JP5226579B2 - Operation method of gasification melting furnace - Google Patents

Description

  The present invention relates to a method for operating a gasification melting furnace for gasifying and melting waste such as municipal waste, and more particularly to a method industrially useful as a technique for adjusting the basicity of slag discharged from the melting furnace.

  In the past, organic waste such as municipal waste was mainly incinerated in incinerators, and the ash was mainly disposed of in landfills. However, in recent years, atmospheric emissions of harmful substances such as dioxins Gasification and melting technology has attracted attention as an effective means for promoting the detoxification of these harmful substances and the volume reduction of ash due to the impact on the environment caused by the tightness of landfills and landfills. It is rapidly spreading as a standard process.

  This gasification and melting technology is operated and operated in a gasification and melting furnace that integrates a gasification furnace and a melting furnace. Gasification and gasification is performed while partially combusting organic waste such as municipal waste in the gasification furnace. The combustible gas and ash generated by this gasification are guided to the melting furnace, the combustible gas is burned in the melting furnace, the ash is melted by the combustion heat, and the slag generated by the melting is discharged out of the furnace. Is cooled and solidified.

  By the way, in order to perform a stable and efficient operation of the gasification melting furnace, it is necessary to sufficiently ensure the fluidity of the molten slag discharged from the melting furnace (hereinafter simply referred to as slag). This is because if the slag fluidity decreases, the discharge from the melting furnace will not be performed smoothly and the productivity will be hindered. This is because a situation in which it is not possible to occur is also generated.

As is well known, slag basicity (CaO / SiO ₂ ) can be cited as a large operating factor that affects the fluidity of this slag. The slag melting point depends on the slag basicity. When the slag basicity is 0.6 to 0.8, the melting point is the lowest (1200 ° C to 1250 ° C). When the slag basicity is 0.6 or less, the melting point increases as the basicity decreases, and the slag basicity is 0. The melting point is higher than 1350 ° C. In addition, when the slag basicity is 0.8 or more, the melting point increases as the basicity increases, and when the slag basicity is 1.0, the melting point is 1250 ° C to 1300 ° C and the basicity exceeds 1.2. The melting point exceeds 1300 ° C. Regardless of the slag basicity, when the furnace temperature of the melting furnace is higher by 50 ° C. or more than the slag melt flow temperature, the slag is sufficiently melted and its fluidity can be improved relatively easily. However, in order to always discharge slag smoothly, for example, a high-temperature operation in which the furnace temperature is 1350 ° C. or higher must be continuously performed. It will have disadvantages such as severe damage to refractories, and it is not preferred.

  On the other hand, if the operation is performed to maintain the slag basicity within a certain range (slag basicity 0.6 to 0.8), the fluidity can be ensured without any operational disadvantage to increase the temperature of the slag. And stable and efficient operation can be continued. This slag basicity deviates from the preset appropriate range due to the influence of the type of waste to be treated and changes in properties even when the operation is continued with the gasification melting furnace operating conditions kept constant. Therefore, the slag discharged is periodically sampled and analyzed for basicity.If the value is outside the set range, a basicity adjuster is conventionally supplied to the melting furnace. Generally, adjustment to the setting range is performed.

  However, conventional basicity adjusting agents used when adjusting the basicity of slag are slaked lime, quicklime or calcium carbonate as a high basicity adjusting agent, and dredged sand as a low basicity adjusting agent. Is also a commercially available drug, which is a purchased product (product), and the large amount of use is a factor that increases the processing cost.

  In addition, conventionally, a component adjusting agent (basicity adjusting agent) such as lime or meteorite is added to the fly ash discharged from the gasification melting furnace to adjust the basicity to 0.5 to 1.5 and the tuyere A technique for blowing in is also proposed (see Patent Document 1). However, this conventional technology still uses purchased lime and meteorite as the main basicity adjuster, and the fly ash itself is not used as a slag basicity adjuster. The effect on reduction is small.

Japanese Patent Laid-Open No. 11-101430

  In view of the above-described conventional technical background and its problems, the present invention adjusts and maintains the basicity of the slag discharged from the melting furnace of the gasification melting furnace to a target setting range to ensure its fluidity. This was achieved by minimizing the amount of purchased basicity modifier and providing a stable and efficient operation method for gasification and melting furnaces at low processing costs. is there.

  SUMMARY An advantage of some aspects of the invention is to solve the above-described problems, and the gist and features of each invention described below are as follows.

1. The waste is pyrolyzed while partially combusting in a pyrolysis furnace, the combustible gas and ash generated by this pyrolysis are guided to the melting furnace, the combustible gas is burned in the melting furnace, and the ash is melted by the combustion heat. In the operation method of the gasification melting furnace in which slag generated by melting is discharged outside the furnace, the basicity of the slag is monitored, and when the basicity is out of the set range, first, the operation of the gasification melting furnace If the primary adjustment is performed using the primary basicity regulator that is generated in the system, and the product does not return to the set range after a certain period of time, the secondary basicity regulator that is purchased outside the system The basic adjustment of the slag is maintained within the set range by performing the next adjustment, and when the basicity of the slag deviates to the lower side than the set range, the primary high basicity adjuster is used as the primary basicity adjuster, and Higher than setting range In the case where the primary basicity adjusting agent is used as the primary basicity adjusting agent, the primary high basicity adjusting agent is primarily adjusted, and the primary high basicity adjusting agent is discharged from the melting furnace by the operation of the gasification melting furnace. A gasification melting furnace operating method, characterized in that the fly ash contains a component, and the primary low basicity regulator is an incombustible material containing a SiO ₂ component discharged from the gasification furnace by operation of the gasification melting furnace. .

2 . If the basicity of the slag does not return to the setting range after the primary adjustment by the primary basicity adjuster and does not return to the setting range, the secondary high basicity adjuster as the secondary basicity adjuster and the primary adjustment 2. The gasification and melting furnace according to 1, wherein secondary adjustment is performed with a secondary low basicity adjusting agent as a secondary basicity adjusting agent when the settling range does not return to the higher range afterward. how to drive.

3 . The secondary high basicity adjusting agent is at least one selected from slaked lime, quick lime, or calcium carbonate, which is an out-of-system purchase, and the secondary low basicity adjustment agent is cinnabar which is an out-of-system purchase. The operation method of the gasification melting furnace of 2 .

4 . The method for operating a gasification melting furnace according to any one of 1 to 3, wherein the incombustible material is discharged from a fluidized bed gasification furnace.

5 . The method for operating a gasification melting furnace according to any one of claims 1 to 4, wherein the incombustible material has a particle size adjusted to 0.1 to 3 mm.

6 . Supply the primary adjustment by the primary basicity adjuster or the secondary adjustment by the secondary basicity adjuster to the basicity of the slag, or supply the primary basicity adjuster or the secondary basicity adjuster to the melting furnace or increase the supply amount. The operation method of the gasification melting furnace in any one of 1-5 characterized by performing.

7 . 6. The gasification and melting according to 6 , wherein when the primary basicity adjusting agent is fly ash, the supply amount thereof is 50% or less of the total amount of fly ash discharged and recovered from the melting furnace. How to operate the furnace.

8 . 1-7 The method of any operating gasification and melting furnace according to of 0.5 to 0.9 the setting range of basicity of the slag.

  According to the present invention, the basicity of the slag in the gasification and melting furnace is effectively utilized as the slag basicity adjusting agent in the gasification and melting process system, such as fly ash and incombustibles generated from the gasification and melting process system. It can be adjusted, maintained, and its fluidity can be ensured. Therefore, a stable and efficient gasification and melting furnace can be used in a state where the amount of use of the conventional basicity adjusting agent, which is an expensive purchase, is greatly reduced. It becomes possible to drive.

  In addition, by using fly ash, non-combustibles, etc. in the gasification and melting process system as a basicity regulator, the amount of waste discharged outside the system can be reduced, and the cost required for final disposal Can also contribute to environmental measures.

The schematic diagram which shows the structure of the gasification melting furnace installation for demonstrating embodiment of this invention.

  Hereinafter, the present invention will be described in detail including embodiments thereof. First, the technical concept and characteristics of the present invention will be described.

  As a basic means for solving the above-mentioned problems, the present inventors have conceived whether the waste generated in the gasification and melting process can be used as a basicity adjusting agent for adjusting the basicity of slag. As a result of various studies based on this idea, incombustibles discharged from the gasification furnace as a low basicity adjusting agent and fly ash discharged from the melting furnace as a high basicity adjusting agent are practical. It came to the conclusion that it is also effective.

That is, the incombustible material discharged from the gasification furnace, particularly the incombustible material discharged from the fluidized bed type gasification furnace, is discharged together with dredged sand (SiO ₂ ) which is a fluidized medium of the gasification furnace. Most of the cinnabar is discharged and classified and separated from coarse materials including metal pieces such as iron and Al, and those having an appropriate particle size are circulated and used as a fluidizing medium for the gasifier. In addition to metal pieces etc., rubble etc. are mixed in coarse materials, and if the metal pieces are sorted, this crushed sand or rubble containing SiO ₂ is crushed to adjust the particle size and used as a low basicity adjusting agent. It is advantageous in terms of cost. According to the investigation and analysis of the non-combustible material after metal piece sorting (hereinafter sometimes referred to as the remaining non-combustible material), it actually contains a lot of SiO ₂ and is almost inferior to that of the purchased product as a low basicity adjuster. It was found that the basicity of the slag can be adjusted.

  Further, fly ash discharged from the melting furnace is accompanied in the melting furnace exhaust gas, and a considerable amount is recovered by a dust collector such as a bag filter. The recovered fly ash undergoes exhaust gas purification treatment for removing acidic gas components such as SOX and HCL by bringing chemicals such as quick lime and slaked lime into contact with the exhaust gas for purification of exhaust gas. CaO-based components derived from these drugs are also included in the fly ash. If this fly ash is used as a high basicity adjusting agent, it is advantageous in terms of cost as in the case of the incombustible material. According to the investigation and analysis of this fly ash, it has been found that CaO is actually contained in an amount of 15 to 40%, has a high basicity, and can be sufficiently used as a high basicity adjusting agent.

  However, this fly ash contains a small amount of heavy metals such as heavy metals (Pb, etc.). Continuing to use these in large quantities will eventually increase the concentration of slag and effectively use slag. There is also a risk that the content standard (for example, Pb <150 mg / kg) of the standard JIS A5032 (general waste, sewage sludge, or road slag obtained by melting and solidifying those wastes) may not be satisfied. Therefore, while confirming that there is no concentration of heavy metals to slag, it should be used after limiting the amount of fly ash used so as not to exceed the emission standard.

  Therefore, the present inventors actively use the emissions in the gasification and melting process system that does not bear the incombustible material cost as the main basicity adjusting agent, and the conventional basicity adjusting agent requiring cost is secondary. As a technical idea, the present invention has been completed by adjusting and maintaining the slag basicity within a target setting range while minimizing the amount used.

  The basic feature of the present invention is to monitor the basicity of the slag discharged from the melting furnace, and when it is out of the set range, first, the primary adjustment is performed with the primary basicity adjusting agent, and a certain period of time has passed. If it does not return to the set range afterward, the basic adjustment of the slag is maintained within the set range by performing secondary adjustment with a secondary basicity adjuster.

  That is, in the present invention, the basicity of slag is monitored, and when it is confirmed that it deviates from the set range, first, incombustibles and fly ash generated in the system are preferentially preferential. If the basicity of the slag is adjusted (primary adjustment) by using it as a basicity adjuster, and it still cannot be adjusted within a certain period of time, the basicity of the slag is adjusted using the purchased basicity adjuster (secondary adjustment). In other words, it adjusts the basicity of slag in two stages by using different regulators with different costs, and this basicity is adjusted by adopting this two-stage slag basicity adjustment method. The adjustment cost can be minimized and the basicity can be reliably adjusted and maintained within the set range.

  The target setting range of the basicity of the slag in the present invention is preferably 0.5 to 0.9 in consideration of the fluidity of the slag and the quality after cooling and solidification, and 0.6 to 0.8, However, it is not necessarily limited to these ranges because it varies depending on the equipment of the melt gasification melting furnace, the operating conditions such as the operation mode and the temperature of the melting furnace, the composition of the slag generated in the melting furnace, etc. is not.

  In the present invention, when the primary adjustment by the primary basicity adjusting agent does not return to the set range even after a certain period of time has elapsed, secondary adjustment by additional supply of the secondary basicity adjusting agent is performed. It is preferable to start after a certain period of time until the start of the next adjustment. In other words, even if too short, the effect of the primary adjustment is not sufficiently reflected in the slag, and excessive supply due to the additional supply due to the secondary adjustment occurs.On the other hand, if it is too long, the adjustment to the setting range of the slag basicity is prolonged. In any case, the operation of the gasification melting furnace becomes unstable, and adverse effects such as deterioration of the slag quality are caused.

  In addition, when primary adjustment of slag basicity with primary basicity adjusting agent is performed, if the same thing as this adjusting agent (non-combustible material, fly ash, etc.) has already been supplied and circulated to the melting furnace for other purposes, etc. , By increasing its supply.

  In the past, incombustibles and part of fly ash may be supplied to the melting furnace to operate the gasification melting furnace, but this is only effective for reducing the final disposal amount. The present invention is intended to make a slag for the purpose of the present invention, and is not intended to adjust the basicity of the slag as in the present invention. The technical idea of the present invention is completely different from that of the present invention.

  When using the incombustible material discharged from the fluidized bed gasifier as the primary low basicity adjuster, it is pulverized in advance and supplied to the melting furnace with a particle size adjusted to 0.1 to 3 mm. It is desirable. If the thickness is less than 0.1 mm, the pulverized incombustible material cannot be captured in the melting furnace and carry over into the exhaust gas, and if it exceeds 3 mm, the melting is insufficient.

  When the primary basicity modifier is fly ash, the amount of fly ash supplied to the melting furnace is discharged from the melting furnace in consideration of the concentration of heavy metals contained in the fly ash as described above. It can be said that it is preferable to carry out as 50% or less of the total amount of recovered fly ash.

  In the present invention, it is essential to monitor the basicity of the slag during operation, and this can be achieved by sampling the slag periodically and analyzing the basicity using a fluorescent X-ray analyzer or the like. However, the basicity may be estimated by using operation data having a strong correlation with the basicity of the slag as a parameter without using such an analysis.

  Next, the present invention will be described in more detail with reference to the drawings and typical embodiments thereof.

  FIG. 1 is a schematic diagram showing the configuration of a gasification melting furnace equipment. The main equipment of the gasification melting furnace has a structure in which a fluidized bed gasification furnace 1 and a swirling flow melting furnace 2 are connected by an exhaust gas duct. After this main body equipment, the sensible heat recovery and exhaust gas treatment of the waste heat boiler 3, the temperature reducing tower 4, the bag filter 5 and the chimney 6 are performed along the flow of the exhaust gas discharged from the melting furnace 2. Exhaust gas treatment system equipment is sequentially installed.

  In the fluidized bed gasifier 1, waste R such as municipal waste which is organic waste is introduced, and the waste is heated at a temperature of 450 to 600 ° C. by combustion air supplied to the fluidized bed 11 from the bottom of the furnace. Partially combusted, and the gasification generates combustible gas and char composed of ash and carbonized solids. These combustible gases and char are accompanied by the exhaust gas of the gasification furnace and are sent to the swirling flow melting furnace 2.

  Silica sand M having an average particle diameter of 0.8 mm is circulated and supplied to the fluidized bed 11 of the gasification furnace 1 as the fluidized medium. The incombustible material H in the garbage R is discharged together with the quartz sand M from the lower part of the furnace to the incombustible material discharge device 12. Silica sand M is separated from the discharged incombustible material by the classifier 13, and the silica sand M is supplied again to the fluidized bed 11 as described above.

  In the swirling flow melting furnace 2, the exhaust gas sent from the fluidized bed gasification furnace 1 becomes a swirling flow in the melting furnace 2, and the combustible gas therein is burned by the supplied combustion air. The carbon in the char is also burned. Due to this combustion heat, the temperature of the furnace becomes a high temperature of 1250 to 1350 ° C. Therefore, the ash content in the char accompanying the exhaust gas is melted.

  The molten ash is slag S and discharged from a tap outlet (not shown) provided at the bottom of the melting furnace 2, and is then rapidly cooled and solidified by cooling water.

  Moreover, unmelted ash is accompanied by the exhaust gas discharged from the melting furnace 2 and is sent to the exhaust gas treatment system. The exhaust gas emitted from the melting furnace 2 is recovered by the waste heat boiler 3 and cooled to 250 to 400 ° C., and further cooled to 150 to 180 ° C. by the temperature reducing tower 4. The exhaust gas exiting the temperature reducing tower 4 is subjected to an exhaust gas purification treatment with a purification treatment GC such as slaked lime or activated carbon, collected by the bag filter 5, and finally diffused into the atmosphere through the chimney 6.

  Most of the fly ash in the exhaust gas discharged from the melting furnace 2 is recovered by the bag filter 5, 5 to 15% from the bottom of the waste heat boiler 3, and 1 from the bottom of the cooling tower 4. ~ 5% is recovered. Conventionally, the recovered fly ash FA is transported to the fly ash treatment apparatus 22, where stabilization processing for preventing heavy metal elution is performed, and the fly ash FA is carried out of the system.

  Therefore, in the present invention, on the premise of the above-described waste gasification melting furnace equipment and its process, the adjustment is performed so that the slag basicity is maintained within the set range, or the primary low basicity adjustment agent or the primary high basicity adjustment. The primary adjustment by the agent and the secondary adjustment by the secondary low basicity adjustment agent or the secondary high basicity adjustment agent are combined in two stages. The primary low basicity adjustment agent newly required for this adjustment and The preparation method for securing the primary high basicity adjusting agent in the gasification melting process system and supplying it to the melting furnace, and the equipment configuration for them will be described with reference to FIG.

  First, the incombustible material discharged from the gasification furnace 1 and separated from the appropriate silica sand M as a fluid medium by the classifier 13 is further separated by the metal sorting device 31 from valuable metals such as iron and Al. .

  In the present invention, the remaining incombustible material HR thus classified and selected is used as a primary low basicity adjusting agent.

  This incombustible material HR is conveyed and stored in the incombustible material storage tank 32, then crushed by the incombustible material crusher 33, further classified by the incombustible material screen 34, and the particle size (average particle size) is adjusted to 0.1 to 3 mm. Is done. The incombustible material whose particle size has been adjusted is stored in the pulverized incombustible material supply device 35. Then, about 90% or more of the incombustible material HR discharged from the gasification furnace 1 and crushed and adjusted in particle size is constantly supplied from the pulverized incombustible material supply device 35 into the furnace from the top of the melting furnace 1. Here, the remaining incombustibles HR that are not supplied to the melting furnace 1 are sent to the primary basicity adjuster supply device 37 and stored. In particular, incombustibles with low basicity such as in summer are preferentially sent to the primary basicity adjusting agent supply device 37 and stored.

  When the slag basicity needs to be adjusted to the low basicity side, in addition to supplying the pulverized incombustible material from the pulverized incombustible material supply device 35, the primary low basicity adjuster supply device 37 provides the primary low basicity. The adjusting agent A1 is supplied from the top of the melting furnace 1 into the furnace. Next, a part of the fly ash FA collected by the bag filter 5 is transported to the fly ash treatment device 22 where the heavy metal or the like is stabilized and carried out of the system.

  In the present invention, the remaining fly ash FR is used as a primary high basicity adjusting agent.

  The fly ash FR is transported and stored in the fly ash storage tank 41 and further sent to the primary high-basicity adjusting agent supply device 42.

  When primary adjustment of the basicity of the slag to the high basicity side becomes necessary, the primary high basicity adjusting agent supply device 42 makes the primary high basicity adjusting agent A2 into the furnace from the top of the melting furnace 1. Supplied.

  Further, since the fly ash collected by the waste heat boiler 3 and the temperature reducing tower 4 also contains CaO components, a part of the fly ash is transported to the fly ash treatment device 22 and the remaining portion (FR) is fly away. It is also possible to store it together with the fly ash FR stored in the fly ash storage tank 41 so as to be sent to the ash storage tank 41 and supply it to the melting furnace 2 as the primary high basicity adjusting agent A2. is there.

  On the other hand, the secondary adjustment of slag basicity in the present invention itself has already been carried out in the past, such as low basicity adjusters (purchased items such as cinnabar) and high basicity adjusters (purchased products such as slaked lime, quicklime or calcium carbonate ) And can be easily implemented with existing equipment. That is, the existing low basicity adjusting agent storage tank is the secondary low basicity adjusting agent storage tank 51, the low basicity adjusting agent supply device is the secondary low basicity adjusting agent supply device 52, and the existing high basicity adjusting agent supply device 52 is used. The adjusting agent storage tank may be used as the secondary high basicity adjusting agent storage tank 53, and the high basicity adjusting agent supply device may be used as the secondary high basicity adjusting agent supply device 54.

  When the slag basicity is secondarily adjusted to the low basicity side or the high basicity side, the secondary low basicity adjusting agent supply device 52 or the secondary high basicity adjusting agent supply device 54 is installed below the slag basicity. The secondary low basicity adjusting agent B1 or the secondary high basicity adjusting agent B2 is supplied into the furnace from the top of the melting furnace 1 through a switching device such as a damper.

In the above embodiment, the incombustibles discharged from the gasification furnace as the primary low basicity adjusting agent in the present invention and the example of fly ash as the primary high basicity adjusting agent have been described. However, the present invention is not limited thereto. The basicity adjustment described above can be performed in the entire process of operation and operation of the gasification melting furnace, including SiO ₂ and CaO components, and any system exhaust that can adjust the basicity of slag S. It can be used as an agent.

In addition, if the system exhaust such as incombustibles and fly ash has a low content of SiO ₂ and CaO and the effect of primary adjustment of sufficient basicity cannot be obtained, purchase with a high purity of these components is required. It is also within the scope of the present invention to add a part of silica sand, slaked lime, quick lime or calcium carbonate, which is a product, and to enhance the effect thereof as a primary low basicity adjusting agent or a primary high basicity adjusting agent in the present invention. is there.

  Furthermore, although the example of the fluidized bed type gasification furnace has been described as the gasification furnace in the present invention, the present invention is not limited thereto, and it is also within the scope of the present invention to apply a kiln type gasification furnace as a gasification furnace. .

(Example)
As shown in Table 1, the basicity of the slag S derived from municipal waste R supplied to the fluidized bed gasifier 1 varies depending on the season, and the slag basicity is 0.9 in the winter season (November to February). As high as ˜1.4, the slag basicity is below 0.6 in the summer (May to August). Therefore, in winter when slag basicity is high, slag basicity adjustment by a low basicity adjusting agent is required, and in summer when slag basicity is low, slag basicity adjustment by a high basicity adjusting agent is required.

  Next, Table 2 shows the pulverized incombustible material HR that is the primary low basicity adjusting agent A1, and Table 3 shows the basicity of the residual fly ash FR that is the primary high basicity adjusting agent B1. As shown in Table 2, the basicity of the pulverized incombustible HR is 0.2 to 0.4 in the summer and 0.2 to 0.8 in the winter, and is effective as the primary low basicity adjuster A1. I understand. The basicity of the fly ash FR varies depending on whether the bag filter 5 is provided in one stage or two stages in series, but is in the range of 1.0 to 3.5, and the primary low basicity adjusting agent B1. It turns out that it is effective as.

In the operation method of the gasification melting furnace in the summer, the basicity of the slag S derived from municipal waste R is 0.6 or less, and the basicity of the pulverized incombustible HR that is constantly supplied is also 0. Since it is 2-0.4, it will be less than 0.6-0.8 slag basicity in which a stable and efficient driving | operation is possible. Then, in order to make slag basicity into an appropriate range, 10-40% of the generation amount of the fly ash F was supplied with the residual fly ash FR which is the primary high basicity regulator B1. Still, since the basicity of the slag S did not become 0.6 to 0.8, calcium carbonate (CaCO ₃ ) as the secondary high basicity adjusting agent B2 was supplied. As a result, the amount of calcium carbonate used as the secondary high basicity adjuster B2 is reduced by 20 to 40% by application of the operation method of the present invention compared to the case where the operation method of the present invention is not applied. I was able to.

  In the operation method of the gasification melting furnace in winter, the basicity of the slag S derived from municipal waste R is 1.0 or more, and the basicity of the pulverized incombustible material HR that is constantly supplied is 0.2 to Since it was 0.6, the basicity of the slag S after supplying the pulverized incombustible material HR became 0.8 or more. Therefore, the basicity stored in the primary low basicity adjusting agent supply device 37 so that the slag basicity can be stably and efficiently operated 0.6 to 0.8, the basicity is 0.2 to As a result of supplying 0.4 primary low basicity adjusting agent A1, the basicity of slag S was within the range of 0.6 to 0.8. However, when the basicity of the slag S derived from municipal waste R exceeds 1.0, the basicity of the slag S does not fall within 0.6 to 0.8 with the primary low basicity adjuster A1. At that time, silica sand was supplied as the secondary low basicity adjusting agent A2. Compared with the case where the primary low basicity adjuster A1 is used and the case where it is not used, the amount of silica sand which is the secondary low basicity adjuster can be reduced by about 5 to 15%.

1: Fluidized bed gasification furnace 2: Swivel melting furnace 3: Waste heat boiler 4: Temperature reduction tower 5: Bag filter 6: Chimney
11: Fluidized bed 12: Incombustible material discharge device 13: Classification device 21: Fly ash treatment device 31: Metal sorting device 32: Incombustible material storage tank 33: Incombustible material crusher
34: Incombustible material screen 35: Ground incombustible material supply device
37: Primary low basicity adjusting agent supply device 41: Fly ash storage tank
42: Primary high basicity adjusting agent supply device 51: Secondary low basicity adjusting agent storage tank
52: Secondary low basicity adjusting agent supply device 53: Secondary high basicity adjusting agent storage tank
54: Secondary high basicity adjusting agent supply device A1: Primary low basicity adjusting agent A2: Primary high basicity adjusting agent B1: Secondary low basicity adjusting agent B2: Secondary high basicity adjusting agent R: Municipal waste S : Slag GC: Exhaust gas purifier M: Silica sand H: Incombustible material HR: Remaining incombustible material F: Fly ash FR: Remaining fly ash

Claims (8)

The waste is pyrolyzed while partially combusting in a pyrolysis furnace, the combustible gas and ash generated by this pyrolysis are guided to the melting furnace, the combustible gas is burned in the melting furnace, and the ash is melted by the combustion heat. In the operation method of the gasification melting furnace in which slag generated by melting is discharged outside the furnace, the basicity of the slag is monitored, and when the basicity is out of the set range, first, the operation of the gasification melting furnace If the primary adjustment is performed using the primary basicity regulator that is generated in the system, and the product does not return to the set range after a certain period of time, the secondary basicity regulator that is purchased outside the system By making the next adjustment, the basicity of the slag is maintained within the set range ,
When the basicity of the slag deviates to the lower side than the setting range, the primary basicity adjusting agent as the primary basicity adjusting agent, and when the basicity deviates from the setting range, the primary basicity adjusting agent. Perform primary adjustment of basicity with primary low basicity adjuster,
The primary high basicity adjusting agent is fly ash containing CaO components discharged from the melting furnace by the operation of the gasification melting furnace, and the primary low basicity adjusting agent is discharged from the gasification furnace by the operation of the gasification melting furnace. A method for operating a gasification melting furnace, wherein the gasification melting furnace is an incombustible material containing a SiO ₂ component .   If the basicity of the slag does not return to the setting range after the primary adjustment by the primary basicity adjuster and does not return to the setting range, the secondary high basicity adjuster as the secondary basicity adjuster and the primary adjustment 2. The gasification and melting according to claim 1, wherein secondary adjustment is performed by using a secondary low basicity adjusting agent as a secondary basicity adjusting agent when it does not return to the set range while remaining on the higher side. How to operate the furnace. The secondary high basicity adjusting agent is at least one selected from slaked lime, quick lime, or calcium carbonate, which is an out-of-system purchase, and the secondary low basicity adjustment agent is cinnabar which is an out-of-system purchase. The operation method of the gasification melting furnace of Claim 2 . The method for operating a gasification melting furnace according to any one of claims 1 to 3, wherein the incombustible material is discharged from a fluidized bed gasification furnace. The method for operating a gasification and melting furnace according to any one of claims 1 to 4, wherein the incombustible material has a particle size adjusted to 0.1 to 3 mm. Supply the primary adjustment by the primary basicity adjuster or the secondary adjustment by the secondary basicity adjuster to the basicity of the slag, or supply the primary basicity adjuster or the secondary basicity adjuster to the melting furnace or increase the supply amount. The operation method of the gasification melting furnace in any one of Claims 1-5 characterized by performing. The gas according to claim 6 , wherein when the primary basicity adjusting agent is fly ash, the supply amount is 50% or less of the total amount of fly ash discharged and recovered from the melting furnace. Operation method of chemical melting furnace. Claim 1-7 The method of operating the gasification melting furnace according to any one of 0.5 to 0.9 the setting range of basicity of the slag.

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