KR20030078641A - Method and apparatus for incineration treatment of material containing organic matter - Google Patents

Abstract

An object of the present invention is to promote an incineration treatment of a processed material which can operate an economical and stable circulating flow incinerator while aiming at reducing harmful substance emissions.

Treatment P is combusted in the fluidized bed 2 of the circulating flow incinerator 1, and the exhaust gas discharged from the fluidized bed 2 is converted into solids and gases in the hot cyclone 4 of the circulating fluidized incinerator 1. It separates and collects solid content of this exhaust gas, conveys it to the fluidized bed 2, and supplies the exhaust gas discharged | emitted from the hot cyclone 4 and the solid content not collected by this hot cyclone to the secondary combustion furnace 5, and combusts it. Let's do it.

Description

Incineration treatment apparatus and treatment method of incineration of organic matter-containing treatment {METHOD AND APPARATUS FOR INCINERATION TREATMENT OF MATERIAL CONTAINING ORGANIC MATTER}

The present invention relates to an incineration treatment apparatus and an incineration treatment method for a treated material which is subjected to combustion treatment by supplying a treated material containing organic matter (hereinafter, simply referred to as "treated material") such as waste such as sewage mud or dust to a circulating flow incinerator. will be.

As an incineration treatment apparatus that burns and treats this kind of treated material, the treated material is supplied to the fluidized bed for combustion treatment, and the exhaust gas discharged from the fluidized bed is supplied to a hot cyclone to be separated into solid content and gas, and the solid content is returned. It is known to have a circulating flow incinerator which circulates through the pipe into the fluidized bed. In such an incineration treatment apparatus, the treated material supplied to the fluidized bed is first dried and heated, and then pyrolyzed into a combustible gas such as hydrogen, methane, carbon monoxide, and ammonia, and carbon-based solids (charcoal). Then, the combustible gas and char which are pyrolyzed in this way are discharged together with the fluid (usually hot air) supplied to the fluidized bed, the combustion gas produced by combustion in the fluidized bed, or a part of the fluidized medium (usually silica sand). As described above, the hot cyclone is supplied to the hot cyclone, and the charcoal having a large flow medium or particles is collected and separated by the cyclone, and then returned to the bottom of the fluidized bed for circulation. Methane and the like are burned by the oxygen in the air as the flowing fluid discharged together while being supplied from the fluidized bed to the hot cyclone or in the hot cyclone, and are discharged simultaneously with the combustion gas and discharged by the exhaust gas treatment facility or the waste heat recovery facility. Is processed.

By the way, carbon monoxide, ammonia, and the like which have a slow combustion rate in the combustible gas may not be sufficiently terminated until they are discharged from a hot cyclone. Thus, the combustion exhaust gas is released in a state where these harmful substances such as carbon monoxide and ammonia are unburned. At the same time, there is a risk of emissions. In addition, charcoal produced by pyrolysis also has a slow combustion rate, and furthermore, since small particles cannot be collected by hot cyclones, they are also discharged from the hot cyclones simultaneously with the combustion gas in an unburned state. Since the char discharged in the unburned state is a combustible material first of all, the heat balance of the circulating flow incinerator is deteriorated by being discharged in the unburned state, and thus the operation of the circulating flow incinerator is required. This leads to an increase in cost and also to an increase in the raw ash of this fly ash because it is incorporated in the fly ash collected by the exhaust gas treatment plant, and part of it is the temperature in the waste heat recovery plant. By burning under reduced conditions, toxic substances such as dioxins, carbon monoxide, cyanide, ammonia and nitrous oxide are generated due to nitrogen, chlorine and the like contained in the char.

By the way, in order to prevent carbon monoxide, ammonia, or charcoal in the unburned state from being discharged from the hot cyclone, the combustion temperature of the treatment product in the circulating flow incinerator is set to a high temperature of, for example, about 850 to 950 ° C. You can increase it. However, operating a circulating flow incinerator at such a high combustion rate not only leads to an increase in auxiliary fuel, which is uneconomical, but also results in sintering of the flow medium, which damages its reliable flow or the return pipe. Occurs in the blockage, which results in inhibiting the stable operation of the circulating flow incinerator.

The present invention has been made under such a background, and this circulating flow incinerator prevents the emission of unburned carbon monoxide, ammonia, or charcoal even when operated at a relatively low temperature, thereby reducing the amount of harmful substances and circulating economically and stably. It is an object of the present invention to provide an incineration treatment apparatus and an incineration treatment method of a processed material that can operate an incinerator.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the incineration treatment installation of the processed material provided with the incineration treatment apparatus of this invention.

2 is a view showing the relationship between the combustion temperature of the secondary combustion furnace and the concentration of harmful substances in the combustion exhaust gas in the embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

1: circulating flow incinerator

2: fluidized bed

4: hot cyclone

4A: return tube

5: secondary combustion furnace

6: exhaust gas supply path from the hot cyclone 4 to the secondary combustion furnace 5

7: Assisted burner (secondary combustion means)

8: supply nozzle (means for supplying secondary combustion air)

A: primary air

B: secondary air

C: auxiliary combustion air

P: processed material

F, G: auxiliary fuel

In order to solve the above problems and achieve the above object, the incineration treatment apparatus of the present invention returns a fluidized bed for combustion treatment of a treated material and the solids collected by separating the exhaust gas discharged from the fluidized bed into solids and gases to the fluidized bed. A circulating flow incinerator having a hot cyclone and a secondary combustion furnace in which exhaust gas discharged from the hot cyclone of the circulating flow incinerator is supplied and combusted with solids not collected in the hot cyclone. In addition, the incineration treatment method of the present invention combusts the treated material in a fluidized bed of a circulating flow incinerator, and the exhaust gas discharged from the fluidized bed is separated into solids and gases in a hot cyclone of the circulating fluidized incinerator, and the solid content of the exhaust gas. Is collected and conveyed to the fluidized bed, and the exhaust gas discharged from the hot cyclone and solids not collected by the hot cyclone are supplied to a secondary combustion furnace for combustion.

Therefore, according to such an incineration apparatus and an incineration treatment method, even if unburned carbon monoxide, ammonia, or charcoal is discharged from the hot cyclone of a circulating flow incinerator, it can be supplied to the secondary combustion furnace and burned completely, In the incineration treatment method, the combustion temperature of the secondary combustion furnace is set to be higher than the combustion temperature of the circulating flow incinerator, so that carbon monoxide, ammonia, dioxins, cyanide, nitrous oxide, etc. can be used even if the combustion temperature in the circulating flow incinerator is relatively low. Reduction of harmful substance discharge can be aimed at. Here, in order to ensure the combustion of carbon monoxide, ammonia and charcoal in the secondary combustion furnace of the incineration apparatus of the present invention, the secondary combustion furnace and / or the supply path of the exhaust gas from the hot cyclone to the secondary combustion furnace. It is preferable to provide the auxiliary combustion means and the supply means of the air for auxiliary combustion, and it is preferable to use a swirl flow type combustion furnace as this secondary combustion furnace. Moreover, this swirl flow type combustion furnace may be a cylindrical longitudinal type or a cylindrical horizontal type.

On the other hand, in the incineration treatment method of the present invention, in order to further ensure the combustion of carbon monoxide, ammonia and charcoal, it is preferable to hold the exhaust gas discharged from the hot cyclone in a secondary combustion furnace for 2 seconds or more, and burn it. Moreover, it is preferable to make the combustion temperature in the said secondary combustion furnace into the range of 800-900 degreeC. In other words, if the residence time of exhaust gas is less than 2 second, carbon monoxide, ammonia, In particular, there is a possibility that charcoal cannot be reliably burned, and even if the residence time is long, if the combustion temperature of the secondary combustion furnace is lower than the above range, it is also difficult to reliably burn, and to achieve a combustion temperature higher than the above range, For example, the amount of auxiliary fuel supplied from the auxiliary combustion means may increase, resulting in economical efficiency. The concern arises to. Moreover, in order to make these economics and combustion of carbon monoxide, ammonia, and charcoal more reliably compatible, it is more preferable to make the combustion temperature in this secondary combustion furnace into the range of 840-860 degreeC.

Fig. 1 shows an incineration treatment facility for a treatment product having an embodiment of an incineration treatment apparatus of the present invention. Hereinafter, an embodiment of the incineration treatment method of the present invention will be described together with the treatment apparatus. In the present embodiment, the circulating flow incinerator 1 is provided with a fluidized bed 2 in which a fluid medium such as silica sand is maintained therein, and adjacent to the fluidized bed 2, and the exhaust gas from the top of the fluidized bed 2 is formed. A hot cyclone 4 is connected to the discharge flow path 3, and from the lower end of the hot cyclone 4, a return pipe 4A extends obliquely downward toward the fluidized bed 2 so that the fluidized bed 2 is provided. It is connected to the bottom of the.

In this circulating flow incinerator 1, the fluid medium maintained inside the fluidized bed 2 is controlled by the primary air A and the secondary air B as the fluid flowing from the bottom and the bottom of the fluidized bed 2. The flow state is maintained and the treatment P such as sewage mud or dust supplied into the fluidized bed 2 from above the primary and secondary air A and B is crushed by the flow medium in this flow state. And the secondary fuel supplied to the fluidized bed 2 as needed from the combustion of the treatment P itself by the primary and secondary air A and B, and from below the treatment P. By the combustion of (F), as described above, pyrolysis is carried out with combustible gases such as hydrogen, methane, carbon monoxide and ammonia and charcoal containing carbon as a main component. Moreover, in this fluidized bed 2, combustion is mainly performed in the density | concentration of the density of the fluid medium of the bottom. Further, the auxiliary fuel F is supplied with a controlled supply amount so as to maintain a constant temperature inside the furnace of the fluidized bed 2.

Here, the cross-sectional area is set such that the riser portion 2A is upward from the substantially central portion of the fluidized bed 2 in the up and down direction so that the Fr (Froude Number) is about 1 to 20. Gases, such as combustible gas, air as a fluid fluid, or combustion exhaust gas generated by combustion, are raised at a relatively high air column velocity, and carry out a hot cyclone from the discharge passage 3 with solids such as a portion of the char or fluid medium. Supplied to (4). In this hot cyclone 4, the flow medium or the relatively large char is separated and collected from the gas into solids and gases, and returned to the bottom of the fluidized bed 2 through the return pipe 4A. While being in a fluidized state, it is used for the crushing of the processing product P, and at the same time, the char is crushed into smaller particles and burned. In addition, combustion of the processed material P is performed even while reaching the hot cyclone 4 from the discharge passage 3, and in particular, in the hot cyclone 4, since the solid content and gas contact are severe, the combustion is also remarkable. Pyrolysis produces flammable gases as described above.

However, among the combustible gases generated in the fluidized bed 2 or the hot cyclone 4, hydrogen or methane which burns rapidly is almost completely burned up to this hot cyclone 4, but carbon monoxide and ammonia which are burned slowly are slow. The back is not completely burned, and similarly, the particles which are not collected in the hot cyclone 4 of the slow burning charcoal are not collected because they are caused by the combustion in the fluidized bed 2 or the hot cyclone 4. It is discharged from the hot cyclone 4 together with the ash. Thus, in the present embodiment, the incineration treatment apparatus is provided with a secondary combustion furnace 5, and the exhaust gas containing solid content, as described above, discharged from the hot cyclone 4 is supplied to the secondary combustion furnace 5 by It burns carbon monoxide, ammonia and charcoal.

Here, the secondary combustion furnace 5 in the present embodiment is a cylindrical longitudinal swirl flow type combustion furnace, that is, the exhaust gas supply passage 6 is formed on the upper portion of the cylindrical furnace body with the axis vertically. It is connected so as to extend in the tangential direction, and the exhaust gas supplied from this supply path 6 is combusted while drawing a spiral swirl flow as shown in the furnace main body. Further, at least one of the exhaust gas supply passage 6 from the secondary combustion furnace 5 and the hot cyclone 4 to the secondary combustion furnace 5, that is, the secondary combustion furnace 5 and / or the supply passage 6. An auxiliary combustion burner 7 such as heavy oil, kerosene burner or gas torch is provided as an auxiliary combustion means, and a supply nozzle 8 is provided as a supply means for auxiliary combustion air C. As the auxiliary combustion air C, a part of the secondary air B supplied to the fluidized bed 2 in the circulation flow incinerator 1 may be supplied.

In addition, in the present embodiment, the supporting burner 7 is installed in the upper center of the secondary combustion furnace 5 at the lower axial direction of the cylinder formed by the furnace body of the secondary combustion furnace 5, and the secondary combustion furnace 5 The supply nozzle 8 is provided on the side wall of the side), and the supporting burner 7 is provided toward the secondary combustion furnace 5 side in the tangential direction in which the supply path 6 extends in the supply path 6. At the same time, a plurality of supply nozzles 8 are provided on the sidewalls. However, only one of these supporting burners 7 and the supply nozzle 8 may be provided, and may be provided only in either the secondary combustion furnace 5 and the supply passage 6, or the secondary combustion furnace One of the assisting burner 7 and the supply nozzle 8 may be provided in one of (5) and the supply path 6, and the other may be provided in the other. In addition, a plurality of supply nozzles 8 may be provided in the secondary combustion furnace 5 and the supply passage 6, respectively.

Therefore, the exhaust gas from the hot cyclone 4 supplied to the secondary combustion furnace 5 through the supply passage 6 is first burner flame or supply nozzle of the supporting burner 7 provided in the supply passage 6. It is combusted by the auxiliary combustion air C supplied from (8) and from the burner flame of the supporting burner 7 or the supply nozzle 8, forming a swirl flow as mentioned above also in the secondary combustion furnace 5. It is burned by the auxiliary combustion air C supplied. Here, the combustion temperature in the secondary combustion furnace (5) is the supply amount of the auxiliary fuel (G) such as heavy oil, kerosene, gas, etc. to the supporting burner (7) and the auxiliary combustion air (C) to the supply nozzle (8). By adjusting a supply amount etc., it is controlled at the temperature higher than the combustion temperature in the said circulation flow incinerator 1, Preferably it is the range of 800-900 degreeC, More preferably, it is the range of 840-860 degreeC. In this secondary combustion furnace 5, the residence time of the exhaust gas is controlled to be 2 seconds or more.

Moreover, the lower part of this secondary combustion furnace 5 is provided with the primary air preheater 9 so that it may be connected to the discharge port of the combustion exhaust gas combusted by the said secondary combustion furnace 5, and is heat-exchanged between these combustion exhaust gases, The primary air A supplied to the fluidized bed 2 of the circulating flow incinerator 1 is preheated, and the combustion exhaust gas thus preheating the primary air A is also supplied to the secondary air preheater 10, The secondary air B supplied to the fluidized bed 2 or the secondary combustion air C supplied to the secondary combustion furnace 5 and / or the supply passage 6 are also preheated by heat exchange. Moreover, the combustion exhaust gas discharged | emitted from this secondary air preheater 10 is the natural prevention air preheater 11, the ash recovery cyclone 12, which are the waste gas processing facilities with which the said incineration treatment facility was equipped, The exhaust gas treatment passes through the flue gas treatment tower 13 and the wet electrostatic precipitator 14, and is discharged from the chimney 15 after being cleaned.

According to the incineration treatment apparatus of the treated material P configured as described above, and the incineration treatment method using the apparatus, carbon monoxide, ammonia, or charcoal having a low combustion rate is unburned from the hot cyclone 4 of the circulating flow incinerator 1. Even if it is discharged | emitted, it can supply this to the secondary combustion furnace 5 as mentioned above, and can burn it completely. Therefore, even if the combustion temperature is kept relatively low in the circulating flow incinerator 1, it is possible to prevent harmful substances such as carbon monoxide and ammonia from being discharged from the incineration treatment apparatus, and also to discharge unburned charcoal. It is possible to prevent the generation of harmful substances such as dioxins, cyanide, carbon monoxide, nitrous oxide and ammonia in the course of the above-described exhaust gas treatment due to nitrogen, chlorine and the like contained in the charcoal. Therefore, according to the incineration treatment apparatus and the incineration treatment method of this embodiment, the auxiliary fuel F in the circulating flow incinerator 1 is reduced while promoting the reduction of the running cost while preventing the generation and discharge of such harmful substances. At the same time, it becomes possible to prevent stable sintering of the fluidized medium and achieve stable operation.

In addition, in the incineration processing apparatus of the present embodiment, an assisting burner as an auxiliary combustion means in the supply passage 6 of the exhaust gas from the secondary combustion furnace 5 and / or the hot cyclone 4 to the secondary combustion furnace 5. (7) and a supply nozzle (8) as a supply means for the auxiliary combustion air (C), and the carbon monoxide, ammonia, charcoal in the exhaust gas in the secondary combustion furnace (5) or the supply passage (6) leading thereto. Can be burned more reliably. Moreover, in this embodiment, this secondary combustion furnace 5 is a swirl flow type combustion furnace, and for this reason, the auxiliary combustion air C supplied from the supply nozzle 8 is sufficiently mixed with the exhaust gas to support the burner burner 7. Since the combustion can be carried out more completely, the carbon monoxide, ammonia, charcoal and the like in the unburned state can be more surely prevented from being discharged. In this embodiment, although the secondary combustion furnace 5 is a cylindrical vertical spiral flow type combustion furnace, one end of the cylindrical furnace body horizontally inclined, including the inclined transverse direction (in the transverse direction in which the axis is inclined) In this case, the cylindrical lateral swirl flow type combustion furnace connected to the upper end portion) so that the exhaust gas supply path 6 also extends in the tangential direction of the cylinder may be used as the secondary combustion furnace 5.

In the incineration treatment method of this embodiment, the combustion temperature in the secondary combustion furnace 5 is higher than the combustion temperature in the circulating flow incinerator 1, so that carbon monoxide in the exhaust gas not burned in the circulating flow incinerator 1 More reliable combustion of ammonia or char exhausted at the same time as the exhaust gas can be achieved. However, if the combustion time in the secondary combustion furnace 5, that is, the residence time of the exhaust gas is too short, there is a fear that such reliable combustion cannot be achieved unless the combustion temperature of the secondary combustion furnace 5 is higher. Therefore, the residence time of the exhaust gas in this secondary combustion furnace 5 is preferably set to 2 seconds or more as in the present embodiment.

On the other hand, if the combustion temperature in the secondary combustion furnace 5 is too low, there is a fear that it will not be possible to reliably combust unburned materials such as carbon monoxide, ammonia, charcoal, etc., if the residence time is not long. have. However, even if the combustion temperature in this secondary combustion furnace 5 is too high, especially when the residence time of 2 seconds or more is ensured, it will be possible to continue combustion after the incineration of the unburned material is completely incinerated, and this secondary combustion furnace 5 ) Or an increase in the supply amount of the auxiliary fuel G from the supply passage 6 to the auxiliary burner 7 or the auxiliary combustion air C to the supply nozzle 8, resulting in an uneconomical risk. Therefore, the combustion temperature in this secondary combustion furnace 5 is also preferably in the range of 800 to 900 ° C as in the present embodiment. In addition, when the combustion temperature in the secondary combustion furnace 5 is in the range of 840 to 860 ° C as described above, the carbon monoxide, ammonia and charcoal are more completely burned to more accurately produce the harmful substances as described above. While preventing, the supply amount of the auxiliary fuel G and the auxiliary combustion air C can be further reduced, which is more preferable.

Here, FIG. 2 shows an example of the exhaust gas treatment facility when the combustion temperature of the secondary combustion furnace 5 is changed by adjusting the amount of auxiliary fuel G supplied to the auxiliary burner 7 in the incineration treatment apparatus of the present embodiment. The change in concentration of various harmful substances in the combustion exhaust gas at the inlet is shown. In addition, the processed material P at this time was sewage mud of 80 wt% of water, 15.8 wt% of organic powder, and 4.2 wt% of inorganic powder, and was supplied to the circulating flow incinerator 1 at a feed rate of 3750 kg / h. In this circulating flow incinerator 1, the riser portion of the fluidized bed 2 has a circular cross section having an inner diameter of 1800 mm, JIS 6 silica sand is used as the fluid medium, and the primary air A of about 650 ° C. is used as the fluid. Is 1800 m ³ N / h, similarly, the secondary air (B) at about 650 ° C. is 3600 m ³ N / h, and as auxiliary fuel (F), city gas (11000 kca 1 / m ³ N) is 67 m ³ N / h. It was supplied respectively at h, and the combustion temperature was 820 degreeC. On the other hand, in the secondary combustion furnace 5, the same city gas as the auxiliary fuel F is supplied as the auxiliary fuel G, and the hot cyclone 4 introduced into the secondary combustion furnace 5, which is a swirl flow combustion furnace, is introduced. The inlet velocity of the exhaust gas from the reactor was about 16 m / s, and the residence time of the exhaust gas in the secondary combustion furnace 5 was 3.8 seconds.

And as a result shown in FIG. 2, in the range where the temperature (combustion temperature) of the secondary combustion furnace 5 is 840 degreeC or more, it turns out that the density | concentration of each harmful component is also reduced significantly with respect to the range below this temperature. For example, with regard to the draft, the result was well below the regulatory value at 10 ppm or less at 850 ° C. However, in the range where the internal combustion temperature (combustion temperature) of the secondary combustion furnace is higher than 860 ° C, the decreasing tendency of the concentration of the hazardous substances caused by the increase of this combustion temperature is very gentle compared to the range of 860 ° C or lower, and furthermore, It can be seen that the range falls considerably below, and thus, it is uneconomical because many auxiliary fuels (G) are required. Therefore, also from the result of this FIG. 2, it turns out that it is more preferable to make the combustion temperature in the secondary combustion furnace 5 into the range of 840-860 degreeC as mentioned above.

As described above, according to the incineration treatment apparatus and the incineration treatment method of the treated materials of the present invention, even if harmful substances such as carbon monoxide and ammonia or unburned charcoal are produced in the circulating flow incinerator, they can be completely combusted in the secondary combustion furnace. Therefore, these harmful substances such as carbon monoxide and ammonia can be prevented from being discharged as they are or new harmful substances are generated by the unburned charcoal. Therefore, the combustion temperature in the circulating flow incinerator can be restrained relatively low to reduce the operating cost. It is possible to reduce the occurrence of reduction and sintering, and to incinerate a stable and efficient processed product. Further, in the incineration treatment apparatus of the present invention, an auxiliary combustion means or an auxiliary combustion air supply means is provided in the secondary combustion furnace or the exhaust gas supply path to the secondary combustion furnace, or the secondary combustion furnace is a rotary flow type combustion furnace. In addition, in the incineration treatment method of the present invention, the combustion temperature in the secondary combustion furnace is set to be higher than the combustion temperature of the circulating flow incinerator, or the exhaust gas is kept in the secondary combustion furnace for 2 seconds or more for combustion, or the secondary combustion furnace By setting the combustion temperature in the range of 800 to 900 DEG C, more preferably in the range of 840 to 860 DEG C, the secondary combustion furnace makes it possible to burn the above-mentioned harmful substances and charcoal more completely. The discharge can be more reliably prevented.

Claims (9)

A circulating fluid incinerator having a fluidized bed for carrying out combustion treatment of an organic matter and a hot cyclone for separating the exhaust gas discharged from the fluidized bed into solids and gases and returning the collected solids to the fluidized bed; An apparatus for incineration treatment of organic matter containing an organic substance, characterized in that it comprises a secondary combustion furnace in which exhaust gas discharged from the hot cyclone is supplied and combusted at the same time as solid content not collected in the hot cyclone. An incineration treatment apparatus for a treatment product containing an organic substance according to claim 1, wherein an auxiliary combustion means is provided in the secondary combustion furnace and / or the exhaust gas supply passage from the hot cyclone to the secondary combustion furnace. The organic material according to claim 1 or 2, wherein the secondary combustion furnace and / or the exhaust gas supply passage from the hot cyclone to the secondary combustion furnace are provided with an auxiliary combustion air supply means. Incineration apparatus of the processing object to contain. 2. An incineration treatment apparatus for a treatment product containing an organic substance according to claim 1, wherein the secondary combustion furnace is a swirl flow type combustion furnace. The treated matter containing organic matter is combusted in a fluidized bed of a circulating fluidized incinerator, and the exhaust gas discharged from the fluidized bed is separated into solids and gases in a hot cyclone of the circulated fluidized incinerator, and the solids in the exhausted gas are collected to collect the fluidized bed. And the exhaust gas discharged from the hot cyclone and the solid content not collected by the hot cyclone are supplied to the secondary combustion furnace for combustion. The incineration treatment method according to claim 5, wherein the combustion temperature in the secondary combustion furnace is set to be higher than the combustion temperature in the circulating flow incinerator. The incineration treatment method according to claim 5 or 6, wherein the exhaust gas discharged from the hot cyclone is kept in the secondary combustion furnace for 2 seconds or more for combustion. The combustion temperature in the secondary combustion furnace is in the range of 800 to 900 ° C, wherein the incineration treatment method for the treated material containing an organic substance according to claim 5. The incineration treatment method of a treated material containing an organic substance according to claim 5, wherein the combustion temperature in the secondary combustion furnace is in a range of 840 to 860 ° C.