pollution.Sodium sulfite (potassium) method sulfur removal technology, Wei Er
Man-Luo Defa Desulfovibrio technique, organic acid-acylate buffer-solution method sulfur removal technology, regeneration steam energy consumption is big and regenerates
Rate is low, therefore it is big to industrialize difficulty.Ammonia corrosion is big in the ammonia process of desulfurization, the production process of equipment burn into and ammonia is caused to be high energy
Consumption, high pollution process.Semi-dry desulphurization equipment corrosion compared with wet desulphurization is small, spreads without obvious temperature drop, conducive to chimney exhaust,
But desulfuration efficiency is relatively low, reaction speed is slow.
The mainstream technology in coke oven flue gas denitration field is NH3SCR denitration, SCR technology use catalyst, and catalytic action makes
Reaction activity reduces.In coke-oven plant, since flue gas self-temperature is very low (200 DEG C ~ 300 DEG C), it need to be urged using low-temperature denitration
Agent carries out denitration reaction during this temperature, and need to spray into ammonia into flue gas and make reducing agent.
Individual desulphurization and denitration technique not only takes up a large area, but also invests, operating cost height.Simultaneous SO_2 and NO removal skill
Art, which has, reduces device configuration, saves space, material source is wide, and price is low, renewable the advantages that recycling.Wherein, with work
Property charcoal (coke) technology be representative dry desulfurization denitrification integral technology be the technology most to the heat energy utilization in flue gas.
Chinese patent 201410119747.9 recycles stack gases waste heat using stack gases waste-heat recovery device, reduces
The temperature of stack gases, the activated adoption ability having using coke and low-temperature denitration catalytic capability realize the de- of stack gases
Sulphur, denitration integration.The concrete operation step of the invention is that 1) stack gases first pass through waste gas residual heat recovery unit, and flue is useless
The waste heat of gas is recovered, and temperature is reduced to 100 DEG C ~ 150 DEG C, is subsequently entered in low-temperature SCR desulphurization denitration unit, in flue gas
SO2It by coke adsorbing and removing, is mixed by the flue gas of desulfurization with ammonia, take coke as the catalyst of SCR method, denitration reduction occurs
NO is completed in reactionXRemoving;2) coke in low-temperature SCR desulphurization denitration unit is supplied from by elevator and grader leveling blade
The coke feed unit of conveyer composition, the coke after denitration reduction reaction is expelled in coke main tank, periodically by outlet vehicle
It sends outside;3) flue gas of low-temperature SCR desulphurization denitration unit discharge is sent after gas cleaning unit dust separation to chimney, realizes flue
The qualified discharge of exhaust gas.The waste heat recycled in the waste gas residual heat recovery unit is sent in ammonia steaming device, is generated to coke-oven plant
Remained ammonia carries out ammonia still process processing, provides necessary ammonia for the denitration reduction reaction in low-temperature SCR desulphurization denitration unit.
Chinese patent 201810438291.0 discloses a kind of low-sulfur flue gas desulfurization and denitrification device.The device includes adsorption tower
And vibrating screen, adsorption tower are successively arranged the firstth area, the secondth area and third area along flue gas circulating direction, the firstth area is equipped with flue gas air inlet
Mouthful and positioned at smoke air inlet ammonia-spraying grid, third area is equipped with the gas outlet of flue gas, the active carbon flowed is equipped in the secondth area
Layer, active carbon layer are flowed into from the top entry of adsorption tower, outlet at bottom outflow;The connection of the outlet at bottom of vibrating screen and adsorption tower,
And it is connected by the top entry of conveying mechanism and adsorption tower.
Chinese patent CN201611269710.X discloses a kind of sintering flue gas ammonia charcoal combined desulfurization and denitration method, sintering
Flue gas is after the desulfurization of absorbing liquid containing ammonia again through activated carbon adsorption;Carbonaceous raw material, the gold that the active carbon is 2:1 ~ 5:1 by mass ratio
Belong to oxide source to roast to obtain in 850 ~ 1100 DEG C of countrysidies;The carbonaceous raw material is semicoke, or is the mixed of coal and biomass
Close material.In the present invention, the active carbon as made from by ammonia and the method for the invention is combined, can effective desulphurization denitration, also
Help reduce secondary pollution, reduction technique.
Document above is active carbon (coke) simultaneous SO_2 and NO removal, but can not all be detached from ammonia as this step of reducing agent denitration
Suddenly.Since coke oven flue flow field is uneven, temperature field is uneven, catalyst failure degree is uneven, the volume fraction of escape ammonia is difficult low
In design discipline.Escape ammonia is exceeded to will cause secondary pollution, and corrosion pipeline material, and there is danger in the use process of ammonia
Property, it is very important to the body harm of people.
In view of the above problems, not using ammonia, simultaneously the invention proposes the technology of molecular sieve adsorption simultaneous SO_2 and NO removal
Adsorb the SO in coke oven flue gas2And NOX, and be worth with certain recycling.
Summary of the invention
The technical problem to be solved by the present invention is to during existing coke-oven plant's Coke-oven flue gas governing, operating cost height is produced
The technical issues of raw secondary pollution, a kind of method of coke oven flue gas low-temp desulfurization denitration is provided, which has process
Short, low equipment investment, regeneration is simple, and low energy consumption, advantage without secondary pollution.
In order to solve the above technical problems, a kind of method that the present invention uses coke oven flue gas low-temp desulfurization denitration, including it is following
Step:
A) coke-stove gas or blast furnace gas for entering coke oven combustion first remove sulfide, then burn before entering coke oven;
B) coke oven flue gas of coke oven flue is drawn sulfur compound and nitrogen oxides, is denoted as material flow A, the temperature of the material flow A
It is 180 ~ 320 DEG C;
C) material flow A enters the denitrating tower comprising denitrating catalyst, after catalysis reduction, forms flow B;
D) flow B carries out UTILIZATION OF VESIDUAL HEAT IN, produces steam, and the flue gas after cooling forms flow C, and the temperature of the flow B is 120
~180℃;
E) flow C enters heat exchanger, by with remove the flue gas heat exchange of chimney after, form logistics D, the temperature of the logistics D is
100~160℃;
F) logistics D enters cooling tower, after spraying cooling, dedusting, forms logistics E, the temperature of the logistics E is 30 ~ 100
DEG C, spray liquid enters waste water treatment system or salt extraction system;
G) logistics E enters the adsorption tower comprising crystallite adsorbent, after adsorbing sulfide and nitrogen oxides, forms logistics F;
H) logistics F enters smoke stack emission;
I) adsorption tower after adsorbing sulfide and nitrogen oxides saturation in step g), with 100 ~ 10000m3The logistics or heat of/h
Air regenesis, regenerated flue gas form logistics G, wherein the temperature of the logistics G is 120 ~ 350 DEG C;
J) logistics G enters the oxidizing tower comprising oxidation catalyst, after catalysis oxidation, forms logistics H;
K) logistics H enters regeneration tail gas desulfurizing tower, after water or lye spray, forms stream I, spray liquid enters wastewater treatment
System or salt extraction system;
L) stream I enters step the cooling tower in f).
In the above-mentioned technical solutions, preferred technical solution is that the temperature of the material flow A is 240 ~ 280 DEG C;Nitrogen oxidation
Object content is 100 ~ 1000mg/m3, sulfide content is 30 ~ 3000 mg/m3。
In the above-mentioned technical solutions, preferred technical solution is, into the coke-stove gas or blast furnace gas of coke oven combustion,
Hydrogen sulfide content is 0 ~ 20 mg/m3, 0 ~ 20 mg/m of organic sulfur content3。
In the above-mentioned technical solutions, preferred technical solution is, into the coke-stove gas or blast furnace gas of coke oven combustion,
Hydrogen sulfide content is 0 ~ 10 mg/m3, 0 ~ 10 mg/m of organic sulfur content3。
In the above-mentioned technical solutions, preferred technical solution is, into the coke-stove gas or blast furnace gas of coke oven combustion,
Hydrogen sulfide content is 0 ~ 5 mg/m3, 0 ~ 5mg/m of organic sulfur content3。
In the above-mentioned technical solutions, preferred technical solution is that the denitrating catalyst includes being selected from SSZ-13 molecule
Sieve, TS-1, Ti-MWW, Ti-MOR, ZSM type molecular sieve, modenite, beta molecular sieve, SAPO type molecular sieve, MCM-22, MCM-
49, MCM-56, ZSM-5/ modenite, ZSM-5/ β zeolite, ZSM-5/Y, MCM-22/ modenite, ZSM-5/Magadiite,
ZSM-5/ β zeolite/modenite, ZSM-5/ β zeolite/at least one of Y zeolite or ZSM-5/Y zeolite/modenite.
In the above-mentioned technical solutions, preferred technical solution is that also containing in the denitrating catalyst includes element week
At least one of Ith A, II A, V A, I B, II B, III B, IV B, V B, VI B, VII B or the VIIIth race's element element in phase table.
In above-mentioned technical proposal, preferred technical solution is that UTILIZATION OF VESIDUAL HEAT IN uses steam boiler in the step d), raw
The vapor (steam) temperature of production is 140 ~ 180 DEG C;The flue gas that waste heat boiler comes out enters back into heat exchanger, the heat exchanger be shell and tube or
Person's finned heat exchanger;Cooling tower in the step f) is spray column or heat exchanger types;The temperature of logistics E be 30 ~
100℃。
In above-mentioned technical proposal, preferred technical solution is that the temperature of the logistics F is 30 ~ 100 DEG C;Nitrogen oxides
Content is 1 ~ 200mg/m3, sulfide content is 0.1 ~ 100 mg/m3。
In above-mentioned technical proposal, preferred technical solution is that the logistics F and material flow A exchange heat after heating up, temperature 80
~200℃。
In above-mentioned technical proposal, preferred technical solution is, in step g), the quantity of adsorption tower is inhaled at least more than two
Attached bed operation temperature is 30 ~ 100 DEG C, and operating pressure is 0.1 ~ 20KPa.
In above-mentioned technical proposal, preferred technical solution is that UTILIZATION OF VESIDUAL HEAT IN uses steam boiler in the step d), raw
The vapor (steam) temperature of production is 150 ~ 170 DEG C;Cooling tower in the step f) is spray column or heat exchanger types;Logistics E's
Temperature is 40 ~ 60 DEG C.In above-mentioned technical proposal, preferred technical solution is, in step g), the quantity of adsorption tower is at least more than two
A, adsorbent bed operation temperature is 30 ~ 100 DEG C, and operating pressure is 0.1 ~ 20KPa.
In above-mentioned technical proposal, preferred technical solution is that the temperature of the material flow A is 200 ~ 300 DEG C;Nitrogen oxides
Content is 100-1000mg/m3, sulfide content is 40 ~ 3000 mg/m3。
In the above-mentioned technical solutions, preferred technical solution is, in step g), the quantity of adsorption tower at least more than two,
Adsorbent bed operation temperature is 30 ~ 80 DEG C, and operating pressure gauge pressure is 0.5 ~ 5Kpa.
In the above-mentioned technical solutions, preferred technical solution is the crystallite adsorbent A or the choosing of crystallite adsorbent B
From including X-type molecular sieve, Y type molecular sieve, A type molecular sieve, SSZ-13 molecular sieve, TS-1, Ti-MWW, Ti-MOR, ZSM type molecule
Sieve, modenite, beta molecular sieve, SAPO type molecular sieve, MCM-22, MCM-49, MCM-56, ZSM-5/ modenite, ZSM-5/
β zeolite, ZSM-5/Y, MCM-22/ modenite, ZSM-5/Magadiite, ZSM-5/ β zeolite/modenite, ZSM-5/ β boiling
At least one of stone/Y zeolite or ZSM-5/Y zeolite/modenite.
In the above-mentioned technical solutions, preferred technical solution is that also containing in the crystallite adsorbent includes element week
At least one of Ith A, II A, V A, I B, II B, III B, IV B, V B, VI B, VII B or the VIIIth race's element element in phase table.
In the above-mentioned technical solutions, preferred technical solution is that containing in the oxidation catalyst includes period of element
At least one of Ith A, II A, V A, I B, II B, III B, IV B, V B, VI B, VII B or the VIIIth race's element element in table.
In the above-mentioned technical solutions, preferred technical solution is that the lye is sodium hydroxide solution, ammonium hydroxide, residue
At least one of ammonium hydroxide, sodium carbonate liquor, calcium hydroxide solution.
In the above-mentioned technical solutions, preferred technical solution, it includes SSZ-13, TS- that the adsorbent of molecular sieve, which is selected from,
1, Ti-MWW, Ti-MOR, ZSM type molecular sieve, modenite, beta molecular sieve, SAPO type molecular sieve, MCM-22, ZSM-5/ mercerising
Zeolite, ZSM-5/ β zeolite, ZSM-5/Y, MCM-22/ modenite, ZSM-5/ β zeolite/modenite, ZSM-5/ β zeolite/Y boiling
At least one of stone or ZSM-5/Y zeolite/modenite.
In the above-mentioned technical solutions, the silica alumina ratio of preferred technical solution, the molecular sieve is greater than 2.
In the above-mentioned technical solutions, preferred technical solution, the IIth element A is selected from magnesium and calcium in the periodic table of elements
At least one of;Ith B race element is selected from least one of copper, silver;IIIth B race element in lanthanum, cerium, yttrium at least
It is a kind of.
In the above-mentioned technical solutions, preferred technical solution, ZSM type molecular sieve is selected from packet in the adsorbent of molecular sieve
At least one of ZSM-5, ZSM-23, ZSM-11, ZSM-48 are included, wherein the silica alumina ratio of the molecular sieve is greater than 20.
In the above-mentioned technical solutions, preferred technical solution, adsorbent bed operation temperature be 30 ~ 50 DEG C, operating pressure be 1 ~
3Kpa, gauge pressure.
In the above-mentioned technical solutions, preferred technical solution is passed through air, ozone, double water oxygen water in regeneration gas oxidizing tower
At least one of.
In the above-mentioned technical solutions, preferred technical solution first uses hot water after the adsorbent of molecular sieve adsorption saturation
It rinses, then with 100-300 DEG C of nitrogen regeneration.
It is known in the art, coal gas is purified using traditional handicraft, using desulfurizing tower again during gas purification process
It is middle to use iron oxide desulfurization;Naphthalene is taken off with active carbon using in de- naphthalene tower;Benzene is taken off with active carbon using debenzolizing tower again;3 are used altogether
Absorbing unit successively purifies coal gas.In device operation, device exit hydrogen sulfide, benzene and naphthalene are dense, influence production effect
Rate.Using method of the invention, have the advantages that (1), can be by benzene, naphthalene and hydrogen sulfide, organic sulfur using adsorbent of molecular sieve
It can thoroughly remove completely, solve the problems, such as line clogging.(2) adsorbent is subjected to multifunction, can desulfurization simultaneously, de- benzene,
De- naphthalene can carry out comprehensive purifying process simultaneously, reduce the quantity of adsorption tower in this way, reduce production in an adsorption tower
Cost.
Using technical solution of the present invention: the coke-stove gas that coke oven comes out enters slightly de- benzene unit, slightly enters after de- benzene
Comprehensive purifying tower, purifying column is interior to contain molecular sieve adsorbent, while removing the aromatic hydrocarbons and sulfide in coal gas, enters back into coke
Furnace burning.De- naphthalene tower exit hydrogen sulfide content is 0 mg/m3, naphthalene content is 0 mg/m3, tar content 0 carries in gas
Organic sulfur be also removed, sulfur dioxide in flue gas is emitted on 10m g/m3Hereinafter, device is stable.It is de- to reduce end desulfurization
The cost of nitre.
By adopting the above technical scheme, using crystallite adsorbent desulphurization denitration, crystallite adsorbent to gas cleaning handle just like
Lower advantage: the sulfur dioxide and nitrogen oxides in flue gas can be effectively adsorbed, discharge standard is made up to;High temperature resistant, structure are steady
It is fixed, iterative regenerable;It is high to adsorb precision, other than adsorb sulfur dioxide, can also dedusting simultaneously remove the harmful substances such as dioxin,
Make up to discharge standard;Crystallite adsorbent long service life, does not generate dangerous waste.By setting up adsorption tower in exhanst gas outlet, benefit
Sulfur dioxide, the nitrogen oxides in flue gas are adsorbed with System of Silica/Aluminum Microparticle hydrochlorate crystallite adsorbent, System of Silica/Aluminum Microparticle in adsorption tower
After hydrochlorate crystallite adsorbent adsorption saturation, crystallite adsorbent is regenerated by high-temperature flue gas, the nitrogen oxides and sulphur of desorption
Compound enters oxidizing tower, is oxidized to sulfur trioxide and nitrogen dioxide, and regenerated flue gas is absorbed with water spray, after effluent part neutralizes,
It is discharged into biochemical system or goes to salt extraction workshop, tail gas enters flue gas spray column circulation.Entire treatment process process is short, equipment investment
It saves, regenerative operation is simple and reliable, and low energy consumption, flue gas emission nitrogen oxides≤50mg/m3, sulfur dioxide≤30mg/m3, dust content
Less than 5 mg/m3, achieve preferable technical effect.
Detailed description of the invention
Fig. 1 is the flow diagram of coke oven flue gas desulfurization denitration method of the invention.
1 is coke oven flue gas in Fig. 1, and 2 be denitrating tower, and 3 be waste heat steam boiler, and 4 be cooling tower, and 5 be adsorption tower, and 6 be wind
Machine, 7 be oxidizing tower, and 8 be spray column, and 9 be sedimentation basin, and 10 be wastewater biochemical pond, and 11 be chimney.
The present invention will be further described below by way of examples, but is not limited only to the present embodiment.
Specific embodiment
[embodiment 1]
The coke-stove gas that coke oven comes out enters slightly de- benzene unit, slightly forms logistics I after de- benzene, wherein benzene concentration exists in logistics I
1000~4000mg/m3Between, naphthalene concentration is in 200~500mg/m3Between, concentration of hydrogen sulfide is in 100~500mg/m3Between;Object
Stream I enters comprehensive purifying tower, ZSM molecular sieve class adsorbent is contained in the comprehensive purifying tower, while removing in coal gas
Aromatic hydrocarbons and sulfide form logistics II, and benzene concentration is less than 1000mg/m in logistics II3, naphthalene concentration is less than 4 mg/m3, hydrogen sulfide is dense
Degree is less than 4mg/m3;Organic sulfur concentration is less than 4mg/m3;Logistics II enters coke oven combustion.
The flue gas of 16 240 DEG C of ten thousand steres, amount of nitrogen oxides 500mg/m3, sulfide content is 200 mg/m3, cigarette
Gas enters denitrating tower, and at 240 DEG C, under ZSM-5 molecular sieve catalyst action, nitrogen oxides is reduced into nitrogen, the cigarette after reaction
Gas enters waste heat boiler, generates steam, and flue-gas temperature is reduced to 180 DEG C or so;Then flue gas enters from heat exchanger, and enters cigarette
The cold flue gas of chimney exchanges heat, and temperature is reduced to 110 DEG C or so;110 DEG C of flue gas is by spraying cooling to 50 DEG C, and shower water is by following
Ring uses, and after effluent part neutralizes, removes biochemical system;After flue gas after cooling passes through defogging equipment, into adsorption tower;Using 3
A 200m3Adsorption tower, two open one standby, and 120m is loaded in each adsorption tower3Micro crystal material amounts to 360 m3Micro crystal material mercerising
Zeolite;Adsorption tower specification is 4.8 meters of diameter, 12.0 meters high;After flue gas removes sulfide and nitrogen oxides, into from heat exchanger,
After hot fume heat exchange, reach 100 DEG C or more, into smoke stack emission, nitrogen oxides in effluent content is 50mg/m3, sulfide contains
Amount is 20 mg/m3.Desulphurization and denitration, dedusting crystallite adsorbent are loaded in adsorption tower, automatically switch circular regeneration after adsorption saturation;
Automatically switch within every 7 days a tower regeneration, the adsorption tower 3000m of saturation3The hot fume of/h is regenerated, the nitrogen oxides of desorption
Enter oxidizing tower with sulfide, is oxidized to sulfur trioxide and nitrogen dioxide;After mixed gas cooling, absorbed with water spray, part
After waste water neutralizes, it is discharged into biochemical system or going produces salt extraction workshop, tail gas enters flue gas spray column.
[embodiment 2]
The coke-stove gas that coke oven comes out enters slightly de- benzene unit, slightly forms logistics I after de- benzene, wherein benzene concentration exists in logistics I
1000~4000mg/m3Between, naphthalene concentration is in 200~500mg/m3Between, concentration of hydrogen sulfide is in 100~500mg/m3Between;Object
Stream I enters comprehensive purifying tower, ZSM molecular sieve class adsorbent is contained in the comprehensive purifying tower, while removing in coal gas
Aromatic hydrocarbons and sulfide form logistics II, and benzene concentration is less than 1000mg/m in logistics II3, naphthalene concentration is less than 4 mg/m3, hydrogen sulfide is dense
Degree is less than 4mg/m3;Organic sulfur concentration is less than 4mg/m3;Logistics II enters coke oven combustion.
Specific embodiment device process as shown in Fig. 1, the flue gas of 15 260 DEG C of ten thousand steres, nitrogen oxides contain
Amount is 400mg/m3, sulfide content is 100 mg/m3, flue gas enters denitrating tower, at 240 DEG C, in ZSM-5 molecular sieve catalyst
Under effect, nitrogen oxides is reduced into nitrogen, and the flue gas after reaction enters waste heat boiler, generates 150 DEG C of steam, and flue-gas temperature reduces
To 140 DEG C or so;Then flue gas enters spraying cooling to 40 DEG C, and shower water after effluent part neutralizes, goes to give birth to by being recycled
Change system;After flue gas after cooling passes through defogging equipment, into adsorption tower;Using 3 200m3Adsorption tower, two open it is one standby, often
120m is loaded in a adsorption tower3Micro crystal material amounts to 360 m3Micro crystal material ZSM-5 molecular sieve;Adsorption tower specification is diameter 4.8
Rice is 12.0 meters high;After flue gas removes sulfide and nitrogen oxides, into from after heat exchanger and hot fume heat exchange, reach 100 DEG C
More than, into smoke stack emission, nitrogen oxides in effluent content is 50mg/m3, sulfide content is 20 mg/m3.Filling in adsorption tower
Desulphurization and denitration, dedusting crystallite adsorbent, automatically switch circular regeneration after adsorption saturation;Automatically switch within every 7 days a tower regeneration,
The adsorption tower 3000m of saturation3The hot fume of/h is regenerated, and the nitrogen oxides and sulfide of desorption enter oxidizing tower, oxidation
At sulfur trioxide and nitrogen dioxide;It after mixed gas cooling, is absorbed with water spray, after effluent part neutralizes, is discharged into biochemical system
Or salt extraction workshop is gone to, tail gas enters flue gas spray column.
[embodiment 3]
The coke-stove gas that coke oven comes out enters slightly de- benzene unit, slightly forms logistics I after de- benzene, wherein benzene concentration exists in logistics I
1000~3500mg/m3Between, naphthalene concentration is in 200~500mg/m3Between, concentration of hydrogen sulfide is in 100~500mg/m3Between;Object
Stream I enters comprehensive purifying tower, and the ZSM-5 molecular sieve class adsorbent containing zinc modification in the comprehensive purifying tower removes simultaneously
Fall the aromatic hydrocarbons and sulfide in coal gas, forms logistics II, benzene concentration is less than 60mg/m in logistics II3, naphthalene concentration is less than 1 mg/m3,
Concentration of hydrogen sulfide is less than 1mg/m3;Toluene, dimethylbenzene, ethylbenzene, trimethylbenzene, naphthalene, anthracene, the concentration in Kun are less than 1 mg/m3;Vulcanization
Object is hydrogen sulfide, the concentration in sulfur dioxide, mercaptan, thioether, thiophene, methyl mercaptan, Dimethyl sulfide is less than 1 mg/m3, logistics
II, which enters coke oven, generates electricity.
Specific embodiment device process as shown in Fig. 1, the flue gas of 14 300 DEG C of ten thousand steres, nitrogen oxides contain
Amount is 450mg/m3, sulfide content is 200 mg/m3, flue gas enters denitrating tower, at 300 DEG C, in the ZSM-5 molecule of copper load
Under sieve catalyst effect, nitrogen oxides is reduced into nitrogen, and the flue gas after reaction enters waste heat boiler, generates 160 DEG C of steam, flue gas
It enters back into from heat exchanger, and enters the cold flue gas heat exchange of chimney, temperature is reduced to 110 DEG C or so;110 DEG C of flue gas passes through spray
Leaching cools to 50 DEG C, and shower water after effluent part neutralizes, removes biochemical system by being recycled;Flue gas after cooling is by removing
After mist equipment, into adsorption tower;Using 3 200m3Adsorption tower, two open one standby, and 120m is loaded in each adsorption tower3Crystallite material
Material amounts to 360 m3Micro crystal material ZSM-5 molecular sieve;Adsorption tower specification is 4.8 meters of diameter, 12.0 meters high;Flue gas removes devulcanization
After object and nitrogen oxides, into from after heat exchanger and hot fume heat exchange, reach 110 DEG C or more, into smoke stack emission, nitrogen in flue gas
Oxide content is 40mg/m3, sulfide content is 10 mg/m3.Desulphurization and denitration, dedusting crystallite adsorbent are loaded in adsorption tower,
After adsorption saturation, automatically switch circular regeneration with high-temperature flue gas;Automatically switch within every 7 days a tower regeneration, the adsorption tower of saturation is used
3000m3240 DEG C of flue gases of/h are regenerated, and the nitrogen oxides and sulfide of desorption enter the oxidizing tower containing vanadium series catalyst,
It is oxidized to sulfur trioxide and nitrogen dioxide;It after mixed gas cooling, is absorbed with water spray, after effluent part neutralizes, is discharged into biochemistry
System goes to salt extraction workshop, and tail gas enters flue gas spray column.
[embodiment 4]
Specific embodiment device process as shown in Fig. 1, the flue gas of 20 180 DEG C of ten thousand steres, amount of nitrogen oxides are
1000mg/m3, sulfide content is 500 mg/m3, flue gas enters denitrating tower, at 180 DEG C, under mordenite catalyst effect,
Nitrogen oxides is reduced into nitrogen, and the flue gas after reaction enters waste heat boiler, generates 10 tons of 165 DEG C of steam, flue-gas temperature per hour
It is reduced to 120 DEG C or so;120 DEG C of flue gas is by spraying cooling to 40 DEG C, and by being recycled, effluent part neutralizes shower water
Afterwards, the salt extraction system that going produces;After flue gas after cooling passes through defogging equipment, into adsorption tower;Using 4 200m3Absorption
Tower, three open standby, a filling 120m in each adsorption tower3Micro crystal material amounts to 480 m3Micro crystal material SSZ-13 molecular sieve;Absorption
Tower specification is 4.8 meters of diameter, 12.0 meters high;After flue gas removes sulfide and nitrogen oxides, changed into from heat exchanger and hot fume
After heat, reach 100 DEG C or more, into smoke stack emission, nitrogen oxides in effluent content is 50mg/m3, sulfide content is 20 mg/
m3.Desulphurization and denitration, dedusting crystallite adsorbent are loaded in adsorption tower, automatically switch circular regeneration after adsorption saturation;Every 7 days automatic
Switch a tower regeneration, the adsorption tower 2000m of saturation3The hot fume of/h is regenerated, the nitrogen oxides and sulfide of desorption
Into the oxidizing tower containing Cu-series catalyst, it is oxidized to sulfur trioxide and nitrogen dioxide;After mixed gas cooling, inhaled with water spray
It receives, after effluent part neutralizes, being discharged into produces salt extraction workshop, and tail gas enters flue gas spray column.
[embodiment 5]
Specific embodiment device process as shown in Figure 1, the flue gas of 20 180 DEG C of ten thousand steres, amount of nitrogen oxides are
1000mg/m3, sulfide content is 500 mg/m3, flue gas enters denitrating tower, at 180 DEG C, in the ZSM-5 molecular sieve of copper zinc load
Under catalyst action, nitrogen oxides is reduced into nitrogen, and the flue gas after reaction enters waste heat boiler, generates 150 DEG C of steam, flue gas drop
Temperature is to 170 DEG C, and then flue gas enters from heat exchanger, and enters the cold flue gas heat exchange of chimney, and temperature is reduced to 130 DEG C or so;Cigarette
Gas enters spray column, and by spraying cooling to 40 DEG C, shower water is by being recycled, and after effluent part neutralizes, what going produced is mentioned
Salt system;After flue gas after cooling passes through defogging equipment, into adsorption tower;Using 4 200m3Adsorption tower, three open it is one standby, often
120m is loaded in a adsorption tower3Micro crystal material, amount to 480 m3Micro crystal material copper ZSM-5 molecular sieve;Adsorption tower specification is diameter
It is 4.8 meters, 12.0 meters high;After flue gas removes sulfide and nitrogen oxides, into from after heat exchanger and hot fume heat exchange, reach 100
DEG C or more, into smoke stack emission, nitrogen oxides in effluent content is 40mg/m3, sulfide content is 10 mg/m3.Adsorption tower is built-in
Desulphurization and denitration, dedusting crystallite adsorbent are filled out, automatically switches circular regeneration after adsorption saturation;One tower of automatic switchover in every 7 days is again
It is raw, the adsorption tower 3000m of saturation3180 DEG C of flue gases of/h are regenerated, and the nitrogen oxides and sulfide of desorption, which enter, contains copper
The oxidizing tower of series catalysts, is oxidized to sulfur trioxide and nitrogen dioxide;It after mixed gas cooling, is absorbed with water spray, part is useless
After water neutralizes, being discharged into produces salt extraction workshop, and tail gas enters flue gas spray column.
[embodiment 6]
Specific embodiment device process as shown in Figure 1, the flue gas of 260 DEG C of 200,000 sides rice, amount of nitrogen oxides are
400mg/m3, sulfide content is 100 mg/m3, flue gas enters denitrating tower, at 250 DEG C or so, in rare earth mordenite catalyst
Under effect, nitrogen oxides is reduced into nitrogen, and the flue gas after reaction enters waste heat boiler, generates 170 DEG C of steam, and flue gas cool-down arrives
175 DEG C, then flue gas enters from heat exchanger, and enters the cold flue gas heat exchange of chimney, and temperature is reduced to 130 DEG C or so;Into spray
Leaching cools to 50 DEG C, and shower water after effluent part neutralizes, removes biochemical system by being recycled;Flue gas after cooling is by removing
After mist equipment, into adsorption tower;Using 3 200m3Adsorption tower, two open one standby, and 120m is loaded in each adsorption tower3Crystallite material
Material amounts to 360 m3Micro crystal material, micro crystal material include the ZSM-5 molecular sieve of lanthanum and zinc modification;Adsorption tower specification is diameter 4.8
Rice is 12.0 meters high;After flue gas removes sulfide and nitrogen oxides, into smoke stack emission, nitrogen oxides in effluent content is 30mg/
m3, sulfide content 5mg/m3.Desulphurization and denitration, dedusting crystallite adsorbent are loaded in adsorption tower, are automatically switched after adsorption saturation
Circular regeneration;Automatically switch within every 7 days a tower regeneration, the adsorption tower 4000m of saturation3180 DEG C of the flue gas of/h is regenerated,
The nitrogen oxides and sulfide of desorption enter oxidizing tower, are oxidized to sulfur trioxide and nitrogen dioxide at 250 DEG C;Mixed gas cooling
Afterwards, it is absorbed with water spray, after effluent part neutralizes, is discharged into biochemical system or goes to salt extraction workshop, tail gas enters flue gas spray column.
[embodiment 7]
Specific embodiment device process as shown in Fig. 1, the flue gas of 18 240 DEG C of ten thousand steres, amount of nitrogen oxides are
400mg/m3, sulfide content is 100 mg/m3, flue gas enters denitrating tower, at 240 DEG C, in rare-earth Y molecular sieve catalyst action
Under, nitrogen oxides is reduced into nitrogen, and the flue gas after reaction enters waste heat steam boiler, generates 145 DEG C of steam, and flue gas cool-down arrives
160 DEG C, by spraying cooling to 40 DEG C, shower water after effluent part neutralizes, removes biochemical system by being recycled;After cooling
Flue gas by after defogging equipment, into adsorption tower;Using 3 200m3Adsorption tower, two open one standby, and each adsorption tower is built-in
Fill out 120m3Micro crystal material amounts to 360 m3Micro crystal material ZSM-5 molecular sieve;Adsorption tower specification is 4.8 meters of diameter, 12.0 meters high;
After flue gas removes sulfide and nitrogen oxides, into from after heat exchanger and hot fume heat exchange, reaches 100 DEG C or more, arranged into chimney
It puts, nitrogen oxides in effluent content is 50mg/m3, sulfide content is 20 mg/m3.Desulphurization and denitration, dedusting are loaded in adsorption tower
Crystallite adsorbent automatically switches circular regeneration after adsorption saturation;Automatically switch within every 7 days a tower regeneration, the adsorption tower of saturation is used
3000m3The hot fume of/h is regenerated, and the nitrogen oxides and sulfide of desorption enter oxidizing tower, is oxidized to sulfur trioxide and two
Nitrogen oxide;It after mixed gas cooling, is absorbed with water spray, after effluent part neutralizes, is discharged into biochemical system or goes to salt extraction workshop,
Tail gas enters flue gas spray column.
[embodiment 8]
Specific embodiment device process as shown in Fig. 1, the flue gas of 18 210 DEG C of ten thousand steres, amount of nitrogen oxides are
400mg/m3, sulfide content is 100 mg/m3, flue gas enters denitrating tower, at 210 DEG C, in the ZSM-5 molecule of copper and tungsten load
Under sieve catalyst effect, nitrogen oxides is reduced into nitrogen, and the flue gas after reaction enters waste heat boiler, generates 160 DEG C of steam, flue gas
185 DEG C are cooled to, then flue gas enters from heat exchanger, and enters the cold flue gas heat exchange of chimney, and temperature is reduced to 130 DEG C or so;
By spraying cooling to 50 DEG C, shower water after effluent part neutralizes, goes to the salt extraction workshop of coking by being recycled;After cooling
Flue gas by after defogging equipment, into adsorption tower;Using 4 200m3Adsorption tower, three open one standby, and each adsorption tower is built-in
Fill out 150m3Micro crystal material amounts to 600 m3Micro crystal material containing modenite and ZSM-5 molecular sieve;Adsorption tower specification is diameter
It is 4.8 meters, 12.0 meters high;After flue gas removes sulfide and nitrogen oxides, into from after heat exchanger and hot fume heat exchange, reach 100
DEG C or more, into smoke stack emission, nitrogen oxides in effluent content is 50mg/m3, sulfide content is 20 mg/m3.Adsorption tower is built-in
Desulphurization and denitration, dedusting crystallite adsorbent are filled out, automatically switches circular regeneration after adsorption saturation;One tower of automatic switchover in every 7 days is again
It is raw, the adsorption tower 4000m of saturation3240 DEG C of the flue gas of/h is regenerated, and the nitrogen oxides and sulfide of desorption enter oxidation
Tower is oxidized to sulfur trioxide and nitrogen dioxide;It after mixed gas cooling, is absorbed with water spray, after effluent part neutralizes, is discharged into life
Change system goes to salt extraction workshop, and tail gas enters flue gas spray column.
Claims (11)
1. a kind of method of coke oven flue gas low-temp desulfurization denitration, comprising the following steps:
A) coke-stove gas or blast furnace gas for entering coke oven combustion first remove sulphur with crystallite adsorbent A before entering coke oven
Compound enters back into coke oven combustion;
B) coke oven flue gas of coke oven flue is drawn sulfur compound and nitrogen oxides, is denoted as material flow A, the temperature of the material flow A
It is 180 ~ 320 DEG C;
C) material flow A enters the denitrating tower comprising denitrating catalyst, after catalysis reduction, forms flow B;
D) flow B carries out UTILIZATION OF VESIDUAL HEAT IN, produces steam, and the flue gas after cooling forms flow C, and the temperature of the flow B is
120~180℃;
E) flow C enters heat exchanger, by with remove the flue gas heat exchange of chimney after, form logistics D, the temperature of the logistics D is
100~160℃;
F) logistics D enters cooling tower, after spraying cooling, dedusting, forms logistics E, and the temperature of the logistics E is 30 ~
100 DEG C, spray liquid enters waste water treatment system or salt extraction system;
G) logistics E enters the adsorption tower comprising crystallite adsorbent B, after adsorbing sulfide and nitrogen oxides, forms logistics F;
H) logistics F enters smoke stack emission;
I) adsorption tower after adsorbing sulfide and nitrogen oxides saturation in step g), with 100 ~ 10000m3The logistics or heat of/h
Air regenesis, regenerated flue gas form logistics G, wherein the temperature of the logistics G is 120 ~ 350 DEG C;
J) logistics G enters the oxidizing tower comprising oxidation catalyst, after catalysis oxidation, forms logistics H;
K) logistics H enters regeneration tail gas desulfurizing tower, after water or lye spray, forms stream I, spray liquid enters at waste water
Reason system or salt extraction system;
L) stream I enters step the cooling tower in f).
2. the method for coke oven flue gas desulphurization denitration according to claim 1, it is characterised in that the temperature of the material flow A is
240~280℃;Amount of nitrogen oxides is 100 ~ 1000mg/m3, sulfide content is 30 ~ 3000 mg/m3。
3. the method for coke oven flue gas low-temp desulfurization denitration according to claim 1, it is characterised in that into coke oven combustion
Coke-stove gas or blast furnace gas, hydrogen sulfide content are 0 ~ 20 mg/m3, 0 ~ 20 mg/m of organic sulfur content3。
Denitrating catalyst A or crystallite adsorbent B described in 4. include being selected from SSZ-13 molecular sieve, TS-1, Ti-MWW, Ti-
MOR, ZSM type molecular sieve, modenite, beta molecular sieve, SAPO type molecular sieve, MCM-22, MCM-49, MCM-56, ZSM-5/
Geolyte, ZSM-5/ β zeolite, ZSM-5/Y, MCM-22/ modenite, ZSM-5/Magadiite, ZSM-5/ β zeolite/mercerising boiling
Stone, ZSM-5/ β zeolite/at least one of Y zeolite or ZSM-5/Y zeolite/modenite.
5. according to the method for the coke oven flue gas low-temp desulfurization denitration that claim 3 is stated, it is characterised in that the denitrating catalyst
In also containing including in the periodic table of elements in the Ith A, II A, V A, I B, II B, III B, IV B, V B, VI B, VII B or the VIIIth race's element
At least one element.
6. the method for coke oven flue gas desulphurization denitration according to claim 1, it is characterised in that waste heat in the step d)
Using steam boiler is used, the vapor (steam) temperature of production is 140 ~ 180 DEG C;Cooling tower in the step f) be spray column or
Heat exchanger types, spray liquid are cooling using cold water;The temperature of flow C is 30 ~ 100 DEG C;The temperature of the logistics D is 30 ~ 100
℃;Amount of nitrogen oxides is 1 ~ 200mg/m3, sulfide content is 0.1 ~ 100 mg/m3。
7. the method for coke oven flue gas low-temp desulfurization denitration according to claim 1, it is characterised in that the liter of the logistics F
Warm mode is using heated by gas heating mode or logistics F and material flow A heat exchange heating mode, and after heating up, temperature is logistics F
80~200℃;In step g), the quantity of adsorption tower is at least more than two, and adsorbent bed operation temperature is 30 ~ 100 DEG C, operating pressure
For 0.1 ~ 20KPa.
8. the method for coke oven flue gas low-temp desulfurization denitration according to claim 1, it is characterised in that described in step g)
It includes X-type molecular sieve, Y type molecular sieve, A type molecular sieve, SSZ-13 molecular sieve, TS-1, Ti-MWW, Ti- that crystallite adsorbent, which is selected from,
MOR, ZSM type molecular sieve, modenite, beta molecular sieve, SAPO type molecular sieve, MCM-22, MCM-49, MCM-56, ZSM-5/
Geolyte, ZSM-5/ β zeolite, ZSM-5/Y, MCM-22/ modenite, ZSM-5/Magadiite, ZSM-5/ β zeolite/mercerising boiling
Stone, ZSM-5/ β zeolite/at least one of Y zeolite or ZSM-5/Y zeolite/modenite.
9. the method for coke oven flue gas low-temp desulfurization denitration according to claim 7, it is characterised in that the crystallite absorption
Also containing including the Ith A, II A, V A, I B, II B, III B, IV B, V B, VI B, VII B or the VIIIth race's element in the periodic table of elements in agent
At least one of element.
10. the method for coke oven flue gas low-temp desulfurization denitration according to claim 1, it is characterised in that the oxidation catalysis
Containing including in the Ith A, II A, V A, I B, II B, III B, IV B, V B, VI B, VII B or the VIIIth race's element in the periodic table of elements in agent
At least one element.
11. according to the method for the coke oven flue gas low-temp desulfurization denitration that claim 7 is stated, it is characterised in that alkali described in step k)
Liquid is at least one of sodium hydroxide solution, ammonium hydroxide, remained ammonia, sodium carbonate liquor, calcium hydroxide solution.
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