JP2013195044A - Combustion device and heating furnace - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate repair, maintenance, etc., by allowing burning fuel by using one or both of fuel gas and fuel oil as the fuel, and to suppress clogging of an oil nozzle with soot due to incomplete combustion of the fuel oil, when burning both the fuel gas and fuel oil simultaneously.SOLUTION: A gas nozzle 13 which jets fuel gas and an oil nozzle 16 which jets fuel oil are provided at different positions apart from an air nozzle 11 which jets air for combustion, and while the fuel gas is jetted from the gas nozzle 13 toward the air for combustion jetted from the air nozzle 11, the fuel oil is jetted from the oil nozzle 16.

Description

  The present invention relates to a combustion apparatus using fuel gas or fuel oil as a fuel used for combustion, and a heating furnace for heating an object to be processed using such a combustion apparatus. In particular, either or both of fuel gas and fuel oil can be used for the fuel used in the combustion device, and repair and maintenance can be easily performed, and fuel oil and fuel gas can be used simultaneously. It is characterized in that the fuel oil is prevented from burning incompletely and causing soot from sticking to the oil nozzle during combustion.

  In a conventional combustion apparatus, generally, a fuel using fuel gas and a fuel oil are used as fuels used for combustion.

  In such a combustion apparatus, when fuel gas or fuel oil is burned, in order to cause the fuel gas or fuel oil to come into contact with combustion air efficiently and burn, generally, the combustion air is ejected. A gas nozzle for injecting fuel gas and an oil nozzle for injecting fuel oil are provided on the inner peripheral side of the air nozzle, and combustion air is injected around the fuel gas injecting from the gas nozzle and the fuel oil injecting from the oil nozzle. I try to make it erupt.

  Here, in the combustion apparatus in which the gas nozzle and the oil nozzle are provided on the inner peripheral side of the air nozzle for injecting the combustion air in this way, when the fuel to be used is converted between the fuel gas and the fuel oil, the piping is replaced. There are various problems, such as the construction work to be performed, the work is very troublesome, time consuming and expensive.

  Conventionally, as a combustion apparatus that uses fuel gas and fuel oil, as disclosed in Patent Document 1, an oil nozzle that ejects fuel oil is provided on the inner peripheral side of an air nozzle that ejects combustion air. On the other hand, a gas nozzle that ejects fuel gas is provided on the outer peripheral side of the air nozzle.

  However, in such a combustion apparatus, since it has a multi-tube structure in which an air nozzle and a gas nozzle are provided on the outer periphery of the oil nozzle, its repair and maintenance are very troublesome, and the oil nozzle and the gas nozzle When fuel oil and fuel gas are simultaneously ejected from the fuel and burned, the fuel gas is easier to burn than the fuel oil, so the fuel gas ejected from the gas nozzle is burned first and its surroundings. The combustion air is consumed, the fuel oil ejected from the oil nozzle is incompletely combusted and soot is generated, and the soot adheres to the oil nozzle and the oil nozzle is clogged.

  In recent years, in order to efficiently burn the fuel gas using the heat of the combustion exhaust gas, the combustion exhaust gas in the heating furnace is discharged through the heat storage part in which the heat storage material is stored during non-combustion, and the combustion exhaust gas While the heat is stored in the heat storage material, at the time of combustion, the combustion air is heated through the heat storage portion in which the heat storage material thus stored is stored, and the combustion air thus heated is ejected from the air nozzle. Thus, a regenerative combustion apparatus that burns fuel gas is used.

  In such a heat storage type combustion apparatus, a gas nozzle that ejects fuel gas is provided on the inner peripheral side of an air nozzle that ejects combustion air, and Patent Documents 2 and 3 show. In addition, a gas nozzle for ejecting fuel gas is provided at a position away from the air nozzle for ejecting combustion air, and the fuel gas is ejected from the gas nozzle toward the combustion air ejected from the air nozzle and burned. There was something like that.

  However, in such a regenerative combustion apparatus, only a gas nozzle for ejecting fuel gas is provided. Therefore, when the fuel to be used is converted from fuel gas to fuel oil, the work for replacing the piping is performed. Etc., and the work is very troublesome, time consuming and expensive. In addition, by simply mixing the fuel gas ejected from the gas nozzle with the combustion air ejected from the air nozzle and burning it, the shape of the flame is changed according to the purpose, and the object to be processed in the heating furnace There is a problem that it becomes difficult to heat the resin properly.

Japanese Utility Model Publication No. 62-156224 JP 2007-24335 A JP 2010-127525 A

  The present invention enables a combustion apparatus that burns fuel gas or fuel oil to use either or both of fuel gas and fuel oil as the fuel, and facilitates repair and maintenance of the combustion apparatus. In addition, when the fuel oil and the fuel gas are burned at the same time, it is an object to suppress a phenomenon in which the fuel oil is incompletely burned and soot adheres to and clogs the oil nozzle.

  In the combustion apparatus according to the present invention, in order to solve the above-described problems, in a combustion apparatus provided with a gas nozzle that ejects fuel gas, an oil nozzle that ejects fuel oil, and an air nozzle that ejects combustion air The gas nozzle and the oil nozzle are provided at different positions apart from the air nozzle, and the fuel gas is ejected from the gas nozzle toward the combustion air ejected from the air nozzle, Fuel oil was ejected from the oil nozzle.

  In this way, if a gas nozzle that ejects fuel gas and an oil nozzle that ejects fuel oil are provided separately, the fuel to be burned can be switched between fuel gas and fuel oil, or both fuel gas and fuel oil are used. It becomes easy to do.

  In addition, when the gas nozzle and the oil nozzle are provided at different positions away from the air nozzle, the gas nozzle and the oil nozzle can be detached individually when repair or maintenance is performed.

  In the combustion apparatus, when a fuel gas adjusting device that adjusts the amount of fuel gas ejected from the gas nozzle and a fuel oil adjusting device that adjusts the amount of fuel oil ejected from the oil nozzle are provided, In addition to switching the fuel to be burned between fuel gas and fuel oil, the ratio of fuel gas and fuel oil in the fuel to be burned can be adjusted appropriately, and appropriate combustion according to the purpose can be performed, When the ratio of the fuel oil is increased, the heat radiation due to the bright flame at the time of combustion of the fuel oil can be increased, the heat radiation can be increased, and the heating time can be shortened and the energy can be saved.

  In addition, the combustion air ejected from the air nozzle and the fuel gas ejected from the gas nozzle merge, and the combustion in which the fuel oil ejected from the oil nozzle is ejected from the air nozzle. If the position where the air for merging is made different, the fuel gas and the fuel oil come into contact with the combustion air at different positions and are burned, thereby suppressing the incomplete combustion of the fuel oil. At the same time, soot generated by incomplete combustion is prevented from adhering to the oil nozzle.

  Further, in the above combustion apparatus, the fuel ejected from the oil nozzle at a position downstream of the ejection direction from the position where the combustion air ejected from the air nozzle and the fuel gas ejected from the gas nozzle merge. If the oil is combined with the combustion air ejected from the air nozzle, the flame caused by the combustion can be lengthened and sufficiently heated even at a position away from the combustion device.

  Here, the position where the combustion air ejected from the air nozzle and the fuel gas ejected from the gas nozzle merge and the position where the fuel oil ejected from the oil nozzle merges with the combustion air ejected from the air nozzle The fuel gas ejection angle at which the fuel gas is ejected from the gas nozzle and the fuel oil ejection angle at which the fuel oil is ejected from the oil nozzle are made different from each other toward the combustion air ejected from the air nozzle. Or by differentiating the interval between the air nozzle and the gas nozzle and the interval between the air nozzle and the oil nozzle.

  Further, in the above combustion apparatus, when the combustion air is ejected from the air nozzle, the heat of the combustion exhaust gas is stored in the heat storage part at the time of non-combustion, while the heat storage in which the combustion air is stored in this way at the time of combustion is stored. It can be made to heat through a part and to eject from said air nozzle. If it does in this way, fuel gas and fuel oil can be burned efficiently using the heat of combustion exhaust gas.

  In the heating furnace of the present invention, the above-described combustion apparatus is used to heat the workpiece.

  In the combustion apparatus according to the present invention, the gas nozzle and the oil nozzle are provided at different positions apart from the air nozzle, and the fuel gas is ejected from the gas nozzle toward the combustion air ejected from the air nozzle. Since the fuel oil is ejected from the fuel gas, the fuel to be burned can be easily switched between the fuel gas and the fuel oil, or both the fuel gas and the fuel oil can be used.

  Also, when both the fuel gas and the fuel oil are burned, the fuel gas and the fuel oil come into contact with the combustion air at different positions and are burned, so that the fuel oil becomes incompletely burned. Is suppressed, and soot generated by incomplete combustion is also prevented from adhering to the oil nozzle.

  Further, since the gas nozzle and the oil nozzle are provided at different positions apart from the air nozzle, the gas nozzle and the oil nozzle can be individually removed, and repair and maintenance can be easily performed.

It is a partial explanatory view of a heating furnace using a combustion device concerning one embodiment of this invention. In the combustion apparatus which concerns on said embodiment, it is the schematic explanatory drawing which showed the state which ejects fuel gas from the gas nozzle unit provided in the gas nozzle, and burns only fuel gas. In the combustion apparatus which concerns on said embodiment, it is the schematic explanatory drawing which showed the state which ejects fuel oil from the oil nozzle unit provided in the oil nozzle, and burns only fuel oil. In the combustion apparatus according to the above-described embodiment, the fuel gas and the fuel oil are ejected from the gas nozzle unit provided in the gas nozzle and the oil nozzle unit provided in the oil nozzle, respectively, and the fuel gas and the fuel oil are burned. It is the schematic explanatory drawing which showed the state. In the combustion apparatus according to the above-described embodiment, NOx in the case where combustion is performed by changing the ratio of the fuel gas and the fuel oil ejected from the gas nozzle unit provided in the gas nozzle and the oil nozzle unit provided in the oil nozzle. It is the figure which showed the change of generation amount. In the combustion apparatus according to the above embodiment, the flame length when the gas nozzle unit provided in the gas nozzle and the ratio of the fuel gas and the fuel oil ejected from the oil nozzle unit provided in the oil nozzle are changed and burned. FIG. In the combustion apparatus according to the above-described embodiment, the fuel oil ejected from the oil nozzle joins the combustion air ejected from the air nozzle at a position downstream of the fuel gas ejected from the gas nozzle in the ejection direction. It is the schematic explanatory drawing which showed the example of. In the combustion apparatus according to the above-described embodiment, the fuel oil ejected from the oil nozzle joins the combustion air ejected from the air nozzle at a position downstream of the fuel gas ejected from the gas nozzle in the ejection direction. It is the schematic explanatory drawing which showed the example of.

  Hereinafter, a combustion apparatus according to an embodiment of the present invention and a heating furnace using the combustion apparatus will be specifically described with reference to the accompanying drawings. In addition, the combustion apparatus and heating furnace which concern on this invention are not limited to what was shown to the following embodiment, In the range which does not change the summary of invention, it can change and implement suitably.

  In this embodiment, as shown in FIG. 1, a combustion device 10 is provided on the side wall 1 a of the heating furnace 1 so as to face the inside of the heating furnace 1.

  Here, in this combustion apparatus 10, an air nozzle 11 for injecting combustion air into the heating furnace 1 is provided, and the combustion air is guided to the air nozzle 11 through the heat storage section 12 in which the heat storage material 12 a is accommodated. ing.

  Further, a gas nozzle 13 for ejecting fuel gas into the heating furnace 1 is provided at a position away from the air nozzle 11, and the fuel gas is directed to the combustion air ejected from the air nozzle 11 in the gas nozzle 13. A fuel gas adjusting valve 15a is mounted as a fuel gas adjusting device for adjusting the amount of fuel gas supplied to the gas nozzle unit 14 to the fuel gas supply path 15 for supplying the gas gas to the gas nozzle unit 14 while mounting the gas nozzle unit 14 to be ejected. Is provided. A pilot burner 14 a for igniting the fuel gas ejected from the gas nozzle unit 14 is provided in the vicinity of the gas nozzle unit 14.

  In addition, an oil nozzle 16 for ejecting fuel oil into the heating furnace 1 is provided at a position away from the air nozzle 11 and different from the gas nozzle 13, and the fuel oil is injected into the oil nozzle 16. An oil nozzle unit 17 is provided for jetting toward the combustion air jetted from the air nozzle 11, and fuel oil supplied to the oil nozzle unit 17 is provided in a fuel oil supply path 18 for supplying fuel oil to the oil nozzle unit 17. A fuel oil adjusting valve 18a is provided as a fuel oil adjusting device for adjusting the amount of the fuel oil. Further, a pilot burner 17 a for igniting fuel oil ejected from the oil nozzle unit 17 is provided in the vicinity of the oil nozzle unit 17.

  Here, in the combustion apparatus 10, when combustion is performed using only the fuel gas, as shown in FIG. 2, the fuel gas regulating valve 15 a is opened, and the fuel gas is supplied to the gas nozzle through the fuel gas supply path 15. On the other hand, the fuel oil regulating valve 18 a is closed while the fuel oil is led to the unit 14 so that the fuel oil is not led to the oil nozzle unit 17.

  The combustion air is guided to the air nozzle 11 through the heat storage section 12 in which the heat of the combustion exhaust gas is stored in the heat storage material 12 a during non-combustion, and the combustion air heated in the heat storage section 12 is heated from the air nozzle 11. The fuel gas is ejected into the furnace 1, and the fuel gas is ejected from the gas nozzle unit 14 to which the fuel gas is introduced as described above, toward the combustion air ejected into the heating furnace 1. It is made to burn in. If the temperature in the heating furnace 1 does not reach the ignition temperature of the fuel gas, the fuel gas ejected from the gas nozzle unit 14 is ignited by the pilot burner 14a.

  On the other hand, in the combustion apparatus 10, when combustion is performed using only fuel oil, the fuel oil regulating valve 18 a is opened and the fuel oil is supplied to the oil nozzle through the fuel oil supply path 18 as shown in FIG. 3. While guiding to the unit 17, the fuel gas regulating valve 15 a is closed so that the fuel gas is not guided to the gas nozzle unit 14.

  As in the case of the fuel gas, the combustion air is guided to the air nozzle 11 through the heat storage unit 12, and the combustion air heated in the heat storage unit 12 is ejected from the air nozzle 11 into the heating furnace 1. In addition, the fuel oil is ejected from the oil nozzle unit 17 to which the fuel oil is introduced as described above toward the combustion air ejected into the heating furnace 1, and the fuel oil is combusted in the heating furnace 1. Like that. When the temperature in the heating furnace 1 does not reach the fuel oil ignition temperature, the fuel oil ejected from the oil nozzle unit 17 is ignited by the pilot burner 17a.

  In this way, the fuel used in the combustion in the combustion apparatus 10 can be easily switched between the fuel gas and the fuel oil.

  In the combustion apparatus 10, when combustion is performed using both fuel gas and fuel oil, the fuel gas adjustment valve 15a and the fuel oil adjustment valve 18a are opened as shown in FIG. The fuel gas is guided to the gas nozzle unit 14 through the fuel gas supply path 15 and the fuel oil is guided to the oil nozzle unit 17 through the fuel oil supply path 18.

  As in the case of the fuel gas or fuel oil, the combustion air is guided to the air nozzle 11 through the heat storage unit 12, and the combustion air heated in the heat storage unit 12 is transferred from the air nozzle 11 to the heating furnace 1. The fuel gas and the fuel oil were respectively ejected into the heating furnace 1 from the gas nozzle unit 14 to which the fuel gas was introduced and the oil nozzle unit 17 to which the fuel oil was introduced as described above. The fuel gas and the fuel oil are burned in the heating furnace 1 by being ejected toward the combustion air.

  Here, in the above combustion apparatus 10, when the fuel oil ejected from the oil nozzle unit 17 is not combusted alone in the heating furnace 1, and is always combusted together with the fuel gas ejected from the gas nozzle unit 14. The pilot burner 17a and the like in the oil nozzle unit 17 can be eliminated. Further, even when the fuel oil is ejected only above the ignition temperature of the fuel oil, the pilot burner 17a and the like in the oil nozzle unit 17 can be eliminated.

  Further, when combustion is performed using both fuel gas and fuel oil as described above, the amount of fuel gas guided to the gas nozzle unit 14 by the fuel gas adjustment valve 15a and the fuel oil adjustment valve 18a, and the oil The amount of fuel oil guided to the nozzle unit 17 can be adjusted appropriately.

  Next, the amount of NOx generated when the combustion amount of fuel in the combustion apparatus 10 is made constant and the ratio of the fuel gas led to the gas nozzle unit 14 and the ratio of the fuel oil led to the oil nozzle unit 17 are changed. Changes in the flame length were examined, and the results are shown in FIGS.

  Here, FIG. 5 shows the change in the amount of NOx generated when the ratio of the fuel oil and the fuel gas is changed with the amount of NOx generated when only fuel oil is burned being 1.00.

  FIG. 6 shows the change in the flame length when the ratio between the fuel oil and the fuel gas is changed by setting the flame length when the fuel oil alone is burned to 1.00.

  As a result, it can be seen that when the ratio of the fuel oil led to the oil nozzle unit 17 increases, the amount of NOx generated increases, while the flame length becomes long and sufficient heating can be performed at a position away from the combustion device 10. Further, when the ratio of the fuel oil is increased, the radiant heat transfer due to the flame due to the combustion of the fuel oil is increased, and the object to be processed (not shown) can be efficiently heated in the heating furnace 1.

  As described above, the ratio of the fuel oil when combustion is performed using both the fuel gas and the fuel oil can be determined by the required flame length and temperature. It can also be determined by the market price and the amount of NOx generated, and by adjusting it, it can contribute to low cost and low pollution combustion.

  Further, as described above, the fuel gas and the fuel oil are ejected from the gas nozzle unit 14 and the oil nozzle unit 17 toward the combustion air ejected from the air nozzle 11, respectively. In burning the fuel oil, the fuel oil ejected from the oil nozzle unit 17 and the combustion air ejected from the air nozzle 11 at a position downstream of the fuel gas ejected from the gas nozzle unit 14 in the ejection direction If they are combined, the flammable fuel gas is burned first, and the non-burnable fuel oil is burned later. Therefore, the flame length at the time of combustion is further increased, and combustion is performed in a wide range in the heating furnace 1. Thus, the inside of the heating furnace 1 is heated uniformly.

  When the fuel oil ejected from the oil nozzle unit 17 is combined with the combustion air ejected from the air nozzle 11 at a position downstream of the fuel gas ejected from the gas nozzle unit 14 in the ejection direction. For example, a method as shown in FIG. 7 or 8 can be used.

  Here, in the method shown in FIG. 7, the distance d1 between the air nozzle 11 and the gas nozzle 13 and the distance d2 between the air nozzle 11 and the oil nozzle 16 are made the same, while the combustion is ejected from the air nozzle 11. Combustion air ejected from the air nozzle 11 more than the fuel gas ejection angle θ1 at which the fuel gas is ejected from the gas nozzle 13 toward the air, that is, the angle at which the axis L1 of the air nozzle 11 and the axis L2 of the gas nozzle 13 intersect. The fuel oil ejection angle θ2 for ejecting fuel oil from the oil nozzle 16, that is, the angle at which the axis L1 of the air nozzle 11 and the axis L3 of the oil nozzle 16 intersect is reduced.

  Further, in the method shown in FIG. 8, the interval d2 between the air nozzle 11 and the oil nozzle 16 is made larger than the interval d1 between the air nozzle 11 and the gas nozzle 13, while the combustion air jetted from the air nozzle 11 is used. The fuel gas ejection angle θ1 for ejecting fuel gas from the gas nozzle 13 and the fuel oil ejection angle θ2 for ejecting fuel oil from the oil nozzle 16 are made the same.

  Although not shown, the method shown in FIG. 7 and the method shown in FIG. 8 are combined to cause the fuel oil ejected from the oil nozzle unit 17 to flow downstream in the ejection direction from the fuel gas ejected from the gas nozzle unit 14. It can also be made to merge with the combustion air ejected from the air nozzle 11 at the position on the side.

  Contrary to the above case, the fuel oil ejected from the oil nozzle unit 17 is burned from the air nozzle 11 at a position upstream of the fuel gas ejected from the gas nozzle unit 14 in the ejection direction. You may make it merge with air. In this case, since the combustion air is mixed with the fuel oil that does not easily burn, the incomplete combustion of the fuel oil is suppressed, and soot generation can be prevented.

  In addition, in said embodiment, although the thermal storage type combustion apparatus 10 provided with the thermal storage part 12 which stores the heat | fever of combustion exhaust gas was demonstrated, it is the same also in the normal combustion apparatus which is not provided with such a thermal storage part 12 Can be configured.

DESCRIPTION OF SYMBOLS 1 Heating furnace 1a Side wall 10 Combustion apparatus 11 Air nozzle 12 Thermal storage part, 12a Thermal storage material 13 Gas nozzle 14 Gas nozzle unit, 14a Pilot burner 15 Fuel gas supply path, 15a Fuel gas regulating valve (fuel gas regulating device)
16 Oil nozzle 17 Oil nozzle unit, 17a Pilot burner 18 Fuel oil supply path, 18a Fuel oil adjustment valve (fuel oil adjustment device)
d1 Distance between the air nozzle and gas nozzle d2 Distance between the air nozzle and oil nozzle L1 Axis line of the air nozzle L2 Axis line of the gas nozzle L3 Axis line of the oil nozzle θ1 Fuel gas ejection angle for ejecting fuel gas to the combustion air Fuel oil ejection angle for ejecting fuel oil to air

In the combustion apparatus according to the present invention, in order to solve the above-described problems, in a combustion apparatus provided with a gas nozzle that ejects fuel gas, an oil nozzle that ejects fuel oil, and an air nozzle that ejects combustion air The gas nozzle and the oil nozzle are provided at different positions apart from the air nozzle, and the fuel gas is ejected from the gas nozzle toward the combustion air ejected from the air nozzle, Fuel oil is ejected from the oil nozzle, a position where combustion air ejected from the air nozzle and fuel gas ejected from the gas nozzle merge, and fuel ejected from the oil nozzle The position where the oil merges with the combustion air ejected from the air nozzle is different from that of the air nozzle. Combustion in which the fuel oil ejected from the oil nozzle is ejected from the air nozzle at a position downstream of the ejection direction from the position where the combustion air ejected and the fuel gas ejected from the gas nozzle merge. It was made to merge with commercial air .

Further, a position where the fuel gas ejected from the combustion air and the gas nozzle ejected from the air nozzles as described above are merged, the fuel oil ejected from the oil nozzle is jetted from the air nozzle If the position where it merges with the combustion air is made different, the fuel gas and fuel oil come into contact with the combustion air at different positions and burn, and the fuel oil is prevented from incomplete combustion. At the same time, soot generated by incomplete combustion is prevented from adhering to the oil nozzle.

Further, at the position of the ejection direction downstream side of the position where the jetted fuel gas merges from jet combustion air and the gas nozzle from the air nozzle, as described above, the air nozzle fuel oil jetted from the oil nozzle When the combustion air jetted from is combined with the combustion air, the flame caused by the combustion can be lengthened and sufficiently heated even at a position away from the combustion device.

Claims (8)

  In a combustion apparatus comprising a gas nozzle for ejecting fuel gas, an oil nozzle for ejecting fuel oil, and an air nozzle for ejecting combustion air, the gas nozzle and the oil nozzle are separated from the air nozzle, respectively. A combustion apparatus characterized in that fuel gas is ejected from the gas nozzle while fuel oil is ejected from the oil nozzle toward combustion air ejected from the air nozzle.   The combustion apparatus according to claim 1, further comprising: a fuel gas adjusting device that adjusts an amount of fuel gas ejected from the gas nozzle; and a fuel oil adjusting device that adjusts an amount of fuel oil ejected from the oil nozzle. A combustion apparatus characterized by that.   The combustion apparatus according to claim 1 or 2, wherein the combustion air ejected from the air nozzle and the fuel gas ejected from the gas nozzle merge and the oil nozzle ejected from the oil nozzle. A combustion apparatus characterized in that the position where the fuel oil merges with the combustion air ejected from the air nozzle is different.   The combustion apparatus according to any one of claims 1 to 3, wherein the combustion air ejected from the air nozzle and the fuel gas ejected from the gas nozzle join each other downstream in the ejection direction. A combustion apparatus characterized in that the fuel oil ejected from the oil nozzle merges with the combustion air ejected from the air nozzle at the position.   The combustion apparatus according to any one of claims 1 to 4, wherein a fuel gas ejection angle for ejecting fuel gas from the gas nozzle toward the combustion air ejected from the air nozzle; A combustion apparatus characterized in that the fuel oil ejection angle for ejecting fuel oil from the oil nozzle is different.   6. The combustion apparatus according to claim 1, wherein an interval between the air nozzle and the gas nozzle is different from an interval between the air nozzle and the oil nozzle. Combustion device characterized by.   The combustion apparatus according to any one of claims 1 to 6, wherein the heat of the combustion exhaust gas is stored in the heat storage part during non-combustion, while the combustion air is heated through the heat storage part thus stored during combustion. A combustion apparatus characterized by being ejected from the air nozzle.   A heating furnace for heating an object to be processed, wherein the combustion apparatus according to any one of claims 1 to 7 is used.

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