KR20030062436A - Method of processing biomass in coke dry quenching equipment - Google Patents

Abstract

In the method of processing a biomass in the coke dry extinguishing apparatus which cools the red coke provided with the prechamber, a biomass is thrown into the said prechamber while blowing air as needed.

Description

METHOD OF PROCESSING BIOMASS IN COKE DRY QUENCHING EQUIPMENT}

Responding to global warming issues includes the development and commercialization of new energy, the transition to low carbon dioxide-energy, the improvement of nuclear power ratios, the efficient and rational use of existing primary energy, and the use of previously unused or waste energy. Has been promoted.

In particular, biomass is carbon neutral and is a resource that should be actively used to replace oil and coal in the sense of achieving international commitments at the COP 3 (The 3rd session of the Conference Of the Party). It can be said.

Biomass is a generic term for biomass, and according to the FAO (Food and Agriculture Organization of the United Nations), the agricultural industry (straw, sugarcane, rice bran, vegetation, etc.), forestry industry (paper waste, lumber waste, lumber lumber) ,), Fuelwood forest, etc.), livestock system (livestock waste), fisheries system (fish processing residue), waste system (raw garbage, RDF (Refused Derived Fuel), garden water, construction Waste, sewage).

By the way, a coke oven is an external heat-heating furnace, and it is inevitably enlarged in order to improve thermal efficiency, and it became a very advanced facility as an energy recovery technology by the development of the energy saving technology of the past. The main method of coke sensible energy recovery technology is to use a coke dry fire extinguishing device (hereinafter referred to as `` CDQ ''), and the coke is cooled by a large amount of circulating gas (mostly nitrogen), Steam is generated by the heat obtained from the circulating gas, and the steam turbine is operated to recover the power.

As a method of treating biomass using this coke dry fire extinguishing device, a method of thermally decomposing biomass (sewage lumps) into a pre-chamber of a cooling tower of a coke dry fire extinguishing device is, for example, Japan. Patent No. 2789988 is disclosed.

The pyrolysis treatment method disclosed in Japanese Patent No. 2789988 utilizes sensible heat of red coke, thermally decomposes organic components of sewage lumps in a prechamber, and simultaneously performs water gasification reaction of water and red coke in sewage lumps. To produce combustible gases such as CO and H ₂ , guide the gases to the flue, and introduce combustion air into the flue to combust it.

In the year of the coke dry extinguishing system, a gravity settling solid gas separation mechanism called a dust catcher is provided to protect the boiler. The gravity sedimentation solid gas separation mechanism is settled by inertial force of solid, and when the gas flow is turbulent, the inertial force of solid is inhibited and the solid gas separation efficiency is remarkably lowered. The flow velocity is reduced as much as possible to keep the gas in a laminar flow state.

Therefore, it is extremely difficult to mix and combust combustible gas and combustion air in the flue while maintaining solid gas separation performance, and the residence time is also short. In addition, when the combustible gas is not completely burned and the combustible gas remains, corrosion components such as H ₂ S are generated to cause corrosion of the metal in the boiler and the lower part of the cooling tower, thereby causing serious equipment failure.

In waste-based biomass such as wood and sewage lumps, there is a carbon content called fixed carbon. Fixed carbon is carbon powder which does not gasify and becomes a residue as solid carbon when thermally decomposing a raw material in an oxygen-free atmosphere. Conventional biomass contains about 20% by weight of fixed carbon. When the biomass raw material is pyrolyzed in the prechamber of the coke dry fire extinguishing device, most of the fixed carbon content in the biomass is guided to the flue with the combustible gas as dust.

As described above, because the combustion efficiency is poor in the flue, the scattered dust (fixed carbon) is not burned, but is collected by the dust collector, and the calorific value due to the combustion of the fixed carbon powder is not effectively used. The calorific value of the fixed carbon component is very high because all of it is carbon, and accounts for about 40% of the calorific value of the biomass.

On the other hand, these days, there are more in the coke oven castration a request for energy saving in the improvement of the yield and coke, and related equipment as coke needed in the CO ₂ reduction. Even in heat recovery, only a low-temperature exhaust heat is difficult to recover, and there is no significant energy saving means or CO ₂ reduction means.

As one of these means, techniques for stabilizing gas components have been proposed by Japanese Patent Application Laid-Open Nos. 6-336588, 7-145377, and 7-242879. There is a problem that the product ratio with respect to the coke raw material is lowered by introducing air into the chamber.

[Configuration of Invention]

It is an object of the present invention to provide a method for treating biomass in a coke dry fire extinguishing apparatus that uses biomass and effectively uses the calorific value of biomass and reduces carbon use derived from fossil resources. .

In addition, the present invention improves the product ratio with respect to the coke feedstock, while energizing biomass having the characteristics of carbon neutrality (gas energy is used as fuel gas and power. Solid residue is used as fuel as coke). It is an object of the present invention to provide a method for treating biomass in a coke dry fire extinguishing device.

In addition, the present invention can effectively utilize a large amount of biomass without causing problems of equipment corrosion due to the residual of combustible gas, and also recovers and effectively utilizes fixed carbon of the injected biomass as heat, not as dust. An object of the present invention is to provide a method for treating biomass in a coke dry fire extinguishing device.

Further, the gist of the present invention to achieve the above object is as follows.

(1) A method of processing biomass in a coke dry fire extinguishing device for cooling a red coke having a prechamber, wherein the biomass is injected into the prechamber. Way.

(2) A method for treating biomass in a coke dry fire extinguishing device for cooling a red coke having a prechamber, wherein the biomass is introduced while introducing air into the prechamber. Method of treating biomass.

(3) The biomass in the coke dry fire extinguishing device according to (1) or (2), wherein biomass is injected onto the coke in the prechamber between the addition and the coke of the coke intermittently made into the prechamber. Treatment method.

(4) A method for treating biomass in the coke dry fire extinguishing device according to (1) or (2), wherein biomass is introduced into the prechamber at the same time as the coke made intermittently into the prechamber.

(5) The coke according to the above (3) or (4), wherein the biomass is introduced into the prechamber from a coke inlet provided in the upper portion of the coke dry fire extinguishing device or one or more inlets provided in the prechamber. Method of treating biomass in a dry fire extinguishing device.

(6) From the coke inlet provided in the upper part of the coke dry fire extinguishing device, or one or two or more inlets provided in the prechamber, biomass is introduced into the prechamber by air flow conveyance using nitrogen and / or circulating gas as the carrier gas. A method for treating biomass in the coke dry fire extinguishing device according to (3) or (4), which is added.

(7) The coke dry type according to the above (3) or (4), wherein the biomass is introduced into the prechamber by air flow conveyance using air as a carrier gas from one or two or more inlets provided in the prechamber. Method of treating biomass in fire extinguishing devices.

(8) A method of treating biomass with a coke dry extinguishing device for cooling a red coke having a prechamber, wherein the biomass is introduced into the prechamber, and the biomass is combustible gas and biomass in the prechamber. A method for treating biomass in a coke dry fire extinguishing device, characterized by pyrolysis using fixed carbon, blowing combustion air into the prechamber, and burning the biomass fixed carbon and combustible gas after thermal decomposition.

(9) The combustion air is blown into the annular duct provided in the prechamber and / or in the flue connected to the annular duct so as to combust the exhaust gas after the combustion of the biomass fixed carbon after the pyrolysis and the combustible gas once again. A method of treating biomass in a coke dry fire extinguishing device according to (8).

(10) A method for treating biomass in the coke dry fire extinguishing device according to (8) or (9), wherein water and / or steam is blown into the prechamber to control the temperature in the prechamber.

(11) A method of treating biomass in a coke dry extinguishing device for cooling a red coke having a prechamber, wherein the biomass is introduced into the prechamber, and the biomass is combustible gas and biomass in the prechamber. Coking dry fire extinguishing apparatus characterized by pyrolyzing with fixed carbon, blowing air for combustion in the annular duct installed in the prechamber and the flue connected to the annular duct, and burning the biomass fixed carbon and combustible gas after pyrolysis. Method of treating biomass in

(12) In the above (11), in order to burn the biomass fixed carbon and the combustible gas after the thermal decomposition, the blowing amount of the combustion air blown into the annular duct is controlled by the gas temperature in the annular duct. A method of treating biomass in the coke dry fire extinguishing device described.

(13) A method for treating biomass in a coke dry fire extinguishing device according to any one of (8) to (12), wherein the biomass is introduced into a prechamber from two or more biomass inlets.

(14) The above (1) to (5) and (5) characterized in that the biomass is dispersed and introduced into the prechamber by an extraction dispersing apparatus having a rotary blower provided near the biomass inlet. The method of treating biomass in the coke dry fire extinguishing device according to any one of 8) to (13).

(15) (1) to (5) and (8) to (5), wherein the biomass is dispersed and introduced into the prechamber by a chute having a changeable inclination angle and / or direction provided near the biomass inlet. The method of processing biomass in the coke dry fire extinguishing device according to any one of 13).

(16) Said (1) characterized in that charging of the biomass to the prechamber is stopped or the amount of charge is reduced while the lid of the coke inlet for injecting coke or the like into the prechamber is open. A method of treating biomass in the coke dry fire extinguishing device according to any one of (3) and (5) to (13).

The present invention relates to a method for treating biomass effectively used as a carbon source by treating biomass in a coke dry fire extinguishing device.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing an embodiment of input treatment of biomass according to the present invention.

Fig. 2 is a diagram showing another embodiment of input treatment of biomass according to the present invention.

3 is a view showing an operating mode of the coke dry fire extinguishing device.

4 is a diagram showing another embodiment of input treatment of biomass according to the present invention.

Fig. 5 is a diagram showing another embodiment of input treatment of biomass according to the present invention.

Fig. 6 is a diagram showing another embodiment of input treatment of biomass according to the present invention.

Fig. 7 is a diagram showing another embodiment of input treatment of biomass according to the present invention.

Fig. 8 is a diagram showing a cut-out dispersing apparatus provided near the biomass charging opening.

9 is a diagram showing a chute for biomass equipment installed in the vicinity of a biomass charging port.

In the present invention, the biomass of agriculture, wood, and wastes is targeted. In the present specification, the definition of biomass follows the definition of FAO. In other words, agricultural biomass refers to agricultural biomass in the FAO definition, and includes straw, sugar cane, rice bran plants, and the like. )

In addition, woody biomass refers to forestry biomass and a part of waste-based biomass in the FAO definitions, and includes paper waste, lumber waste, pruning lumber, new coal forest, garden water, and wood waste. The reason for using these is because the amount of moisture contained is low (9 to 50% by mass) and the calorific value on the basis of the moisture content is also high, so that the gas and solid energy more than the amount of heat necessary for dry distillation can be recovered only by the sensible coke sensible heat.

Regarding biomass other than agriculture and wood, it is not included in wood, but raw waste, RDF (Refused Derived Fuel), sewage, waste plastic, livestock waste as livestock, fishery processing as fisheries Residuals, etc., and basically, if the moisture content based on the moisture content is more than the heat of vaporization of water + the sensible heat rise of biomass itself + decomposition heat can be an effective energy source.

When biomass is added to the CDQ, volatiles are desorbed by the sensible heat of the glowing coke.

In the prechamber, air enters when coke is introduced, but air is present due to air injection for gas property optimization, and carbon (volatile matter, coke biomass) in the prechamber reacts with the air at the temperature of the coke that has been degraded. .

In the present invention, since the thermal decomposition (volatilization) reaction of the biomass introduced into the prechamber is fast, the biomass preferentially reacts with the air in place of the coke which has been reacted (burned) with the conventional air.

In addition, if the prechamber does not have the necessary amount of air for combustion, or if coke or biomass is introduced into the prechamber regularly, and the coke or biomass injected last time is cut off from the gas and air in the prechamber. The prechamber becomes a reducing atmosphere without oxygen at an early time. Under this atmosphere, the unreacted biomass is thermally decomposed (dry distilled), gas is generated, and solid carbonaceous solids are generated.

Biomass residue can be used as coke because it has excellent combustibility and flammability, and other properties are inferior to coke.

Therefore, the use of biomass increases the amount of coke by biomass-derived solids, and if the amount of coke required is constant, the amount of coke-derived coke can be reduced.

In order to clarify the operation and effect of the present invention, first, the normal operation example of CDQ is shown based on FIG. The coke at about 800 to 1000 ° C. manufactured in the coke oven is extruded into a bucket car by an extruder, conveyed to the CDQ facility, and then opened in the prechamber 2 by opening the upper lid 1 at the top of the CDQ facility. The part that was blocked by the upper lid (l) is the upper coke inlet.

The high temperature coke 3 entered into the prechamber is gradually cooled by the circulating gas 4 and cooled to about 200 ° C. Heat is recovered by the heat exchanger 5 (boiler) by a circulating gas containing nitrogen as a main component, and the steam turbine 6 is generated by the steam made of the heat.

At this time, air 9 (outside air) in the vicinity of the ring duct 8, which is the outlet of the gas after exiting the prechamber 2, does not cause residual volatile matter or powder coke to reach the heat exchanger and cause problems of coking or heat transfer inhibition. ), And it is completely burned.

In addition, air is introduced into the prechamber 2 from an air inlet (see Fig. 2) provided in the prechamber 2, but the air is carbon powder (volatile matter generated from coke, powdered coke, bulk) in the prechamber 2. Reacts with coke) to produce carbon dioxide and water.

Accordingly, the amount of air introduced from the air inlet is not particularly defined, and may be any amount of air required for proper gas properties. The produced carbon dioxide or water also reacts with the surrounding carbon powder to become carbon monoxide or hydrogen, joins with the circulating gas 4, completely burns in the ring duct 8, and is then recovered by the heat exchanger 5 as a hot gas. On the way, the coke movement was shown by the thick line arrow, and the gas movement was shown by the thin line arrow.

1) The present invention for treating biomass will be described.

1 shows Biomass Input Example-1. Since coke feeding is batch feeding performed every few minutes to several ten minutes, biomass is thrown in between the feeding and feeding of coke which is easy to set the timing of feeding. Between the coke input and the input, it refers to the point from which the coke disappeared in the bucket car at the time of coke input of a certain amount, and from the time of opening of the lower part of the bucket car at the time of coke input of the next quota.

The injection position of biomass may be input from the coke input port 10, and the biomass input port 11 may be newly installed. The feeding method is a method of dropping by self-weight in a cutout supply device such as a screw feeder or a table feeder at each feeding position, using a part of the circulating gas 4 or nitrogen gas, or air to the air inlet 7 There is a method of returning and blowing.

In the case of the circulating gas, the gas temperature is lowered, for example, a part of the gas of the circulating blower is branched to the biomass inlet 10 and used in combination with a cutout supply facility such as a table feeder. In the case of nitrogen gas, nitrogen is drawn from the outside to the biomass inlet 10 through a pipe, and used in combination with a cutout supply facility.

Since the superiority of the airflow conveyance can expand the dispersion range with a smaller number of input ports, the uniformity of the layer thickness is increased than in the case of falling of the weight (dispersibility is improved at the same time as the coke input described later). In addition, by using the circulating gas 4 for the carrier gas, the problem of using nitrogen can be minimized.

Regarding the loading amount, if it is put between the coke input and the input, the conditions from the heat transfer (remaining layered in the CDQ and receiving heat from the upper and lower red coke) in the CDQ transit time are allowed to react all biomass within the CDQ passage time. It is preferable that it is a quantity to maintain below thickness thickness. If it is described later and added at the same time, there is no restriction due to the thickness, and it can be added up to the gas side temperature decrease allowable range (heat exchange efficiency decrease allowable limit) of the heat exchanger 5 for power generation described later.

The upper limit of the input amount is about 40% of the coke amount in consideration of the conditions under which unreacted biomass is mixed in the coke and is not discharged from the CDQ, that is, the biomass layer thickness and heat transfer conditions where the biomass drying and carbonization proceeds sufficiently in the CDQ. It can be added up to (depending on the moisture) until the appropriate dose is set based on this relationship. There is no lower limit on input.

When injected from the biomass inlet 11, in order to reduce the amount of unreacted biomass, it is preferable to secure two or more inlets for the purpose of depositing in the prechamber as uniformly and layered as possible. Usually, about 4 to 16 places are set. The coke layer 12 descends the CDQ while being alternately sandwiched with the injected biomass layer 13 and is sequentially discharged from the bottom.

Since the biomass introduced into the prechamber 2 partially covers the coke layer and reacts preferentially with the input air, the chance of contact between the air from the air inlet 7 and the coke is reduced, and the amount of combustion of the coke by the input air is reduced. Reduce. When the generated carbon dioxide or water vapor passes through the coke layer 12, the same reaction occurs as in the prior art to generate carbon monoxide or hydrogen.

2 shows Biomass Input Example-2. The difference from the feeding example 1 is that the feeding point and the type of feeding method are the same as those of the feeding example 1 by simultaneously feeding the coke. The term " simultaneous feeding " means when a certain amount of coke drops from the bucket. Means that the biomass input is terminated from the time of dropping to the end of the drop, and the same time period is used to increase the contact area of the biomass with air by mixing with the coke on average by using diffusion during the coke drop. In order to preferentially react with air as compared with, the reaction between coke and air can be suppressed.

In the middle, it is modeled as the coke and biomass mixed layer 14. Next, an Example is shown.

Example 1

In Table 1, the result of having injected and processed biomass according to the invention of Claim 1 is shown. The result of letting the biomass fall into the weight from the coke inlet between the coke inlet and the inlet is described in the column of "Result-1 Using This Method", and the coke inlet and the biomass inlet (8 places) The result at the time of carrying out nitrogen conveyance from the above was described in the column of "Result-2 using this method."

The sample used was a wood-based biomass, and a water 15% one was used. In "Result using this method-1" in which biomass was added between the coke input and the input, the average thickness was about 120 mm. In addition, for the result comparison, the input amount in "Result-2 using this method" was made similar to the input amount in "Result-1 using this method".

With increase of coke recovery, we assume biomass effective use index. The coke recovery rate is the ratio of the coke mass discharged from the lower part to the coke mass injected from the upper part of the dry fire extinguishing device, and the biomass-derived carbide mass is also added to the discharged coke mass.

Results of using this law-1 Result of using this law-2 Comparative example (no biomass input) Input coke mass [kg] α 1000 1000 1000 Input coke mass [kg] β 986 988 974 Coke Recovery [-] β / α 0.986 0.988 0.974 Biomass input [kg] 50 50 0 Steam generation amount [kg] 197 191 0 (incremental)

By adding biomass corresponding to 5% of the amount of coke, the recovery as coke was 1.2% (refer to the column of `` Result-1 of the method-1 '') and 1.4% (Result-2 of the method). ). As for the feeding method, the coke recovery was high in the case of mixing uniformly (in the case of "2 using this method").

From this result, if the coke production is made constant, the coke of the recovery rate improvement can be reduced (for example, 1.4% of the result-2 using this method), which can reduce the coke raw material coal. It means. In addition, there was also little variation in the amount of gas due to biomass input, and there was no problem in the operation.

Example 2

In Table 2, the result of processing by inputting biomass according to the invention of Claim 2 is shown. The results when the biomass is dropped into the coke inlet by weight between the coke inlet and the inlet are described in `` Results-1 Using This Method ''. Then, the coke is injected and the nitrogen from the biomass inlet (8 locations). The result at the time of carrying out conveyance was shown to the "result -2 using this method" column.

The sample used was wood-based biomass, and a water 15% one was used. In "Result using this method-1" in which biomass was added between the coke input and the input, the biomass layer was calculated to have an average thickness of about 120 mm. In addition, for the comparison of the results, the input amount in "Result-2 using this method" was made similar to the input amount in "Result-1 using this method". The increase in coke recovery is taken as an indicator of effective use of biomass.

The coke recovery rate is the ratio of the coke mass discharged from the bottom to the coke mass injected from the top of the dry fire extinguishing apparatus, and the coke mass from which the biomass-derived carbide mass is discharged is added. The amount of discharged coke discharged is the sum of the mass of coke generated when the coke is strong in the CDQ and the amount of biomass residue (carbide) discharged from the lower part of the CDQ, and is the external water of the discharged coke mass.

Results of using this law-1 Result of using this law-2 Comparative example (no biomass input) Input coke mass [kg] α 1000 1000 1000 Input coke mass [kg] β 967 970 960 Coke Recovery [-] β / α 0.967 0.970 0.960 Biomass input [kg] 50 50 0 Discharged coke amount [kg] 16 13 12 Steam generation amount [kg] 200 195 0 (incremental)

It can be seen that the coke recovery is improved by the biomass input. By adding 5% of the biomass of coke, the recovery as coke was 0.7% (refer to column of `` result-1 using this method '') and 1.0% (columns of `` result-2 using this method ''), respectively. Rise). As for the feeding method, the coke recovery was high in the case of mixing uniformly (in the case of "2 using this method").

In addition, the decrease in the amount of discharged coke and the same amount of discharged coke decreased as the part where the air and the bulk coke were burned by direct contact increased the amount of contact between the biomass and the air by the uniform dispersion of the biomass, Moreover, in order to react with air preferentially compared with coke, it is thought that the powdery coke which reacts easily by suppressing the reaction of block coke and air also advanced.

From these results, when the coke production rate is made constant, the recovery rate is improved, so that petroleum-derived coke can be reduced (for example, 1.0% of the result-2 using the present method). It means that coal can be reduced. In addition, the amount of gas fluctuations due to biomass input was also small with respect to the operation, and there was no problem in the operation at all.

2) Next, the other this invention which processes a biomass is demonstrated.

(1) input treatment sun 1

4 is a diagram showing another input and treatment aspect of biomass. In the coke dry fire extinguishing device, the coke 15 is opened from the coke inlet 17 at the top of the cooling tower 16, the lid 17a is opened, and then charged into the prechamber 18 to lower the coke 15. The inert gas as the cooling gas supplied from the cooling gas pipe 28 is exchanged with the red coke 15 to recover the heat of the red coke 15 from the annular duct 19 via the flue 24 from the annular duct 19. After introducing into (27) and exchanging heat, it is conveyed by the circulation blower 29 to the lower part of the cooling tower 16, and circulated. The cooled coke is discharged from the coke outlet 20 at the bottom of the cooling tower 16.

The prechamber 18 is provided with a biomass charging port 21 and a combustion air inlet 22. In the biomass, the wood is coarsely pulverized by a hammer crusher or the like (not shown) to about 10 to 50 mm and continuously charged from the biomass charging port 21.

In the flue 24, a dust collector 26 for collecting dust separated by the combustion air inlet 23, the collision wall 25, and the collision wall 25 is provided. In addition, the pipe between the boiler 27 and the circulation blower 29 is provided with a cyclone 30 for dust separation.

In this coke dry fire extinguishing device, biomass is processed as follows.

The biomass charged into the prechamber 18 from the biomass charging port 21 is thermally decomposed into combustible gas and biomass fixed carbon by the sensible heat of the red coke 15. The combustible gas produced by pyrolysis is burned in the prechamber 18 by the combustion air continuously introduced from the combustion air inlet 22. Combustion air introduces the amount of air necessary for complete combustion of the charged biomass (hereinafter referred to as the required amount of air).

It burns with combustion air as with biomass fixed carbon produced by pyrolysis. Since the biomass-fixed carbon has a significantly lower strength than the coke, the biomass fixed carbon differentiates in the packed layer of the red coke 15. The differentiated biomass-fixed carbon has a relatively large specific surface area compared to the red coke 15 and is combustible because it is made porous by pyrolysis.

As a result, the glowing coke 15 is first burned prior to burning. In addition, the residence time in the prechamber 18 is much longer than the residence time in the flue 24, and since the gas becomes turbulent by the packed bed of the glowing coke 15, it is surely mixed and combustion is efficient. Is done.

The exhaust gas after combustion has contained a small amount of combustibles by the equilibrium reaction by the moisture, and is led to the flue 24 via the annular duct 19. In the flue 24, combustion air is continuously introduced again from the combustion air inlet 23. Since the combustible powder is a small amount, it is completely burned even during a short residence time, and is completely burned until the exhaust gas reaches the collision wall 28 installed in the flue 24, and the unburned biomass fixed carbon collides. There is no collision with the wall 25.

In this way, all of the fixed carbon in the biomass raw material is burned and converted into flue-gas sensible heat, and is effectively heat-exchanged in the boiler 27 to recover heat. This makes it possible to treat a large amount of biomass in a coke dry fire extinguishing device, to recover the amount of heat possessed by the biomass as heat and effectively use it.

At this time, the combustion air for burning the biomass fixed carbon after pyrolysis and the flue gas after burning the flammable gas once again may be introduced into the flue 24 as described above, or may be introduced into the annular duct 19. You may introduce into both.

On the other hand, when the lid 17a is opened at the time of charging the red coke, a large amount of air flows in from the coke charging hole 17 of the cooling tower 16. Therefore, there is a risk of explosion if the flammable gas is filled in the prechamber 18.

Since biomass is more than 80% volatile, a large amount of gas is released. When the total amount of the discharged gas amount and the amount of air introduced from the coke charging port 17 exceeds the allowable amount of the circulation blower 29, the cooling tower 16 government becomes a static pressure and gas leaks out from the coke charging port 17.

Therefore, in processing the biomass, while the lid 17a of the coke charging opening 17 is opened, charging of the biomass into the prechamber 18 is stopped or the amount of charging is reduced. Thereby, gas leakage and the like can be avoided without enhancing the capability of the circulation blower 29.

(2) input treatment solar 2

Fig. 5 is a diagram showing another input embodiment of the present invention. The prechamber 18 of the coke dry fire extinguishing device shown in FIG. 5 is provided with a water and / or vapor inlet 31 in addition to the biomass charging port 21 and the combustion air inlet 22. .

As described above, when the biomass is burned in a large amount in the prechamber 18 and used effectively, a temperature rise occurs in the prechamber 18. This rise in temperature is also a problem for the device, but causes a serious problem of melting of the ashes.

In general, the melting point of ash contained in biomass is lower than that of coal ash. For this reason, when burning at high temperatures, the ashes scatter in a semi-melt state, and adhere to walls, heat transfer tubes, and the like, causing damage. Therefore, it is necessary to manage combustion temperature.

At this time, for temperature control in the case where a large amount of biomass is burned by the prechamber 18, water and / or steam are blown in from the inlet port 31 as necessary to control the temperature. The blown water and / or steam causes the carbon powder and the water gasification reaction (endothermic reaction) in the prechamber 18 to cool the prechamber 18.

By this temperature control, it is possible to utilize biomass as effectively as possible without causing ash melting, generating unburned gas, and discharging recoverable heat to the outside of the system as dust.

(3) input treatment solar 3

Fig. 6 is a diagram showing another input embodiment of the present invention. In the coke dry fire extinguishing apparatus shown in FIG. 6, the prechamber 18 does not make the combustion air inlet 32 for introducing the combustion air which burns biomass fixed carbon and combustible gas after pyrolysis, and annular duct (19) and year (24).

In the combustion of biomass fixed carbon generated by pyrolysis of biomass, the residence time is too short only by introducing combustion air into the flue 24, and it is difficult to completely burn it. Therefore, in this embodiment, combustion air is introduced into the annular duct 19, and the time for burning biomass fixed carbon by the combustion air is extended.

In that sense, it is preferable to introduce the entire amount of the required air amount from the annular duct 19. However, when a large amount of combustion air is introduced into the annular duct 19, the temperature of the annular duct 19 is increased by the combustion heat. As mentioned above, melting and adhesion of biomass ash occur as it rises remarkably and the temperature rise in the annular duct 19 is carried out.

In addition, since the inner wall of the annular duct 19 generally has a lead and single-piece structure, there is no strength at high temperatures, so it is necessary to avoid local high temperatures, and the temperature of the inner wall of the annular duct 19 needs to be maintained at or below an allowable temperature.

Therefore, in this embodiment, the gas temperature in the annular duct 19 is measured by a temperature sensor (not shown), and the combustion from the annular duct 19 is not carried out so that the gas temperature may not exceed an allowable temperature (for example, 1000 degreeC). The blowing amount of the air is controlled so that the remaining amount of the required air amount is blown into the flue 24.

This method of blowing air for combustion makes it possible to prevent a small amount of coke combustion generated when air is introduced into the prechamber 18, and does not cause loss of coke to be a product, and does not cause ash melting. It is possible to utilize the biomass as effectively as possible without generating gas and discharging recoverable heat to dust outside the system.

(4) input treatment solar 4

Figure 7 illustrates another input aspect of the present invention.

When the throughput of the biomass is increased, the heat transfer efficiency is lowered and the temperature of the biomass does not rise, so that a portion where thermal decomposition is not reliably pyrolyzed and burned does not occur. In addition, the part becomes low temperature, and when the part exists near the inner wall of the cooling tower 16, it also adversely affects the brick which comprises an inner wall.

One of the factors that lower the heat transfer efficiency is the filling thickness of the biomass. That is, if a locally thick portion exists in the filling thickness, the temperature is lowered due to the thermal insulation effect of the biomass, and the thermal efficiency of the portion is lowered, thereby lowering the thermal efficiency. Therefore, in order to increase the throughput of the biomass without lowering the thermal efficiency, it is necessary to charge the biomass into the prechamber 18 evenly. Therefore, in the coke dry fire extinguishing device of FIG. 7, two or more biomass charging holes 21 are made, thereby dispersing the biomass in the prechamber 18, so that charging can be carried out as evenly as possible.

In addition, as shown in FIG. 8, when the cutting-dispersion apparatus 33 equipped with the rotary blades is installed in the vicinity of the biomass charging opening 21, the biomass can be charged evenly in the prechamber 18 more uniformly. have.

In addition, as shown in FIG. 9, the biomass equipment chute 34 in which the inclination angle and / or direction can be changed is provided in the vicinity of the biomass charging opening 21 to further equalize the biomass in the prechamber 18. I can charge it.

In the input treatment aspect of the present invention, since the combustion gas for burning the biomass fixed carbon and the combustible gas after pyrolysis is blown into the prechamber, most of the unburned gas is combusted in the prechamber, and the residual of the combustible gas Biomass can be effectively used in large quantities without causing the problem of corrosion of the equipment.

In addition, since the biomass fixed carbon is first burned in the prechamber by the combustion air, the fixed carbon of the charged biomass can be recovered as heat without being recovered as dust and can be effectively used.

Further, by blowing combustion air into the annular duct and / or the flue, it is possible to completely burn the biomass fixed carbon, and it is possible to recover and effectively use the amount of heat possessed by the biomass as heat.

In addition, the temperature rise in the prechamber can be suppressed by blowing temperature control water and / or vapor into the prechamber, and a large amount of biomass can be caused without melting of ash in the biomass having a low melting point, without causing any damage. The mass can be processed, and the amount of heat possessed by the biomass can be recovered as the total amount and the heat, thereby making effective use of the mass.

In addition, as a method for treating biomass in the coke dry fire extinguishing apparatus of the present invention, biomass fixed carbon is completely burned by blowing biomass fixed carbon after pyrolysis and air for combustion to burn flammable gas into an annular duct and flue. It becomes possible to do this, and it becomes possible to collect | recover and use effectively the quantity of heat which biomass possesses as whole quantity and heat.

When the combustion air is blown into the annular duct, the amount of combustion air to the annular duct is controlled so that the annular duct temperature does not exceed the allowable temperature, and the remaining amount of the required air is blown from the year to suppress the combustion of coke generated in the prechamber. The amount of heat that the biomass possesses can be prevented and the large amount of biomass can be processed without causing damage such as adhesion by melting ash in biomass having a low melting point without causing loss of coke to be a product. It is possible to recover as a whole quantity and heat and to use effectively.

In addition, charging of the biomass into the prechamber from two or more charging openings, or providing a cutting dispersing device having a rotary blade near the biomass charging opening, or inclining angle and / or direction near the biomass charging opening By installing this changeable biomass charging chute, the biomass can be dispersed in the prechamber and loaded evenly, preventing the temperature drop due to the thermal insulation effect of the biomass and causing adverse effects on the refractory due to temperature fluctuations. It does not cause a decrease in thermal efficiency due to insufficient thermal decomposition and combustion of the biomass, and it is possible to process a large amount of biomass, and to recover and effectively use the amount of heat possessed by the biomass as heat and heat. do.

Further, gas leakage can be avoided by stopping the charging of the biomass into the prechamber or reducing the amount of charging when the lid is opened, such as when charging the red coke.

By injecting and treating the biomass into the coke dry fire extinguishing device, the input coke and raw material coal can be reduced without affecting the operation of the coke dry fire extinguishing device. In addition, the biomass-derived volatiles generated in the coke dry fire extinguishing device can recover the sensible and combustion heat from the boiler of the coke dry fire extinguishing device. Therefore, biomass can be effectively used in a coke dry fire extinguishing device.

Claims (16)

A method of processing biomass in a coke dry fire extinguishing device for cooling a red coke having a prechamber, wherein the biomass is injected into the prechamber. A method of processing biomass in a coke dry fire extinguishing device for cooling a red coke provided with a prechamber, wherein the biomass is introduced while introducing air into the prechamber. Treatment method. The method according to claim 1 or 2, A method of processing biomass in a coke dry fire extinguishing device, characterized in that biomass is injected onto coke in a prechamber between the coke input and the intermittent coke formed in the prechamber. The method according to claim 1 or 2, A method of processing biomass in a coke dry fire extinguishing device, characterized in that biomass is introduced into a prechamber at the same time as the coke is intermittently made in the prechamber. The method according to claim 3 or 4, A method of processing biomass in a coke dry fire extinguishing device, characterized in that biomass is introduced into a prechamber from a coke inlet provided in an upper portion of the coke dry fire extinguishing device or one or more inlets provided in a prechamber. The method according to claim 3 or 4, Biomass is introduced into the prechamber by air flow conveyance using nitrogen and / or circulating gas as the carrier gas from the coke inlet provided in the upper portion of the coke dry fire extinguishing device, or one or two or more inlets provided in the prechamber. A method of treating biomass in a coke dry fire extinguishing device, characterized in that. The method according to claim 3 or 4, A biomass treatment method in a coke dry fire extinguishing device, characterized in that the biomass is introduced into the prechamber by airflow conveying air as a carrier gas from one or more inlets provided in the prechamber. A method of processing biomass in a coke dry extinguishing device for cooling a red coke having a prechamber, wherein the biomass is introduced into the prechamber, and the biomass is converted into combustible gas and biomass fixed carbon in the prechamber. A method of treating biomass in a coke dry fire extinguishing device, characterized by pyrolysis, and blowing combustion air into the prechamber to combust the biomass fixed carbon and combustible gas after pyrolysis. The method of claim 8, The combustion air is blown into the annular duct provided in the prechamber and / or the flue connected to the annular duct so as to burn the exhaust gas after the biomass fixed carbon after the thermal decomposition and the combustible gas are burned once again. A method of treating biomass in a coke dry fire extinguishing device. The method according to claim 8 or 9, And injecting water and / or steam to control the temperature in the prechamber into the prechamber. A method of treating biomass with a coke dry extinguishing device for cooling a red coke having a prechamber, wherein the biomass is introduced into the prechamber, and the biomass is combusted with combustible gas and biomass fixed carbon in the prechamber. Biomass in the coke dry fire extinguishing apparatus, characterized by pyrolysis, and blowing combustion air into the annular duct installed in the prechamber and the flue connected to the annular duct to combust the biomass fixed carbon and combustible gas after pyrolysis. Treatment method. The method of claim 11, In order to combust the biomass fixed carbon and the combustible gas after the thermal decomposition, the amount of blowing air blown into the annular duct is controlled by the gas temperature in the annular duct. Treatment method. The method according to any one of claims 8 to 12, The biomass treatment method in a coke dry fire extinguishing device, characterized in that the biomass is introduced into the prechamber from two or more biomass inlet. The method according to any one of claims 1 to 5 and 8 to 13, The biomass treatment method in the coke dry fire extinguishing apparatus characterized by dispersing and injecting the biomass into the prechamber by a cutting-out dispersing device having a rotary blower provided near the biomass inlet. The method according to any one of claims 1 to 5 and 8 to 13, The biomass treatment method in a coke dry fire extinguishing device, characterized in that the biomass is dispersed and introduced into the prechamber by a chute having an inclination angle and / or a direction that can be changed in the vicinity of the biomass inlet. The method according to any one of claims 1 to 3 and 5 to 13, Coking dry fire extinguishing characterized in that the charging of the waste-based biomass into the prechamber is stopped or the amount of charging is reduced while the lid of the coke inlet for injecting the coke or the like into the prechamber is opened. Method of treating biomass in an apparatus.