JP2018091574A - Incineration apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an incineration apparatus which can reduce time and fuel consumption when vertical incinerator 1 is turned down.SOLUTION: An incineration apparatus has a burner (8, 9) which heats a combustion object input into a combustion chamber 1a of an incinerator 1, and combustion air supply means (6, 7) which supplies combustion air into the combustion chamber 1a from a grate 1d below the combustion chamber 1a. When the incinerator 1 is turned down, the input of the combustion object into the combustion chamber 1a is stopped, and the combustion object in the combustion chamber 1a is left as carbide.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an incinerator having a vertical incinerator for incinerating, for example, general garbage and industrial waste.

  For example, Patent Document 1 states that “when a garbage incinerator is shut down, the introduction of the garbage into the garbage incinerator is stopped, the exhaust gas temperature is maintained in a normal operation state for about one hour, and then the exhaust gas temperature is lowered. When the temperature reaches about 800 ° C., the start burner is controlled to start combustion until it runs out of dust.

  Further, Patent Document 2 states that “when the waste incinerator is shut down, the incinerator receiving part is closed, and water is sprayed from the injection nozzle onto the incinerated object on the guide surface during the extinguishing time in the furnace. In addition, it is described that the incineration object on the guide surface is ignited by the hot air of the furnace and prevents the smoldering from continuing, and prevents the time required for the shutdown from being extended.

  Furthermore, Patent Document 3 states that “When the incinerator is shut down, waste plastic is melted or crushed and injected into the combustion chamber in order to maintain the temperature of the furnace body as the amount of waste input decreases. To heat the inside of the furnace.

JP-A-8-193709 JP 2002-61801 A JP 2004-169931 A

  In Patent Document 1, since the combustion operation of the start burner is performed until the garbage in the garbage incinerator is exhausted, there is a concern that it takes a long time for the start burner and the fuel cost increases.

  Further, in Patent Document 2, although the fall time can be shortened and the fuel cost can be reduced, the combustion state of the incinerated material is not uniform and contains harmful substances such as CO, NOx, and dioxin. As a result, there is a concern that the subsequent processing will be time-consuming and time-consuming when restarting.

  Furthermore, in Patent Document 3, it can be said that it is possible to reduce the fall time and fuel cost as compared with Patent Document 1, but the labor and cost of preparing the waste plastic and the melting or crushing of the waste plastic are still possible. There is room for improvement, such as concerns over the labor and cost required for the process.

  In view of such circumstances, an object of the present invention is to make it possible to shorten the time and reduce the fuel used when a vertical incinerator is lowered in an incinerator.

  The present invention relates to an incinerator having a burner for heating an incinerated product to be put into a combustion chamber of a vertical incinerator, and a combustion air supply means for supplying combustion air from a grate below the combustion chamber to the combustion chamber. The apparatus is characterized in that when the incinerator is lowered, the incineration material into the combustion chamber is stopped and the incineration material in the combustion chamber remains as carbide.

  In this configuration, when the incinerator is shut down, the incinerated material is left as carbide on the grate of the incinerator, so that the incinerated material is completely burned as in Patent Document 1. It is possible to shorten the time required for the start-up and to reduce the fuel used. Also, compared with the case of injecting water as in Patent Document 2 and the case of supplying waste plastic as in Patent Document 3. Increase in cost can be suppressed.

  Moreover, when the incinerator is started up again, for example, the carbide remaining in the combustion chamber is ignited by heating with a burner, so that the carbide is used as a seed fire, and the carbide remains as a result of soot combustion. Since the temperature of the ash layer rises quickly, for example, compared with the case where the incinerated object in the combustion chamber is completely burned and then restarted and then restarted, The start-up time of the incinerator can be shortened compared to the conventional example, for example, it is possible to advance the timing for supplying the combustion air.

  By the way, the incinerator stops the charging of the incinerated material, and then performs a process of drying and pyrolyzing the incinerated material in the combustion chamber, and the combustion air when it is determined that the drying and thermal decomposition are completed. And a process of stopping heating by the burner.

  Here, the process which makes the said to-be-incinerated material a carbide | carbonized_material is specified, and construction | assembly of embodiment becomes easy by this specification.

In the above incinerator, in the process of drying and thermally decomposing the incinerated material in the combustion chamber, the O ₂ concentration generated from the incinerated material in the combustion chamber is set to a predetermined value, and the amount of primary combustion air associated therewith is usually It is checked whether the condition that the value is 30% or less of the value at the time of the combustion operation and the condition that the temperature of the incinerated object in the combustion chamber is less than a predetermined value is satisfied. When it is established, it can be configured that it is determined that drying and thermal decomposition of the incineration object are completed.

  In this configuration, it is possible to determine with relative accuracy that the incineration object has been dried and thermally decomposed.

  Moreover, the said incinerator can be set as the structure which further performs the process which injects nitrogen gas or the gas of less than 12% of oxygen concentration in the said combustion chamber after the process which stops the supply of the said combustion air.

  In this configuration, the incinerated object can be promptly forcibly extinguished. Thereby, after the supply and heating of the combustion air are stopped, the incinerated object can be prevented from proceeding with combustion due to preheating.

  Further, the gas having an oxygen concentration of less than 12% can be exhaust gas discharged from the combustion chamber.

  As in this configuration, if the exhaust gas is used effectively when the incinerated material is forcibly extinguished quickly, it is not necessary to use the nitrogen gas or the synthesis gas having an oxygen concentration of less than 12%, thereby eliminating waste. It becomes advantageous in improving purification of exhaust gas.

  Further, when the incinerator is started up again after the incinerator has been shut down, the incinerator left as carbide in the combustion chamber is heated by the burner to ignite, and the combustion chamber When it is determined that the temperature reaches a predetermined temperature at which the incinerated material to be combusted is combustible, the incinerated material is gradually introduced into the combustion chamber while supplying the combustion air into the combustion chamber. It is possible to adopt a configuration for performing the processing.

  In this configuration, when the incinerator is started up again, the incinerated material remaining as carbides in the combustion chamber can be effectively used as seed fuel, so that the incinerated material in the combustion chamber can be completely burned to stand up. Compared to the case of starting up again after being lowered, the start-up time of the incinerator can be shortened compared to the conventional example, such as the start time of supplying the combustion air and the start time of charging the incinerated material can be advanced. At the same time, the temperature of the ash remaining at the time of shutdown can be quickly raised, and the discharge of unburned components at the time of startup can be suppressed.

  According to the incinerator according to the present invention, it is possible to reduce the time required for starting up the vertical incinerator and reduce the amount of fuel used.

It is a figure which shows typically the structure of one Embodiment of the waste incinerator which concerns on this invention.

  BEST MODE FOR CARRYING OUT THE INVENTION Best modes for carrying out the present invention will be described in detail below with reference to the accompanying drawings.

  FIG. 1 shows an embodiment of the present invention. The incinerator exhaust gas treatment facility in the illustrated example includes an incinerator 1, a cooling device 2, a filtering dust collector 3 such as a bag filter, an induction fan 4, a chimney 5, a primary combustion air supply means 6, and a secondary combustion air supply. Means 7, auxiliary burner 8, control device 10 and the like are provided.

  The incinerator 1 burns incinerated materials such as general waste, industrial waste, and infectious medical waste in a predetermined package, for example, and the lower half of the incinerator 1 is in the combustion chamber 1a. The upper half is the recombustion chamber 1b. A combustion burner 8 is provided in the combustion chamber 1a.

Further, the incinerator 1 is provided with a hopper 1c for introducing an incinerated material into the combustion chamber 1a, and an O ₂ concentration detection means 21, a first temperature detection means 22, a second temperature detection means 23, and the like. Is provided.

O ₂ concentration detector 21 is for detecting the O ₂ concentration generated from the surface of the incinerated in the combustion chamber 1a. The first temperature detection means 22 detects the temperature (furnace outlet temperature) in the vicinity of the exhaust port above the incinerator 1. The second temperature detection means 23 is installed in a state where it is exposed to the inside of the furnace from the small-diameter furnace wall above the grate 1d of the incinerator 1, and the temperature of the installation place is incinerated in the combustion chamber 1a. This is detected as the temperature.

  Although the cooling device 2 is not shown in detail, the boiler for lowering the high temperature exhaust gas discharged from the incinerator 1 to, for example, about 220 ° C., or the exhaust gas cooled by the cooling device 2 is further reduced to approximately 200 ° C. or less. It has a gas cooling chamber for heating.

  The dust collector 3 neutralizes, filters, and purifies the dust and harmful gas components in the exhaust gas reduced in temperature by the cooling device 2, and is a bag filter, for example.

  The induction ventilator 4 sucks the exhaust gas in the dust collector 3 and releases it from the chimney 5 to the atmosphere.

  The primary combustion air supply means 6 supplies primary combustion air from the grate 1d at the lower end of the incinerator 1 to the combustion chamber 1a, and includes a first supply path 6a, a first blower 6b, and the like.

  The secondary combustion air supply means 7 supplies secondary combustion air to the combustion chamber 1a of the incinerator 1, and includes a second supply path 7a, a second blower 7b, and the like.

  The 2nd supply path 7a connects the combustion chamber 1a of the incinerator 1 and air | atmosphere. The second blower 7b sucks at least one of the atmosphere and the exhaust gas discharged from the incinerator 1 into the second supply passage 7a as secondary combustion air.

  The control device 10 controls at least a combustion operation, a shutdown operation, a restart operation, and the like.

  Next, the operation of the incinerator according to this embodiment will be described.

  First, at the start of the combustion operation in a state where there is no burned residue of incinerated material remaining in the combustion chamber 1, the inside of the combustion chamber 1a and the recombustion chamber 1b is heated by the auxiliary burner 8 to The temperature is raised to an ignition temperature of the incinerated material (for example, 400 ° C.) or higher. The ignition temperature of the incinerated object is controlled by monitoring the detection output of the second temperature detection means 23.

  After that, the combustion chamber 1a is further heated by gradually supplying burnable garbage for start-up classified in a garbage storage area (not shown) little by little from the hopper 1c onto the grate 1d and burning it. To do. The combustion gas generated with this combustion is sent to the recombustion chamber 1b.

  In the recombustion chamber 1b, the combustion gas is heated to 850 ° C. or higher by the supplied high-temperature recombustion air, and unburned carbon that is a precursor of dioxins generation and unpleasant odors in the high-temperature atmosphere. Fuel gas etc. are completely burned. The temperature of the combustion gas is controlled by monitoring the detection output from the first temperature detection means 22.

  The exhaust gas discharged from the recombustion chamber 1 b is cooled by passing through the cooling device 2, and then dust, acid harmful gases, etc. contained in the exhaust gas are filtered, neutralized and adsorbed in the dust collector 3. And is discharged from the chimney 5 through the induction fan 4.

  If the temperature in the vicinity of the exhaust port of the recombustion chamber 1b is stably maintained at 850 ° C. or higher in such a state, the incinerated material introduced from the hopper 1c can be changed to general waste and the combustion can be stabilized. If so, the operation of the auxiliary burner 8 is stopped. If combustion becomes unstable during combustion, the operation of the auxiliary burner 8 is resumed.

  When the incinerator 1 is lowered after starting such a combustion operation, charging of the incinerated material into the combustion chamber 1a is stopped so that the incinerated material in the combustion chamber 1a remains as carbide. .

  Specifically, when the introduction of the incinerated material into the combustion chamber 1a is stopped, the temperatures of the combustion chamber 1a and the recombustion chamber 1b gradually decrease.

  Therefore, the control device 10 controls the operation of the primary combustion air supply means 6, the secondary combustion air supply means 7, and the auxiliary combustion burner 8 so as to maintain the temperature of the recombustion chamber 1b at 850 ° C. The pyrolysis gas discharged from the tank is completely burned.

In this way, the control device 10 monitors whether or not drying and thermal decomposition have been completed. For example, the control device 10 has a condition that the O ₂ concentration generated from the surface of the incinerated object in the combustion chamber 1a based on the detection output from the O ₂ concentration detecting means 21 is a predetermined value (for example, 4%) or more, Based on the detection output from the second temperature detection means 23, the condition that the temperature of the incinerated object in the combustion chamber 1a is lower than a predetermined value (for example, 500 ° C., which is the ignition point of fixed carbon having no volatile content), respectively. Check whether it is true.

The primary combustion air amount is controlled by setting the O ₂ concentration to a predetermined value (for example, 1%). When the primary combustion air amount becomes less than the value during normal combustion operation (for example, 30%), drying and pyrolysis are performed. Can be determined to be completed.

When the controller 10 determines that both of the two conditions are satisfied, that is, when both the O ₂ concentration and the temperature of the incinerated material are less than the predetermined value, “the incinerated material It is determined that drying and thermal decomposition have been completed. In addition, about the completion determination of the said drying and thermal decomposition, you may further add the conditions that the height of the to-be-incinerated thing in the combustion chamber 1a is below predetermined height other than the said conditions.

  Here, when the control device 10 determines that the drying and pyrolysis are completed, first, the primary combustion air supply means 6 for the combustion chamber 1a is stopped, and then the operation of the secondary combustion air supply means 7 is stopped, If the auxiliary burner 8 is being operated, the operation is stopped.

  Thereby, since the progress of the combustion of the incinerated material in the combustion chamber 1a is gradually weakened, the temperature of the combustion chamber 1a is gradually decreased. In such a process, the incinerated material gradually carbonizes on the grate 1d. The incinerated material that has become the carbonized material is left in the combustion chamber 1a without being discarded to the outside.

  By the way, after stopping the supply of the primary combustion air, by injecting nitrogen gas (or synthesis gas having an oxygen concentration of less than 12%) by the nitrogen supply means 9 to the incinerated object in the combustion chamber 1a at a predetermined timing, It is possible to force fire extinguish quickly.

  When such forced fire extinguishing is performed, the incinerated object does not sufficiently come into contact with oxygen after the supply of the primary combustion air is stopped, so that it is possible to prevent the combustion from proceeding.

  In the case where the incinerator 1 is started up again after the incinerator 1 has been lowered in the form described above, the control device 10 first causes the carbide to remain on the grate 1d in the combustion chamber 1a. A certain incineration object is ignited by heating with an auxiliary burner 8.

  Based on the detection output from the second temperature detection means 23, the control device 10 determines that the temperature of the incinerated material left as carbide on the grate 1d in the combustion chamber 1a is a predetermined temperature (in the combustion chamber 1a). If it determines with having reached the temperature which can combust the to-be-injected to-be-injected object, for example, 500 degreeC or more), supplying primary combustion air in the combustion chamber 1a by starting operation of the primary combustion air supply means 6 Then, a process of gradually injecting the incinerated material from the hopper 1c into the combustion chamber 1a is performed.

  In this way, when the incinerator 1 is started up again, the incinerated material remaining as carbide on the grate 1d in the combustion chamber 1a can be effectively used as seed fuel, so that at the start of the operation or the combustion chamber 1a. Compared with the case where the incinerated object in the interior is completely burned and then restarted and then restarted, the supply start time of the primary combustion air to the combustion chamber 1a and the input start time of the incinerated object can be advanced, etc. The startup time of the incinerator 1 can be shortened compared to the conventional example.

  As described above, in the incinerator according to the embodiment to which the present invention is applied, when the incinerator 1 is lowered, the incineration object remains as carbide on the grate 1d.

  This makes it possible to shorten the time required for the start-up and save fuel used as compared with the case where the incineration object is completely burned as in Patent Document 1, and the water as in Patent Document 2 can be saved. Compared to the case of injecting and the case of supplying waste plastic as in Patent Document 3, an extra cost increase can be suppressed.

  Moreover, when starting up the incinerator 1 again, for example, by heating and igniting the carbide remaining in the combustion chamber 1a with the auxiliary combustion burner 8, the carbide can be used as a seed fire. For example, as compared with the case where the incinerated object in the combustion chamber 1a is completely burned and then restarted, the time when the incinerated object is introduced into the combustion chamber 1a and the time when the combustion air is supplied can be advanced. For example, the start-up time of the incinerator 1 can be shortened compared to the conventional example.

  In addition, this invention is not limited only to the said embodiment, It can change suitably in the range equivalent to the claim and the said range.

  For example, although not shown, it is possible to install a reburning burner in the reburning chamber 1b. In this case, when controlling the temperature of the reburning chamber 1b, it is possible to control not only the auxiliary burner 8 but also the operation of the reburning burner. Further, when the combustion operation is stopped, when it is determined that the drying and thermal decomposition are completed, if the auxiliary burner 8 and the reburn burner are operating, it is necessary to stop those operations.

  Furthermore, at the time of forced fire extinguishing described in the above embodiment, exhaust gas that has passed through the dust collector 3 can be used as “syngas having an oxygen concentration of less than 12%”. In this way, when exhaust gas is effectively used during forced fire extinguishing, it is not necessary to use the above-described nitrogen gas or synthesis gas having an oxygen concentration of less than 12%, so that waste can be eliminated and purification of exhaust gas can be improved. Will be advantageous.

  The present invention comprises a burner that heats an incinerated product that is put into a combustion chamber of a vertical incinerator, and primary combustion air supply means that supplies primary combustion air from a grate below the combustion chamber to the combustion chamber. It is possible to use suitably for the incinerator which has.

1 Incinerator
1a Combustion chamber
1b Recombustion chamber
1c hopper
1d grate
2 Cooling device
3 Dust collector
6 Primary combustion air supply means
7 Secondary combustion air supply means
8 Auxiliary burner 10 Control device 11 Exhaust passage 12 Exhaust gas recirculation means 21 O ₂ concentration detection means 22 First temperature detection means 23 Second temperature detection means 24 Flow rate detection means

The present invention relates to an auxiliary combustion burner for heating an incineration object to be put into a combustion chamber of a vertical incinerator, and primary combustion air supply means for supplying primary combustion air to a combustion chamber from a grate below the combustion chamber. An incinerator having secondary combustion air supply means for supplying secondary combustion air to the combustion chamber, and a control device for controlling combustion operation, shutdown operation, and restart operation , wherein the control device comprises: When the incinerator is lowered, the incinerated material is stopped from being introduced into the combustion chamber, and then the primary combustion air supply means, the secondary combustion air supply means, and the auxiliary combustion burner are controlled to control the incinerator. The process of drying and pyrolyzing the incinerated product, the process of monitoring whether the drying and pyrolysis are completed, and stopping the supply of the primary combustion air when it is determined that the drying and pyrolysis is completed. Followed by the secondary combustion In addition to stopping the operation of the air supply means, if the auxiliary combustion burner is operating, a process of stopping the operation is performed, and in the process of monitoring whether the drying and pyrolysis are completed, the combustion is performed. Investigate whether or not the condition that the O ₂ concentration generated from the surface of the incinerated object in the room is equal to or higher than the predetermined value and the condition that the temperature of the incinerated object in the combustion chamber is lower than the predetermined value are satisfied. When the two conditions are both satisfied , it is determined that drying and thermal decomposition of the incineration object are completed .

In the above incinerator, said control device, after stopping the supply of the primary combustion air, further performs a process of injecting a nitrogen gas or an oxygen concentration of 12% less than the gas in the combustion chamber, have a structure it can.

Further, in the incinerator , when the control device starts up again after the incinerator has been shut down, the incinerator to be left as carbide in the combustion chamber with the shutdown of the incinerator is removed. A process of heating and igniting with the auxiliary combustion burner, and the primary combustion in the combustion chamber when it is determined that the temperature in the combustion chamber has reached a predetermined temperature at which the incinerated material put into the combustion chamber is combustible While supplying air, it can be set as the structure which performs the process which throws in to-be-incinerated material into the said combustion chamber gradually.

Then, the control unit 10, if the two conditions is determined to be satisfied together, i.e. the case where the temperature of the O ₂ concentration in said predetermined value or more and the object to be incinerated is before Symbol less than the predetermined value, It is determined that “the drying and thermal decomposition of the incineration object has been completed”. In addition, about the completion determination of the said drying and thermal decomposition, you may further add the conditions that the height of the to-be-incinerated thing in the combustion chamber 1a is below predetermined height other than the said conditions.

Here, if the control device 10 determines that the drying and pyrolysis are completed, first, the operation of the primary combustion air supply means 6 for the combustion chamber 1a is stopped, and then the operation of the secondary combustion air supply means 7 is stopped. In addition, when the auxiliary burner 8 is operated, the operation is stopped.

Claims (6)

An incinerator having a burner that heats an incinerator to be put into a combustion chamber of a vertical incinerator, and a combustion air supply means that supplies combustion air from a grate below the combustion chamber to the combustion chamber. ,
An incinerator for stopping the incinerator to stop the introduction of the incinerated material into the combustion chamber and to leave the incinerated material in the combustion chamber as carbide. Incinerator according to claim 1,
After stopping the charging of the incinerated material, the incinerated material in the combustion chamber is dried and thermally decomposed, and when it is determined that the drying and thermal decomposition is completed, the combustion air is supplied and the burner An incinerator characterized by performing a process of stopping heating. Incinerator according to claim 2,
In the process of drying and pyrolyzing the incinerated material in the combustion chamber, the O ₂ concentration generated from the incinerated material in the combustion chamber is set to a predetermined value, and the amount of primary combustion air associated therewith is a value during normal combustion operation. Whether or not the condition that the temperature of the incinerated object in the combustion chamber is less than a predetermined value is satisfied, and if both of the two conditions are satisfied, An incinerator for determining that drying and thermal decomposition of an incinerated object are completed. The incinerator according to claim 2 or 3,
An incinerator further comprising a process of injecting nitrogen gas or a gas having an oxygen concentration of less than 12% into the combustion chamber after the process of stopping the supply of combustion air. The incinerator according to claim 4,
The incinerator characterized in that the gas having an oxygen concentration of less than 12% is exhaust gas discharged from the combustion chamber. The incinerator according to any one of claims 1 to 5,
When starting up again after the incinerator has been shut down, the incinerated material that remains as carbide in the combustion chamber is heated by the burner to ignite, and the temperature in the combustion chamber is charged into the combustion chamber. Performing a process of gradually injecting the incinerator into the combustion chamber while supplying the combustion air to the combustion chamber when it is determined that the predetermined temperature at which the incinerated object to be burnt has reached a predetermined temperature. Incinerator characterized by.

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