CN205560759U - Mechanical stoker formula waste gasification burns dual -boiler power generation system - Google Patents

Mechanical stoker formula waste gasification burns dual -boiler power generation system Download PDF

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Publication number
CN205560759U
CN205560759U CN201521142637.0U CN201521142637U CN205560759U CN 205560759 U CN205560759 U CN 205560759U CN 201521142637 U CN201521142637 U CN 201521142637U CN 205560759 U CN205560759 U CN 205560759U
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China
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steam
furnace
incinerator
gasification
connects
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CN201521142637.0U
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Chinese (zh)
Inventor
严欣平
肖大志
周雄
林顺洪
李长江
丁又青
徐�明
柏继松
季炫宇
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Chongqing University of Science and Technology
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Chongqing University of Science and Technology
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/12Heat utilisation in combustion or incineration of waste

Abstract

The utility model discloses an it is less to change the heat exchange efficiency loss, mechanical stoker formula waste gasification burns dual -boiler power generation system that thermal recovery efficiency is higher. Including gasification incineration furnace, boiler system, circular air supplying system, power generation system, gasification incineration furnace includes the gasifier that can seal or communicate and fires the cinder stove, boiler system includes boiler body a, b, and boiler body a has cyclone combustion chamber, oven chamber a, b, and boiler body b has oven chamber d, cyclone dust chamber, establishes the water -cooling wall in cyclone combustion chamber, the cyclone dust chamber, establishes the over heater in the oven chamber a, establishes the evaporimeter in the oven chamber b, establishes over heater, evaporimeter in the oven chamber d, and the steam pocket is established on two boiler body's top, and cyclone combustion chamber flue gas entry linkage gasifier exhanst gas outlet, cyclone dust chamber flue gas entry linkage fire the export of cinder kiln gas, power generation system includes steam input pipe, steam turbine, generator, and steam input pipe connects over heater a, b and steam turbine.

Description

Stoker fired grate formula refuse gasification burns double boiler electricity generation system
Technical field
The utility model belongs to solid waste incineration processing technology field, particularly relates to stoker fired grate formula refuse gasification and burns double boiler electricity generation system.
Background technology
Existing technology of garbage disposal mainly has burning, sanitary landfills, compost, waste recovery etc..The advantages such as in garbage disposal routine techniques, it is obvious that burning disposal has reduced training, and innoxious thoroughly occupation of land amount is little, and waste heat energy is obtained by, and secondary pollution is few, meet the strategic requirement of China's sustainable development.But along with both at home and abroad environmental requirement being improved constantly, how to strengthen the control to secondary pollution particularly important.Therefore, refuse pyrolysis gasification burning technology is by the road gradually shifting industrial applications onto, primarily now using all kinds of incineration technology especially for domestic rubbish, gasification burning technology industrializes widely regenerates the technological innovation bringing domestic garbage disposal industry.
For many years, China's scientific research to the gasification burning technology such as living beings, rubbish, it is in progress a lot of, the basic research in laboratory is a lot, also has application study, such as: rotary kiln type, vertical and the destructive gasifying of fluidized bed type or temperature gasification and high fusion technology etc..But Technique Popularizing application is upper or there is a definite limitation, and raw material type, garbage treatment quantity, secondary pollution control and economic benefit etc. are principal elements.
In existing burning process and equipment, fire grate type incinerator is various informative, its application accounts for more than the 80% of the whole world waste incineration total market size, wherein has and uses mechanical type backstepping fire grate, forwards fire grate or combined fire grate in body of heater, also has the employing fire grate such as chain-plate type and drum-type.In boiler plant, it is a lot of that boiler reclaims heat methods, technology maturation;Heating style is the most, such as: the thermals source such as solar energy, smelting furnace waste heat, coal furnace, fluid bed, fixed bed, rotary kiln, utilizes boiler to reclaim heat, be used for generating electricity, heat supply, heating etc..
In sum, typical gasification burning and boiler plant technology maturation, it is respectively arranged with himself advantage, but in the actual application of China, needs the problem and shortage solved:
1., for characteristics such as China's house refuse water content height, complicated components, the technology of moving hearth uses, and needs emphasis to consider the conveying capacity of rubbish.In flue gas after simultaneously burning, fly ash content is higher, and collecting ash is heavier, and the deashing repair and maintenance cycle is short.
2. being on the increase along with refuse production, sanitary fill such as mountain, garbage treatment quantity must be effectively improved, could meeting the market requirement.
3., in the face of strict pollutant emission requirement, secondary pollution controls the key problem being technically need to solve.
4., in order to effectively increase economic efficiency, in rubbish heat treatment process, the organic efficiency of heat needs to improve.Existing rubbish heat treatment technics generally uses the high-temperature flue gas heat after boiler recovery waste incineration, produce steam and shift steam turbine power generation onto, whole transition heat efficiency losses is relatively big, processes identical quantity of refuse, relatively reduces thermal losses and raising heat exchanger effectiveness just can improve the thermal efficiency.
Existing incinerator such as following two patent of invention: an open question in multiple row sectional drive combined type domestic garbage incinerator (ZL200710092508.9) and two-stage garbage incinerator (ZL201010268376.2): rubbish heat treatment mode is relatively backward, simply be dried-burn-burn, the process of solid combustion release heat;In stove, thermal chemical reaction is based on oxidation reaction, and reduction reaction assists, and is easily generated secondary pollution;When rubbish burns in stove, crossing oxygen quotient big, First air, Secondary Air infeed amount are big, and in flue gas, dust content is higher, affect heat reclaiming system and smoke processing system relatively big, easy dust stratification, and exhaust gas volumn is relatively big, reduces thermal conversion efficiency;The gasification furnace not being separately provided and incinerator, can only process rubbish by several times, it is impossible to realizing large-scale rubbish continuous gasification burning disposal, garbage treatment quantity is less.
Utility model content
The purpose of this utility model is to overcome the deficiencies in the prior art, it is provided that a kind of stoker fired grate formula refuse gasification burns double boiler electricity generation system.Its rubbish conveying capacity is higher, and garbage treatment quantity is bigger, it is possible to reducing thermal losses and improve heat exchanger effectiveness, the organic efficiency of heat is higher, and can efficiently reduce pollutant discharge amount.
The purpose of this utility model is achieved in that
A kind of stoker fired grate formula refuse gasification burns double boiler electricity generation system, including incinerator, steam generator system, circulation air feed system, electricity generation system,
Described incinerator includes grate, and the feed hopper set gradually along feedstock direction on grate, gasification furnace and incinerator, the rear of gasification furnace is the cinder notch that falls of gasification furnace, incinerator is positioned at gasification furnace and falls the front lower place of cinder notch, the rear of incinerator is the slag notch of incinerator, described grate is provided with garbage pusher device, described garbage pusher device is positioned at the lower section of feed hopper, for the rubbish in feed hopper is pushed in gasification furnace, the lower section of gasification furnace moving hearth and incinerator moving hearth be respectively arranged below with at least one air compartment being independently arranged, described feed hopper, windrow seal section it is provided with between gasification furnace, leave transition in grate part between described gasification furnace and incinerator to fall slag section, the described transition slag section that falls is provided with residue pusher, the rubbish residue fallen in by gasification furnace pushes in incinerator;Described gasification furnace, incinerator include furnace shell, moving hearth respectively, the forward and backward side of described gasification furnace respectively by windrow seal section, transition fall slag section seal, described transition fall slag section isolation gasification furnace, incinerator, make gasification furnace, incinerator separate;Described gasification furnace, incinerator are respectively in the shape that arches upward, secondary it is respectively provided with for air port on the face arch of described gasification furnace, rear arch, the vault of described gasification furnace arranges the first exhanst gas outlet, and the vault of described incinerator arranges the second exhanst gas outlet, and described gasification furnace, incinerator are respectively equipped with igniting combustion supporting hole;
nullDescribed steam generator system includes boiler body a、Boiler body b,Described boiler body a has cyclone combustion chamber、Furnace chamber a、Furnace chamber b,The lower end of described cyclone combustion chamber arranges smoke inlet,The smoke inlet of cyclone combustion chamber and the connection of the first exhanst gas outlet,Cyclone combustion chamber upper end is the 3rd exhanst gas outlet,Described cyclone combustion chamber is provided with some combustion airs for air port,Described some combustion airs are positioned at smoke inlet for air port、Between 3rd exhanst gas outlet,3rd exhanst gas outlet of cyclone combustion chamber upper end connects with the upper end of furnace chamber a,Described furnace chamber a、The lower end connection of furnace chamber b,The upper end of described furnace chamber b arranges waste gas outlet,Described cyclone firing is indoor circumferentially arranged with water-cooling wall a ringwise,It is provided with superheater a in described furnace chamber a,Evaporimeter a it is provided with in furnace chamber b,The top of boiler body a arranges drum a,Described cyclone combustion chamber、Furnace chamber a、Furnace chamber b is respectively positioned on below drum a,Described drum a is provided with carbonated drink import,Drum a passes through water separator separation steam water interface,The delivery port of drum a connects water-cooling wall a by pipeline respectively、The water inlet of evaporimeter a,For exporting the isolated water of water separator,Described water-cooling wall a、The venthole of evaporimeter a connects the air intake of drum a respectively by steam pipe,For the high-temperature steam that refluxes,The saturated vapor outlet of described drum a connects the air intake of superheater a by pipeline,For by the high-temperature steam input superheater a of backflow,The venthole output superheated steam of described superheater a;
nullDescribed boiler body b has cyclone dust removal room、Furnace chamber d,The lower end of described cyclone dust collectors connects with the second exhanst gas outlet,The upper end of cyclone dust removal room connects with the upper end of furnace chamber d,Described cyclone dust removal is indoor circumferentially arranged with water-cooling wall b ringwise,It is provided with superheater b in described furnace chamber d、Evaporimeter b,Described superheater b is positioned at the top of evaporimeter b,The top of boiler body b arranges drum b,Described cyclone dust removal room、Furnace chamber d is respectively positioned on below drum b,Described drum b is provided with carbonated drink import,Drum b passes through water separator separation steam water interface,The delivery port of drum b is by connecting water-cooling wall b by pipeline respectively、The water inlet of evaporimeter b,For exporting the isolated water of water separator,Described water-cooling wall b、The venthole of evaporimeter b connects the air intake of drum b respectively by steam pipe,For the high-temperature steam that refluxes,The saturated vapor outlet of described drum b connects the air intake of superheater b by pipeline,For by the high-temperature steam input superheater b of backflow,The venthole output superheated steam of described superheater b;
Described circulation air feed system includes the first blower fan, second blower fan, the inlet end of described first blower fan is connected with the lower end of furnace chamber d by pipeline, the outlet side of described first blower fan is connected with furnace chamber b by pipeline, the air inlet of described second blower fan and atmosphere, the gas outlet of described second blower fan connects the first manifold respectively, the house steward of the second manifold, the arm of described first manifold connects for air port with each air compartment below gasification furnace moving hearth and each secondary on gasification furnace respectively, the arm of described second manifold connects for air port with some combustion airs of each air compartment below incinerator moving hearth and cyclone combustion chamber respectively;
nullDescribed electricity generation system includes steam input pipe、Steam turbine and the generator being connected with turbine power,Described steam input pipe connects described superheater a by pipeline respectively、The venthole of superheater b,The output of steam input pipe connects the steam input of steam turbine,The steam output end of described steam turbine is sequentially connected with condenser by pipeline、Water pump、Low pressure vapor heater、Oxygen-eliminating device、Booster water pump、High pressure steam water heater,The input that is heated of described low pressure vapor heater is connected with water pump,Being connected with oxygen-eliminating device by hot output terminal of low pressure vapor heater,The input of oxygen-eliminating device is provided with moisturizing pipeline,The input that is heated of described high pressure steam water heater is connected with booster water pump,High pressure steam water heater by hot output terminal by pipeline connect drum a、The carbonated drink import of drum b,Described steam turbine is provided with the first steam and takes pipe、Second steam takes pipe and takes steam to the steam output end of steam turbine respectively,Described first steam takes the heating input of the output connection high pressure steam water heater of pipe,Described second steam takes the heating input of the output connection low pressure vapor heater of pipe.
In order to make full use of the waste heat that steam turbine has not utilized, also include high pressure vapour gas heat exchanger, low-pressure steam gas heat exchanger, the heated passage of described high pressure vapour gas heat exchanger is connected to the first steam by pipeline and takes between pipe, oxygen-eliminating device input, the heated passage of described low-pressure steam gas heat exchanger is connected to the second steam by pipeline and takes between pipe, oxygen-eliminating device input, low-pressure steam gas heat exchanger add the passage of heat, high pressure vapour gas heat exchanger heating Tandem on the house steward of the first manifold, described high pressure vapour gas heat exchanger is positioned at the downstream of low-pressure steam gas heat exchanger.
Flue gas in order to discharge furnace chamber b carries out further heat recovery, improves heat recovery efficiency, it is preferable that described boiler body a has furnace chamber c, and the upper end of described furnace chamber c connects with the waste gas outlet of furnace chamber b upper end, and the lower end of furnace chamber c arranges Waste gas outlet.
Further, being provided with air preheater in described furnace chamber c, the outlet side of described second blower fan connects the air inlet of air preheater, and the gas outlet of air preheater connects the first manifold, the house steward of the second manifold.
Further, being provided with economizer in described furnace chamber c, the water inlet of described economizer connects with the delivery port of booster water pump, and the delivery port of described economizer is respectively by pipeline and drum a, the carbonated drink inlet communication of drum b.
Flue gas in order to discharge furnace chamber c carries out harmless treatment, and further, the Waste gas outlet of described furnace chamber c connects flue gas purification system, aeration tower that described flue gas purification system includes being sequentially connected in series along discharge directions, deduster, air-introduced machine, chimney.
In order in discharging furnace chamber a, furnace chamber b, flue gas deposits the waste residue produced, and prevent waste residue effusion from producing pollution, it is preferable that being provided with common slag notch below described furnace chamber a, furnace chamber b, this common slag notch connects with the burner hearth of gasification furnace.
In order to discharge the waste residue that cyclone firing indoor flue gas deposition produces, and prevent waste residue effusion from producing pollution, it is preferable that the lower end of described cyclone combustion chamber is provided with the taper slag notch that radius from top to bottom diminishes, and this taper slag notch connects with the burner hearth of gasification furnace.
High-temperature flue gas in order to produce after making burning is easily drained, and the installation of beneficially pipeline, it is preferable that described smoke inlet, the 3rd exhanst gas outlet are positioned at the opposition side of cyclone combustion chamber circumferential wall;Described 3rd exhanst gas outlet is radially or tangentially arranged along cyclone combustion chamber circumferential wall.
In order to prevent altering wind between gasification furnace, incinerator, it is preferable that described transition falls and is provided with isolating door to be opened/closed in slag section, described isolating door is for cutting off gasification furnace, incinerator.
Owing to have employed technique scheme, the utility model has the advantages that
The gasification furnace of incinerator, incinerator are provided separately, the vault of gasification furnace arranges the first exhanst gas outlet, the vault of incinerator arranges the second exhanst gas outlet, it is beneficial to process flue gas respectively according to the difference of flue gas quality, be conducive to flue gas ash removal simultaneously, can provide the flue gas of higher quality, the utilization rate making flue gas is higher, and the waste residue of discharge is less.
The waste gas that first blower fan extraction is discharged from furnace chamber d, is introduced in furnace chamber b, makes full use of the waste heat that boiler body b has not utilized, reach, also by cyclone dust removal room, the purpose that dedusting prevents flue dust from overflowing;Second blower fan utilizes the waste gas discharged from furnace chamber c by air preheater, makes full use of the waste heat that boiler body a has not utilized.The wind that second blower fan bloats provides First air, Secondary Air by the first manifold for gasification furnace, in making gasification furnace, rubbish produces gasification, and gasification furnace is contained within the flue gas of a certain amount of synthesis gas, discharges from the first exhanst gas outlet, entering cyclone combustion chamber processing links, cyclone combustion chamber provides high-temperature flue gas.The wind that second blower fan bloats provides First air by the second manifold for incinerator, and provides combustion air for cyclone combustion chamber, makes incinerator residue fully burn, and the synthesis flue gas of cyclone firing indoor fully burns.The stoker fired grate formula refuse gasification incinerator garbage treatment quantity of this structure is big, the rubbish bed of material can experience on stoker fired grate be dried, gasification and residue burn the stage, adapt to the characteristics such as China's house refuse water content height, complicated component, improve the energy conversion efficiency in garbage processing procedure and reduce pollutant discharge amount in flue gas, effectively prevent secondary pollution, and it is capable of large-scale rubbish continuous gasification burning disposal, ensure that refuse gasification burns effect and lime-ash clinker ignition loss, relatively reduce thermal losses and improve heat exchanger effectiveness, improve the thermal efficiency.
This steam generator system have employed the structure of two boilers, fully the synthesis flue gas of burning the first exhanst gas outlet release, utilizes the heat that smoke combustion discharges, and makes full use of the heat that the second exhanst gas outlet discharges, and heat transfer loss is less, and heat recovery efficiency is higher.Synthesis gas is the most abundant in cyclone firing Indoor Combustion, and the temperature that burning produces is higher, is arranged on cyclone combustion chamber by the water-cooling wall a of annular, relatively reduces thermal losses and improve heat exchanger effectiveness.The origin of heat that this steam generator system reclaims is in the high-temperature synthesis gas flue gas of refuse gasification outlet of still, synthesis gas flue gas enters cyclone combustion chamber, tangential air-supplied combustion-supporting flammable synthesis gas in cyclone combustion chamber simultaneously, flue gas sequentially passes through cyclone combustion chamber, furnace chamber a, furnace chamber b, economizer and air preheater.Recycling economizer preheating condensed water, preheating condensed water enters two boilers, condensed water heats in two water-cooling walls and two evaporimeters, form saturated vapor and enter two drums, after steam-water separation, saturated vapor enters two superheaters, again be thermally formed superheated steam output, can be used for generating electricity, heat supply, heating etc..The utility model is novel, utilizes cyclone-burning method, decreases fly ash content in flue gas;Syngas combustion temperature is high, and gas residence time is long, and pollutant is effectively decomposed, and reduces pollutant emission, it is achieved that the synthesis gas burning disposal after rubbish continuous gasification and heat recovery and utilization.
The steam that steam turbine can not utilized by condenser is all converted to water, and absorb the heat of steam release, the Main Function of oxygen-eliminating device is exactly the oxygen removing in boiler feedwater with it and other gas, ensure the quality of feedwater, booster water pump can improve hydraulic pressure, it is ensured that to the water supply capacity of water input system, electricity generation system is by heating low-grade steam and condensed water by high-grade steam, improve utilization rate of waste heat, reduce thermal losses.
Accompanying drawing explanation
Fig. 1 is structural representation of the present utility model;
Fig. 2 is the structural representation of cyclone combustion chamber;
Fig. 3 is the schematic top plan view of Fig. 2;
Fig. 4 is the structural representation of electricity generation system;
Fig. 5 is the structural representation of flue gas purification system;
Fig. 6 is the structural representation of incinerator.
Reference
1 is incinerator, and 101 is grate, and 102 is feed hopper, 103 is gasification furnace, and 104 is incinerator, and 105 is siege, 106 is garbage pusher device, and 107 is an air compartment, and 108 is windrow seal section, 109 fall slag section for transition, and 110 is residue pusher, and 111 is isolating door, 112 is the first exhanst gas outlet, and 113 is the second exhanst gas outlet, and 114 is igniting combustion supporting hole, 115 supply air port for secondary, and 116 is slag notch, and 117 is the cinder notch that falls;
202 is the first blower fan, and 203 is the second blower fan, and 204 is the first manifold, and 205 is the second manifold;
3 is cyclone combustion chamber, and 301 is combustion chamber ignition combustion-supporting hole, and 302 is taper slag notch, and 303 is smoke inlet, and 304 is the 3rd exhanst gas outlet, and 305 supply air port for combustion air;
4 is boiler body a, and 402 is furnace chamber a, and 403 is furnace chamber b, 404 is furnace chamber c, and 405 is water-cooling wall a, and 406 is superheater a, 407 is evaporimeter a, and 408 is drum a, and 418 is economizer, 419 is flue gas purification system, 420 is aeration tower, and 421 is deduster, and 422 is air-introduced machine, 423 is chimney, and 424 is air preheater;
5 is boiler body b, and 501 is furnace chamber d, and 502 is cyclone dust removal room, and 503 is water-cooling wall b, and 504 is superheater b, and 505 is evaporimeter b, and 506 is drum b;
6 is electricity generation system, and 601 is steam input pipe, and 602 is steam turbine, 603 is generator, and 604 is condenser, and 605 is water pump, 606 is low pressure vapor heater, and 607 is oxygen-eliminating device, and 608 is booster water pump, 609 is high pressure steam water heater, 610 is moisturizing pipeline, and 611 is that the first steam takes pipe, and 612 is that the second steam takes pipe, 613 is high pressure vapour gas heat exchanger, and 614 is low-pressure steam gas heat exchanger.
Detailed description of the invention
See Fig. 1 to Fig. 6, burn a kind of preferred embodiment of double boiler electricity generation system for stoker fired grate formula refuse gasification, including incinerator, steam generator system, circulation air feed system.
See Fig. 6, for stoker fired grate formula refuse gasification incinerator, including grate 101, and feed hopper 102, gasification furnace 103 and the incinerator 104 set gradually along feedstock direction on grate 101, the rear of incinerator 104 is the slag notch 116 of incinerator 104, and described incinerator 104 is provided with cinder notch 117, and the slag notch 116 of described incinerator 104 is positioned at incinerator and falls the underface of cinder notch 117, this sealing structure is effective, can effectively hold minimizing pollutant discharge amount.The carbon-containing part of rubbish is mainly gasified by gasification furnace 103, and discharges flammable gasification flue gas and rubbish residue, and incinerator 104 is substantially carried out the burning of carbon residue and processes, and discharges innoxious lime-ash.The siege 105 of gasification furnace 103 and incinerator 104 all uses the stoker fired grate formula moving hearth 105 that segmentation independently drives, the fire grate of stoker fired grate formula moving hearth 105 is to be forward lapped with fixed grate plate by moving grate plate, collect alternately and form, adjacent many groups moving grate plate is connected by pull bar, uses a set of driving means to drive.Stoker fired grate formula moving hearth 105 is as the carrier of conveying garbage, and its embodiment can be all types of moving hearths 105, such as chain-plate type, drum-type, multisection type fire grate system etc..
Described grate 101 is provided with garbage pusher device 106, described garbage pusher device 106 is positioned at the lower section of feed hopper 102, for the rubbish in feed hopper 102 is pushed in gasification furnace 103, the lower section of gasification furnace 103 moving hearth 105 and incinerator 104 moving hearth 105 be respectively arranged below with at least one air compartment 107 being independently arranged, in the present embodiment, the fire grate corresponding with an air compartment 107 of gasification furnace 103 first half, driving means, dryer section as gasification furnace 103 siege 105, one time latter half of with gasification furnace 103 fire grate that air compartment 107 is corresponding, driving means is as the gasification section of gasification furnace 103 siege 105.The dryer section of gasification furnace 103 siege 105, gasification section can be respectively adopted 1-2 independent air compartment 107 air feed, it is also possible to be respectively adopted 3-4 independent air compartment 107 air feed.Certainly, fire grate, driving means and an air compartment 107 also can not be correspondingly arranged, and preferably on regulation moving hearth 105, the bed of material moves and air distribution relation.Incinerator 104 can use 1-4 independent air compartment 107 air feed, burns rear lime-ash and gets rid of from slag notch, enters next step treatment process.
It is provided with windrow seal section 108 between described feed hopper 102, gasification furnace 103, garbage pusher device 106 work enters position and is in windrow seal section 108, garbage raw material is put into from feed hopper 102 and is fallen, garbage pusher device 106 retreats, advancing, pusher forms windrow at windrow seal section 108 back and forth again, makes gasification furnace 103 entrance be in windrow sealing state, strengthen gasification furnace 103 sealing effectiveness, solve garbage pusher device 106 and the easy leakage problem of feed hopper 102.When needing complete prepurging to dispose all rubbish, garbage pusher device 106 forward impelling half stroke again, rubbish is pushed completely in gasification furnace 103, makes gasification furnace 103 entrance lose windrow sealing effectiveness.Leave transition in grate 101 part between described gasification furnace 103 and incinerator 104 to fall slag section 109, the described transition slag section 109 that falls is provided with residue pusher 110, the rubbish residue fallen in by gasification furnace 103 pushes in incinerator 104, transition fall slag section 109 pile up rubbish residue time can be at windrow sealing state, strengthen gasification furnace 103 sealing effectiveness, solve to go here and there between gasification furnace 103, incinerator 104 problem of wind.In the present embodiment, described transition falls and is provided with isolating door 111 to be opened/closed in slag section 109, and described isolating door 111 is for cutting off gasification furnace 103, incinerator 104.At the furnace lifting initial stage or when needing to control to alter wind between gasification furnace 103 and incinerator, close isolating door 111, after the slag section that falls stacks the formation windrow sealing of a certain amount of residue, isolating door 111 can be kept to open, the residue pusher 110 arranged with lower section is coordinated to use, to realize rubbish continuous gasification burning disposal.
The upper end of described gasification furnace 103, incinerator 104 upper end respectively in the shape that arches upward, the face arch of described gasification furnace 103 is flat construction, or, the face arch of gasification furnace 103 is that rear end is inclined upwardly structure.The vault of described gasification furnace 103 arranges the first exhanst gas outlet 112, and the vault of described incinerator 104 arranges the second exhanst gas outlet 113, and the arching upward of described gasification furnace 103 upper end, the arching upward of incinerator 104 upper end are respectively equipped with igniting combustion supporting hole 114.Gasification flue gas is got rid of from first exhanst gas outlet the 112, second exhanst gas outlet 113, and gasification furnace 103 furnace cavity is compared with traditional incinerator, relatively reduced;Forward and backward arch position relative with moving hearth 105 diminishes, and decreases the space that incinerator takies, and is also easier to insulation, decreases the amount of leakage of heat, beneficially rubbish and fully gasify.Secondary it is respectively provided with for air port 115 on the face arch of described gasification furnace 103, rear arch.
See Fig. 1 to Fig. 3, described steam generator system includes boiler body a4, boiler body b5, described boiler body a4 has cyclone combustion chamber 3, furnace chamber a402, furnace chamber b403, furnace chamber c404, the lower end of described cyclone combustion chamber 3 arranges smoke inlet 303, the smoke inlet 303 of described cyclone combustion chamber 3 is connected with the first exhanst gas outlet 112 of gasification furnace 103 by pipeline, cyclone combustion chamber 3 upper end is the 3rd exhanst gas outlet 304, described smoke inlet 303, 3rd exhanst gas outlet 304 is positioned at the opposition side of cyclone combustion chamber 3 circumferential wall, the top of cyclone combustion chamber 3 arranges combustion chamber ignition combustion-supporting hole 301.In order to discharge from the 3rd exhanst gas outlet 304 after making flue gas, combustion air be sufficiently mixed in cyclone combustion chamber 3, burning, described cyclone combustion chamber 3 is provided with some combustion airs and supplies air port 305, and described some combustion airs supply air port 305 between smoke inlet the 303, the 3rd exhanst gas outlet 304.Described smoke inlet the 303, the 3rd exhanst gas outlet 304, combustion air are radially or tangentially arranged along cyclone combustion chamber 3 circumferential wall for air port 305.3rd exhanst gas outlet 304 of cyclone combustion chamber 3 upper end connects with the upper end of furnace chamber a402, described furnace chamber a402, the lower end connection of furnace chamber b403, the upper end of described furnace chamber b403 arranges waste gas outlet, the lower end of described cyclone combustion chamber 3 is provided with the taper slag notch 302 that radius from top to bottom diminishes, and this taper slag notch 302 connects with the burner hearth of gasification furnace 103.Being provided with common slag notch below described furnace chamber a402, furnace chamber b403, this common slag notch connects with the burner hearth of gasification furnace 103.In the present embodiment, this common slag notch and taper slag notch 302 all afterbody changeover portions with gasification furnace 103 burner hearth connect.
nullIt is circumferentially with water-cooling wall a405 ringwise along inwall in described cyclone combustion chamber 3,It is provided with superheater a406 in described furnace chamber a402,Evaporimeter a407 it is provided with in furnace chamber b403,The top of boiler body 4 arranges drum a408,Described cyclone combustion chamber 3、Furnace chamber a402、Furnace chamber b403 is respectively positioned on below drum a408,Described drum a408 is provided with carbonated drink import,For inputting steam water interface,It is provided with water separator in drum a408,For separating steam water interface,The delivery port of drum a408 is by connecting water-cooling wall a405 by pipeline respectively、The water inlet of evaporimeter a407,For exporting the isolated water of water separator,Described water-cooling wall a405、The venthole of evaporimeter a407 connects the air intake of drum a408 respectively by steam pipe,For the high-temperature steam that refluxes,The saturated vapor outlet of described drum a408 connects the air intake of superheater a406 by pipeline,For by the high-temperature steam input superheater a406 of backflow,The venthole output superheated steam of described superheater a406.
nullDescribed boiler body b5 has cyclone dust removal room 502、Furnace chamber d501,The lower end of described cyclone dust collectors connects with the second exhanst gas outlet,The upper end of cyclone dust removal room 502 connects with the upper end of furnace chamber d501,Circumferentially arranged with water-cooling wall b503 ringwise in described cyclone dust removal room 502,It is provided with superheater b504 in described furnace chamber d501、Evaporimeter b505,Described superheater b504 is positioned at the top of evaporimeter b505,The top of boiler body b5 arranges drum b506,Described cyclone dust removal room 502、Furnace chamber d501 is respectively positioned on below drum b506,Described drum b506 is provided with carbonated drink import,Drum b506 passes through water separator separation steam water interface,The delivery port of drum b506 is by connecting water-cooling wall b503 by pipeline respectively、The water inlet of evaporimeter b505,For exporting the isolated water of water separator,Described water-cooling wall b503、The venthole of evaporimeter b505 connects the air intake of drum b506 respectively by steam pipe,For the high-temperature steam that refluxes,The saturated vapor outlet of described drum b506 connects the air intake of superheater b504 by pipeline,For by the high-temperature steam input superheater b504 of backflow,The venthole output superheated steam of described superheater b504;Described cyclone dust removal room 502, the lower end of furnace chamber d501 are provided with common slag notch, and this slag notch passes through pipeline communication with the cinder notch 117 that falls of incinerator.
nullSee Fig. 4,Described electricity generation system 6 includes steam input pipe 601、Steam turbine 602 and the generator 603 being connected with steam turbine 602 power,Described steam input pipe 601 connects described superheater a by pipeline respectively、The venthole of superheater b,The output of steam input pipe 601 connects the steam input of steam turbine 602,The steam output end of described steam turbine 602 is sequentially connected with condenser 604 by pipeline、Water pump 605、Low pressure vapor heater 606、Oxygen-eliminating device 607、Booster water pump 608、High pressure steam water heater 609,The input that is heated of described low pressure vapor heater 606 is connected with water pump 605,Being connected with oxygen-eliminating device 607 by hot output terminal of low pressure vapor heater 606,The input of oxygen-eliminating device 607 is provided with moisturizing pipeline 610,The input that is heated of described high pressure steam water heater 609 is connected with booster water pump 608,High pressure steam water heater 609 by hot output terminal by pipeline connect drum a、The carbonated drink import of drum b,Described steam turbine 602 is provided with the first steam and takes pipe 611、Second steam takes pipe 612 and takes steam to the steam output end of steam turbine 602 respectively,Described first steam takes the heating input of the output connection high pressure steam water heater 609 of pipe 611,Described second steam takes the heating input of the output connection low pressure vapor heater 606 of pipe 612.Also include high pressure vapour gas heat exchanger 613, low-pressure steam gas heat exchanger 614, the heated passage of described high pressure vapour gas heat exchanger 613 is connected to the first steam by pipeline and takes between pipe 611, oxygen-eliminating device 607 input, the heated passage of described low-pressure steam gas heat exchanger 614 is connected to the second steam by pipeline and takes between pipe 612, oxygen-eliminating device 607 input, low-pressure steam gas heat exchanger 614 add the passage of heat, high pressure vapour gas heat exchanger 613 heating Tandem on the house steward of the first manifold, described high pressure vapour gas heat exchanger 613 is positioned at the downstream of low-pressure steam gas heat exchanger 614.
nullSee Fig. 1,Described circulation air feed system includes the first blower fan 202、Second blower fan 203,The inlet end of described first blower fan 202 is connected with the lower end of furnace chamber d by pipeline,The outlet side of described first blower fan 202 is connected with furnace chamber b by pipeline,The air inlet of described second blower fan 203 and atmosphere,The gas outlet of described second blower fan 203 connects the first manifold 204 respectively、The house steward of the second manifold 205,The arm of described first manifold 204 connects for air port with each air compartment below gasification furnace moving hearth and each secondary on gasification furnace respectively,The arm of described second manifold 205 connects for air port with some combustion airs of each air compartment below incinerator moving hearth and cyclone combustion chamber respectively,It is respectively provided with the first regulation valve on each arm of described first manifold 204,It is respectively provided with the second regulation valve on each arm of described second manifold 205.
See Fig. 1, Fig. 5, in the present embodiment, the upper end of described furnace chamber c404 connects with the waste gas outlet of furnace chamber b403 upper end, the lower end of furnace chamber c404 arranges Waste gas outlet, it is provided with economizer 418 in described furnace chamber c404, the water inlet of described economizer 418 connects with the delivery port of booster water pump 416, the delivery port of described economizer 418 and the carbonated drink inlet communication of drum a408.The Waste gas outlet of furnace chamber c404 connects flue gas purification system 419, aeration tower 420 that described flue gas purification system 419 includes being sequentially connected in series along discharge directions, deduster 421, air-introduced machine 422, chimney 423.Being provided with air preheater in described furnace chamber c, the outlet side of described second blower fan 203 connects the air inlet of air preheater, and the gas outlet of air preheater connects the house steward of first manifold the 204, second manifold 205.
The origin of heat that boiler body a reclaims is in the high-temperature synthesis gas flue gas of refuse gasification outlet of still, synthesis gas flue gas enters cyclone combustion chamber, tangential air-supplied combustion-supporting flammable synthesis gas in cyclone combustion chamber simultaneously, flue gas sequentially passes through cyclone combustion chamber, furnace chamber a, furnace chamber b, economizer and air preheater.
The origin of heat that boiler body b reclaims high-temperature flue gas after residual burning after refuse gasification, flue gas enters cyclone dust removal room, tangentially enters, tangentially export, and flue gas sequentially passes through cyclone dust removal room, furnace chamber d, then by high-temperature blower, flue gas introduces furnace chamber b.
Recycling economizer preheating condensed water, preheating condensed water enters boiler a and boiler b, and condensed water heats in water-cooling wall and evaporimeter, form saturated vapor and enter drum, after steam-water separation, saturated vapor enters superheater, is again thermally formed superheated steam output generating, it is possible to heat supply, heating etc..)
Saving energy in Steam Turbine electricity generation system: the superheated steam from boiler superheater enters the generating of steam cylinder pushing turbine;In steam cylinder, take the first steam entrance high pressure steam water heater and high pressure vapour hot-air heater, heating condensate water and rear formation condensed water return oxygen-eliminating device;In steam cylinder, take formation condensed water after the second steam enters low pressure vapor heater and low-pressure steam hot-air heater, heating condensate water and air return oxygen-eliminating device.
Steam cylinder steam (vapor) outlet connects condenser, is entered low pressure vapor heater by water pump pressurization after steam is condensed, and the condensed water after heating is formed and enters oxygen-eliminating device;Utilization of condensed water booster water pump pressurization after deoxygenation, feeds high pressure steam water heater, and the condensed water of heating enters economizer and again heats, and enters back into boiler part.
Add hot-air and condensed water by high-grade steam, improve utilization rate of waste heat, reduce loss.
Circulation air feed system is to the waste disposal method after stoker fired grate formula refuse gasification incinerator air feed, and the method sequentially includes the following steps:
nullStep A、Close the gate of stoker fired grate formula refuse gasification incinerator 1 and atmospheric vent,Start machinery grate-type refuse gasification incinerator 1,Garbage raw material is put into feed hopper 102,Garbage pusher device 106 pusher back and forth,The garbage raw material fallen from feed hopper 102 is pushed feed hopper 102、Windrow seal section 108 between gasification furnace 103,Windrow seal section 108 is made to form windrow sealing state,Unnecessary rubbish falls into the moving hearth 105 of gasification furnace 103,The moving hearth 105 of gasification furnace 103 works,Rubbish is conveyed into transition fall slag section 109,Residue pusher 110 pusher back and forth,The rubbish in slag section 109 that transition fallen pushes in incinerator 104,The moving hearth 105 of incinerator 104 works conveying garbage,Until rubbish is at gasification furnace 103、The moving hearth 105 of incinerator 104 is accumulated to required thickness: 0.6-0.8m,,During baker,The rubbish piled up can protect moving hearth 105,Prevent scaling loss siege 105.Stop feeding intake to feed hopper 102, the moving hearth 105 of gasification furnace 103 and incinerator 104 quits work, then, with start-up burner by the igniting combustion supporting hole 114 of gasification furnace 103 and incinerator 104 respectively burner hearth with gasification furnace 103 and incinerator 104 communicate, under the effect of start-up burner, gasification furnace 103 and incinerator 104 are carried out furnace lifting, baker, treats that this process stabilization completes, make gasification furnace 103 and incinerator 104 burner hearth reach predetermined temperature 600-700 DEG C;The purpose of baker is the Natural Water in order to remove in lining and the crystallization water, in order to avoid rising too fast when going into operation due to furnace temperature, moisture content expands in a large number to cause body of heater spalling, bubbling or deform even furnace wall and collapses, and affects intensity and the service life of heating furnace furnace wall.
Step B, start regulation circulation air feed system 2, regulation gasification furnace 103, incinerator 104 and technological parameter (the pusher speed of circulation air feed system 2, fire grate speed, wind-warm syndrome, blast and air quantity, secondary air temperature, blast and air quantity, furnace temperature, negative pressure in stove, thickness of feed layer etc.), feed intake to feed hopper 102, the moving hearth 105 of gasification furnace 103 works conveying garbage, rubbish proceeds by burning in the burner hearth of gasification furnace 103, rubbish residue is piled up formation windrow at transition falls slag section 109 and is sealed, the stove chamber inner combustion state temperature making gasification furnace 103 is stabilized to more than 850 DEG C, moving hearth 105 work of incinerator 104 exports the rubbish residue after burning.
Each technological parameter (negative pressure, thickness of feed layer etc. in pusher speed, fire grate speed, wind-warm syndrome, blast and air quantity, secondary air temperature, blast and air quantity, furnace temperature, stove) of step C, regulation gasification furnace 103, incinerator 104 and circulation air feed system 2, rubbish is gradually gasified by gasification furnace 103, gasification temperature is stable between 700-800 DEG C, making the stable high-temperature flue gas produced containing 10%-20% synthesis gas of gasification furnace 103, gasification furnace 103 vaporized state stably carries out low temperature, middle temperature or high-temperature gasification.Make incinerator 104 fired state temperature stabilization to more than 850 DEG C, it is achieved rubbish continuous gasification burning disposal;Each technological parameter of cyclone combustion chamber 3 need to be regulated simultaneously, make cyclone combustion chamber 3 the 3rd exhanst gas outlet 304 temperature stabilization to more than 850 DEG C.
Step D, need to overhaul or during blowing out, stopping feeds intake, regulation gasification furnace 103, incinerator 104 and the technological parameter of circulation air feed system 2, gasification furnace 103 is made to be gradually restored to fired state, after rubbish and rubbish residue burn, close stoker fired grate formula refuse gasification incinerator 1 and circulation air feed system 2.Each technological parameter of cyclone combustion chamber 3 need to be regulated simultaneously, make gasification furnace 103 be gradually restored to fired state.
Finally illustrate is, preferred embodiment above is only in order to illustrate the technical solution of the utility model and unrestricted, although the utility model being described in detail by above preferred embodiment, but skilled artisan would appreciate that, in the form and details it can be made various change, without departing from the utility model claims limited range.

Claims (10)

1. stoker fired grate formula refuse gasification burns a double boiler electricity generation system, including incinerator, steam generator system, circulation air feed system, electricity generation system, it is characterised in that:
Described incinerator includes grate, and the feed hopper set gradually along feedstock direction on grate, gasification furnace and incinerator, the rear of gasification furnace is the cinder notch that falls of gasification furnace, incinerator is positioned at gasification furnace and falls the front lower place of cinder notch, the rear of incinerator is the slag notch of incinerator, described grate is provided with garbage pusher device, described garbage pusher device is positioned at the lower section of feed hopper, for the rubbish in feed hopper is pushed in gasification furnace, the lower section of gasification furnace moving hearth and incinerator moving hearth be respectively arranged below with at least one air compartment being independently arranged, described feed hopper, windrow seal section it is provided with between gasification furnace, leave transition in grate part between described gasification furnace and incinerator to fall slag section, the described transition slag section that falls is provided with residue pusher, the rubbish residue fallen in by gasification furnace pushes in incinerator;Described gasification furnace, incinerator include furnace shell, moving hearth respectively, the forward and backward side of described gasification furnace respectively by windrow seal section, transition fall slag section seal, described transition fall slag section isolation gasification furnace, incinerator, make gasification furnace, incinerator separate;Described gasification furnace, incinerator are respectively in the shape that arches upward, secondary it is respectively provided with for air port on the face arch of described gasification furnace, rear arch, the vault of described gasification furnace arranges the first exhanst gas outlet, and the vault of described incinerator arranges the second exhanst gas outlet, and described gasification furnace, incinerator are respectively equipped with igniting combustion supporting hole;
nullDescribed steam generator system includes boiler body a、Boiler body b,Described boiler body a has cyclone combustion chamber、Furnace chamber a、Furnace chamber b,The lower end of described cyclone combustion chamber arranges smoke inlet,The smoke inlet of cyclone combustion chamber and the connection of the first exhanst gas outlet,Cyclone combustion chamber upper end is the 3rd exhanst gas outlet,Described cyclone combustion chamber is provided with some combustion airs for air port,Described some combustion airs are positioned at smoke inlet for air port、Between 3rd exhanst gas outlet,3rd exhanst gas outlet of cyclone combustion chamber upper end connects with the upper end of furnace chamber a,Described furnace chamber a、The lower end connection of furnace chamber b,The upper end of described furnace chamber b arranges waste gas outlet,Described cyclone firing is indoor circumferentially arranged with water-cooling wall a ringwise,It is provided with superheater a in described furnace chamber a,Evaporimeter a it is provided with in furnace chamber b,The top of boiler body a arranges drum a,Described cyclone combustion chamber、Furnace chamber a、Furnace chamber b is respectively positioned on below drum a,Described drum a is provided with carbonated drink import,Drum a passes through water separator separation steam water interface,The delivery port of drum a connects water-cooling wall a by pipeline respectively、The water inlet of evaporimeter a,For exporting the isolated water of water separator,Described water-cooling wall a、The venthole of evaporimeter a connects the air intake of drum a respectively by steam pipe,For the high-temperature steam that refluxes,The saturated vapor outlet of described drum a connects the air intake of superheater a by pipeline,For by the high-temperature steam input superheater a of backflow,The venthole output superheated steam of described superheater a;
nullDescribed boiler body b has cyclone dust removal room、Furnace chamber d,The lower end of described cyclone dust collectors connects with the second exhanst gas outlet,The upper end of cyclone dust removal room connects with the upper end of furnace chamber d,Described cyclone dust removal is indoor circumferentially arranged with water-cooling wall b ringwise,It is provided with superheater b in described furnace chamber d、Evaporimeter b,Described superheater b is positioned at the top of evaporimeter b,The top of boiler body b arranges drum b,Described cyclone dust removal room、Furnace chamber d is respectively positioned on below drum b,Described drum b is provided with carbonated drink import,Drum b passes through water separator separation steam water interface,The delivery port of drum b is by connecting water-cooling wall b by pipeline respectively、The water inlet of evaporimeter b,For exporting the isolated water of water separator,Described water-cooling wall b、The venthole of evaporimeter b connects the air intake of drum b respectively by steam pipe,For the high-temperature steam that refluxes,The saturated vapor outlet of described drum b connects the air intake of superheater b by pipeline,For by the high-temperature steam input superheater b of backflow,The venthole output superheated steam of described superheater b;
Described circulation air feed system includes the first blower fan, second blower fan, the inlet end of described first blower fan is connected with the lower end of furnace chamber d by pipeline, the outlet side of described first blower fan is connected with furnace chamber b by pipeline, the air inlet of described second blower fan and atmosphere, the gas outlet of described second blower fan connects the first manifold respectively, the house steward of the second manifold, the arm of described first manifold connects for air port with each air compartment below gasification furnace moving hearth and each secondary on gasification furnace respectively, the arm of described second manifold connects for air port with some combustion airs of each air compartment below incinerator moving hearth and cyclone combustion chamber respectively;
nullDescribed electricity generation system includes steam input pipe、Steam turbine and the generator being connected with turbine power,Described steam input pipe connects described superheater a by pipeline respectively、The venthole of superheater b,The output of steam input pipe connects the steam input of steam turbine,The steam output end of described steam turbine is sequentially connected with condenser by pipeline、Water pump、Low pressure vapor heater、Oxygen-eliminating device、Booster water pump、High pressure steam water heater,The input that is heated of described low pressure vapor heater is connected with water pump,Being connected with oxygen-eliminating device by hot output terminal of low pressure vapor heater,The input of oxygen-eliminating device is provided with moisturizing pipeline,The input that is heated of described high pressure steam water heater is connected with booster water pump,High pressure steam water heater by hot output terminal by pipeline connect drum a、The carbonated drink import of drum b,Described steam turbine is provided with the first steam and takes pipe、Second steam takes pipe and takes steam to the steam output end of steam turbine respectively,Described first steam takes the heating input of the output connection high pressure steam water heater of pipe,Described second steam takes the heating input of the output connection low pressure vapor heater of pipe.
Stoker fired grate formula refuse gasification the most according to claim 1 burns double boiler electricity generation system, it is characterized in that: also include high pressure vapour gas heat exchanger, low-pressure steam gas heat exchanger, the heated passage of described high pressure vapour gas heat exchanger is connected to the first steam by pipeline and takes pipe, between oxygen-eliminating device input, the heated passage of described low-pressure steam gas heat exchanger is connected to the second steam by pipeline and takes pipe, between oxygen-eliminating device input, low-pressure steam gas heat exchanger add the passage of heat, the heating Tandem of high pressure vapour gas heat exchanger is on the house steward of the first manifold, described high pressure vapour gas heat exchanger is positioned at the downstream of low-pressure steam gas heat exchanger.
Stoker fired grate formula refuse gasification the most according to claim 1 burns double boiler electricity generation system, it is characterised in that: described boiler body a has furnace chamber c, and the upper end of described furnace chamber c connects with the waste gas outlet of furnace chamber b upper end, and the lower end of furnace chamber c arranges Waste gas outlet.
Stoker fired grate formula refuse gasification the most according to claim 3 burns double boiler electricity generation system, it is characterized in that: in described furnace chamber c, be provided with air preheater, the outlet side of described second blower fan connects the air inlet of air preheater, and the gas outlet of air preheater connects the first manifold, the house steward of the second manifold.
Stoker fired grate formula refuse gasification the most according to claim 3 burns double boiler electricity generation system, it is characterized in that: in described furnace chamber c, be provided with economizer, the water inlet of described economizer connects with the delivery port of booster water pump, and the delivery port of described economizer is respectively by pipeline and drum a, the carbonated drink inlet communication of drum b.
Stoker fired grate formula refuse gasification the most according to claim 3 burns double boiler electricity generation system, it is characterized in that: the Waste gas outlet of described furnace chamber c connects flue gas purification system, aeration tower that described flue gas purification system includes being sequentially connected in series along discharge directions, deduster, air-introduced machine, chimney.
Stoker fired grate formula refuse gasification the most according to claim 1 burns double boiler electricity generation system, it is characterised in that: being provided with common slag notch below described furnace chamber a, furnace chamber b, this common slag notch connects with the burner hearth of gasification furnace.
Stoker fired grate formula refuse gasification the most according to claim 1 burns double boiler electricity generation system, it is characterised in that: the lower end of described cyclone combustion chamber is provided with the taper slag notch that radius from top to bottom diminishes, and this taper slag notch connects with the burner hearth of gasification furnace.
Stoker fired grate formula refuse gasification the most according to claim 1 burns double boiler electricity generation system, it is characterised in that: described smoke inlet, the 3rd exhanst gas outlet are positioned at the opposition side of cyclone combustion chamber circumferential wall;Described 3rd exhanst gas outlet is radially or tangentially arranged along cyclone combustion chamber circumferential wall.
Stoker fired grate formula refuse gasification the most according to claim 1 burns double boiler electricity generation system, it is characterised in that: described transition falls and is provided with isolating door to be opened/closed in slag section, and described isolating door is for cutting off gasification furnace, incinerator.
CN201521142637.0U 2015-12-31 2015-12-31 Mechanical stoker formula waste gasification burns dual -boiler power generation system Withdrawn - After Issue CN205560759U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105627320A (en) * 2015-12-31 2016-06-01 重庆科技学院 Mechanical grate type garbage gasification and incineration furnace and double-boiler power generation system

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105627320A (en) * 2015-12-31 2016-06-01 重庆科技学院 Mechanical grate type garbage gasification and incineration furnace and double-boiler power generation system
CN105627320B (en) * 2015-12-31 2017-10-31 重庆科技学院 Double boiler electricity generation system based on stoker fired grate formula refuse gasification incinerator

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