JP3017661B2 - Dry distillation gasification and incineration of waste - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an apparatus for incinerating waste such as waste tires.

[0002]

2. Description of the Related Art An apparatus for incinerating waste such as waste tires is disclosed in, for example, Japanese Patent Application Laid-Open No. 2-135280.
Patent Document 1 discloses a dry distillation gasification and incineration treatment apparatus.

[0003] This dry distillation gasification and incineration apparatus burns a part of the waste housed in a gasification furnace, and carbonizes (resolves) the remainder of the waste by the heat of combustion, and finally, While the waste is completely burned and ashed,
A combustible gas generated by the dry distillation of the waste is introduced from a gasifier into a combustion furnace through a gas passage, and the combustible gas is mixed with oxygen (air) in the combustion furnace to form the combustible gas. Is burned at a temperature at which the generation of nitrogen oxides or the like is sufficiently reduced, whereby the waste is incinerated without causing environmental pollution by nitrogen oxides or the like.

[0004] In this case, the combustion of a part of the waste in the gasification furnace and the dry distillation of the remainder, and the combustion of the combustible gas generated by the dry distillation in the combustion furnace are performed as follows.

That is, the combustion of a part of the waste in the gasification furnace and the distillation of the remaining part are started by igniting a part of the waste after storing the waste in the gasification furnace, As described above, when a part of the waste starts burning due to the ignition, the combustion heat starts the carbonization of the waste to generate combustible gas. The amount of combustible gas generated increases as the carbonization of waste proceeds.

On the other hand, the combustible gas generated in the gasification furnace is introduced into the combustion furnace from the gasification furnace through a gas passage, and further mixed with oxygen required for the combustion in the combustion furnace. It is ignited and burned by an ignition device mounted on the combustion furnace. At this time, the combustion temperature of the combustible gas in the combustion furnace is detected by a temperature sensor provided in the combustion furnace, and the detected combustion temperature of the combustible gas is generated in the gasification furnace after ignition of the waste. As the amount of combustible gas increases and the amount of combustible gas introduced into the combustion furnace increases, the temperature rises. Then, when the combustion of the combustible gas in the combustion furnace is started, the oxygen supply device connected to the gasification furnace changes the combustion temperature of the combustible gas detected by the temperature sensor to nitrogen by the combustion. While adjusting the amount of oxygen supplied to the gasifier so that the combustion temperature at which the generation of oxides and the like is sufficiently low is maintained at a predetermined temperature substantially constant, a part of the waste is added to the gasifier. To supply the oxygen required for the combustion of the coal and for the remaining carbonization.

At the same time, the oxygen supply device connected to the combustion furnace performs complete combustion of the combustible gas in an amount corresponding to the combustion temperature of the combustible gas detected by the temperature sensor, and emits nitrogen oxides. The necessary oxygen is supplied to the combustion furnace while adjusting the amount of oxygen supplied to the combustion furnace so as to perform combustion with a sufficiently small amount of generation.

As a result, the combustion of part of the waste and the dry distillation of the remainder proceeds smoothly in the gasification furnace, and the combustion temperature of the combustible gas in the combustion furnace is set at a combustion temperature at which generation of nitrogen oxides and the like is sufficiently small. While being kept substantially constant, the combustible gas is completely burned without causing environmental pollution, and the combustion heat of the combustible gas is effectively used as a heat source for a boiler or the like.

When the waste is carbonized in the gasification furnace, the ash of the waste proceeds as the partial combustion of the waste progresses. At the same time, the portion of the waste that can be carbonized is reduced while moving to another site where the carbonization is almost completed.

[0010] Therefore, finally, the waste in the gasification furnace is generated in such an amount that the combustion temperature of the combustible gas in the combustion furnace is maintained substantially constant regardless of the supply of oxygen to the gasification furnace. Combustible gas cannot be generated, and the combustion temperature of the combustible gas also decreases. At this stage, most of the waste in the gasifier will burn except for the already incinerated parts.
The combustion results in the final incineration of the waste.

[0011] By the way, in such a dry distillation gasification incineration apparatus, when waste is burned in a gasification furnace with insufficient dry distillation, the amount of generated nitrogen oxides increases.
It is preferable to burn the waste after carbonizing the waste as much as possible. Further, in order to combust flammable gas generated by dry distillation of waste in a combustion furnace while minimizing the generation of nitrogen oxides and the like, the flammable gas must be minimized to generate nitrogen oxides and the like. It is preferable that the combustible gas is generated in the gasifier by performing dry distillation of the waste as much as possible so that the combustion can be performed while maintaining the combustion temperature substantially constant. Further, from the viewpoint of incineration of the waste, it is preferable to smoothly and surely burn and incinerate the waste which has been subjected to the dry distillation at the end of the dry distillation.

For this reason, in the conventional dry distillation gasification and incineration treatment apparatus, as the dry distillation of waste proceeds, the combustion temperature of the flammable gas is kept substantially constant by the oxygen supply device connected to the gasification furnace as described above. Oxygen is supplied to the gasification furnace from below the waste so as to keep the combustion at a constant level, so that the combustion of a part of the waste and the remaining portion can be continuously and stably performed. The oxygen supply device increases the amount of oxygen supplied to the gasification furnace in accordance with the temperature in the gasification furnace detected by a temperature sensor provided in the gasification furnace, thereby increasing the final combustion of waste.・ We promote incineration.

That is, the temperature in the gasification furnace is generally
At a stage where the carbonization of the waste is progressing stably, a part of the heat of the combustion part of the waste is absorbed by the carbonization part, but gradually rises with the progress of the combustion. In the termination stage, since the carbonization portion is reduced and the heat of the combustion portion absorbed by the carbonization portion is reduced, once the temperature rises rapidly, the waste A decreases due to the progress of combustion and incineration of the combustion portion. It descends with. Therefore, when the temperature in the gasification furnace rapidly rises due to the decrease in the carbonization section, when the temperature exceeds a predetermined temperature determined in advance based on experiments, experience, and the like, there is almost no portion where the waste can be carbonized. As a result, the oxygen supply to the gasification furnace is increased to promote the final combustion and incineration of the waste.

However, in such a dry distillation gasification and incineration treatment apparatus, an oxygen supply device is used to promote the final combustion and incineration of the waste at the end stage of the dry distillation of the waste from the lower part of the waste in the gasification furnace. When the amount of oxygen supplied to the furnace is increased, the ashed portion of the waste is blown upward by the supply of the oxygen, and the blown ash is transferred to the combustion furnace through the gas passage together with the combustible gas. Will be introduced. For this reason, combustion failure of combustible gas occurs in the combustion furnace,
Furthermore, despite the fact that the combustible gas is completely burned in the combustion furnace to prevent the generation of nitrogen oxides and the like as described above, ash was mixed in the exhaust gas after the combustion of the combustible gas. There is an inconvenience that it is released into the atmosphere in a state and causes environmental pollution.

After the waste is finally burned and ashed by increasing the amount of oxygen supplied into the gasification furnace by the oxygen supply device, the oxygen supply device is stopped and the gasification furnace and the combustion furnace are stopped. The supply of oxygen to the gas is cut off. Then, the discharge door provided at the bottom of the gasification furnace is opened to collect the ashed waste (ash), and thereafter, new waste is put into the gasification furnace to perform the next incineration treatment. You.

However, when the ash is collected, the ash in the gasification furnace is heated to a high temperature immediately after the incineration and is difficult to handle. Therefore, the ash is left in the gasification furnace for a predetermined time after the incineration. The ash is allowed to cool naturally, and when the ash reaches a temperature at which it can be easily handled, the discharge door is opened and collected. For this reason, the waiting time until the ash is naturally cooled in the gasification furnace becomes long, and it takes a long time before the incineration of the next waste is restarted, and the efficiency of the incineration is significantly reduced. There are inconveniences.

Further, at the stage when the final incineration of the waste is carried out, although the carbonization has been almost completed, there is a small portion that can be carbonized, and the flammability generated by the carbonization of this portion remains. Gas is led to the combustion furnace and burned.

However, since the amount of flammable gas generated at the stage of final incineration of the waste is very small, the supply of oxygen by the oxygen supply device connected to the combustion furnace is performed by dry distillation of the waste. Is performed in the same manner as the stage in which the progress is stable, the adjustment of the oxygen supply amount cannot follow the temperature change of the flammable gas detected by the temperature sensor,
There is a disadvantage that the supply of oxygen becomes excessive with respect to the amount of the flammable gas, and the combustion of the flammable gas tends to become unstable.

[0019]

SUMMARY OF THE INVENTION The present invention has been made to solve such inconvenience, and prevents ash in a gasification furnace from being introduced into a combustion furnace through a gas passage together with combustible gas. It is another object of the present invention to provide a dry distillation gasification and incineration apparatus capable of improving the combustion of combustible gas in the combustion furnace.

Further, the present invention can prevent the ash in the gasification furnace from being introduced into the combustion furnace through the gas passage together with the combustible gas, and then restart the incineration of the waste. It is an object of the present invention to provide a dry distillation gasification and incineration apparatus capable of shortening the time required for incineration and improving the efficiency of incineration.

It is a further object of the present invention to provide a carbonization gasification incineration apparatus capable of stabilizing combustion of combustible gas in a combustion furnace at the stage of carbonization termination.

[0022]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a method for storing waste and burning the remaining part of the waste by the combustion heat while burning a part of the waste. Gasifier that generates flammable gas by heating, a combustion furnace that burns flammable gas introduced from the gasifier through a gas passage, and a first temperature detector that detects a temperature in the gasifier Means, second temperature detecting means for detecting the combustion temperature of the combustible gas in the combustion furnace, and combustion of the combustible gas detected by the second temperature detecting means during the progress of the carbonization of the waste. While adjusting the amount of oxygen supplied to the gasification furnace so as to maintain the temperature substantially constant, oxygen necessary for combustion of part of the waste and dry distillation of the remaining part is supplied to the gasification furnace, Combustion of the waste at the end of carbonization of the waste First oxygen supply means for supplying oxygen that promotes incineration to the gasification furnace from below the waste, wherein the first oxygen supply means includes a first oxygen supply means for terminating the dry distillation of the waste. When the temperature in the gasification furnace detected by the first temperature detection means rises to a predetermined temperature or more with the progress of the combustion of the waste, the amount of oxygen supplied to the gasification furnace is increased. Thus, in the dry distillation gasification and incineration apparatus configured to promote the combustion and incineration of the waste, the waste is provided at a position above the waste at the stage of completion of the dry distillation and directed toward the waste. To
An injection nozzle for injecting oxygen through the first oxygen
When the feed means increases the amount of oxygen supplied to the pre-Symbol gasifier rather promote all the combustion and ashing of the waste at the end stage of the dry distillation, covers the upper layer combustion of the waste is carried out
To prevent ash accumulated at the bottom of the layer from blowing up
As described above, the apparatus is provided with the second oxygen supply means for injecting oxygen from the injection nozzle toward the layer .

According to the present invention, when the amount of oxygen supplied from below the waste into the gasification furnace by the first oxygen supply means is increased to promote the combustion and incineration of the waste,
Since oxygen is injected from the injection nozzle toward the waste, even if the incinerated portion of the waste is going to blow upward, the oxygen injected from the injection nozzle prevents the blow-up. You. Therefore, the ash in the gasification furnace is prevented from being introduced into the combustion furnace through the gas passage together with the flammable gas, and the combustion of the flammable gas in the combustion furnace can be improved. It is possible to prevent the ash from being mixed into the exhaust gas after the burning of the reactive gas and to be released into the atmosphere, and to perform a clean incineration treatment of the waste.

The oxygen injected from the injection nozzle is
Since the fuel is injected from above the waste, oxygen can be satisfactorily supplied to the upper combustion portion of the ash portion of the waste, and the waste can be burned and ashed smoothly.

By the way, the temperature in the gasification furnace generally gradually rises as the partial distillation of the waste proceeds while the carbonization of the waste proceeds. Next, in the end stage of the carbonization, the portion of the waste which can be carbonized is reduced once as the portion which can be carbonized is reduced and then as the burning and incineration of the waste proceeds. However, depending on the storage state of the waste in the gasifier, the type of the waste, and the like, the carbonization is temporarily unstable, and the heat absorption by the carbonization is reduced, and the stage of the carbonization termination The temperature in the gasifier may rise temporarily temporarily before the temperature of the gasification furnace is reached.

Therefore, the present invention provides a method according to the present invention, wherein the first oxygen supply means detects the temperature in the gasification furnace detected by the first temperature detection means at the end of the dry distillation of the waste. The combustion temperature of the combustible gas, which rises to a predetermined temperature or higher with the progress of combustion and is detected by the second temperature detection means, is maintained at a predetermined temperature from the combustion temperature maintained substantially constant during the progress of the dry distillation. When the temperature falls below the temperature, the amount of oxygen supplied to the gasification furnace is increased to promote the combustion and incineration of the waste, and the second oxygen supply means is provided by the first oxygen supply means. When increasing the supply amount of oxygen to the gasifier, oxygen is injected from the injection nozzle.

According to the present invention, as described above, the first
Not only the temperature inside the gasification furnace detected by the temperature detecting means has risen to a predetermined temperature or more that can be regarded as the end of the dry distillation of the waste, but also the second temperature detecting means When the detected combustion temperature of the combustible gas falls from a combustion temperature maintained substantially constant during the progress of the carbonization of the waste to a predetermined temperature or less, it is assumed that the carbonization of the waste is in an end stage. Thus, it is possible to reliably detect a state where the carbonization of the waste has sufficiently proceeded and the portion where the carbonization can be sufficiently reduced.

Further, according to the present invention, the temperature of the gasification furnace detected by the first oxygen supply means by the first temperature detection means at the end of the dry distillation of the waste is determined by the first oxygen supply means. When the temperature rises to a predetermined temperature or higher with the progress of combustion and the predetermined temperature continues for a predetermined time, the amount of oxygen supplied to the gasification furnace is increased to promote the combustion and incineration of the waste. And the second oxygen supply means includes the first oxygen supply means.
When the amount of oxygen supplied to the gasification furnace is increased by the oxygen supply means, oxygen is injected from the injection nozzle.

According to the present invention, as described above, the first
Not only does the temperature in the gasifier detected by the temperature detecting means rise to a predetermined temperature or more that can be regarded as the end of the dry distillation of the waste, but also after the predetermined time, When the temperature in the gasification furnace is equal to or higher than the predetermined temperature, the dry distillation of the waste is considered to be in the end stage. Can be reliably detected.

Further, in the present invention, the first oxygen supply means supplies oxygen for cooling ash in the gasification furnace into the gasification furnace after incineration of the waste is completed. It is characterized by having such a configuration.

According to the present invention, since the inside of the gasification furnace is forcibly cooled by the supply of oxygen after the incineration of the waste is completed, the ash in the gasification furnace can be recovered. The waiting time before cooling to the temperature is reduced. Therefore, it is possible to shorten the time until the incineration of the waste is restarted next, and to improve the efficiency of the incineration.

Further, according to the present invention, the amount of oxygen supplied to the combustion furnace is controlled in accordance with the combustion temperature of the combustible gas detected by the second temperature detecting means when the carbonization of the waste proceeds. A third oxygen supply means is provided for adjusting the amount of oxygen necessary for gas combustion and supplying the oxygen to the combustion furnace. The third oxygen supply means is provided with the first temperature at the end of the dry distillation of the waste. Reducing the oxygen supply amount to the combustion furnace at a predetermined rate after the temperature in the gasification furnace detected by the detection means rises to a predetermined temperature or more with the progress of the combustion of the waste. It is characterized by.

As described above, at the end stage of the carbonization of the waste, since the carbonization of the waste proceeds and the portion that can be carbonized is sufficiently reduced, a small amount of flammable gas is generated in the combustion furnace. It is just burning. Therefore, the third
The oxygen supply means, in the end stage of the dry distillation of the waste, the temperature in the gasification furnace detected by the first temperature detection means becomes higher than a predetermined temperature as the combustion of the waste proceeds If it rises, it is assumed that the dry distillation of the waste has reached the end stage, and thereafter the oxygen supply to the combustion furnace is reduced at a predetermined rate, whereby the oxygen supply is reduced with respect to the combustible gas. It can be prevented from becoming excessive. By doing so, the combustible gas can be stably burned even at the end of the dry distillation.

[0034]

Next, an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.
FIG. 1 is an explanatory diagram of an example of a dry distillation gasification and incineration apparatus of the present invention, FIG. 2 is a diagram for explaining the operation of the apparatus, and FIG. 3 is another dry distillation gasification and incineration processing apparatus of the present invention. It is a diagram for explaining the operation in the example.

In FIG. 1, reference numeral 1 denotes a gasification furnace for storing waste A such as waste tires and performing dry distillation / gasification and combustion / ashing of the waste A, and reference numeral 2 denotes a combustible gas generated by dry distillation of the waste A. The combustion furnace 3 for burning is a first oxygen supply means for supplying oxygen (air) to the gasification furnace 1, and 3a is a first oxygen supply means for supplying oxygen to the waste A in the gasification furnace 1 at the end of the dry distillation. The second oxygen supply means 4 is a third oxygen supply means for supplying oxygen (air) to the combustion furnace 2. Further, in the figure, a to e are ashed layers a, glowing layers b, fluidized layers c formed sequentially from the lower side to the upper side inside the gasification furnace 1 during the dry distillation of the waste A. The heat transfer layer d and the gas layer e.

An inlet 6 having an opening door 5 that can be opened and closed is formed on the upper surface of the gasifier 1, and waste A can be charged into the gasifier 1 from the inlet 6. The lower part of the gasification furnace 1 is formed in the shape of a truncated cone protruding downward, and a discharge port 7a having a discharge door 7 that can be opened and closed is formed at the bottom thereof, and the waste A is ashed from the discharge port 7a. This portion can be discharged from the gasification furnace 1. When the charging door 5 and the discharging door 7 are closed, the inside of the gasification furnace 1 is substantially shut off from the outside air.
Vacancies 10 and 11 are formed on the outer surface of the discharge door 7 and the sloped side wall 8 at the lower part of the gasification furnace 1, respectively, which are isolated from the inside of the gasification furnace 1. And these vacancies 1
Reference numerals 0 and 11 are connected to the inside of the gasification furnace 1 through air supply ports 12 provided in the discharge door 7 and the side wall portion 8, respectively.

A plurality of injection nozzles 9 are mounted on the upper part of the side wall 8 of the gasification furnace 1 at equal intervals in the circumferential direction. The injection nozzle 9 has its injection port 9a disposed on the same plane as the inner surface of the side wall portion 8, and the injection port 9a is located above the red-hot layer b formed in the gasification furnace 1 at the end of the dry distillation. Is disposed so as to be directed to the glow layer b at a position, and injects oxygen toward the glow layer b so as to cover above the glow layer b where the combustion of the waste A is performed on the upper layer side of the incineration layer a It has become.

An ignition device (ignition means) 13 for igniting the waste A stored in the gasification furnace 1 is attached to a lower portion of the side wall portion 8 of the gasification furnace 1. This ignition device 1
Reference numeral 3 denotes an ignition burner or the like, which is connected via a supply pipe 15 to a fuel supply device 14 such as auxiliary fuel oil provided outside the gasification furnace 1. With this configuration, the ignition device 13 is connected to the fuel supply device 14 from the supply pipe 15.
By burning the fuel supplied via the gas generator, a combustion flame is generated toward the inside of the gasification furnace 1, and the combustion flame ignites the waste A in the gasification furnace 1.

On the outer periphery of the gasification furnace 1, a water jacket 16 is formed as a cooling structure, which is separated from the inside of the gasification furnace 1. Above the water jacket 16, the water level in the water jacket 16 is detected. A water level sensor 17 is mounted.

In the figure, reference numeral 18 denotes the water jacket 1
6 is a water supply means for supplying water to the water supply means 6.
A water supply device 19 provided outside the gasification furnace 1, a water supply pipe 20 connecting the water supply device 19 and the water jacket 16, an on-off valve 21 provided in the water supply pipe 20,
An on-off valve controller 22 for appropriately opening and closing the on-off valve 21 is provided. The detection signal of the water level sensor 17 is input to the on-off valve controller 22.

In this case, the on-off valve controller 22 controls the on-off valve 2
1 includes a drive unit 22a such as a motor for opening and closing the drive unit 1 and a control unit 22b including a CPU and the like for controlling the operation of the drive unit 22a. Activate 22a.

With this configuration, the water supply means 18 supplies water to the water jacket 16 from the water supply device 19 via the water supply pipe 20 by appropriately opening the on-off valve 21 by the on-off valve controller 22. The controller 22 opens and closes the on-off valve 21 so that the water level detected by the water level sensor 17 becomes a predetermined water level.

In the figure, reference numeral 23 denotes a temperature sensor (first temperature detecting means) for detecting the temperature T ₁ inside the gasification furnace 1, and this temperature sensor 23 is provided above the gasification furnace 1. Installed.

The combustion furnace 2 burns a combustible gas generated by carbonization of the waste A and oxygen (air) required for complete combustion thereof, and burns the combustible gas mixed with the oxygen. And a combustion unit 25.
Is connected to the burner section 24 at the tip end side of the burner section 24. The combustion unit 25 includes a temperature sensor (second temperature detection means) 2 for detecting the combustion temperature T ₂ of the combustible gas.
6 are attached.

At the rear end of the burner section 24, a gas pipe 28 which is a gas passage derived from a connecting section 27 provided in the upper part of the gasification furnace 1 in communication with the inside thereof is connected. The flammable gas generated by the dry distillation of the waste A inside 1 is introduced into the burner unit 24 through the gas pipe 28.

An empty space 29 is formed in the outer peripheral portion of the burner portion 24 and is isolated from the inside of the burner portion 24. The empty space 29 is formed by a plurality of holes formed in the inner peripheral portion of the burner portion 24. It communicates with the inside of the burner section 24 via the nozzle hole 30.

An ignition device 3 for igniting the combustible gas introduced therein is provided at the rear end of the burner section 24.
1 is attached. The ignition device 31 is configured by an ignition burner or the like, like the ignition device 13, and is connected to the fuel supply device 14 via a supply pipe 32. With this configuration, the ignition device 31 causes the fuel supplied from the fuel supply device 14 via the supply pipe 32 to burn, so that the combustion device 25
, A combustion flame is generated, and the combustion flame ignites the combustible gas introduced into the combustion section 25 via the burner section 24.

In this case, the ignition device 31 includes a control unit 31a for controlling the ignition operation, and the control unit 31a
, A detection signal of the temperature sensor 26 is input. As will be described later in detail, the control unit 31a of the ignition device 31
In this configuration, the ignition operation of the ignition device 31 is appropriately performed according to the combustion temperature of the combustible gas detected by the temperature sensor 26.

The combustion furnace 2 is connected to, for example, a boiler device 33 that uses the heat of combustion of the combustible gas burned in the combustion section 25 as a heat source.

The first oxygen supply means 3 comprises a gasifier 1
And an oxygen supply fan 34 provided outside the gasification furnace 1.
Oxygen supply pipe 35 derived from the main oxygen supply pipe 3
5 and a pair of oxygen supply pipes 36 and 37 connected to the empty chambers 10 and 11 of the gasification furnace 1, respectively, and on-off valves 38 and 37 provided in the oxygen supply pipes 36 and 37, respectively.
39, on-off valve controllers (on-off valve control means) 40, 41 for opening and closing the on-off valves 38, 39 as appropriate, respectively, and the on-off valve 3
And an oxygen supply fan 34a for cooling interposed in an oxygen supply pipe 36 upstream of the on-off valve controller 8.
The detection signal of the temperature sensor 26 is inputted, and the on-off valve controller 4
1, the detection signals of both the temperature sensor 26 and the temperature sensor 23 are input.

In this case, the on-off valve controller 40 controls the on-off valve 3
And a control unit 40b including a CPU for controlling the operation of the drive unit 40a. The control unit 40b drives the drive unit 40a in response to a detection signal of the temperature sensor 26. Activate 40a. Similarly, the opening / closing valve controller 41 includes a driving unit 41a for opening and closing the opening / closing valve 39 and a control unit 4 for controlling the operation of the driving unit 41a.
1b, and the control unit 41b includes the temperature sensor 2
The drive unit 41a is operated in accordance with both the detection signals 3 and 26.

With this configuration, the first oxygen supply means 3
The opening / closing valve 38 is opened by the opening / closing valve controller 40 during the dry distillation of the waste A, whereby the oxygen supply fan 34
Of the gasifier 1 through the oxygen supply pipes 35 and 36
Oxygen (air) is supplied to the gasification furnace 1 through the air supply port 12. At this time, the on-off valve controller 40
Is adapted to adjust the opening of the on-off valve 38 in accordance with the combustion temperature of the flammable gas detected by the temperature sensor 26.

Further, the first oxygen supply means 3 includes a waste A
At the end of dry distillation (ashing stage), the on-off valve 39 is also opened by the on-off valve controller 41 in parallel with the on-off valve 38 being opened. Oxygen (air) is supplied to the vacant chamber 11 of the gasification furnace 1 via 37, and oxygen is supplied from the vacant chamber 11 to the inside of the gasification furnace 1 via the air supply port 12. I have. At this time, the on-off valve controller 41 determines the temperature inside the gasification furnace 1 detected by the temperature sensor 23,
The on-off valve 39 is opened at a predetermined timing based on the flammable gas combustion temperature detected by the temperature sensor 26.

Further, the first oxygen supply means 3 operates the on-off valve controllers 40 and 41 after the end of the incineration of the waste A.
By opening the on-off valves 38 and 39 for a predetermined time,
Oxygen (air) is supplied from the oxygen supply fan 34 to the cavities 10 and 11 of the gasification furnace 1 through the oxygen supply pipes 36 and 37, and gasified from the vacancies 10 and 11 through the air supply port 12. Oxygen is supplied to the inside of the furnace 1, and the cooling oxygen supply fan 34a is driven.

The second oxygen supply means 3a injects oxygen toward the waste A in the gasification furnace 1 at the end of the dry distillation (ashing stage). The oxygen supply fan 34, the main oxygen supply A pipe 35, an oxygen supply pipe 37, an on-off valve 39, an on-off valve controller 41, and an oxygen supply pipe 37 branched from the oxygen supply pipe 37 downstream of the on-off valve 39 and connected to the injection nozzle 9.
a.

With this configuration, the second oxygen supply means 3
a, the on-off valve 39 is opened by the on-off valve controller 41 in parallel with the on-off valve 38 of the first oxygen supply means 3 being opened at the end stage of the dry distillation of the waste A (ashing stage). And oxygen supply pipes 35, 3 from the oxygen supply fan 34.
Oxygen (air) is supplied to the injection nozzle 9 through the injection nozzles 9 and 37a, and further, the red-hot layer b
Oxygen is injected toward the red-hot layer b so as to cover the upper part of the red-hot layer. Further, as described in the first oxygen supply means 3, the on-off valve 39 is opened for a predetermined time even after the end of the incineration of the waste A. Oxygen is injected.

The third oxygen supply means 4 supplies oxygen to the combustion furnace 2. The third oxygen supply means 4 includes the oxygen supply fan 34 and the main oxygen supply pipe 35, and is branched from the main oxygen supply pipe 35 to supply the combustion gas. A pair of oxygen supply pipes 42 and 43 connected to the empty chamber 29 of the furnace 2, on-off valves 44 and 45 provided on the oxygen supply pipes 42 and 43, and on-off valve control for appropriately opening and closing the on-off valves 44. And an on-off valve controller 46
, Detection signals of both the temperature sensor 26 and the temperature sensor 23 are input.

In this case, the on-off valve controller 46 is, like the on-off valve controllers 40 and 41, constituted by a drive unit 46a for opening and closing the on-off valve 44 and a control unit 46b for controlling the operation of the drive unit 46a. The control unit 46b operates the drive unit 46a in accordance with both detection signals of the temperature sensors 23 and 26.

With this configuration, the third oxygen supply means 4
When the dry distillation of the waste A proceeds, the on-off valve 44 is opened by the on-off valve controller 46 as appropriate, so that the oxygen is supplied from the oxygen supply fan 34 to the empty chamber 29 of the combustion furnace 2 via the oxygen supply pipes 35 and 42. Oxygen (air) is supplied, and oxygen is supplied from the empty chamber 29 to the burner 24 of the combustion furnace 2 through the nozzle hole 30. At this time, the on-off valve controller 46 opens the on-off valve 44 according to the combustion temperature of the combustible gas detected by the temperature sensor 26.

In this case, the on-off valve 45 is configured to be able to be opened and closed manually, and the oxygen from the oxygen supply fan 34 to the burner section 24 can also be changed by manually opening and closing the on-off valve 45 appropriately. The supply amount can be adjusted.

Further, the third oxygen supply means 4 includes a waste A
In the end stage of the dry distillation, the on-off valve controller 46 controls the opening degree of the on-off valve 44 in accordance with the temperature in the gasification furnace 1 detected by the temperature sensor 23,
The opening degree of the on-off valve 44 is reduced at a predetermined rate in accordance with the decrease in the combustion temperature of the flammable gas detected by the above.

Next, the operation of the dry distillation gasification and incineration equipment will be described.

In FIG. 1, when incinerating waste A, first, the charging door 5 of the gasification furnace 1 is opened, and the waste A is charged into the gasification furnace 1.

Next, after closing the charging door 5, the igniter 13 is operated, thereby igniting the waste A in the gasification furnace 1 and partially burning the waste A. Begin. Then, when the partial combustion of the waste A is started, the ignition device 13 is stopped.

In this case, prior to the ignition, the water jacket 16 of the gasifier 1 is appropriately supplied with water from the water supply device 19 of the water supply means 18 via the water supply pipe 20 as described above. The ignition device 31 of the combustion furnace 2 is operated under the control of the control unit 31a. Further, in order to introduce flammable gas generated as described later into the combustion furnace 2, the internal space of the gasification furnace 1 is filled with the combustion furnace 2 and the gas pipe by a suction fan (not shown) provided in the boiler device 33. The air is appropriately sucked in through the air inlet 28.

At the time of this ignition, the on-off valve 38 of the first oxygen supply means 3 is controlled by the on-off valve controller 40 as shown in FIG.
As shown in (b), the opening is previously opened at a relatively small predetermined opening degree, so that the oxygen supply fan 34, the oxygen supply pipes 35 and 36, and the vacant A relatively small amount of oxygen is supplied into the gasification furnace 1 through the gas supply port 12. For this reason, the ignition of the waste A by the ignition device 13 is performed using the oxygen existing in the gasification furnace 1 and a small amount of oxygen supplied from the air supply port 12 of the empty room 10. At the time of this ignition, the on-off valves 39 of the first and second oxygen supply means 3 and 3a and the on-off valves 44 and 45 of the third oxygen supply means 4 are both closed.

When the ignition is performed, the waste A in the gasification furnace 1 is made up of the oxygen whose lower layer is present in the gasification furnace 1 and a small amount of oxygen supplied from the oxygen supply fan 34. It burns gradually while consuming, and by the heat of combustion,
The upper part of the waste A starts to dry-distill and starts to generate flammable gas by the dry-distillation, and this flammable gas is supplied from the gasification furnace 1 via the gas pipe 28 to the burner 24 of the combustion furnace 2. Will be introduced. The combustible gas introduced into the burner section 24 is mixed with air (oxygen) existing in the combustion furnace 2 and ignited by the ignition device 31, whereby the combustible gas is removed. Starts to burn in the combustion section 25.

At this time, the combustion of the lower part of the waste A is gradually stabilized while consuming a small amount of oxygen supplied from the oxygen supply fan 34, and the range is gradually expanded. Then, as the combustion of the lower part of the waste A is stabilized, the waste A
As the carbonization of the upper layer progresses, the amount of combustible gas generated by the carbonization also increases. For this reason, the amount of combustible gas introduced into the combustion furnace 2 also increases.
As shown in (a), the combustion temperature T ₂ of the combustible gas in the combustion furnace ₂ also increases.

At this time, the combustion temperature T of the combustible gas
₂ is detected by the temperature sensor 26, the combustion temperature T ₂ of the combustible gas detected by the temperature sensor 26 reaches the predetermined temperature T _2a predetermined (FIGS. 2 (a) and 2 (b ) point of Viewing the t _1), the first oxygen supply means 3
As shown in FIG. 2B, the on-off valve controller 40 opens the on-off valve 38 to a slightly larger opening than the initial opening for a predetermined time, and further, after the predetermined time elapses, The on-off valve 38 is opened to a larger opening.

As described above, by gradually increasing the opening degree of the on-off valve 38 in a stepwise manner, the lower portion of the waste A is supplied from the oxygen supply fan 34 to the extent necessary for its continuous combustion. Oxygen is supplied, so that combustion in the lower part of the waste A is performed stably without unnecessarily expanding, and dry distillation of the upper part of the waste A also proceeds stably. I will start to do.

Next, the combustion temperature T ₂ of the combustible gas detected by the temperature sensor 26 further rises, so that the combustible gas can spontaneously burn, and the generation of nitrogen oxides and the like by the combustion is reduced. When the temperature reaches a temperature T _2c (T _2a <T _2c <T _2b ) slightly lower than the temperature T _2b (see FIG. 2 (a)) preset as the combustion temperature (FIGS. 2 (a) and 2 (b)). ) point of shown in t _2), the first oxygen supply means 3
The on-off valve controller 40 automatically adjusts the opening of the on-off valve 38 so that the combustion temperature T ₂ of the combustible gas is maintained at the temperature T _2b (see FIG. 2B). Control area).

In the automatic control region, specifically, when the combustion temperature T ₂ becomes lower than the temperature T _2b , the opening of the on-off valve 38 is increased, and the amount of oxygen supplied to the gasification furnace 1 is increased. Thereby, the combustion of the lower part of the waste A is promoted, and the heat of combustion promotes the dry distillation of the upper part of the waste A and the generation of combustible gas by the dry distillation.

Conversely, when the combustion temperature T ₂ becomes higher than the temperature T _2b , the opening of the on-off valve 38 is reduced, and the amount of oxygen supplied to the gasification furnace 1 is reduced. The combustion of the lower part is suppressed, and the carbonization of the upper part of the waste A by the heat of combustion and the generation of combustible gas due to the carbonization are suppressed.

As a result, the amount of combustible gas generated is controlled, and as shown in FIG. 2A, the combustion temperature T ₂ of the combustible gas is reduced to the temperature T _{2b at} which the combustible gas can spontaneously burn. In this state, the combustion of the lower layer of the waste A and the dry distillation of the upper layer of the waste A proceed stably.

When the combustion temperature T ₂ of the combustible gas is maintained at the temperature T _{2b at} which spontaneous combustion is possible, the ignition device 31 of the combustion furnace 2 is stopped by the control of the control unit 31a. As a result, the combustible gas continuously burns spontaneously. Further, the heat of combustion of the combustible gas is used as a heat source of the boiler device 33.

On the other hand, the combustion of the combustible gas in the combustion furnace 2 requires oxygen, and the oxygen required for the combustion is determined by the temperature sensor 26 as described below. The gas is supplied by the third oxygen supply means 4 according to the gas combustion temperature T ₂ .

That is, the on-off valve controller 46 of the third oxygen supply means 4 opens the on-off valve 44 at an appropriate opening in accordance with the combustion temperature T ₂ of the flammable gas detected by the temperature sensor 26. As described above, the oxygen supply fan 3
4 supplies oxygen to the burner section 24 of the combustion furnace 2 through the oxygen supply pipes 35 and 42, the empty chamber 29 of the combustion furnace 2, and the nozzle hole 30, and the flammable gas introduced into the combustion furnace 2 Oxygen required for combustion is mixed in the burner section 24.

Next, when the combustion temperature T ₂ of the flammable gas detected by the temperature sensor 26 rises and reaches the temperature T _2c , the opening and closing of the third oxygen supply means 4 is performed as shown in FIG. The valve controller 46 automatically adjusts the opening of the on-off valve 44 so that the combustible gas performs combustion in which the generation amount of nitrogen oxides and the like is sufficiently small (see FIG. 2C). Automatic control area).

In the automatic control region, specifically, when the combustion temperature T ₂ becomes low, the opening of the on-off valve 44 is also made small, and the amount of oxygen supplied to the combustion furnace 2 is reduced. _{When 2} is increased, the opening degree of the on-off valve 44 is also increased, and the amount of oxygen supplied to the combustion furnace 2 is increased. In this way, the amount of oxygen supplied to the combustion furnace 2 is adjusted, and thereby, the amount of oxygen that can completely burn the combustible gas introduced into the combustion furnace 2 is mixed with the combustible gas. I do.

When supplying oxygen to the combustion furnace 2, the operator manually operates the on-off valve 45 while checking the combustion state of the flammable gas to reduce the oxygen supply amount to the combustion furnace 2. It is also possible to make adjustments.

During the dry distillation of the waste A in the gasification furnace 1, the temperature sensor 23 detects the temperature T ₁ in the gasification furnace 1, and the detected temperature T ₁ is usually
It changes as shown in FIG.

[0082] That is, the temperature T ₁ of the the gasification furnace 1, in the initial stage of the dry distillation of the waste A, after increased with the start of the combustion of the lower portion of the waste A, the combustion heat is discarded Once the material A is absorbed for the carbonization of the upper layer, it descends once, and subsequently the carbonization of the waste A proceeds stably, and as the combustion of the lower layer of the waste A progresses, Going up.

At this time, as shown in FIG.
Inside, an incineration layer a, a red heat layer b, a fluidization layer c, a heat transfer layer d, and a gas layer e are formed in order from the lower side to the upper side. Of these tanks a to e, The ash layer a generated by the completion of the combustion of the waste A increases as the partial combustion of the waste A progresses, and at the same time, the waste A
The red-hot layer b, in which the combustion is performed, gradually rises and shifts from the lower layer toward the upper layer. Further, with the increase of the incinerated layer a and the rise of the red-hot layer b, the fluidized layer c, the heat transfer layer d, and the gas layer e in which the dry distillation of the waste A proceeds decrease, in other words, the dry distillation. The amount of waste A obtained decreases.

Then, the waste A which can be carbonized as described above
When the amount of oxygen decreases, the combustion of combustible gas in the combustion furnace 2 regardless of the supply of oxygen to the gasifier 1 by opening the on-off valve 38 of the first oxygen supply means 3 at an appropriate opening. An amount of flammable gas that can maintain the temperature T ₂ at a substantially constant temperature T _2b cannot be generated.
The amount of the flammable gas introduced into the combustion furnace 2 eventually decreases, and the combustion temperature T ₂ of the flammable gas finally decreases as shown in FIG. To go.

As described above, when the combustion temperature T ₂ of the combustible gas decreases, the amount of the red-hot layer b occupying the portion of the waste A excluding the ash layer a increases, and the combustion heat thereof increases. The amount T absorbed by the dry distillation of the waste A also decreases, so that the temperature T ₁ in the gasification furnace 1 usually rises rapidly as shown in FIG. At the end of the dry distillation of the waste A, the waste A descends as the burning and incineration of the waste A progresses. And, like this, waste A
In the stage of ending the carbonization of the waste A, that is, the stage in which the final incineration of the waste A proceeds, it is necessary to completely burn the waste A for incineration.

Therefore, when the combustion temperature T ₂ of the combustible gas falls after being maintained at a substantially constant temperature T _2b , the combustion temperature T ₂ of the combustible gas detected by the temperature sensor 26 is detected.
For example, the temperature drops below the predetermined temperature T _2a (see FIG. 2).
(A) to time t ₄ shown in FIG. 2 (d)) and the temperature T ₁ in the gasification furnace 1 detected by the temperature sensor 23 is:
When the temperature of the waste A rises to a predetermined temperature T _1a or more (indicating the end stage of the dry distillation of the waste A) (at time t ₃ shown in FIGS. 2A to 2D), the on-off valve is opened. Controller 41
However, as shown in FIG. 2D, the on-off valve 39 is opened, and gasification is performed from the oxygen supply fan 34 through the oxygen supply pipes 35 and 37, the empty chamber 11 of the gasification furnace 1, and the air supply port 12. Oxygen is supplied into the furnace 1.

As a result, the vacant space 10
Oxygen is supplied from both the air supply port 12 of the empty room 11 and the air supply port 12 of the vacant room 11 to increase the supply amount, thereby promoting the final combustion and incineration of the waste A. At this time, the ash of the ashing layer a tends to blow up above the gasification furnace 1 due to the increase in the oxygen supply amount. In this embodiment, when the on-off valve 39 is opened when the oxygen supply amount increases. Oxygen is supplied to the injection nozzle 9 via the oxygen supply pipe 37a branched from the oxygen supply pipe 37, and the oxygen is supplied from the injection nozzle 9 to the red hot layer b so as to cover the red hot layer b of the waste A. Since the oxygen is injected, the injection of the oxygen prevents the ash of the ashed layer a from being blown up well, and the ash of the ashed layer a is removed together with the combustible gas at the end of the dry distillation, as in the related art. It is prevented from being introduced into the combustion furnace 2 via the gas pipe 28. For this reason, good combustion of the combustible gas is ensured in the combustion furnace 2, and ash is well prevented from being mixed into the exhaust gas after combustion of the combustible gas and released into the atmosphere. A clean incineration treatment of A is performed.

In this case, the temperature T ₁ in the gasification furnace 1 detected by the temperature sensor 23 depends on the type and storage of the waste A even though there is a sufficient portion where the waste A can be carbonized.
Depending on the state and the like, the combustion heat consumed for carbonization may temporarily decrease and increase to the predetermined temperature _T1a or higher. As long as the temperature T ₂ does not drop below the predetermined temperature T _2a , the on-off valve 39 will not be opened. Oxygen that promotes gasification is supplied to the gasification furnace 1, and oxygen that prevents the ash of the ash layer a from blowing up is injected from the injection nozzle 9.

The oxygen supply pipe 37 provided with the on-off valve 39
Is connected to the gasification furnace 1 above the oxygen supply pipe 36 having the on-off valve 38, so that oxygen is supplied to the gasification furnace 1 through the oxygen supply pipe 37. This is performed at a position closer to the glow layer b than the oxygen supply through the glow, and the oxygen injected from the injection nozzle 9 is injected toward the glow layer b, so that sufficient oxygen is supplied to the glow layer b. The final combustion and incineration of the supplied waste A is performed smoothly and reliably.

By the way, at the end of the carbonization, the waste A has almost no carbonizable portion.
It is not completely lost, and a portion that can be carbonized remains, and a small amount of combustible gas generated by carbonization of this portion is burned in the combustion furnace 2. Therefore, if the adjustment of the amount of oxygen supply by the on-off valve controller 46 in the combustion furnace 2 is the same as the stage in which the dry distillation proceeds, the oxygen supplied to the combustible gas in the combustion furnace 2 is reduced. It becomes excessive, and the combustion of the combustible gas tends to become unstable.

Therefore, when the combustion temperature T ₂ of the combustible gas decreases after being maintained at a substantially constant temperature T _2b , the temperature T ₂ in the gasification furnace 1 detected by the temperature sensor 23 is detected.
₁ rises to a predetermined temperature T _1a or more, which indicates the end stage of the distillation of the waste A (FIG. 2).
(A) to FIG. 2 (c) when the shows of t _3), FIG. 2 (c)
As shown, the opening of the on-off valve 44 is reduced to an appropriate opening by the on-off valve controller 46, and the temperature sensor 2
6 when the combustion temperature T ₂ of the flammable gas drops to, for example, the predetermined temperature T _2a or lower (FIG. 2A).
And FIG 2 (c) when the shows of t ₄₎ or later to be reduced in proportion to the combustion temperature T ₂ of the combustible gas opening of the closing valve 44 is detected by the temperature sensor 26.

Thus, the amount of oxygen supplied to the combustion furnace 2 is reduced to a predetermined amount when the carbonization of the waste A reaches the end stage, and the oxygen supply to the combustion furnace thereafter is reduced. Since the amount decreases in proportion to the combustion temperature T ₂ of the combustible gas, it is possible to prevent the supply of excess oxygen to the combustible gas in the combustion furnace 2 and to stabilize the combustible gas. Can be burned.

The degree of opening of the on-off valve 44 is determined by the temperature of the gasification furnace detected by the temperature sensor 23 when the combustion temperature T ₂ of the combustible gas is lowered after being maintained at a substantially constant temperature T _2b. 1 when the temperature T _{1 in} the sample ₁ has risen to a predetermined temperature T _1a or more that indicates the end stage of the dry distillation of the waste A (t ₃ shown in FIGS. 2A to 2C). ),
As shown by a virtual line in FIG. 2C, the temperature may decrease in proportion to the combustion temperature T ₂ of the combustible gas detected by the temperature sensor 26.

After the incineration of the incinerated material A is completed, the on-off valves 38 and 39 are both opened (not shown), and the oxygen supply fan 34
5, 36, gasification furnace 1 through vacant room 10 and air supply port 12
Oxygen is supplied to the inside, and oxygen supply pipes 35, 37,
Oxygen is supplied into the gasification furnace 1 through the vacant chamber 11 and the air supply port 12, and oxygen is further supplied into the gasification furnace 1 through the oxygen supply pipes 35, 37, and 37 a and the injection nozzle 9.
The ash in the gasifier 1 is cooled. In this case, since the injection nozzle 9 injects oxygen from above the ash in the gasification furnace 1, the supply pressure of oxygen supplied from the air supply port 12 of the vacant room 10 decreases, and the injection pressure into the gasification furnace 1 decreases. The supply of oxygen decreases,
There is a possibility that the efficiency of cooling the inside of the gasification furnace 1 may deteriorate.
For this reason, in this embodiment, the supply pressure of oxygen supplied from the air supply port 12 of the vacant room 10 is reduced by driving the cooling oxygen supply fan 34 a interposed in the oxygen supply pipe 36 on the upstream side of the on-off valve 38. To improve the cooling efficiency in the gasification furnace 1.

By the supply of oxygen, the ash in the gasification furnace 1 is forcibly cooled, and the ash is cooled to a temperature that is easy to handle efficiently in a short time. At this time, the discharge door 7 is opened to open the discharge port. The ash in the gasification furnace 1 is recovered from 7a, and then, new waste A is charged into the gasification furnace 1 from the charging port 6, and the next incineration treatment is performed.

The present invention is not limited to the above embodiment, but can be appropriately modified without departing from the gist of the present invention. For example, in the above embodiment, the on-off valve controller 41 of the first oxygen supply means 3 determines the combustion temperature T ₂ of the combustible gas detected by the temperature sensor 26 and the temperature sensor at the end stage of the dry distillation of the waste A. to open the on-off valve 39 in accordance with the temperatures T ₁ in the gasification furnace 1 is detected by 23, thereby, in a state in which carbonization was capable moiety has almost disappeared waste a, the combustion-waste a Oxygen that promotes incineration is supplied to the gasification furnace 1 and oxygen that prevents the ash of the incineration layer a from blowing up is injected from the injection nozzle 9. based on only the temperature T ₁ of the the gasification furnace 1 is detected, it is also possible to open the on-off valve 39 with appropriate timing.

That is, in this case, the on-off valve controller 4
1, only the detection signal of the temperature sensor 23 is input, and the other configuration is the same as that of the above-described dry distillation gasification and incineration treatment apparatus. The on-off valve controller 41 is configured as shown in FIG.
As shown in (a) and (b), as the dry distillation of the waste A proceeds, the temperature T ₁ in the gasification furnace 1 detected by the temperature sensor 23 becomes the predetermined temperature T _1a (FIG. 3 (a) refer) rises above, further, when the predetermined time T _s has elapsed from the time it reaches the said predetermined temperature T _1a, the temperature the temperature T ₁ is equal to or higher than the predetermined temperature T _1a detected by the temperature sensor 23 If so, the on-off valve 39 is opened assuming that the dry distillation has ended, and the amount of oxygen supplied to the gasification furnace 1 is increased.

In this manner, as described above, the temperature T ₁ in the gasification furnace 1 is temporarily increased to the predetermined temperature T _1a or more even though the waste A that can be carbonized is sufficient. In such a case, the on-off valve controller 41 does not open the on-off valve 39, so that continuous carbonization of the waste A proceeds as in the above-described embodiment.

Then, at normal times, the temperature T ₁ in the gasification furnace 1 changes as described above, so that the predetermined time T _s
Is appropriately set, the on-off valve 39 is opened at the end of the dry distillation to increase the amount of oxygen supplied to the gasification furnace 1 and to prevent the ash from rising from the ashing layer a. The generated oxygen is injected from the injection nozzle 9.

[Brief description of the drawings]

FIG. 1 is an explanatory configuration diagram of an example of a dry distillation gasification and incineration treatment apparatus of the present invention.

FIG. 2 is a diagram for explaining the operation of the dry distillation gasification and incineration apparatus.

FIG. 3 is a diagram for explaining the operation of another example of the dry distillation gasification and incineration apparatus of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Gasification furnace, 2 ... Combustion furnace, 3 ... 1st oxygen supply means,
3a: second oxygen supply means, 9: injection nozzle, 23: first temperature detection means, 26: second temperature detection means, 28 ...
Gas passage.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification code FI F23G 5/00 ZAB F23G 5/50 ZABH 5/027 ZAB ZABM 5/50 ZAB 7/12 ZABA F23L 7/00 ZABA 7/12 ZAB B09B 3/00 ZAB F23L 7/00 ZAB 302B

Claims (5)

(57) [Claims] 1. A gasification furnace for storing waste and burning a part of the waste while carbonizing the remainder of the waste by the combustion heat to generate a combustible gas, and a gasification furnace. A combustion furnace for burning a combustible gas introduced from a gas passage through a gas passage, first temperature detecting means for detecting a temperature in the gasification furnace, and detecting a combustion temperature of the combustible gas in the combustion furnace. Second temperature detecting means for performing the oxygen distillation on the gasification furnace so as to maintain the combustion temperature of the combustible gas detected by the second temperature detecting means during the dry distillation of the waste substantially constant. While adjusting the supply amount, oxygen necessary for burning part of the waste and carbonizing the remainder is supplied to the gasifier, and at the end of the carbonization of the waste, the combustion and incineration of the waste is performed. Promoting oxygen from below the waste to the gasifier A first oxygen supply unit for supplying the waste gas, wherein the first oxygen supply unit detects the temperature in the gasification furnace detected by the first temperature detection unit at a stage of terminating the dry distillation of the waste. A carbonization gas that increases the amount of oxygen supplied to the gasifier when the temperature rises to a predetermined temperature or higher as the combustion of waste proceeds, thereby promoting the combustion and incineration of the waste. In the incineration treatment apparatus, oxygen is provided at a position above the waste at the end of the dry distillation and directed toward the waste, and oxygen is injected toward the waste.
The first oxygen supply means should promote the combustion and incineration of the waste at the end of the carbonization.
When increasing the Ku oxygen supply Previous Symbol gasifier, the
Over and above the layer where waste combustion takes place
So that the ash that has accumulated in the
A dry distillation gasification and incineration apparatus comprising a second oxygen supply means for injecting oxygen from an injection nozzle toward the layer . 2. The method according to claim 1, wherein the first oxygen supply means detects the temperature in the gasification furnace detected by the first temperature detection means at a stage of completion of the dry distillation of the waste, as the combustion of the waste progresses. Accordingly, the temperature rises to a predetermined temperature or higher, and the second
When the combustion temperature of the combustible gas detected by the temperature detection means falls from a combustion temperature maintained substantially constant during the dry distillation to a predetermined temperature or less, the combustion and incineration of the waste is promoted. In order to increase the amount of oxygen supplied to the gasification furnace, the second oxygen supply means increases the amount of oxygen supplied to the gasification furnace by the first oxygen supply means. The dry distillation gasification and incineration apparatus according to claim 1, wherein the gas is incinerated. 3. The first oxygen supply means, wherein the temperature in the gasification furnace detected by the first temperature detection means at the end of the dry distillation of the waste is determined by the progress of the combustion of the waste. Along with it rises above a predetermined temperature, and when the predetermined temperature continues for a predetermined time, increasing the oxygen supply amount to the gasification furnace to promote the combustion and incineration of the waste,
The said 2nd oxygen supply means injects oxygen from the said injection nozzle, when increasing the oxygen supply amount to the said gasification furnace by the said 1st oxygen supply means. The Claim 1 or Claim 2 characterized by the above-mentioned. 2. The dry distillation gasification and incineration treatment device according to 2. 4. The first oxygen supply means is configured to supply oxygen for cooling ash in the gasification furnace into the gasification furnace after completion of the incineration of the waste. The dry distillation gasification and incineration treatment apparatus according to any one of claims 1 to 3, wherein: 5. An oxygen supply amount to the combustion furnace according to a combustion temperature of the flammable gas detected by the second temperature detection means when the dry distillation of the waste proceeds. 3rd supply to the combustion furnace after adjusting to the required amount of oxygen
The third oxygen supply means, wherein the temperature in the gasification furnace detected by the first temperature detection means at the end of the dry distillation of the waste is determined by the combustion of the waste. The carbonization gas according to any one of claims 1 to 4, wherein the amount of oxygen supplied to the combustion furnace is reduced at a predetermined rate after the temperature rises to a predetermined temperature or more as the process proceeds. Chemical incineration equipment.