JP3152581B2 - Dry distillation gasification incineration equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for incinerating waste such as waste tires, and more particularly, to a heating apparatus for introducing and heating a part of the heat of combustion in the incineration. It relates to an incineration treatment device.

[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 (pyrolyzes) an undried part of the waste by the heat of combustion. In this method, the waste is completely burned and incinerated, while a combustible gas generated by dry distillation of the waste is introduced from the gasification furnace into a combustion furnace and mixed with oxygen (air) for combustion. Then, the combustion temperature is detected, and the amount of oxygen supplied to the gasification furnace is adjusted so that the gasification furnace is burned at a preset combustion temperature. The waste is incinerated by burning the combustible gas at the preset combustion temperature without causing environmental pollution by nitrogen oxides or the like.

[0004] In such a dry distillation gasification and incineration apparatus,
In order to make effective use of the combustion heat of the combustible gas, a part of the exhaust gas of the combustible gas is introduced into a heat treatment means such as various drying devices such as a rotary kiln and used as a heat source. . At this time, in order to simplify the exhaust equipment, it is desirable that the exhaust gas of the heat treatment unit is exhausted together with the exhaust gas of the combustible gas of the combustion furnace. Further, when the sludge containing the stench component is dried by a drying device such as the rotary kiln, if the stench component vaporized from the sludge is directly discharged into the atmosphere, the stench component may cause environmental pollution. In some cases, it is desired that the exhaust gas from the heat treatment unit is discharged together with the combustible gas exhaust gas from the combustion furnace to thermally decompose and deodorize the malodorous component.

However, if the exhaust gas from the heat treatment means is introduced again into the combustion furnace, there is a disadvantage that the state of the combustible gas in the combustion furnace becomes unstable and the combustion does not proceed smoothly.

[0006]

SUMMARY OF THE INVENTION The present invention has been made to solve such inconvenience, and introduces exhaust gas from a heating means into a combustion furnace without hindering combustion of combustible gas in the combustion furnace. It is another object of the present invention to provide a dry distillation gasification and incineration apparatus capable of preventing environmental pollution due to malodorous components generated from the heat treatment means.

[0007]

In order to achieve the above object, a dry distillation gasification and incineration apparatus of the present invention stores wastes and burns a part of the wastes by the combustion heat. A gasification furnace for carbonizing the undried portion of waste to generate combustible gas, a combustion furnace for burning combustible gas introduced from the gasification furnace, and a combustion temperature of the combustible gas in the combustion furnace A combustion temperature of the combustible gas detected by the gas combustion temperature detection means after spontaneous combustion of the combustible gas is started in the combustion furnace to a preset temperature. Oxygen supply means for supplying oxygen necessary for combustion of a part of the waste and carbonization of the undried portion to the gasification furnace while adjusting the amount of oxygen supplied to the gasification furnace so as to maintain substantially constant; Gasification and incineration equipment equipped with Heat treatment means for introducing and heating a part of the exhaust gas of the combustible gas burned in the combustion furnace, suction introduction means for sucking the exhaust gas of the heat treatment means and introducing it to the combustion furnace; Furnace pressure detecting means for detecting the pressure in the furnace, and exhausting the combustible gas in the combustion furnace so as to maintain the pressure in the combustion furnace detected by the furnace pressure detecting means substantially constant. And a discharge means for sucking the exhaust gas from the heat treatment means and discharging it to the atmosphere.

In the dry distillation gasification and incineration apparatus of the present invention, the heat treatment means is provided with an auxiliary heat source for supplying heat when the combustion of the combustible gas in the combustion furnace is stopped. It is characterized by being.

Further, in the dry distillation gasification and incineration treatment apparatus of the present invention, the combustion furnace communicates with a first combustion section for combustible gas introduced from the gasification furnace, and communicates with the first combustion section. A second combustion unit into which the exhaust gas from the heat treatment unit is introduced by the suction introduction unit; the furnace pressure detection unit is provided in the first combustion unit; and the discharge unit is the second combustion unit. The exhaust of the combustible gas in the combustion furnace and the exhaust of the heat treatment means are sucked through the combustion section and discharged into the atmosphere.

Further, the dry distillation gasification and incineration apparatus of the present invention is provided with a heating furnace for heating the exhaust gas of the heat treatment means sucked by the suction introduction means, and the suction introduction means exhausts the exhaust gas of the heat treatment means. It is introduced into the combustion furnace through the heating furnace. When the heating furnace is provided, a recirculation means for recirculating the exhaust gas heated by the heating furnace to the heat treatment means is provided.

Further, the dry distillation gasification and incineration apparatus of the present invention is provided with a pressure detecting means in the heating means for detecting the air pressure in the heating means, and the suction introducing means is a pressure detecting means in the heating means. Exhaust gas in the heat treatment means is suctioned so as to maintain the detected pressure in the heat treatment means lower than the pressure in the combustion furnace, and exhaust gas introduced into the heat treatment means from the suction introduction means is removed. The pressure is set to be higher than the atmospheric pressure in the combustion furnace.

[0012]

According to the dry distillation gasification and incineration treatment apparatus of the present invention, a part of the waste stored in the gasification furnace is burned, and the ignited portion of the waste is carbonized (pyrolysis) by the combustion heat. And
Eventually, the waste is completely burned and ashed,
The combustible gas generated by the dry distillation of the waste is introduced from the gasification furnace into the combustion furnace and mixed with oxygen (air) for combustion.
Then, the combustion temperature is detected, and the amount of oxygen supplied to the gasification furnace is adjusted so that the gasification furnace is burned at a predetermined combustion temperature, and the dry distillation gasification in the gasification furnace is feedback-controlled, and The waste is incinerated by burning the combustible gas at the preset combustion temperature without causing environmental pollution such as nitrogen oxides.

In the dry distillation gasification and incineration apparatus of the present invention, a part of the exhaust gas of the combustible gas burned in the combustion furnace is introduced into a heating treatment means such as a rotary kiln or other drying apparatus to remove sludge-like waste. A heat treatment such as drying is performed. After performing the heat treatment, the exhaust gas of the heat treatment means is sucked from the inside of the heat treatment means by the suction introduction means, introduced into the combustion furnace, and discharged into the atmosphere together with the exhaust of the combustible gas by the discharge means. Is done.

At this time, the discharging means discharges the combustible gas in the combustion furnace and performs the heat treatment so as to keep the pressure in the combustion furnace detected by the furnace pressure detecting means substantially constant. Since the exhaust gas of the heating means is sucked, even if the exhaust gas of the heat treatment means is introduced into the combustion furnace, the flammable gas stably burns spontaneously in the combustion furnace.

At this time, if the exhaust gas from the heat treatment means contains a combustible component such as a malodorous component, the combustible component is heated in the combustion furnace and thermally decomposed. Therefore, when the exhaust gas from the heat treatment means contains a malodorous component, the malodorous component is deodorized by thermal decomposition.

The waste incineration process is a batch process, and once the carbonization of the waste stored in the furnace is completed,
Until the next waste is stored in the gasifier and carbonization starts,
Combustible gas combustion stops. Therefore, in the dry distillation gasification and incineration apparatus of the present invention, an auxiliary heat source is provided in the heat treatment means, and while the combustion of the combustible gas is stopped in the combustion furnace, heat is supplied from the auxiliary heat source. And continuously operating the heating means without stopping.

The heat of the flammable gas supplied to the heat treatment means is deprived of heat by the heat treatment and the temperature thereof becomes low. Therefore, when the exhaust gas is directly introduced into the combustion furnace, it is detected by the gas combustion temperature detection means. It is feared that an error occurs in the combustion temperature of the combustible gas. Therefore, in the dry distillation gasification and incineration treatment apparatus of the present invention, the combustion furnace is provided so as to communicate with the first combustion section for burning the combustible gas introduced from the gasification furnace, and the first combustion section. A second combustion section into which the gas in the heat treatment means is introduced by the suction introduction means, so that when the gas in the heat treatment means is introduced into the combustion furnace, the flammable gas Influence on the combustion temperature is reduced. At this time, the in-furnace pressure detection means is provided in the first combustion section, and the discharge means is provided in the combustion furnace through the second combustion section communicating with the first combustion section. Since the exhaust of the flammable gas and the exhaust of the heat treatment means are sucked and discharged into the atmosphere, even if the exhaust of the heat treatment means is introduced into the second combustion section, the entire combustion furnace Is maintained substantially constant.

Further, in the dry distillation gasification and incineration apparatus of the present invention, a heating furnace for heating the exhaust air of the heating processing means sucked by the suction introducing means is provided, and the heating processing means heated by the heating furnace is provided. By introducing exhaust gas into the combustion furnace, the effect of the combustible gas on the combustion temperature is further reduced. Further, when the combustion of the combustible gas in the combustion furnace is stopped, if the exhaust gas of the heat treatment means contains a combustible component such as a malodorous component, the combustible component is discharged in the heating furnace. Decomposes thermally when heated.

When the heating furnace is provided, a recirculation means for recirculating the gas heated in the heating furnace to the heat treatment means is provided, so that the temperature of the exhaust of the combustible gas is reduced. Is reduced. Further, when the combustion of the combustible gas in the combustion furnace is stopped, the amount of heat supplied from the auxiliary heat source is reduced.

Further, a pressure detecting means in the heat treatment means for detecting an air pressure in the heat treatment means is provided, and the suction introducing means keeps the pressure in the heat treatment means lower than the pressure in the combustion furnace. The exhaust gas in the heat treatment means is sucked, and the pressure of the exhaust gas introduced from the suction introduction means into the combustion furnace is made higher than the pressure in the combustion furnace. By doing so, the suction of the exhaust gas from the combustion furnace to the heat treatment unit and the introduction of the exhaust gas of the heat treatment unit to the combustion furnace are performed smoothly.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The dry distillation gasification and incineration apparatus of the present invention will be described in more detail with reference to the accompanying drawings.
FIG. 1 is a schematic system configuration diagram showing an example of a dry distillation gasification incineration apparatus of the present invention, FIG. 2 is a schematic system configuration diagram showing another example of a dry distillation gasification incineration device of the present invention, and FIG. It is a schematic system block diagram which shows another example of the dry distillation gasification incineration processing apparatus of this invention.

First, the dry distillation gasification and incineration apparatus shown in FIG. 1 will be described.

The gasification and incineration apparatus shown in FIG. 1 stores two gasification furnaces 1, 1 for storing waste A such as waste tires and performing the carbonization, gasification, combustion and incineration of the waste A. combustion furnace 2 for combusting a combustible gas generated by dry distillation of the object a, the temperature sensor 3 for detecting the combustion temperature T ₁ of the combustible gas in the combustion furnace 2, the oxygen supply for supplying oxygen (air) into the gasification furnace 1 An oxygen supply means 5 for supplying oxygen (air) to the means 4 and the combustion furnace 2 is provided.

The dry distillation gasification and incineration apparatus of this embodiment is further connected to the combustion furnace 2 to introduce a part of the flammable gas exhaust gas, heat the sludge and dry it by a rotary kiln 6 and a rotary kiln 6. Of the combustion furnace 2
, A pressure sensor 8 for detecting the atmospheric pressure P ₁ in the combustion furnace 2, a discharge connected to the combustion furnace 2 and sucking the combustible gas exhaust and the rotary kiln 6 exhaust and releasing them to the atmosphere. Means 9 are provided.

An inlet 11 having an opening door 10 that can be opened and closed is formed on the upper surface of the gasifier 1 so that waste A can be introduced into the gasifier 1 through the inlet 11. . When the charging door 10 is closed, the inside of the gasification furnace 1 is substantially shut off from the outside air. Slope-shaped side wall 12 and bottom 1 protruding downward
In the lower part of the gasification furnace 1 formed in the shape of a truncated cone by 3, a vacant space 14 is formed on the outer surface of the side wall part 12 and the bottom part 13 and is isolated from the inside of the gasification furnace 1. 14
Is connected to the oxygen supply means 4. And vacancy 14
Is designed to supply oxygen supplied from the oxygen supply means 4 to the inside of the gasification furnace 1 through a plurality of air supply nozzles 15 provided on the side wall portion 12 and the bottom portion 13.

An ignition device 16 composed of an ignition burner or the like is attached to a lower side portion of the gasification furnace 1.
The ignition device 16 burns fuel such as auxiliary fuel oil supplied from a fuel supply device (not shown) to thereby form the gasification furnace 1.
A combustion flame is generated toward the interior of the gasification furnace 1, and the combustion flame ignites the waste A in the gasification furnace 1.
Further, a water jacket 17 separated from the inside of the gasification furnace 1 as a cooling structure is provided on an outer peripheral portion of the gasification furnace 1.
The water jacket 17 is supplied with water from a water supply device (not shown) provided outside the gasification furnace 1.

The combustion furnace 2 has a gasifier 1 at its base.
Is connected to a gas passage 19 led out from a connection portion 18 provided at an upper portion of the switching valve 1 provided in the gas passage 19.
9a by switching the two gasifiers 1,
A flammable gas generated by the dry distillation of the waste A is introduced from either one of them, and an ignition device 20 constituted by an ignition burner or the like is attached to the rear end of the flammable gas. The flammable gas introduced is ignited. The ignition device 20 is configured by an ignition burner or the like in the same manner as the ignition device 16, and burns a combustion flame toward the inside of the combustion furnace 2 by burning fuel such as auxiliary fuel supplied from a fuel supply device (not shown). It is designed to give birth.

At the outer periphery of the combustion furnace 2, an empty space 21 is formed which is isolated from the inside of the combustion furnace 2, and the empty space 21 is connected to the oxygen supply means 5. The vacant chamber 21 supplies oxygen supplied from the oxygen supply means 5 to the inside of the combustion furnace 2 through a plurality of nozzle holes 22 provided on the outer peripheral wall of the combustion furnace 2.

An exhaust outlet 23 is provided below the side of the combustion furnace 2 for supplying a part of the exhaust gas generated by the combustion of the combustible gas to the rotary kiln 6, and above the side of the rotary kiln 6. An exhaust inlet 24 into which the exhaust gas is introduced is provided. And, in the upper part of the combustion furnace 2,
Discharging means 9 for discharging the exhaust of the combustible gas and the exhaust of the rotary kiln 6 is connected.

A temperature sensor 3 for detecting the combustion temperature T ₁ of the combustible gas and a pressure sensor 8 for detecting the pressure P ₁ in the combustion furnace 2 are provided below the combustion furnace 2. The temperature sensor 3 outputs the detection signal to each of the oxygen supply means 4 and 5, and the pressure sensor 8 outputs the detection signal to the discharge means 9.

The oxygen supply means 4 for supplying oxygen to the gasification furnace 1 includes an oxygen supply source 2 provided outside the gasification furnace 1.
5 and a main oxygen supply pipe 2 derived from the oxygen supply source 25
6 and a sub-oxygen supply pipe 27 branched from the main oxygen supply pipe 26 and connected to the empty space 14 of the gasification furnace 1. The sub-oxygen supply pipe 27 has a detection input from the temperature sensor 3. An on-off valve 28 that opens and closes according to a signal is provided.

The oxygen supply means 5 for supplying oxygen to the combustion furnace 2 includes the oxygen supply source 25 and the oxygen supply source 2.
5 and a sub-oxygen supply pipe 29 branched from the main oxygen supply pipe 26 and connected to the empty chamber 21 of the combustion furnace 2. An on-off valve 30 that opens and closes according to a detection signal input from the temperature sensor 3 is provided.

The rotary kiln 6 has a rotary furnace 31 gently inclined along the length direction, an input port 32 provided above the rotary furnace 31 for charging sludge waste,
An outlet 3 provided below to take out dried waste
3 The rotary furnace 31 has the lower part of the combustion furnace 2
The upper part is connected to a suction introducing means 7 for sucking the exhaust gas from the rotary kiln 6 and introducing the exhaust gas into the combustion furnace 2. Further, the rotary furnace 31 is provided with a pressure sensor 34 for detecting the internal pressure P ₂ , and the pressure sensor 34 outputs a detection signal to the suction introducing means 7. Further, a temperature sensor 32 provided near the outlet of the rotary furnace 31 is provided at the input port 32.
a motor 32b is controlled in accordance with the outlet temperature T ₂ detected by a, a screw conveyor 32c is driven by a motor 32b are provided so as to supply the introduced sludge-like waste into the rotary furnace 31 Has become.

The suction introducing means 7 includes a duct 35 connecting the upper part of the rotary furnace 31 of the rotary kiln 6 and the exhaust gas inlet 24 of the combustion furnace 2, and a cyclone dust collector 36 provided in the middle of the duct 35. And a fan 37. The fan 37 sucks the exhaust of the rotary kiln 6 so that the pressure P ₂ inside the rotary kiln 6 is always lower than the internal pressure P ₁ of the combustion furnace 2 according to the detection signal input from the pressure sensor 34. The pressure of the exhaust gas introduced into the combustion furnace 2 is set to be higher than the internal pressure P ₁ of the combustion furnace 2.

The discharge means 9 includes a duct 38 connected to the upper part of the combustion furnace 2, a cooling tower 39 provided in the middle of the duct 38, a chemical adsorption device 40, an electric precipitator 41, a fan 42, and a duct 38. And a chimney 43 provided at the end of the stack. The chemical adsorption device 40 is used when the exhaust of combustible gas discharged from the combustion furnace 2 and the exhaust of the rotary kiln 6 contain a substance that causes environmental pollution when emitted directly into the atmosphere, such as a bad odor component. The substance is changed to a chemically stable substance and removed from the exhaust gas. In this embodiment, hydrogen chloride gas in the exhaust gas reacts with slaked lime and is removed as calcium chloride. Further, the fan 42 controls the pressure P inside the combustion furnace 2 according to the detection signal input from the pressure sensor 8.
_The combustion furnace 2 sucks the exhaust of combustible gas and the exhaust of the rotary kiln 6 so that ₁ is always maintained at a substantially constant pressure.

Next, the operation of the dry distillation gasification and incineration apparatus shown in FIG. 1 will be described.

When incinerating the waste A, first, the charging door 10 of one of the gasification furnaces 1 is opened, and the waste A is charged into the gasification furnace 1 through the charging port 11. Next, after closing the charging door 10, the ignition device 16 is operated for a predetermined time to ignite the waste A in the gasification furnace 1, and the partial combustion of the waste A is started.

When the partial combustion of the waste A is started, the lower part of the waste A gradually burns, and the combustion heat causes the upper part of the waste A to start carbonization. The combustible gas starts to be generated by the dry distillation, and the combustible gas is introduced into the combustion furnace 2 from the gasification furnace 1 through the gas passage 19. When the ignition device 20 is operated for a predetermined time, the combustible gas is ignited, and spontaneous combustion of the combustible gas is started.

The combustion temperature T ₁ of the combustible gas is detected by the temperature sensor 3, and a detection signal is output to the on-off valve 28 of the oxygen supply means 4 and the on-off valve 30 of the oxygen supply means 5.

At this time, the on-off valve 2 of the oxygen supply means 4
8 is a combustion in which the combustion temperature T ₁ of the flammable gas is such that the flammable gas can spontaneously burn and the generation of nitrogen oxides and the like due to the combustion is small in accordance with the detection signal input from the temperature sensor 3. The opening degree is automatically adjusted so as to substantially maintain a predetermined set temperature as the temperature to control the amount of the flammable gas generated. The on-off valve 28
Specifically, when the combustion temperature T ₁ becomes lower than the set temperature, the opening degree of the on-off valve 28 is increased to increase the amount of oxygen supplied to the gasification furnace 1. , and increases generation of the combustible gas to promote combustion of the lower portion of the waste a, conversely, when the combustion temperature T ₂ is larger than the set temperature, and decreases the opening of the opening and closing valve 28, The amount of oxygen supplied to the gasification furnace 1 is reduced so that the combustion of the lower part of the waste A is suppressed and the generation of the combustible gas is suppressed.

The on-off valve 30 of the oxygen supply means 5
As in accordance with the detection signal input from the temperature sensor 3, in accordance with the combustion temperature T ₁ of the said combustible gas, supplying the oxygen required for complete combustion of the combustible gas introduced into the combustion furnace 2, The opening is automatically adjusted. Specifically, in the automatic adjustment of the opening of the on-off valve 30, specifically, in the initial stage of the dry distillation of the waste A, the amount of the combustible gas introduced into the combustion furnace 2 increases, and the combustion temperature T ₁ thereof increases. As the temperature rises, the opening is increased to increase the amount of oxygen supplied to the combustion furnace 2, and in the stage where the carbonization of the waste A proceeds stably, the combustion temperature T ₁ of the combustible gas slightly increases or decreases. Accordingly, the opening degree is increased or decreased to adjust the amount of oxygen supplied to the combustion furnace 2, thereby
The combustible gas introduced into the combustion furnace 2 is mixed with the combustible gas in an amount such that the combustible gas can completely burn.

As described above, waste A in the gasification furnace 1
As the dry distillation gasification progresses stably, the combustion of the combustible gas introduced from the gasification furnace 1 into the combustion furnace 2 also progresses stably, and the combustible gas exhausted. Is introduced into the rotary kiln 6 from the exhaust outlet 23 and subjected to a heat treatment.

In the rotary kiln 6, sludge-like waste is introduced from the upper inlet 32 of the rotary furnace 31 gently inclined along the length direction as described above, and gradually moves toward the lower outlet 33. I have. Then, the exhaust of the combustible gas is introduced from the lower part of the rotary furnace 31, and the sludge-like waste moving from the inlet 32 to the outlet 33 as described above is dried. The exhaust of the combustible gas cooled by drying the sludge waste and the gas generated by drying the sludge waste are supplied to the rotary kiln 6.
The exhaust gas is sucked by the fan 37 and introduced into the combustion furnace 2 from the exhaust gas inlet 24 of the combustion furnace 2.

At this time, since the exhaust gas from the rotary kiln 6 contains fine dust as the sludge-like waste is dried, the fine dust is removed by the cyclone type dust collector 36 provided in the middle of the duct 35. I am collecting. Also,
The sludge-like waste often contains a malodorous component, and the malodorous component evaporates as the sludge-like waste dries, so that the exhaust air of the rotary kiln 6 contains the malodorous component. When introduced into the combustion furnace 2, the malodorous components and the like are heated by the combustion heat of the combustible gas, and are thermally decomposed and deodorized. Then, the exhaust gas of the combustible gas and the exhaust gas of the rotary kiln 6 are sucked by the fan 42 through the duct 38 and discharged to the atmosphere from the chimney 43.

The exhaust of the rotary kiln 6 is supplied to the combustion furnace 2
When it is introduced into the combustion furnace, the power of the combustible gas introduced from the gasification furnace 1 and the power of the exhaust gas become unbalanced, and the combustion furnace 2
The combustion of the flammable gas inside may become unstable.
Therefore, the fan 42 discharges the combustible gas in the combustion furnace 2 and discharges the combustible gas in the combustion furnace 2 such that the internal pressure P ₁ of the combustion furnace 2 is always maintained at a substantially constant pressure in accordance with the detection signal input from the pressure sensor 8. The exhaust gas from the rotary kiln 6 is sucked to stably burn the combustible gas.

The fan 37 sucks the exhaust of the rotary kiln 6 in accordance with the detection signal input from the pressure sensor 34 so that the pressure P ₂ inside the rotary kiln 6 is always lower than the internal pressure P ₁ of the combustion furnace 2. At the same time, the pressure of the exhaust gas introduced from the fan 37 into the combustion furnace 2 is made higher than the internal pressure P ₁ of the combustion furnace 2.
By doing so, the exhaust of the combustible gas is smoothly sucked from the combustion furnace 2 into the rotary kiln 6,
The exhaust gas from the rotary kiln 6 is smoothly introduced into the combustion furnace 2.

At this time, the rotary furnace 3 of the rotary kiln 6
Since 1 has a gap in a large amount, the pressure P ₂ in the rotary kiln 6 is greater than atmospheric pressure, wherein the malodorous component leaks to the outside of the rotary kiln 6, there is a possibility of causing environmental pollution. Therefore, the fan 37 sucks the exhaust gas from the rotary kiln 6 so that the pressure P ₂ in the rotary kiln 6 is always maintained at a negative pressure.
Leakage of the malodorous component can be prevented.

If the amount of the sludge-like waste fed into the rotary kiln 6 is large, the exhaust gas from the rotary kiln 6 becomes low in temperature, and when such exhaust gas is introduced into the combustion furnace 2, There is a possibility that combustion of the combustible gas may be hindered. Therefore, in the rotary kiln 6, when the outlet temperature T ₂ detected by the temperature sensor 32a is lower than a predetermined temperature reduces the rotational speed of the motor 32b, sludge-like waste supplied to the rotary furnace 31 by the screw conveyor 32c It is designed to reduce things. As described above, after the amount of sludge waste supplied to the rotary furnace 31 is reduced, the outlet temperature T ₂ detected by the temperature sensor 32a.
Is restored to a predetermined temperature or higher, the rotation speed of the motor 32b is also returned to the normal value.

The exhaust of the combustible gas and the exhaust of the rotary kiln 6 are at a high temperature. Therefore, before the exhaust from the chimney 43 as described above, a large capacity cooling tower 3
9 to be cooled. Further, when the thermal decomposition products such as the offensive odor components are directly discharged into the atmosphere and cause environmental pollution, they are converted into stable substances by the chemical adsorption device 40 provided in the middle of the duct 38, and are converted from the exhaust gas. Removed. Further, fine dust contained in the exhaust gas is collected by an electric dust collector 41 provided in the middle of the duct 38.

In the dry distillation gasification and incineration apparatus shown in FIG. 1, when the dry distillation of one of the gasification furnaces 1 approaches the end, new waste A is charged into the other gasification furnace 1 in the same manner as described above.
Ignite and start incineration. When the generation of combustible gas in the first gasification furnace 1 is stopped, the gas passage 19 is immediately connected to the other gasification furnace 1 by the switching valve 19a.
So that the combustion of the combustible gas in the combustion furnace 2 is not interrupted. In this way, by continuously switching the two gasifiers 1 and 1 to perform the incineration of the waste, the rotary kiln 6 can be continuously operated without being stopped.

The switching between the two gasifiers 1 and 1 can be performed smoothly by tracking the temperature in the gasifier 1 in which the incineration of the waste A is being performed over time immediately after ignition. Can be done.

Next, the dry distillation gasification and incineration apparatus shown in FIG. 2 will be described.

The dry distillation gasification and incineration treatment apparatus shown in FIG. 2 is a rotary kiln in which the combustion furnace 2 communicates with the first combustion section 44 for combustible gas introduced from the gasification furnace 1 and the first combustion section 44. Except for the point of the second combustion section 45 into which the exhaust gas of No. 6 is introduced, the configuration is completely the same as that of the dry distillation gasification and incineration apparatus shown in FIG.

The first combustion section 44 is provided with a temperature sensor 3 and a pressure sensor 8, the base of which is connected to the gas passage 19, and the rear end of which is provided with an ignition device 20. Further, an exhaust outlet 23 is provided on a side wall of the first combustion unit 44.

The second combustion section 45 is provided with an exhaust inlet 24 on a side wall thereof, and an exhaust means 9 for exhausting the combustible gas and the exhaust of the rotary kiln 6 is connected to an upper portion thereof. Have been. Further, a temperature sensor 45a and a temperature sensor 45a
A burner device 45b to the internal temperature T ₃ is ignited when it becomes lower than a predetermined temperature is provided which is detected by.

In the dry distillation gasification and incineration apparatus shown in FIG. 2, the exhaust of the rotary kiln 6 is
It is introduced into the combustion section 45. Since the second combustion unit 45 is configured separately from the first combustion unit 44 that burns the combustible gas, even if the temperature of the exhaust gas of the rotary kiln 6 has been reduced by the heating process, the first combustion unit 45 does not. The effect of the combustible gas on the combustion temperature T ₁ in the combustion section 44 can be reduced, and the feedback control of oxygen supply to the gasification furnace 1 and the combustion furnace 2 by the temperature sensor 3 is not hindered. Further, the internal temperature T ₃ of the second combustion section 45
Is lower than the predetermined temperature, and there is a possibility that the combustion of the combustible gas in the first combustion section 44 may be hindered, the internal temperature T ₃ is raised by igniting the burner device 45b. Incidentally, the burner apparatus 45b is the internal temperature T ₃ of the second combustion section 45 is equal to or higher than a predetermined temperature, is stopped.

Next, the dry distillation gasification and incineration apparatus shown in FIG. 3 will be described.

The dry distillation gasification and incineration treatment apparatus shown in FIG. 3 has a single gasification furnace 1 and a rotary kiln 6 of a rotary kiln 6.
1 is provided with a burner device 46 as an auxiliary heat source, and a heating furnace 47 for heating the exhaust gas of the rotary kiln 6 downstream of the fan 37 of the duct 35, except for the dry distillation gasification and incineration treatment device shown in FIG. It is exactly the same.

The heating furnace 47 has a burner device 48 as a heat source for heating the exhaust of the rotary kiln 6, and is connected to the rotary kiln 31 of the rotary kiln 6 by a duct 50 having an on-off valve 49. The burner device 4
The combustion units 6 and 48 burn fuel such as auxiliary fuel supplied from a fuel supply device (not shown) to generate combustion flame toward the inside of the rotary kiln 6 or the heating furnace 47, respectively, and heat them.

While the combustible gas is being combusted in the combustion furnace 2, the gasification and incineration apparatus shown in FIG. 3 operates in exactly the same manner as the gasification and incineration apparatus shown in FIG. However, in the dry distillation gasification and incineration treatment apparatus shown in FIG. 3, when the combustion of the combustible gas in the combustion furnace 2 is stopped, new waste A is stored in the gasification furnace 1 and the combustion of the combustible gas in the combustion furnace 2 again. Until the start of the combustion, exhaust of combustible gas from the combustion furnace 2 to the rotary kiln 6 is stopped.

Therefore, when the combustion of the combustible gas in the combustion furnace 2 is stopped, the burner device 46 is ignited, and the heat treatment in the rotary kiln 6 is performed by the burner device 46. At this time, the exhaust of the rotary kiln 6
Although the combustible gas is discharged through the combustion furnace 2 by the discharge means 7, the combustion of the combustible gas is not performed in the combustion furnace 2.
By igniting the burner device 48 and heating the exhaust of the rotary kiln 6 with the heating furnace 47, the rotary kiln 6 is heated.
Decomposes by thermally decomposing the malodorous components and the like contained in the exhaust gas.

Since the inside of the rotary kiln 6 is maintained at a negative pressure by the fan 37 as described above, when the heating furnace 47 heats the exhaust of the rotary kiln 6, the opening and closing valve 49 of the duct 50 is opened. The exhaust gas heated at 47 is sucked into the rotary kiln 6 and recirculated. Therefore, the heat of the heating furnace 47 can be effectively used, and the burner device 4 provided in the rotary kiln 6 can be used.
6 can reduce fuel consumption.

When the temperature of the exhaust of the rotary kiln 6 is significantly reduced, such as when the capacity of the rotary kiln 6 is large, when the exhaust of the rotary kiln 6 is introduced into the combustion furnace 2, There is a possibility that combustion of the combustible gas may be hindered. Therefore, in the dry distillation gasification and incineration processing apparatus shown in FIG.
a, and the heating furnace 4 detected by the temperature sensor 47a
7, when the internal temperature T ₄ becomes lower than the predetermined temperature.
The combustion temperature T of the combustible gas by the exhaust of the rotary kiln 6 which is ignited to the burner device 48 and introduced into the combustion furnace 2
_The effect on ₁ is reduced.

In the dry distillation gasification and incineration apparatus shown in FIG. 3, the combustion furnace 2 may be constituted by a first combustion section 44 and a second combustion section 45 as shown in FIG. Also, in the dry distillation gasification and incineration treatment apparatus shown in FIG. 2, the heating furnace 47 shown in FIG.

In each of the above embodiments, an example in which sludge-like waste is dried in the rotary kiln 6 is used. However, it may be used for drying other waste such as waste oil pitch. The material may be used for drying. Further, the heating treatment means may be another drying device instead of the rotary kiln 6.

[0066]

As is apparent from the above, according to the dry distillation gasification and incineration apparatus of the present invention, the exhaust gas of the heat treatment means is supplied to the combustion furnace without hindering the combustion of the combustible gas in the combustion furnace. It can be introduced and discharged with the flammable gas exhaust.

When the exhaust gas from the heat treatment means contains a malodorous component, the malodorous component can be heated and thermally decomposed, so that environmental pollution due to the malodorous component generated from the heat treatment means can be prevented. can do.

[Brief description of the drawings]

FIG. 1 is a schematic system configuration diagram showing one example of a dry distillation gasification and incineration treatment apparatus of the present invention.

FIG. 2 is a schematic system configuration diagram showing another example of the dry distillation gasification and incineration apparatus of the present invention.

FIG. 3 is a schematic system configuration diagram showing still another example of the dry distillation gasification and incineration treatment apparatus of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Gasification furnace, 2 ... Combustion furnace, 3 ... Gas combustion temperature detection means, 4 ... Oxygen supply means, 6 ... Heat treatment means, 7
... suction introduction means, 8 ... furnace pressure detection means, 9 ... discharge means, 34 ... heat treatment means pressure detection means, 44 ... first combustion section, 45 ... second combustion section, 46 ... auxiliary heat source,
47: heating furnace, 50: reflux means.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification code FI F23G 5/50 ZAB F23G 5/50 ZABP 7/12 ZAB 7/12 ZABA (56) References JP-A-54-110672 (JP, A) JP-A-2-135280 (JP, A) JP-A-6-82023 (JP, A) JP-A-60-144512 (JP, A) JP-A-6-11126 (JP, A) JP-A Sho51 -121976 (JP, A) JP-A-49-118284 (JP, A) JP-A-55-165417 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) F23G 5/027 F23G 5/14-5/16 F23G 5/20 F23G 5/50 F23G 7/12 F23G 5/00

Claims (4)

(57) [Claims] 1. A gasification furnace for storing waste and burning a part of the waste while carbonizing an undistilled portion of the waste by the combustion heat to generate a flammable gas. A combustion furnace for burning the combustible gas introduced from the gasification furnace, gas combustion temperature detection means for detecting a combustion temperature of the combustible gas in the combustion furnace, and spontaneous combustion of the combustible gas in the combustion furnace is started. After adjusting the amount of oxygen supplied to the gasification furnace so as to maintain the combustion temperature of the combustible gas detected by the gas combustion temperature detection means substantially constant at a preset temperature, An oxygen supply means for supplying oxygen necessary for partial combustion of the gasification and carbonization of the unrefined portion to the gasification furnace, wherein the combustible gas burned in the combustion furnace is exhausted. Heat treatment means to introduce a part of Suction suction means for sucking the exhaust gas from the heat treatment means and introducing the exhaust gas into the combustion furnace, furnace pressure detection means for detecting the pressure in the combustion furnace, and pressure detection by the furnace pressure detection means. so as to maintain the pressure in the combustion furnace to be substantially constant, provided with a discharge means for discharging to the atmosphere by sucking the exhaust of the exhaust and the heat treatment means of the combustible gas combustion furnace, the combustion furnace Flammable gas introduced from the gasifier
A first combustion section to be burned and before communication with the first combustion section
The exhaust of the heat treatment means is introduced by the suction introduction means.
A second combustion section, wherein the in-furnace pressure detection means is provided in the first combustion section.
And the discharge means is connected to the combustion section through the second combustion section.
Exhaust of the combustible gas in the furnace and exhaust of the heat treatment means
A dry distillation gasification and incineration system characterized by suction and discharge to the atmosphere . 2. A method for storing waste and a part of the waste.
While drying the undried portion of the waste by the combustion heat.
Gasifier for generating flammable gas by distillation and gasifier
A combustion furnace for burning combustible gas introduced from
Gas fuel for detecting the combustion temperature of the combustible gas in the furnace
A burning temperature detecting means, and a combustible gas in the combustion furnace.
After the combustion is started, detection is performed by the gas combustion temperature detecting means.
A preset setting of the known combustion temperature of the combustible gas
Oxygen supply to the gasifier so as to maintain a substantially constant temperature
Combustion of part of the waste and drying of undried
Oxygen supply means for supplying oxygen required for distillation to the gasification furnace;
And a part of the exhaust of the combustible gas burned in the combustion furnace is introduced.
Processing means for performing heat treatment by heating, and exhaust of the heat processing means
Suction introduction means for sucking and introducing the mixture into the combustion furnace;
Furnace pressure detecting means for detecting the atmospheric pressure in the furnace;
Maintain the pressure in the combustion furnace detected by the detection means at a substantially constant value
Exhausting the combustible gas in the combustion furnace and
Exhaust means for sucking the exhaust gas from the heat treatment means and discharging it to the atmosphere;
And the heat treatment means sucked by the suction introduction means.
A heating furnace for heating the exhaust gas, and the exhaust gas heated by the heating furnace;
And a reflux means for refluxing the heat treatment means,
The suction introducing means sends the exhaust gas of the heat treatment means through the heating furnace.
Wherein the gasification and incineration treatment apparatus is introduced into the combustion furnace . Wherein the heating processing means, wherein the combustion of the combustible gas in the combustion furnace when it is stopped, wherein the auxiliary heat source for supplying heat is provided
Item 3. The dry distillation gasification incineration apparatus according to Item 1 or 2 . 4. A pressure detecting means in the heat treatment means for detecting an air pressure in the heat treatment means, wherein the suction introducing means detects a pressure in the heat treatment means detected by the pressure detection means in the heat treatment means. Exhaust gas in the heat treatment means is suctioned so as to be maintained at a pressure lower than the pressure in the combustion furnace, and the pressure of the exhaust gas introduced from the suction introduction means into the combustion furnace is higher than the pressure in the combustion furnace. A contract characterized by
The dry distillation gasification and incineration apparatus according to any one of claims 1 to 3 .