JP2003269711A - Combustion method for ash melting furnace - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a combustion method for an ash melting furnace which prevents an increase of a quantity of fuel and further reducing NOx. <P>SOLUTION: In the combustion method for the ash melting furnace, ash is led into a melting chamber 5, it is melted by a combustion device 4 provided with a combustion air supply nozzle 11 for raising the temperature with a fuel supply nozzle 12 arranged in an interior and a combustion air supply nozzle 13 for low NOx provided in a portion different to the combustion air supply nozzle 11 for raising the temperature, molten slag is discharged from a slag discharging chamber 7, and exhaust gas generated in the melting chamber is led into a secondary combustion chamber 2 provided in a position nearer to an ash input port to burn unburned combustibles. A part of the exhaust gas generated in the melting chamber 5 is extracted from a side wall part of the slag discharging chamber 7 via an exhaust gas lead-in pipe 22, and the exhaust gas is led into the combustion air supply nozzle 11 for raising the temperature of the combustion device 4. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a combustion method in an ash melting furnace having a burner type combustion device.

[0002]

2. Description of the Related Art A conventional burner type ash melting furnace is shown in FIG.
There is something like. A furnace main body 51 of the ash melting furnace is connected to a melting chamber 53 for heating and melting the ash by a melting burner 52 provided on an upper wall portion, and the ash is connected to the melting chamber 53 via a communicating portion 54 and the ash. And a secondary combustion chamber 55 for burning unburned components of the furnace body 5
An ash supply port 56 is formed in the side wall portion of the secondary combustion chamber 55 which is the front wall portion of No. 1 and the molten ash melted in the melting chamber 53, that is, molten slag is provided outside in the rear portion of the furnace body 51. A slag discharge chamber 57 for guiding is formed.

Further, in the furnace body 51, the exhaust gas generated in the melting chamber 53 is extracted by the ejector 58 from the side wall of the slag discharge chamber 57 and is supplied to the secondary combustion chamber 55. An introduction pipe 59 is provided. Further, the ash melting furnace is provided with an ash pushing device 60 for pushing the ash into the furnace body 51 from the ash supply port 56, and below the slag discharge chamber 57. , A water granulation device 61 comprising a water tank or the like for water granulating the molten slag
Is provided. The melting burner 52 includes a fuel supply nozzle 62 and a combustion air supply pipe 63.

In the above structure, ash (which is a mixed ash of incinerated ash and fly ash) A is ash pushed by the ash pushing device 60.
When it is supplied into the secondary combustion chamber 55, the inclined bottom wall surface of the secondary combustion chamber 55 moves into the melting chamber 53 through the communicating portion 54, where
It is heated and melted by the melting burner 52. While the ash moves from the secondary combustion chamber 55 to the melting chamber 53 via the communication portion 54, the heat generated when the combustion exhaust gas generated in the melting chamber 53 moves to the secondary combustion chamber 55 side. Is preheated and dried.

Then, the molten slag S melted in the melting chamber 53 is discharged from the slag discharge chamber 57 to the water granulation device 61, and is solidified by water granulation, that is, water cooling. Also,
In this slag discharge chamber 57, since a part of the combustion exhaust gas generated in the melting chamber 53 is extracted from the exhaust gas introduction pipe 59, it is prevented that the molten slag S in the slag discharge chamber 57 is heated and solidified. At the same time, the combustion exhaust gas was introduced into the secondary combustion chamber 55 to perform complete combustion.

By the way, in the ash melting furnace, it is necessary to maintain the temperature of the bottom of the furnace in the melting chamber at a temperature higher than the melt flow temperature of the molten slag (molten ash), that is, at a high temperature of 1400 ° C. or higher. in (single stage combustion), the temperature is increased NO _x in the combustion exhaust gas is increased, in the above-mentioned ash melting furnace, an air ratio of the combustion air in the melt chamber 53 is 1.0 (combustion theory air at melting burner The amount of oxygen is deficient below, and NO _x is reduced by the two-stage combustion in which the combustion exhaust gas is completely combusted in the secondary combustion chamber 55.

[0007]

However, when the air ratio in the melting chamber 53 is set to 1.0 or less, the combustion efficiency decreases and unburned components (CO content, CO content, etc.) in the exhaust gas extracted from the melting chamber 53 are reduced. Since unburned carbon, etc.) is present, there is a problem that it leads to an increase in fuel amount.
Reduction of O _x is desired.

[0008] Therefore, an object of the present invention is to provide a combustion method in an ash melting furnace which can suppress an increase in the amount of fuel and can further reduce NO _x .

[0009]

In order to solve the above-mentioned problems, a combustion method in an ash melting furnace according to claim 1 of the present invention introduces the ash supplied from an ash charging port into a melting chamber, and a fuel supply nozzle. After being melted by a combustion device equipped with a combustion air supply nozzle that is arranged inside to supply combustion air,
While discharging this molten slag from the slag discharge chamber,
A combustion method in an ash melting furnace in which the combustion exhaust gas generated in the melting chamber is guided to a secondary combustion chamber provided near the ash input port to burn unburned components, which is generated in the melting chamber. A part of the combustion exhaust gas is extracted from the side wall of the slag discharge chamber, and the combustion exhaust gas is introduced into the combustion air supply nozzle of the combustion device.

Further, the combustion method in the ash melting furnace according to claim 2 introduces the ash supplied from the ash inlet into the melting chamber,
After being melted by a combustion device equipped with a combustion air supply nozzle in which a fuel supply nozzle is arranged to supply combustion air, this molten slag is discharged from a slag discharge chamber and combustion exhaust gas generated in the melting chamber is generated. Is a combustion method in an ash melting furnace in which the unburned components are burned by introducing the slag to a secondary combustion chamber provided near the ash charging port, and a part of the combustion exhaust gas generated in the melting chamber is discharged by slag. It is a method of extracting the combustion exhaust gas from the side wall of the chamber and introducing the combustion exhaust gas into the fuel supply nozzle of the combustion device.

A combustion method in an ash melting furnace according to a third aspect is the method according to the first aspect, wherein the combustion exhaust gas extracted from the slag discharge chamber is introduced into the fuel supply nozzle of the combustion device.

Further, in the combustion method in the ash melting furnace according to the fourth aspect, the ash supplied from the ash charging port is guided to the melting chamber,
A fuel supply nozzle is arranged inside to supply temperature-raising combustion air and a temperature-raising combustion air supply nozzle and a part different from the temperature-raising combustion air supply nozzle to supply low NO _x combustion air. The molten slag is discharged from the slag discharge chamber after being melted by a combustion device equipped with a low NO _x combustion air supply nozzle, and the combustion exhaust gas generated in the melting chamber is provided near the ash charging port. A method of combustion in an ash melting furnace that is configured to guide unburned components to a secondary combustion chamber and to extract a part of the combustion exhaust gas generated in the melting chamber from the side wall of the slag discharge chamber, This combustion exhaust gas is introduced into the temperature raising combustion air supply nozzle and / or the low NO _x combustion air supply nozzle of the combustion apparatus.

Further, in the combustion method in the ash melting furnace according to the fifth aspect, the ash supplied from the ash charging port is guided to the melting chamber,
A fuel supply nozzle is arranged inside to supply temperature-raising combustion air and a temperature-raising combustion air supply nozzle and a part different from the temperature-raising combustion air supply nozzle to supply low NO _x combustion air. The molten slag is discharged from the slag discharge chamber after being melted by a combustion device equipped with a low NO _x combustion air supply nozzle, and the combustion exhaust gas generated in the melting chamber is provided near the ash charging port. A method of combustion in an ash melting furnace that is configured to guide unburned components to a secondary combustion chamber and to extract a part of the combustion exhaust gas generated in the melting chamber from the side wall of the slag discharge chamber, The combustion exhaust gas is introduced into the fuel supply nozzle of the combustion device.

A combustion method in an ash melting furnace according to claim 6 is the method according to claim 4, wherein the combustion exhaust gas extracted from the slag discharge chamber is introduced into a fuel supply nozzle of a combustion device.

Further, a combustion method in an ash melting furnace according to a seventh aspect is to introduce the ash supplied from the ash charging port into a melting chamber,
A temperature raising combustion air supply nozzle having a first fuel supply nozzle disposed therein for supplying temperature raising combustion air, and a second fuel supply nozzle provided at a location different from the temperature raising combustion air supply nozzle. After being melted by the provided combustion device, the molten slag is discharged from the slag discharge chamber, and the combustion exhaust gas generated in the melting chamber is introduced to the secondary combustion chamber provided near the ash charging port to unburnt components. Is a combustion method in an ash melting furnace configured to burn, and a part of the combustion exhaust gas generated in the melting chamber is extracted from the side wall portion of the slag discharge chamber, and the combustion exhaust gas is heated in the combustion device. It is a method of introducing it into the combustion air supply nozzle for use.

Further, in the combustion method in the ash melting furnace according to the eighth aspect, the ash supplied from the ash charging port is guided to the melting chamber,
A temperature raising combustion air supply nozzle having a first fuel supply nozzle disposed therein for supplying temperature raising combustion air, and a second fuel supply nozzle provided at a location different from the temperature raising combustion air supply nozzle. After being melted by the provided combustion device, the molten slag is discharged from the slag discharge chamber, and the combustion exhaust gas generated in the melting chamber is introduced to the secondary combustion chamber provided near the ash charging port to unburnt components. Is a combustion method in an ash melting furnace, in which a part of the combustion exhaust gas generated in the melting chamber is extracted from the side wall of the slag discharge chamber, and the combustion exhaust gas is discharged from the first side of the combustion device. It is a method of introducing into the fuel supply nozzle and / or the second fuel supply nozzle.

Further, the combustion method in the ash melting furnace according to claim 9 is the combustion method according to claim 7, wherein the combustion exhaust gas extracted from the slag discharge chamber is supplied to the first fuel supply nozzle and / or the second fuel supply nozzle of the combustion device. This is a method of introducing into the fuel supply nozzle.

According to the combustion method in the ash melting furnace according to any one of claims 1 to 9, while a part of the combustion exhaust gas generated in the melting chamber is extracted through the slag discharge chamber,
At least one of the combustion air supply nozzles and each fuel supply nozzle is mixed, so that the oxygen concentration in the combustion air decreases and the combustion becomes slow, so that the combustion air ratio is 1. NO _x without making it 0 or less
Can be suppressed, and an increase in the amount of fuel can be suppressed.

[0019]

DETAILED DESCRIPTION OF THE INVENTION A combustion method in an ash melting furnace according to a first embodiment of the present invention will be described below with reference to FIGS. 1 and 2.

First, the ash melting furnace will be described. This ash melting furnace is of a burner type, and the furnace body 1 is communicated with the secondary combustion chamber 2 and the secondary combustion chamber 2 via a communication part 3 and the ash melting furnace is connected to the upper wall part 1a. And a melting chamber 5 in which a burner-type combustion device 4 is arranged. Further, an ash charging port 6 is formed in a front wall portion 1b on one end side of the furnace body 1, and a rear wall on the other end side is formed. A slag discharge chamber 7 for discharging the molten slag (molten ash) S melted in the melting chamber 5 to the outside of the furnace is provided near the portion 1c. In addition, the secondary combustion chamber 2, the communication portion 3, and the bottom wall portion 1 of the melting chamber 5
d is slightly inclined downward from the ash charging port 6 side toward the melting chamber 5 side.

As shown in FIG. 2, the combustion device 4 is provided at the center of the upper wall 1a of the furnace body 1 forming the melting chamber 5 and is provided with temperature raising combustion air (combustion air is atmospheric air). A cylindrical temperature rising combustion air supply nozzle (which may be a temperature rising combustion air supply port or a temperature rising combustion air supply pipe) 11 for supplying the same, hereinafter, and this combustion air supply nozzle A tubular fuel supply nozzle (which may be a fuel supply port or a fuel supply pipe) 12 which is provided in the inside of 11, for example, a central position and supplies fuel, and this fuel supply nozzle
A position apart by a predetermined distance from, i.e. temperature for combustion air supply nozzles (connecting port) temperature 11 plurality of low NO _x combustion air supply nozzles tubular disposed at predetermined intervals around the (for low NO _x It may be a combustion air supply port or a combustion air supply pipe for low NO _x ) 13.

Combustion air is supplied from the temperature raising combustion air supply nozzle 11 and the low NO _x combustion air supply nozzle 13, and the low NO _x combustion air is melted in the melting chamber 5.
It is supplied (may be called jet) at a considerably high speed (for example, about 50 m / sec).

Further, in the rear wall portion 1c corresponding to the slag discharge chamber 7 of the furnace body 1, the combustion exhaust gas generated in the melting chamber 5 is extracted via an ejector 21 provided on the way, and An exhaust gas introduction pipe 22 for introducing into the temperature rising combustion air supply nozzle 11 of the combustion device 4 is connected. Of course, air is used as the driving fluid for the ejector 21. Even if the ejector 21 is not used,
The exhaust gas can be supplied to the combustion device 4 side.

A hopper 8 is provided on the side of the ash charging port 6.
Ash stored inside (mixed ash of incinerated ash and fly ash)
An ash pushing device 9 for pushing A into the furnace is provided, and below the slag discharge chamber 7, a water tank for quenching the molten slag S into fine particles by water, that is, for water granulation, etc. The water granulation device 10 is provided.

Next, a combustion method in the ash melting furnace will be described. In the above ash melting furnace, when the ash A is supplied into the secondary combustion chamber 2 of the furnace body 1 by the ash pushing device 9, the inclined bottom wall portion 1d is passed through the communication portion 3 to the melting chamber 5 side. The ash A which has moved to the inside of the melting chamber 5 where the fuel supplied from the fuel supply nozzle 12 of the combustion device 4 is burned by the combustion air supplied from the temperature raising combustion air supply nozzle 11 After being melted, the molten slag S is discharged from the slag discharge chamber 7 to the water granulation device 10 to be water granulated.

When the ash A moves from the secondary combustion chamber 2 to the melting chamber 5 via the communicating portion 3, when the combustion exhaust gas generated in the melting chamber 5 moves to the secondary combustion chamber 2 side, , And is dried by being preheated by the heat.

A part of the combustion exhaust gas generated in the melting chamber 5 is discharged by the ejector 21 into the exhaust gas introducing pipe 2
It is extracted from the slag discharge chamber 7 via 2 and is introduced into the temperature rising combustion air supply nozzle 11 of the combustion device 4. The heat of the combustion exhaust gas extracted from the melting chamber 5 to the slag discharge chamber 7 prevents the molten slag S from solidifying.

By the way, the combustion exhaust gas extracted from the exhaust gas introduction pipe 22 is about 5 to 20% (preferably about 10%) of the combustion exhaust gas generated in the melting chamber 5, and the temperature is raised. The air ratio of the combustion air supplied from the for-use combustion air supply nozzle 11 is larger than 1.0, for example, about 1.1.

That is, a part of the combustion exhaust gas generated in the melting chamber 5 is extracted through the slag discharge chamber 7,
Since the combustion air is mixed in a part of the combustion air in the combustion device 4, the oxygen concentration in the combustion air decreases and the combustion becomes slow, so that the flame temperature decreases and the generation of NO _x is suppressed. Since the air ratio of the temperature raising combustion air supplied from the combustion device 4 into the furnace at this time is 1.1 as described above, it is 1.0 or less as in the conventional case. It is possible to suppress such an increase in the amount of fuel.

Further, since the combustion exhaust gas containing the unburned components extracted from the melting chamber 5 is not directly introduced into the secondary combustion chamber 2, the combustion of the unburned components moved from the melting chamber 5 through the communicating portion 3 is performed. Can be carried out satisfactorily, and therefore C at the exit of the furnace
Generation of O can be suppressed.

By the way, it is preferable to mix the combustion exhaust gas with the temperature raising combustion air when, for example, the inside of the melting chamber 5 is operated at a predetermined temperature or higher. That is, at the start of combustion, only the combustion air for heating is supplied until the temperature in the melting chamber 5 reaches a temperature at which the fuel is sufficiently self-ignited (for example, 900 ° C.), and is supplied from the fuel supply nozzle 12. When it is considered that the fuel burns stably, and when the temperature in the melting chamber 5 exceeds the self-ignition temperature, the supply of the combustion air for heating is stopped and only the combustion air for low NO _x is discharged. The flue gas is supplied, and thereafter, the flue gas is supplied to the combustion air for heating. Of course, the combustion exhaust gas may be mixed with the temperature raising combustion air at a low temperature when the inside of the melting chamber 5 is not operated at a predetermined temperature or higher.

As described above, when the low NO _x combustion air is supplied straight into the melting chamber 5 at a high speed, it does not directly mix with the fuel supplied from the fuel supply nozzle 12, and this supply is also performed. Combustion exhaust gas that has sufficiently radiated heat at its lower portion (ash melting portion) is attracted to the space around the (jetted) fuel. Since the combustion air is supplied from the low NO _x combustion air supply nozzle 13 into the attracted combustion exhaust gas, the combustion air is diluted with the low temperature combustion exhaust gas and the fuel is also diluted with the low temperature combustion exhaust gas. After that, since it is mixed with the combustion air diluted with the combustion exhaust gas, the slow combustion with low oxygen concentration is effectively performed. That is, in addition to suppressing the generation of thermal NO _x based on maintaining the low temperature of the flame by supplying low NO _x combustion air, it is possible to further (further) reduce NO _x by mixing combustion exhaust gas.

In the first embodiment, the combustion exhaust gas extracted from the slag discharge chamber 7 is introduced (mixed) into the temperature rising combustion air supply nozzle 11 of the combustion device 4, that is, the combustion air. However, the exhaust gas introduction pipe 22 has a low N
Suppressing an increase in the fuel quantity with O also _x combustion air supply connected to the nozzle 13 side flue gas so as to introduce into the molten chamber 5 from the nozzle 13, it is possible to further reduce of the NO _x can do.

Further, as described above, the combustion air supply for heating is used.
Supply nozzle 11 or low NO_xCombustion air supply nozzle 13
I tried to introduce combustion exhaust gas to, but instead of this,
The combustion exhaust gas is introduced into the fuel supply nozzle 12.
May be. Also in this case, NO _xCan be reduced
In addition, it is possible to suppress the increase in the fuel amount.

Further, the combustion exhaust gas may be introduced into both the temperature raising combustion air supply nozzle 11 and the fuel supply nozzle 12, and both the low NO _x combustion air supply nozzle 13 and the fuel supply nozzle 12 may be introduced. Combustion exhaust gas may be introduced, and in these cases as well, it is possible to further reduce NO _x and suppress an increase in the amount of fuel.

Here, the second and third embodiments will be further described. However, the points different from the first embodiment are the combustion device and the portion where the combustion exhaust gas is introduced, and therefore the respective embodiments shown below. In the embodiment, only the different portions will be described, and regarding the configuration (including the drawings), the same components as those in the first embodiment will be denoted by the same reference numerals and the description thereof will be omitted.

The combustion method in the ash melting furnace according to the second embodiment of the present invention will be described below with reference to FIG. In the combustion apparatus according to the first embodiment, the combustion air supply nozzle 11 for temperature increase and the combustion air supply nozzle 13 for low NO _x are provided, and the combustion exhaust gas extracted from the slag discharge chamber 7 is increased in temperature. Combustion air or low NO _x
However, in the second embodiment, the low NO _x combustion air supply nozzle is not provided.

That is, as shown in FIG. 3, in the state where the low NO _x combustion air supply nozzle is not provided,
By connecting the exhaust gas introduction pipe 22 to the combustion air supply nozzle 31 side (of course, it may be directly connected to the combustion air supply nozzle or may be connected to the combustion air supply pipe to the nozzle), and slag discharge The combustion exhaust gas from the chamber 7 is introduced directly into the combustion air. In the first embodiment, because the low NO _x combustion air supply nozzle is provided, the combustion air supply nozzle 11 is named for temperature raising, but it is not necessary to distinguish it here. Therefore, it is simply referred to as a combustion air supply nozzle and is given a different number.

Also in this case, as in the first embodiment,
It is possible to reduce NO _x and suppress an increase in the amount of fuel. Further, in the second embodiment, the combustion exhaust gas is introduced into the combustion air supply nozzle 31, but, for example, the combustion air supply nozzle 31
Alternatively, the combustion exhaust gas may be introduced into the fuel supply nozzle 12, or the combustion exhaust gas may be introduced into both the combustion air supply nozzle 31 and the fuel supply nozzle 12. Of course, also in these cases, it is possible to reduce NO _x and suppress an increase in the amount of fuel.

Next, a combustion method in the ash melting furnace according to the third embodiment of the present invention will be described with reference to FIG. The combustion apparatus according to the third embodiment does not include the low NO _x combustion air supply nozzle, and the fuel supply nozzles are arranged both inside and outside the temperature rising combustion air supply nozzle.

That is, as shown by the solid line in FIG. 4, the first fuel supply nozzle 41 is connected to the temperature raising combustion air supply nozzle 11
And a plurality of second fuel supply nozzles 42 are arranged around the temperature rising combustion air supply nozzle 11,
Further, the exhaust gas introduction pipe 22 is connected to the combustion air supply nozzle 1 for heating.
The exhaust gas from the slag discharge chamber 7 is directly introduced into the temperature raising combustion air by connecting to the first side.

Also in the third embodiment, the first
Similar to the embodiment, on which aimed at suppression of NOx without mixing with directly combustion air also fuel supplied from the second fuel supply nozzle 42, by the incorporation of the combustion exhaust gas, a further of the NO _x It is possible to reduce the amount of fuel and to suppress an increase in the amount of fuel.

In the third embodiment, the combustion exhaust gas is introduced into the temperature-raising combustion air supply nozzle 11, but instead of being introduced into the temperature-raising combustion air supply nozzle 11, the first embodiment It may be introduced into the fuel supply nozzle 41 and / or the second fuel supply nozzle 42. Further, as described in the third embodiment, the combustion exhaust gas is introduced into the temperature raising combustion air supply nozzle 11. In addition to the above, the first fuel supply nozzle 41 and / or
Alternatively, it may be introduced into the second fuel supply nozzle 42. Again, it is possible to suppress the increase of the fuel amount it is possible to further reduce the NO _x.

[0044]

As described above, according to the combustion method in the ash melting furnace according to claims 1 to 9 of the present invention, a part of the combustion exhaust gas generated in the melting chamber is extracted through the slag discharge chamber. In addition, since it is mixed in any of the combustion air supply nozzles and the fuel supply nozzles, the oxygen concentration in the combustion air decreases and the combustion becomes slow, so that the combustion air ratio is 1. Without making it less than 0
It is possible to suppress the generation of NO _x and suppress an increase in the amount of fuel.

[Brief description of drawings]

FIG. 1 is a sectional view showing a schematic configuration of an ash melting furnace according to a first embodiment of the present invention.

FIG. 2 is a sectional view of a main part of a melting chamber in the ash melting furnace.

FIG. 3 is a sectional view showing a schematic configuration of an ash melting furnace according to a second embodiment of the present invention.

FIG. 4 is a sectional view showing a schematic configuration of an ash melting furnace according to a third embodiment of the present invention.

FIG. 5 is a sectional view showing a schematic configuration of a conventional ash melting furnace.

[Explanation of symbols]

1 furnace body 2 the secondary combustion chamber 3 communicating section 4 combustion apparatus 5 melters 6 ash inlet 7 slag discharge chamber 9 ash pressing device 11 for heating the combustion air supply nozzles 12 fuel supply nozzle 13 combustion air supply nozzle for low NO _x 21 ejector 22 exhaust gas introduction pipe 31 combustion air supply nozzle 41 first fuel supply nozzle 42 second fuel supply nozzle

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yoshitoshi Sekiguchi             1-89 South Kohoku, Suminoe-ku, Osaka-shi, Osaka             Issue Hitachi Shipbuilding Co., Ltd. (72) Inventor Kunio Sasaki             1-89 South Kohoku, Suminoe-ku, Osaka-shi, Osaka             Issue Hitachi Shipbuilding Co., Ltd. (72) Inventor Hide Momota             1-89 South Kohoku, Suminoe-ku, Osaka-shi, Osaka             Issue Hitachi Shipbuilding Co., Ltd. (72) Inventor Morio Sugiura             1-89 South Kohoku, Suminoe-ku, Osaka-shi, Osaka             Issue Hitachi Shipbuilding Co., Ltd. F term (reference) 3K061 NB03 NB15                 3K078 AA04 BA02 CA03 CA06 CA07                       CA11                 4D004 AA36 CA28 CA29 CB02 CB34

Claims (9)

[Claims] 1. The ash supplied from the ash feed port is introduced into a melting chamber, and the ash is melted by a combustion device having a combustion air supply nozzle having a fuel supply nozzle arranged therein to supply combustion air, and then the ash is melted. Combustion method in ash melting furnace that discharges slag from the slag discharge chamber and guides combustion exhaust gas generated in the melting chamber to a secondary combustion chamber provided near the ash input port to burn unburned components A part of the combustion exhaust gas generated in the melting chamber is extracted from the side wall of the slag discharge chamber, and the combustion exhaust gas is introduced into the combustion air supply nozzle of the combustion device. Combustion method in a furnace. 2. The ash supplied from the ash charging port is introduced into a melting chamber, and the ash is melted by a combustion device equipped with a combustion air supply nozzle having a fuel supply nozzle disposed inside to supply combustion air, and then the ash is melted. Combustion method in an ash melting furnace that discharges slag from the slag discharge chamber and guides the combustion exhaust gas generated in the melting chamber to the secondary combustion chamber provided near the ash inlet to burn unburned components In addition, a part of the combustion exhaust gas generated in the melting chamber is extracted from the side wall portion of the slag discharge chamber, and the combustion exhaust gas is introduced into the fuel supply nozzle of the combustion device. Combustion method in. 3. The combustion method in an ash melting furnace according to claim 1, wherein the combustion exhaust gas extracted from the slag discharge chamber is introduced into a fuel supply nozzle of a combustion device. 4. A temperature raising combustion air supply nozzle for guiding the ash supplied from the ash input port to a melting chamber and having a fuel supply nozzle disposed therein for supplying temperature raising combustion air, and the temperature raising combustion air. Low NO because it is installed in a place different from the supply nozzle
was melted by the combustion apparatus comprising a low NO _x combustion air supply nozzle for supplying a _x combustion air, while discharging the molten slag from the slag discharge chamber, ash combustion exhaust gas generated at the melter It is a combustion method in an ash melting furnace that guides a secondary combustion chamber provided at a position near the charging port to burn unburned components, and a part of the combustion exhaust gas generated in the melting chamber is transferred to the slag discharge chamber. A combustion method in an ash melting furnace, characterized in that the combustion exhaust gas is extracted from a side wall portion and introduced into a temperature rising combustion air supply nozzle and / or the low NO _x combustion air supply nozzle of the combustion apparatus. 5. A temperature rising combustion air supply nozzle for guiding the ash supplied from the ash input port to a melting chamber and having a fuel supply nozzle disposed therein for supplying temperature rising combustion air, and the temperature rising combustion air. Low NO because it is installed in a place different from the supply nozzle
was melted by the combustion apparatus comprising a low NO _x combustion air supply nozzle for supplying a _x combustion air, while discharging the molten slag from the slag discharge chamber, ash combustion exhaust gas generated at the melter It is a combustion method in an ash melting furnace that guides a secondary combustion chamber provided at a position near the charging port to burn unburned components, and a part of the combustion exhaust gas generated in the melting chamber is transferred to the slag discharge chamber. A combustion method in an ash melting furnace, characterized in that the combustion exhaust gas is extracted from a side wall portion and introduced into a fuel supply nozzle of the combustion device. 6. The combustion method in an ash melting furnace according to claim 4, wherein the combustion exhaust gas extracted from the slag discharge chamber is introduced into a fuel supply nozzle of a combustion device. 7. A combustion air supply nozzle for raising temperature, which guides ash supplied from an ash input port to a melting chamber and has a first fuel supply nozzle arranged therein to supply combustion air for temperature rise, and a temperature raising combustion air supply nozzle for this temperature rise. The molten slag is discharged from the slag discharge chamber after being melted by a combustion device having a second fuel supply nozzle provided at a location different from the combustion air supply nozzle, and the combustion exhaust gas generated in the melting chamber. Is a combustion method in an ash melting furnace in which the unburned components are burned by introducing the slag to a secondary combustion chamber provided near the ash charging port, and a part of the combustion exhaust gas generated in the melting chamber is discharged by slag. A combustion method in an ash melting furnace, characterized in that the combustion exhaust gas is extracted from a side wall portion of the chamber and is introduced into a temperature rising combustion air supply nozzle of the combustion device. 8. A temperature rising combustion air supply nozzle for guiding the ash supplied from an ash charging port to a melting chamber and having a first fuel supply nozzle disposed therein to supply temperature rising combustion air, and a temperature raising combustion air supply nozzle for this temperature rising. The molten slag is discharged from the slag discharge chamber after being melted by a combustion device having a second fuel supply nozzle provided at a location different from the combustion air supply nozzle, and the combustion exhaust gas generated in the melting chamber. Is a combustion method in an ash melting furnace in which the unburned components are burned by introducing the slag to a secondary combustion chamber provided near the ash charging port, and a part of the combustion exhaust gas generated in the melting chamber is discharged from the slag. A combustion method in an ash melting furnace, characterized in that the combustion exhaust gas is extracted from the side wall of the chamber and is introduced into the first fuel supply nozzle and / or the second fuel supply nozzle of the combustion device. 9. Combustion in an ash melting furnace according to claim 7, wherein the combustion exhaust gas extracted from the slag discharge chamber is introduced into the first fuel supply nozzle and / or the second fuel supply nozzle of the combustion device. Method.