CN102260538A - Method and device for air-floatation flow-state high-temperature heat-transfer gasification of biomass - Google Patents
Method and device for air-floatation flow-state high-temperature heat-transfer gasification of biomass Download PDFInfo
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Abstract
The invention discloses a method and a device for air-floatation flow-state high-temperature heat-transfer gasification of biomass. The method comprises the following steps: (1) stirring a biomass gasifying raw material so as to form a mist state; (2) cracking under the heating of high temperature smoke at 800-1000 DEG C so as to obtain high temperature tar gas; (3) carrying out high temperature cracking and gasification on the high temperature tar gas and steam at the temperature of 1050-1150 DEG C; and (4) filtering, condensing and purifying solid residue and gas while stirring so as to obtain gas with a middle heat value. The device comprises a gas making furnace and at least one coke cracking furnace, wherein the gas making furnace comprises a gas collecting chamber and a stirring chamber; and the coke cracking furnace comprises an upper coke cracking furnace gas collecting chamber provided with a coke cracking furnace row tube, and a coke cracking furnace row tube shell layer is communicated with a gas making furnace row tube shell layer. According to the invention, a heat source in the whole cracking and gasification process is derived from high temperature smoke generated by combustion of a biomass micrometer fuel which is a renewable clean energy and is wide in source and low in cost. The method and device provided by the invention have the characteristics of high heat efficiency, high gas making efficiency and high gas heat value.
Description
Technical field
The invention belongs to biomass energy technology, be specifically related to a kind of biomass air supporting fluidised form high temperature heat exchange gasification process and device, be applicable to organism and coal, be particularly useful for agriculture and forestry organic waste material and coal dust pyrolysis gasification reformation and produce combustion gas.
Background technology
Serious day by day along with the exhausted day by day and environmental problem of fossil energy, the recycling treatment of developing clean renewable energy source, refuse has become urgent subject.Biomass fuel will become the substitute of mineral fuel such as coal, oil and natural gas, and its crucial part converts low-grade biomass energy to the high-grade energy exactly.
The domestic and international internal heat type gasification process that generally adopts, it be biomass at vaporizer and air incomplete combustion, the direct heating biomass make it to gasify.This method heating efficiency height, but a large amount of nitrogen that the air that internal combustion needs is brought into have reduced the combustion gas quality, so the calorific value of combustion gas is low, has only 1200 kilocalories/M
3Below.The gasification efficiency of this method only is below 70%, awkward tar and the residual carbon of resultant product to utilize, and the combustion gas transformation efficiency is low, the serious waste energy.In the gas-purification process, can produce a large amount of tar and waste waters, contaminate environment simultaneously.Though it has been carried out improvement for many years both at home and abroad, the internal heat type gasification process can't be applied because of the defective of self eventually.Therefore, must gasify to the biomass indirect heating, avoiding bringing calorific value and the quality that a large amount of nitrogen reduce combustion gas into, and tar, residual carbon must be converted into combustion gas as much as possible in gasification, to improve the economic benefit that biomass are utilized because of internal combustion heating.The gasification of biomass external-heat exists heat and moisture transfer problems, because heat carries out thermal conduction and radiation heat transfer by the outer wall of pyrolysis vaporizer to the center, this will cause outside temperature too high, and the temperature at center is on the low side, thereby influenced the reaction times, and the heating and cooling time of pyrolysis vaporizer is also long.
Chinese patent literature CN101935568A discloses " a kind of high temperature biomass micron fuel " (open day is on 01 05th, 2011), it comprises plant fibre powder and additive, wherein, the plant fibre powder massfraction accounts for 75~100%, additive is at least a during coal dust, lime powder and red mud account for, and the plant fibre powder particle diameter accounts for more than 70% less than the particle diameter of 250 μ m.Its temperature of combustion improves about 1 times than traditional method, and efficiency of combustion improves more than 1 times.Ordinary student material filamentary material can be carried by the micronization technology in fluidization, has become a kind of higher-grade fluid fuel near fuel oil and combustion gas.Can be widely used in that thermal power generation, Metal Melting, sea water desaltination, cities and towns heating, lime are fired, heat system air-conditioning, industry heating etc.
The subject matter that currently used biomass gasification method exists:
(1) the internal heat type gasification is a vaporized chemical with the air, contains a large amount of N in the gasification burning
2And CO
2, fuel gases calorific value is lower, and gasification efficiency is low, produces a large amount of tar.
(2) the internal heat type gasification is a vaporized chemical with the pure oxygen, the cost height, and investment is big.
(3) traditional external-heat gasifies, and the solid gasified raw material stockpiles at vaporizer, by the furnace wall indirect heating, because the vaporizer diameter is big (usually at 300-800mm), heat transfer distances is long, and heat transmission resistance is big, thereby heat transfer efficiency is low, and gasification efficiency is low, causes energy transformation efficiency low.
(4) external-heat gasifies if adopt electricity, combustion gas or fuel oil as external heat source, the heating cost height.
Summary of the invention
The objective of the invention is to overcome above-mentioned the deficiencies in the prior art part, biomass air supporting fluidised form high-temperature tubular heat exchange gasification square law device is provided, the present invention has the advantages that cost is low, thermo-efficiency is high, gas producing efficiency is high and fuel gases calorific value is high.
A kind of biomass air supporting fluidised form high temperature heat exchange gasification process provided by the invention is characterized in that this method comprises the steps:
The 1st step stirred the gasifying biomass raw material, made it form fog flow with air-flow, wherein, particle grain size more than 80% was arranged in the initial gasifying biomass raw material below 2mm, and the particle grain size more than 30% is below 0.5mm; If gasified raw material is a coal dust, particle grain size more than 80% is arranged in the initial gasified raw material below 1mm, the particle grain size more than 30% is below 0.3mm;
The material that the 2nd step obtained the 1st step carries out cracking under 800-1400 ℃ high-temperature flue gas indirect heating condition in the air supporting campaign, obtain high-temperature coke oil gas;
The 3rd step was gasified high-temperature coke oil gas high-temperature flue gas indirect heating Pintsch process by 1000-1800 ℃ under the condition that water vapour exists, and reaction generates CO, H
2And CH
4, also reaction generates CO and H to the residual carbon particle with water vapour in the high-temperature coke oil gas
2
The 4th step filtered with condensation cleaning and handles solid residue and combustion gas that the 3rd step obtained, obtained medium calorific value gas.
A kind of device of realizing above-mentioned biomass air supporting fluidised form high temperature heat exchange gasification process provided by the invention is characterized in that, this device comprises Gas-making Furnace and the burnt pyrolyzer of at least one carbon;
Gas-making Furnace comprises teeter column, tubulation pipe layer, goes up collection chamber and tubulation shell.Be communicated with by tubulation pipe layer between the teeter column of Gas-making Furnace and the last collection chamber.The upper and lower dividing plate that is provided with of Gas-making Furnace tubulation is fixed, by dividing plate with teeter column, tubulation pipe layer, go up hermetic seal between collection chamber three and the Gas-making Furnace tubulation shell; Gas-making Furnace tubulation shell is provided with high-temperature flue gas import and the outlet with external communications, and is provided with one or more ash buckets in the shell bottom;
The teeter column is positioned at tubulation pipe layer below, and last collection chamber is positioned at tubulation pipe layer top, is provided with biomass feed inlet in the teeter column, and agitating vane is installed in the bottom of teeter column, and agitating vane links to each other with first motor;
The burnt pyrolyzer of carbon comprises tubulation pipe layer, tubulation shell, goes up collection chamber and following collection chamber.Be communicated with by tubulation pipe layer between last collection chamber and the following collection chamber.The upper and lower dividing plate that is provided with of the burnt pyrolyzer tubulation of carbon is fixed, and will go up hermetic seal between collection chamber, tubulation pipe layer, following collection chamber three and the tubulation shell by dividing plate; The burnt pyrolyzer tubulation of carbon shell is provided with high-temperature flue gas import and the outlet with external communications; Last collection chamber is provided with the water vapour import, and last collection chamber communicates with collection chamber on the Gas-making Furnace by the tar gas pipeline; Following collection chamber is provided with the air outlet, and its bottom is equipped with the burnt pyrolyzer agitating vane of the carbon that links to each other with second motor; The burnt pyrolyzer tubulation of carbon shell communicates by the high-temperature flue gas pipeline with Gas-making Furnace tubulation shell.
The another kind of device of realizing above-mentioned biomass air supporting fluidised form high temperature heat exchange gasification process provided by the invention is characterized in that, this device comprises Gas-making Furnace and the burnt pyrolyzer of at least one carbon; Gas-making Furnace comprises tubulation pipe layer, last collection chamber, following collection chamber, teeter column and tubulation shell;
Gas-making Furnace tubulation shell bottom is provided with the teeter column, and the teeter column is provided with biomass feed inlet, and agitating vane is installed in the bottom of teeter column, and agitating vane links to each other with motor; Collection chamber is provided with the high-temperature flue gas mouth on the Gas-making Furnace; The last collection chamber of Gas-making Furnace and following collection chamber are communicated with by tubulation pipe layer.The upper and lower dividing plate that is provided with of Gas-making Furnace tubulation is fixed, and will go up hermetic seal between collection chamber, tubulation pipe layer, following collection chamber and the Gas-making Furnace tubulation shell by dividing plate;
The burnt pyrolyzer of carbon comprises collection chamber, tubulation pipe layer, following collection chamber and tubulation shell.The last collection chamber and the following collection chamber of the burnt pyrolyzer of carbon are communicated with by tubulation pipe layer, the upper and lower dividing plate that is provided with of the burnt pyrolyzer tubulation of carbon is fixed, by dividing plate with the last collection chamber of the burnt pyrolyzer of carbon, tubulation pipe layer, hermetic seal between collection chamber three and the carbon Jiao pyrolyzer tubulation shell down.Collection chamber and following collection chamber respectively are provided with the high-temperature flue gas mouth on the burnt pyrolyzer of carbon.The following collection chamber of the burnt pyrolyzer of carbon is communicated with by the high-temperature flue gas pipe with the following collection chamber of Gas-making Furnace, is provided with ash bucket in the middle of the high-temperature flue gas pipeline; The burnt pyrolyzer tubulation of carbon shell is provided with the water vapour import; The burnt pyrolyzer tubulation of carbon shell top communicates with Gas-making Furnace tubulation shell top by the tar gas pipeline; The burnt pyrolyzer tubulation of carbon shell bottom is provided with the oil gas vent that discharges of the coke.
The present invention has the following advantages compared to existing technology:
(1) biomass air-isolation sealing charging under the condition of pressure, guaranteed that the pyrolysis gasification product is pressed into gasification system and continues cracking, the combustion gas that has guaranteed simultaneously to produce does not contain the nitrogen that derives from air, the fuel gases calorific value height not by airborne nitrogen dilution in the combustion gas of generation
(2) biological particles relies on mechanical stirring in Gas-making Furnace, makes it be vaporific fluidised form, helps the raising of solid particulate even heating and heat transfer efficiency.
(3) gasified raw material flows in tubulation and is gasified by indirect heating, so just the indirect heating that the solid indirect heating is transformed into to vapor phase stream, greatly increase the unit heat transfer area, shorten heat transfer distances, improve heat transfer efficiency, solved the low problem of external-heat gasified raw material indirect heating thermo-efficiency.
(4) adopt tubular heat exchange to conduct heat in the burnt pyrolyzer of carbon, tubulation shell district adopts the thermal-flame heating of biomass micron fuel combustion, tubulation pipe floor district passes through gas-gas heat-exchange method to tar gas and semicoke high temperature cracking steam gasification, help tar uniform high-efficiency ground and obtain high temperature, has coke tar cracking efficient height, the semicoke advantage completely that gasifies.
(5) after the high-temperature flue gas of biomass micron fuel combustion carries out indirect heating to the tubulation shell in the burnt pyrolyzer of carbon, again the tubulation shell in the Gas-making Furnace is carried out indirect heating, its using waste heat from tail gas and then be used for to the indirect heating preheating of gasifying biomass raw material with to participating in the indirect heating preheating with the air of biomass micron fuel combustion, realize the multistage cascade utilization of heat energy, improved the efficiency of utilization of gasification system
(6) mechanical movement of solid gasified raw material in whole gasification system is transformed into liquid motion, designs simplification, and process is controlled easily; Raw material pyrolysis gasification in the air supporting campaign, systemic resistance is little.
(7) the biomass micron fuel of the thermal source use of whole pyrolysis gasification process heating is a kind of reproducible clean energy, and the source is wide, cost is low.
Description of drawings
Fig. 1 is the structural representation of first kind of embodiment of apparatus of the present invention;
Fig. 2 is the structural representation of second kind of embodiment of apparatus of the present invention;
Among the figure: 1, collection chamber on the Gas-making Furnace; 2, Gas-making Furnace tubulation upper spacer; 3, exhanst gas outlet; 4, Gas-making Furnace tubulation shell; 5, Gas-making Furnace tubulation pipe layer; 6, teeter column; 7, opening for feed; 8, Gas-making Furnace agitating vane; 9, tar gas pipeline; 10, water vapour import; 11, high-temperature flue gas import; 12, the burnt pyrolyzer tubulation of carbon pipe layer; 13, the burnt pyrolyzer tubulation of carbon shell; 14, air outlet; 15, collection chamber on the burnt pyrolyzer of carbon; 16, the burnt pyrolyzer agitating vane of carbon; 17, the burnt pyrolyzer tubulation of carbon upper spacer; 18, high-temperature flue gas pipeline; 19, ash bucket; 20, Gas-making Furnace tubulation lower clapboard; 21, collection chamber under the burnt pyrolyzer of carbon; 22, the burnt pyrolyzer tubulation of carbon lower clapboard; 23, collection chamber under the Gas-making Furnace.
Embodiment
The inventive method comprises the steps:
(1) the gasifying biomass raw material is stirred, make it form fog flow with air-flow, wherein, particle grain size more than 80% is arranged in the initial gasifying biomass raw material below 2mm, the particle grain size more than 30% is below 0.5mm; If gasified raw material is a coal dust, particle grain size more than 80% is arranged in the initial gasified raw material below 1mm, the particle grain size more than 30% is below 0.3mm;
(2) in 800-1400 ℃ high-temperature flue gas, optimal temperature is to carry out cracking under 900-1050 ℃ the high-temperature flue gas indirect heating condition to the material that step (1) is obtained, and obtains high-temperature coke oil gas in the air supporting campaign;
(3) with high-temperature coke oil gas high-temperature flue gas by 1000-1800 ℃ under the water vapour existence condition, optimal temperature is under 1100-1400 ℃ the high-temperature flue gas indirect heating, to carry out the Pintsch process gasification, and reaction generates CO, H
2And CH
4, also reaction generates CO and H to residual carbon with water vapour in the high-temperature coke oil gas
2Water vapour feeding amount S/B is best in the 0.73-1.02 scope, and S represents the flow velocity of water vapour, and B represents gasifying biomass material feeding speed.
(4), filter with condensation cleaning and handle, with regard to available CO, H to resulting solid residue of step (3) and combustion gas
2And CH
4Content accounts for the medium calorific value gas about 80%, contains tar in the combustion gas hardly.
Optimization as technique scheme, the biomass micron fuel combustion that high-temperature flue gas in step (2) and (3) provides by CN101935568A produces, and 1800 ℃ high-temperature flue gas is that air through preheating produces biomass micron fuel generation high-temp combustion.
The thermal source air-flow of gas-air-tube type heat-exchange method can be walked shell, also can walk the pipe layer.Fig. 1 is the embodiment that the thermal source air-flow is walked shell.In this embodiment, device comprises Gas-making Furnace and the burnt pyrolyzer of at least one carbon.Gas-making Furnace comprises collection chamber 1 and Gas-making Furnace tubulation shell 4 on teeter column 6, Gas-making Furnace tubulation pipe layer 5, the Gas-making Furnace.The teeter column 6 of Gas-making Furnace and last collection chamber 1 are communicated with by tubulation pipe layer 5.The Gas-making Furnace tubulation is provided with upper spacer 2 and lower clapboard 20, and fixes by upper and lower dividing plate, by dividing plate with teeter column 6, tubulation pipe layer 5, go up hermetic seal between collection chamber 1 three and the Gas-making Furnace tubulation shell 4; Gas-making Furnace tubulation shell 4 is provided with the high-temperature flue gas outlet 3 with external communications, and is provided with ash bucket 19 in the shell bottom;
Be positioned at Gas-making Furnace tubulation pipe layer 5 below in the teeter column 6, collection chamber 1 is positioned at Gas-making Furnace tubulation pipe layer 5 top on the Gas-making Furnace, be provided with biomass feed inlet 7 in the teeter column 6, Gas-making Furnace agitating vane 8 is installed in the bottom of teeter column 6, and agitating vane 8 links to each other with first motor.
The burnt pyrolyzer of carbon comprises on the burnt pyrolyzer tubulation of carbon pipe layer 12, the burnt pyrolyzer tubulation of carbon shell 13, the burnt pyrolyzer of carbon collection chamber 21 under collection chamber 15, the burnt pyrolyzer of carbon.Be communicated with by tubulation pipe layer 12 between last collection chamber 15 and the following collection chamber 21.The burnt pyrolyzer tubulation of carbon is provided with upper spacer 17 and lower clapboard 22, and fix by upper and lower dividing plate, by dividing plate with hermetic seal between collection chamber 21 threes under collection chamber 15, tubulation pipe layer 12, the burnt pyrolyzer of carbon on the burnt pyrolyzer of carbon and the carbon Jiao pyrolyzer tubulation shell 13; The burnt pyrolyzer tubulation of carbon shell 13 is provided with the high-temperature flue gas import 11 with external communications; Last collection chamber 15 is provided with water vapour import 10, and last collection chamber 15 tops are communicated with collection chamber 1 on the Gas-making Furnace by tar gas pipeline 18; Following collection chamber 21 is provided with air outlet 14, and its bottom is equipped with the burnt pyrolyzer agitating vane 16 of the carbon that links to each other with second motor; The burnt pyrolyzer tubulation of carbon shell 13 and Gas-making Furnace tubulation shell 4 communicate by high-temperature flue gas pipeline 18.
The high-temperature flue gas of biomass micron fuel combustion enters the burnt pyrolyzer tubulation of carbon shell 13 by high-temperature flue gas import 11 its tubulation pipe layer 12 is carried out heat.The high-temperature flue gas of the burnt pyrolyzer tubulation of carbon shell 13 carries out indirect heating by the tubulation shell 4 that high-temperature flue gas pipeline 18 enters Gas-making Furnace to its tubulation pipe layer 5 subsequently, the part ash deposition is in ash bucket 19 in the final high temperature flue gas, flue gas is from exhanst gas outlet 3 dischargings, can utilize its waste heat to the indirect heating preheating of gasifying biomass raw material with to the indirect heating preheating of participation, to improve the efficiency of utilization of gasification system with the air of biomass micron fuel combustion.
Biological particles pressure sealing enters the teeter column of Gas-making Furnace bottom 6 from opening for feed 7, relies on agitating vane 8 mechanical stirring, and with the biological particles atomizing, atomizing particle rises with air-flow and enters Gas-making Furnace tubulation pipe layer 5.Gas-making Furnace tubulation shell 4 adopts high-temperature flue gas 900-1050 ℃ of biomass micron fuel combustion, for the vaporific biological particles pyrolysis gasification in the tubulation pipe layer provides heat energy, the high-temperature coke oil gas that produces rises under the effect of hot gas buoyant flow, enter the last collection chamber 1 of Gas-making Furnace tubulation upper spacer 2 tops, the high-temperature coke oil gas that carries residual carbon enters the last collection chamber 15 of the burnt pyrolyzer tubulation of carbon upper spacer 17 tops by tar gas pipeline 9 and the water vapor 10 added, and the generation pyrolysis gasification is reacted in the burnt pyrolyzer tubulation of carbon pipe layer 12 then.1300-1500 ℃ of thermal-flame of biomass micron fuel combustion enters its tubulation shell 13 by high-temperature flue gas import 11, by tar and the water vapor in 1100-1400 ℃ the high-temperature flue gas indirect heating tubulation pipe layer in the tubulation shell, makes it reaction and generates CO, H
2And CH
4, residual carbon also generates CO and H with steam reaction
2, tar and residual carbon are gasified by high temperature pyrolysis by gas-air-tube type interchanger at the volley.And the mechanical stirring by agitating vane 16, preventing that solid residue is deposited on collection chamber 21 under the burnt pyrolyzer of carbon, last combustion gas and solid residue lime-ash 14 are gone out from the air outlet, carry out next step gas filtration and condensation cleaning, contain tar in the combustion gas hardly.The CO that obtains, H
2And CH
4Content accounts for the medium calorific value gas about 80%.
90% particle is at the following gasified raw material of 2mm, the air-isolation sealing enters the teeter column 6 of Gas-making Furnace bottom under the condition of pressure, relies on blade mechanism to stir, and has certain crushing effect, with the biological particles atomizing, atomizing particle rises with air-flow and enters Gas-making Furnace tubulation pipe layer.Gas-making Furnace tubulation shell district feeds the high-temperature flue gas waste heat heating of micron fuel combustion, its high-temperature flue gas waste heat comes from the high-temperature flue gas in the tubulation shell district of the burnt pyrolyzer of carbon, vaporific granular fuel in the Gas-making Furnace tubulation pipe layer is heated, make it pyrolysis gasification, the high-temperature coke oil gas that produces rises under the effect of hot gas buoyant flow, and carry residual carbon and the water vapor added enters in the tubulation pipe layer of the burnt pyrolyzer of carbon, its tubulation shell district feeds biomass micron fuel combustion high-temperature flue gas, tar and water vapor in the heating tubulation pipe layer make it reaction and generate CO, H
2And CH
4, residual carbon also generates CO and H with steam reaction
2, tar and residual carbon are separated thermal cracking gasification by gas-air-tube type heat-exchange method by high temperature in transmission.
Wherein the burnt pyrolyzer of carbon can be 1-6, and optimum quantity is 2-3, and the thermal source air-flow of gas-air-tube type heat-exchange method can be walked shell, also can walk the pipe layer; The diameter of heat exchanging pipe is 10-220mm, and optimum diameter is 30-80mm.The material of burnt pyrolyzer tubulation of Gas-making Furnace tubulation and shell and carbon and shell can be metal heat-stable material or nonmetal heatproof material.The inorganics of minority separates with combustion gas by dedusting in the gasification product of the burnt pyrolyzer gasification of carbon back; High-temperature fuel gas obtains tar and the required water vapor of residual carbon gasification through pre-thermal utilization, and gasification gas purifies after filtration and obtains required combustion gas.The energy of heating can be biomass micron fuel, combustion gas, fuel oil and residual carbon dust.The particulate diameter of biomass micron fuel is main powder below 400 μ m, and optimum particle diameter is to be main powder below 250 μ m.Particle grain size more than 80% is below 2mm, and the particle grain size more than 30% is below 0.5mm.The waste heat of the high-temperature flue gas tail gas of the micron fuel combustion of coming out from Gas-making Furnace tubulation shell district is used for to the preheating of solid particle fuel indirect heating with to the indirect heating preheating of participation with the air of biomass micron fuel combustion, to improve the efficiency of utilization of gasification system.
Fig. 2 is the embodiment that the thermal source air-flow is walked the pipe layer, and among Fig. 2, apparatus of the present invention comprise Gas-making Furnace and the burnt pyrolyzer of at least one carbon.Gas-making Furnace comprises on tubulation pipe layer 5, the Gas-making Furnace collection chamber 23, teeter column 6 and tubulation shell 4 under collection chamber 1, the Gas-making Furnace.
Gas-making Furnace tubulation shell 4 bottoms are provided with teeter column 6, are provided with biomass feed inlet 7 in the teeter column 6, and agitating vane 8 is installed in the bottom of teeter column 6, and agitating vane 8 links to each other with motor; Collection chamber 1 is provided with high-temperature flue gas outlet 3 on the Gas-making Furnace; On the Gas-making Furnace under collection chamber 1 and the Gas-making Furnace collection chamber 23 be communicated with by tubulation pipe layer 5.Upper spacer 2 that the Gas-making Furnace tubulation is provided with and lower clapboard 20, and fix by upper and lower dividing plate will be gone up hermetic seal between the collection chamber 23 and tubulation shell 4 under collection chamber 1, tubulation pipe layer 5, the Gas-making Furnace by dividing plate;
The burnt pyrolyzer of carbon comprises collection chamber 21 and the burnt pyrolyzer tubulation of carbon shell 13 under collection chamber 15 on the burnt pyrolyzer of carbon, the burnt pyrolyzer tubulation of carbon pipe layer 12, the burnt pyrolyzer of carbon.Last collection chamber 15 and following collection chamber 21 communicate by tubulation pipe layer 12, upper spacer 17 and lower clapboard 22 that the burnt pyrolyzer tubulation of carbon is provided with, and fix by upper and lower dividing plate, to go up hermetic seal between collection chamber 15, tubulation pipe layer 12, following collection chamber 21 threes and the burnt pyrolyzer tubulation of the carbon shell 13 by dividing plate, collection chamber 15 tops are provided with high-temperature flue gas import 11 on the burnt pyrolyzer of carbon, collection chamber 21 is communicated with collection chamber 20 under the Gas-making Furnace by high-temperature flue gas pipeline 18 under the burnt pyrolyzer of carbon, and is provided with ash bucket 19 in the middle of high-temperature flue gas pipeline 18; The burnt pyrolyzer tubulation of carbon shell 13 is provided with water vapour import 10; The burnt pyrolyzer tubulation of carbon shell 13 tops communicate with Gas-making Furnace tubulation shell 4 tops by tar gas pipeline 9; The burnt pyrolyzer tubulation of carbon shell 13 bottoms are provided with air outlet 14.
Below by by embodiment the present invention being described in further detail, but following examples only are illustrative, and protection scope of the present invention is not subjected to the restriction of these embodiment.
Example 1:
Used gasified raw material is a pine sawdust, be processed into particle diameter less than 3mm through homemade crusher, adopt this gasification process, the air-isolation sealing enters Gas-making Furnace, after atomizing, enter Gas-making Furnace tubulation pipe layer, tubulation shell feeding temperature is that 1050 ℃ high-temperature flue gas carries out pyrolysis gasification to pine sawdust particle in the pipe layer, high-temperature coke oil gas that produces and the water vapor of adding enter the burnt pyrolyzer of carbon, wherein S/B is 1.02, carry out the pyrolysis gasification reaction of tar gas through pipe type heat transfer, under 1400 ℃ high-temperature flue gas heating, make the reaction of tar generating gasification generate CO, H
2And CH
4, residual carbon also generates CO and H with steam reaction
2
High-temperature flue gas in this experiment be by diameter less than the thermal-flame that the biomass micron fuel high-temp combustion of 250 μ m is produced, progressively feed burnt tubulation furnace shell layer of carbon and Gas-making Furnace tubulation shell.
By present method, the combustion gas total gas production of acquisition is 1.77Nm
3/ kg.Tar content is 0.12%, and gaseous product mainly comprises H
2, CO, CH
4, C
2H
4, C
2H
6And CO
2Deng, content is respectively 40.8%, 25.4%, 8.5%, 2.2%, 0.1% and 23% separately, carbon conversion efficiency is 88.2%.
Used gasified raw material is a stalk, make the biomass material that particle diameter is 3-15mm after the fragmentation, adopt this gasification process, the air-isolation sealing enters Gas-making Furnace, after atomizing, enter Gas-making Furnace tubulation pipe layer, tubulation shell feeding temperature is that 900 ℃ high-temperature flue gas carries out pyrolysis gasification to stalk particle in the pipe layer, high-temperature coke oil gas that produces and the water vapor of adding enter the burnt pyrolyzer of carbon, wherein S/B is 0.73, carry out the pyrolysis gasification reaction of tar gas through pipe type heat transfer, under 1100 ℃ high-temperature flue gas heating, make the reaction of tar generating gasification generate CO, H
2And CH
4, residual carbon also generates CO and H with steam reaction
2
High-temperature flue gas in this experiment be by diameter less than the thermal-flame that the biomass micron fuel high-temp combustion of 250 μ m is produced, progressively feed burnt tubulation furnace shell layer of carbon and Gas-making Furnace tubulation shell.
By present method, the combustion gas total gas production of acquisition is 1.23Nm
3/ kg.Tar content is 0.96%, and gaseous product mainly comprises H
2, CO, CH
4, C
2H
4, C
2H
6And CO
2Deng, content is respectively 36.3%, 20.4%, 12.2%, 2.3%, 0.8% and 28% separately, carbon conversion efficiency is 73%.
The above is preferred embodiment of the present invention, but the present invention should not be confined to the disclosed content of this embodiment and accompanying drawing.So everyly do not break away from the equivalence of finishing under the spirit disclosed in this invention or revise, all fall into the scope of protection of the invention.
Claims (8)
1. a biomass air supporting fluidised form high temperature heat exchange gasification process is characterized in that this method comprises the steps:
The 1st step stirred the gasifying biomass raw material, made it vaporific, wherein, 80% particle grain size was arranged in the gasifying biomass raw material below 2mm, and the particle grain size more than 30% is below 0.5mm; If gasified raw material is a coal dust, particle grain size more than 80% is arranged in the initial gasified raw material below 1mm, the particle grain size more than 30% is below 0.3mm;
The material that the 2nd step obtained the 1st step carries out cracking under 800-1400 ℃ high-temperature flue gas indirect heating condition in the air supporting campaign, obtain high-temperature coke oil gas;
The 3rd step was gasified high-temperature coke oil gas high-temperature flue gas indirect heating Pintsch process by 1000-1800 ℃ under the condition that water vapour exists, and reaction generates CO, H
2And CH
4, also reaction generates CO and H to residual carbon with water vapour in the high-temperature coke oil gas
2
The 4th step filtered with condensation cleaning and handles solid residue and combustion gas that the 3rd step obtained, obtained medium calorific value gas.
2. biomass air supporting fluidised form high temperature heat exchange gasification process according to claim 1 is characterized in that S/B is in the 0.73-1.02 scope for water vapour feeding amount, and S represents the flow velocity of water vapour, and B represents gasifying biomass material feeding speed.
3. biomass air supporting fluidised form high temperature heat exchange gasification process according to claim 1 and 2, it is characterized in that, high-temperature flue gas in the 2nd step and the 3rd step is by biomass micron fuel combustion generation, and 1800 ℃ high-temperature flue gas is that air through preheating produces biomass micron fuel generation high-temp combustion.
4. biomass air supporting fluidised form high temperature heat exchange gasification process according to claim 3 is characterized in that, in the 2nd step, the temperature of high-temperature flue gas is 900-1050 ℃.
5. biomass air supporting fluidised form high temperature heat exchange gasification process according to claim 3 is characterized in that, in the 3rd step, the temperature of high-temperature flue gas is 1100-1400 ℃.
6. a device of realizing the described biomass air supporting of claim 1 fluidised form high temperature heat exchange gasification process is characterized in that, this device comprises Gas-making Furnace and the burnt pyrolyzer of at least one carbon;
Gas-making Furnace comprises collection chamber (1) and Gas-making Furnace tubulation shell (4) on teeter column (6), Gas-making Furnace tubulation pipe layer (5), the Gas-making Furnace.Teeter column of Gas-making Furnace (6) and last collection chamber (1) are communicated with by tubulation pipe layer (5); The Gas-making Furnace tubulation is provided with upper spacer (2) and lower clapboard (20), and fixes by upper and lower dividing plate, by dividing plate with teeter column (6), tubulation pipe layer (5), go up hermetic seal between collection chamber (1) three and the Gas-making Furnace tubulation shell (4); Gas-making Furnace tubulation shell (4) is provided with the high-temperature flue gas outlet (3) with external communications, and is provided with ash bucket (19) in the shell bottom;
Be positioned at Gas-making Furnace tubulation pipe layer (5) below in the teeter column (6), collection chamber on the Gas-making Furnace (1) is positioned at Gas-making Furnace tubulation pipe layer (5) top, be provided with biomass feed inlet (7) in the teeter column (6), Gas-making Furnace agitating vane (8) is installed in the bottom of teeter column (6), and agitating vane (8) links to each other with first motor.
The burnt pyrolyzer of carbon comprises on the burnt pyrolyzer tubulation pipe layer (12) of carbon, the burnt pyrolyzer tubulation shell (13) of carbon, the burnt pyrolyzer of carbon collection chamber (21) under collection chamber (15), the burnt pyrolyzer of carbon; Be communicated with by tubulation pipe layer (12) between last collection chamber (15) and the following collection chamber (21); The burnt pyrolyzer tubulation of carbon is provided with upper spacer (17) and lower clapboard (22), and fix by upper and lower dividing plate, by dividing plate with hermetic seal between collection chamber (21) three under collection chamber (15), tubulation pipe layer (12), the burnt pyrolyzer of carbon on the burnt pyrolyzer of carbon and the carbon Jiao's pyrolyzer tubulation shell (13); The burnt pyrolyzer tubulation shell of carbon (13) is provided with the high-temperature flue gas import (11) with external communications; Last collection chamber (15) is provided with water vapour import (10), and last collection chamber (15) top is communicated with collection chamber (1) on the Gas-making Furnace by tar gas pipeline (18); Following collection chamber (21) is provided with air outlet (14), and its bottom is equipped with the burnt pyrolyzer agitating vane (16) of the carbon that links to each other with second motor; The burnt pyrolyzer tubulation shell of carbon (13) communicates by high-temperature flue gas pipeline (18) with Gas-making Furnace tubulation shell (4).
7. device according to claim 6 is characterized in that, wherein the quantity of the burnt pyrolyzer of carbon is 2-3.
8. a device of realizing the described biomass air supporting of claim 1 fluidised form high temperature heat exchange gasification process is characterized in that, this device comprises Gas-making Furnace and the burnt pyrolyzer of at least one carbon; Gas-making Furnace comprises on tubulation pipe layer (5), the Gas-making Furnace collection chamber (23), teeter column (6) and tubulation shell (4) under collection chamber (1), the Gas-making Furnace;
Gas-making Furnace tubulation shell (4) bottom is provided with teeter column (6), is provided with biomass feed inlet (7) in teeter column (6), and agitating vane (8) is installed in the bottom of teeter column (6), and agitating vane (8) links to each other with motor; Collection chamber on the Gas-making Furnace (1) is provided with high-temperature flue gas outlet (3); Collection chamber (23) is communicated with by tubulation pipe layer (5) under collection chamber on the Gas-making Furnace (1) and the Gas-making Furnace; Upper spacer that the Gas-making Furnace tubulation is provided with (2) and lower clapboard (20), and fix by upper and lower dividing plate will be gone up hermetic seal between the collection chamber (23) and tubulation shell (4) under collection chamber (1), tubulation pipe layer (5), the Gas-making Furnace by dividing plate;
The burnt pyrolyzer of carbon comprises collection chamber (21) and the burnt pyrolyzer tubulation shell (13) of carbon under collection chamber (15) on the burnt pyrolyzer of carbon, the burnt pyrolyzer tubulation pipe layer (12) of carbon, the burnt pyrolyzer of carbon; On the burnt pyrolyzer of carbon under the burnt pyrolyzer of collection chamber (15) and carbon collection chamber (21) by the burnt pyrolyzer tubulation pipe layer of carbon (12) connection, upper spacer (17) and lower clapboard (22) that the burnt pyrolyzer tubulation of carbon is provided with, and by last, lower clapboard is fixed, to go up collection chamber (15) by dividing plate, tubulation pipe layer (12), hermetic seal between the burnt pyrolyzer tubulation shell of following collection chamber (21) three and carbon (13), collection chamber (15) top is provided with high-temperature flue gas import (11) on the burnt pyrolyzer of carbon, collection chamber (21) communicates with collection chamber (20) under the Gas-making Furnace by high-temperature flue gas pipeline (18) under the burnt pyrolyzer of carbon, and is provided with ash bucket (19) in the middle of high-temperature flue gas pipeline (18); The burnt pyrolyzer tubulation shell (13) of carbon top is provided with water vapour import (10); The burnt pyrolyzer tubulation shell (13) of carbon top communicates with Gas-making Furnace tubulation shell (4) top by tar gas pipeline (9); The burnt pyrolyzer tubulation shell (13) of carbon bottom is provided with air outlet (14).
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102899091A (en) * | 2012-11-14 | 2013-01-30 | 程培胜 | Method for preparing coal gas by cracking biomasses and municipal wastes by using system self heat source |
| CN105299622A (en) * | 2014-05-27 | 2016-02-03 | 上海毅知实业有限公司 | Method for combusting biomass synthetic fuel |
| CN110066692A (en) * | 2019-03-22 | 2019-07-30 | 张英华 | Coal hydrogen equipment and control method |
Citations (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1603388A (en) * | 2004-09-03 | 2005-04-06 | 南京工业大学 | Process and apparatus for preparing coal gas by using bulky biomass materials |
| CN1831094A (en) * | 2006-04-21 | 2006-09-13 | 江苏大学 | Process and equipment for co-gasification of biomass and coal |
| US20070062117A1 (en) * | 2005-09-09 | 2007-03-22 | Future Energy Gmbh And Manfred Schingnitz | Method and device for producing synthesis gases by partial oxidation of slurries prepared from fuels containing ash and full quenching of the crude gas |
| CN202401035U (en) * | 2011-11-15 | 2012-08-29 | 华中科技大学 | Biomass air-floatation flow-state high-temperature heat-exchange gasifying device |
-
2011
- 2011-06-24 CN CN 201110173914 patent/CN102260538B/en active Active
Patent Citations (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1603388A (en) * | 2004-09-03 | 2005-04-06 | 南京工业大学 | Process and apparatus for preparing coal gas by using bulky biomass materials |
| US20070062117A1 (en) * | 2005-09-09 | 2007-03-22 | Future Energy Gmbh And Manfred Schingnitz | Method and device for producing synthesis gases by partial oxidation of slurries prepared from fuels containing ash and full quenching of the crude gas |
| CN1831094A (en) * | 2006-04-21 | 2006-09-13 | 江苏大学 | Process and equipment for co-gasification of biomass and coal |
| CN202401035U (en) * | 2011-11-15 | 2012-08-29 | 华中科技大学 | Biomass air-floatation flow-state high-temperature heat-exchange gasifying device |
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102899091A (en) * | 2012-11-14 | 2013-01-30 | 程培胜 | Method for preparing coal gas by cracking biomasses and municipal wastes by using system self heat source |
| CN105299622A (en) * | 2014-05-27 | 2016-02-03 | 上海毅知实业有限公司 | Method for combusting biomass synthetic fuel |
| CN110066692A (en) * | 2019-03-22 | 2019-07-30 | 张英华 | Coal hydrogen equipment and control method |
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| CN102260538B (en) | 2013-04-17 |
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