KR101676605B1 - Method for controlling combustion in continuous heat treating furnace and method for modifying continuous heat treating furnace - Google Patents

Abstract

It is possible to suppress the generation of NO _x during the combustion operation when burning the fuel in the radiant tube burners provided in parallel along the running direction of the strip running in the heat treatment furnace, The present invention has been made in view of the above problems.
When burning fuel by supplying fuel and combustion air to a radiant tube burner 20 provided in parallel along a running direction of the strip 1 running in the heat treatment furnace 10, And the radiant tube burner for stopping the combustion is changed so as to lower the air ratio mu of the combustion air to be supplied during the combustion operation, Only the air for combustion is supplied to remove the soot.

Description

TECHNICAL FIELD [0001] The present invention relates to a combustion control method for a continuous heat treatment furnace, and a method for modifying a continuous heat treatment furnace. BACKGROUND OF THE INVENTION < RTI ID = 0.0 >

The present invention relates to a radiant tube burner comprising a plurality of radiant tube burners arranged side by side along a running direction of a strip running in a heat treatment furnace and supplying fuel and combustion air to the radiant tube burner, To a continuous heat treatment furnace for performing heat treatment such as annealing in succession on a strip running in a heat treatment furnace and a method for modifying the continuous heat treatment furnace. Particularly, when fuel and combustion air are supplied to the radiant tube burner and the fuel is burned in the radiant tube burner, the generation of NO _x during the combustion operation of the radiant tube burner is suppressed, Thereby preventing the soot from sticking to the burner.

A plurality of radiant tube burners are arranged side by side along the running direction of the strip running in the heat treatment furnace, and the radiant tube burners are arranged side by side along the traveling direction of the strip running in the heat treatment furnace, as shown in Patent Documents 1 and 2, Fuel and combustion air are supplied to the burner, the fuel is burned in the radiant tube burner, and a strip running in the heat treatment furnace is successively subjected to heat treatment.

Here, when fuel and combustion air are supplied to the radiant tube burner and the amount of combustion air supplied when the fuel is burned in the radiant tube burner is taken as the theoretical air amount required for combusting the fuel, , Incomplete combustion occurs due to various causes such as the fuel and the combustion air being not mixed uniformly, soot is generated, soot is adhered to the radiant tube burner to cause combustion problem, and the radiant tube burner There is a problem such that the radiant tube is deformed.

Therefore, conventionally, when the fuel and the combustion air are supplied to the radiant tube burner and the fuel is burned in the radiant tube burner, the ratio of the combustion air amount actually supplied to the theoretical air amount, It is proposed that the amount of combustion air to be supplied to the radiant tube burner is set to be considerably larger than the theoretical air amount so as to prevent the occurrence of soot by incomplete combustion.

However, when the combustion is performed by setting the air ratio mu of the combustion air supplied into the radiant tube burner to about 1.15 to 1.30, the temperature of the flame at the time of combustion increases and the amount of generated NO _x increases, There was a problem of harming.

Therefore, in the conventional continuous heat treatment furnace, it is possible to prevent soot from adhering to the radiant tube burner and to prevent combustion from occurring, and also to suppress the increase in the amount of NO _x generated due to the increase in the temperature of the flame at the time of combustion There was no.

Further, in Patent Document 1, the inside of the continuous heat treatment furnace is divided into a plurality of zones along the course of the strip, and depending on the required calorific value for each zone, the combustion to be supplied to the radiant tube burners provided in each zone It has been proposed to control the flow rate of the gas.

However, even when the flow rate of the combustion gas to be supplied to the radiant tube burners provided in the respective zones is controlled as shown in Patent Document 1, if the air ratio mu of the combustion air supplied to each radiant tube burner is reduced , Soot is deposited in the radiant tube burner to cause a problem of combustion, and when the air ratio mu of the combustion air is increased, the temperature of the flame at the time of combustion increases and the amount of generated NO _x increases, It is impossible to prevent soot from adhering to the inside of the tube burner and to prevent the combustion from occurring, and it is impossible to suppress the increase of the amount of NO _x due to the increase of the temperature of the flame at the time of combustion.

Japanese Patent Application Laid-Open No. 8-35015 Japanese Patent Application Laid-Open No. 2002-294347

The present invention relates to a radiant tube burner comprising a plurality of radiant tube burners arranged side by side along a running direction of a strip running in a heat treatment furnace and supplying fuel and combustion air to the radiant tube burner, The present invention has been made in order to solve the above-described problem in the case of continuously performing a heat treatment on a strip running in a heat treatment furnace.

That is, in the combustion control method of the continuous heat treatment furnace of the present invention, when the fuel and the combustion air are supplied to the radiant tube burner as described above, the fuel is burned in the radiant tube burner, To suppress the generation of NO _x in the radiant tube burner, and to appropriately prevent the soot from adhering to the radiant tube burner.

In order to solve the above problems, in a combustion control method for a continuous heat treatment furnace according to the present invention, a plurality of radiant tube burners are provided side by side along a running direction of a strip running in a heat treatment furnace, A method for controlling combustion in a continuous heat treatment furnace in which fuel and combustion air are supplied to a radiant tube burner to burn fuel in a radiant tube burner and to continuously heat a strip running in the heat treatment furnace, And a combustion control device for individually controlling the stopping of the combustion of the radiant tube burner is provided so that the combustion of the radiant tube burner is stopped by the combustion control device and the radiant tube burner whose combustion is stopped is changed, in Radiant tube burner to conduct, supplying to suppress the generation of NO _x In Radiant tube burner with a low air ratio μ of the combustion air and it stops to perform combustion while the combustion operation, the air supplied for combustion has to remove the soot generated in the Radiant tube burner.

Here, in the Radiant tube burner subjected to combustion operation as described above, when subjected to combustion by a low air ratio μ of the combustion for supplying air, and inhibits a flame temperature at the time of combustion increases, the generation of NO _x While the air ratio mu of the combustion air is low, soot is easily generated in the radiant tube burner at the time of combustion.

On the other hand, in the radiant tube burner in which the combustion operation is stopped, when the combustion air is supplied, soot generated in the radiant tube burner as described above is decomposed by reacting with the combustion air, and in the radiant tube burner Of the soot is removed. Here, when the combustion air heated by heat exchange with the combustion exhaust gas or the like is used as the combustion air to be supplied to the radiant tube burner that stops the combustion operation, the temperature of the radiant tube burner that stops the combustion operation And the temperature in the furnace is prevented from lowering.

If the radiant tube burner for stopping the combustion in some of the radiant tube burners and for stopping the combustion is changed by the combustion control device as in the combustion control method of the continuous heat treatment furnace according to the present invention, At the time of stopping the combustion operation, even if soot is generated in the radiant tube burner because the air ratio mu of the combustion air is lowered so as to suppress the generation of NO _x during operation, soot is generated in the radiant tube burner, The soot in the radiant tube burner is decomposed by the reaction with the combustion air and the soot is removed from the inside of the radiant tube burner.

Here, as described above, in the radiant tube burner for stopping the combustion in some radiant tube burners and changing the radiant tube burners for stopping the combustion by the combustion control device as described above, The air ratio mu of the combustion air supplied to suppress the generation of NO _x is lowered and the combustion is performed. On the other hand, in the radiant tube burner which stops the combustion operation, the combustion air is supplied to the soot generated in the radiant tube burner In order to remove the air, an individual fuel supply pipe for supplying fuel to each radiant tube burner is provided with an on-off valve for changing the supply and stop of the fuel, and an individual air Control for controlling the supply amount of combustion air supplied to the radiant tube burner to the supply pipe It can be installed to the end.

Further, in the combustion control method for a continuous heat treatment furnace according to the present invention, when the burning in some radiant tube burners is stopped by the combustion control device as described above, the strip running in the heat treatment furnace is appropriately heat- It is preferable to control the number of the radiant tube burners that stop the combustion so that the furnace temperature of the furnace is maintained at the predetermined heat treatment temperature.

Further, in the radiant tube burner that carries out the combustion operation as described above, when the air ratio mu of the supplied combustion air is made low, it is preferable that the air ratio mu is set to 1.1 or less so that the generation of NO _x is properly suppressed . For example, when the air ratio μ of the combustion air supplied to the radiant tube burner is 1.05, the amount of NO _x generally decreases by 10 to 20% compared to when the air ratio μ is 1.20.

When the combustion air is supplied to the radiant tube burner that stops the combustion operation as described above, if the amount of the combustion air to be supplied becomes large, the radiant tube burner becomes cold by the supplied combustion air, The internal temperature of the furnace may be lowered. Therefore, it is preferable that the amount of the combustion air supplied to the radiant tube burner that stops the combustion operation is made smaller than the amount of the combustion air supplied to the radiant tube burner that performs the combustion operation.

In addition, in the case where combustion air is supplied to the radiant tube burner which stops the combustion operation, in order to prevent the radiant tube burner from being cooled by the supplied combustion air so that the furnace temperature of the heat treatment furnace is lowered, It is preferable to use combustion air heated by heat exchange with the combustion exhaust gas in advance.

Further, in the combustion control method for the continuous heat treatment furnace according to the present invention, it is also possible to use only a radiant tube burner that performs ON / OFF control of the combustion to supply only the combustion air to the radiant tube burner whose combustion has been turned OFF have.

In the method for retrofitting a continuous heat treatment furnace according to the present invention, a plurality of radiant tube burners are provided side by side along the running direction of a strip running in the treatment furnace, and fuel and combustion air are supplied to the radiant tube burners A combustion control device for separately controlling the combustion and the stop in each radiant tube burner in a continuous heat treatment furnace in which heat is applied to a strip for burning fuel in a radiant tube burner and traveling in a heat treatment furnace, In the radiant tube burner for performing the combustion operation by changing the radiant tube burner for stopping the combustion in some of the radiant tube burners and for stopping the combustion by the combustion control device, by lowering the air ratio μ of the combustion air for supplying to suppress the generation of the _x and subjected to combustion On the other hand, in the Radiant tube burner stops the combustion operation, supplies the air for combustion and to remove the soot generated in the Radiant tube burner.

In the combustion control method for a continuous heat treatment furnace according to the present invention, a combustion control device for individually controlling the combustion and the stop of each radiant tube burner is provided as described above. By this combustion control device, The burning of the burner is stopped and the radiant tube burner for stopping the combustion is changed to lower the air ratio mu of the combustion air supplied to the radiant tube burner for performing the combustion operation, at the same time to suppress the generation of NO _x, by supplying combustion air to the Radiant tube burner stops the combustion operation, and to remove the soot in the inside Radiant tube burner.

As a result, in the combustion control method for a continuous heat treatment furnace according to the present invention, the generation of NO _x during the combustion operation of the radiant tube burner is suitably suppressed, and the adhesion of soot in the radiant tube burner is suitably suppressed And it is possible to stably perform appropriate combustion in each radiant tube burner.

Further, as shown in the method for modifying the continuous heat treatment furnace according to the present invention, it is possible to carry out the combustion controlling method for the continuous heat treatment furnace according to the present invention in the conventional continuous heat treatment furnace by modifying the continuous heat treatment furnace, .

1 is a schematic cross-sectional view showing a heat treatment furnace used in a combustion control method for a continuous heat treatment furnace related to the embodiment of the present invention.
Fig. 2 is a flowchart showing a method of controlling combustion in a continuous heat treatment furnace related to the above-described embodiment, in which the combustion control device controls the combustion and the stop of each radiant tube burner individually and controls the combustion in some radiant tube burners Fig. 8 is a schematic explanatory diagram showing a state in which the stopping is performed.
3 is a partial schematic explanatory view showing a state in which a combustion tube is changed by a combustion control device to stop combustion in a combustion control method for a continuous heat treatment furnace related to the above embodiment.
FIG. 4 is a graph showing the relationship between the combustion gas (fuel) supplied to each radiant tube burner and the amount of combustion gas (fuel) supplied to each radiant tube burner when the combustion and the stop of each radiant tube burner are individually controlled, And the amount of combustion air is changed.
5 is a partial schematic explanatory view showing a modification of the combustion control method for the continuous heat treatment furnace related to the above embodiment, in which combustion and stoppage of each radiant tube burner are individually controlled by the combustion control device .

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a combustion control method for a continuous heat treatment furnace according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. Incidentally, the combustion control method of the continuous heat treatment furnace according to the present invention is not limited to the one shown in the following embodiments, but can be suitably modified and carried out within the range not changing the gist of the invention.

In this embodiment, as shown in Fig. 1, a plurality of rolls 11 are arranged in the lower part and the upper part of the heat treatment furnace 10 from the inlet 12 of the heat treatment furnace 10 toward the outlet 13, And the strip 1 introduced into the heat treatment furnace 10 from the inlet 12 is fed to the lower and upper rolls 11 in the heat treatment furnace 10 from the inlet 12 to the outlet 13, So that the strip 1 is caused to travel from the inlet 12 of the heat treatment furnace 10 toward the outlet 13.

In the heat treatment furnace 10, a plurality of (for example, 100 or more) radiant tube burners 20 are provided side by side along the running direction of the strip 1 running as described above, The fuel gas and the combustion air serving as fuel are supplied to the tube burner 20 so that the fuel gas is burned in the radiant tube burner 20 and crossed to the lower and upper rolls 11 as described above The strip 1 running in the heat treatment furnace 10 from the inlet 12 toward the outlet 13 is continuously heat treated.

2 and 3, when supplying the fuel gas and the combustion air to the respective radiant tube burners 20, the fuel gas is supplied from the gas guide pipe 30 to the individual gas supply pipes (individual fuel supply pipes) The air is guided to each radiant tube burner 20 through the air guide tube 31 and the combustion air is led from the air guide tube 40 to the respective radiant tube burners 20 through the individual air supply tubes 41 have.

The individual gas supply pipe 31 for leading the fuel gas to the radiant tube burner 20 is provided with an on-off valve 32 for changing the supply and stop of the fuel gas to the radiant tube burner 20.

The individual air supply pipe 41 for leading the combustion air to the radiant tube burner 20 is provided with control means for controlling the supply amount of the combustion air to be supplied to the radiant tube burner 20, Off valve 42 is provided for changing the supply and stop of combustion air to the bypass pipe 20 and a bypass pipe 43 is provided so as to bypass the on-off valve 42. Further, the bypass pipe 43 A control valve 44 is provided.

When the opening / closing valve 42 provided in the individual air supply pipe 41 is closed, the amount of the combustion air directed to the radiant tube burner 20 through the bypass pipe 43 is controlled by the control valve (44). When the on-off valve 42 is closed as described above, the amount of air to be supplied to the radiant tube burner 20 is reduced by opening the on-off valve 42, The amount of combustion air drawn by the tube burner 20 is reduced. Further, as the degree of opening of the control valve 44 is increased, the effect of removing soot is increased, so that the soot attached to the radiant tube burner 20 can be removed in a short time.

The combustion control device 50 for controlling the opening and closing of the opening and closing valves 32 provided in the individual gas supply pipes 31 and the opening and closing valves 42 provided in the respective individual air supply pipes 41, And the combustion control device 50 controls the combustion and the stop of each radiant tube burner 20 individually.

Here, in the radiant tube burner 20 for performing the combustion operation, the combustion control device 50 controls the opening / closing valve 32 provided to the individual gas supply pipe 31 and the individual air supply pipe 41 Closing valve 42 is opened to supply the fuel gas and combustion air to the radiant tube burner 20 to burn the fuel gas in the radiant tube burner 20.

In this embodiment, when burning the fuel gas in the radiant tube burner 20, the air ratio mu of the combustion air drawn by the radiant tube burner 20 through the individual air supply pipe 41 For example, the air ratio mu of the combustion air is set to 1.05 to 1.10, and the combustion is performed.

When the air ratio mu of the combustion air is changed to 1.05 to 1.10 in this way, the temperature of the flame at the time of combustion is prevented from rising and the generation of NO _x during combustion is suppressed. However, The soot tends to be generated in the tube burner 20.

In the radiant tube burner 20 for stopping the combustion, the combustion control device 50 controls the opening / closing valve 32 provided in the individual gas supply pipe 31 and the individual air supply pipe 41 provided in the individual air supply pipe 41 Closing valve 42 is closed and combustion is stopped by preventing the fuel gas from being supplied to the radiant tube burner 20 through the individual gas supply pipe 31 and the combustion air is radiated through the on- So that it is not attracted to the tube burner 20. In this case, an adequate amount of combustion air is supplied to the radiant tube burner 20 through the bypass pipe 43 provided with the control valve 44 for the combustion air.

When a proper amount of combustion air is supplied to the radiant tube burner 20 through the bypass tube 43 to the radiant tube burner 20 thus stopped, the radiant tube burner 20 The soot generated in the radiant tube burner 20 is decomposed by the reaction with the combustion air and the soot is removed from the radiant tube burner 20.

Here, in this embodiment, when the combustion control device 50 individually controls the combustion and the stop of each radiant tube burner 20, as shown in Figs. 2 and 3, The open / close valve 32 provided in the individual gas supply pipe 31 and the open / close valve 42 provided in the individual air supply pipe 41 are closed and the fuel gas is supplied to the individual gas supply pipe 31 Off valve 32 and the individual air supply pipe 41 provided in the individual gas supply pipe 31 in the other radiant tube burner 20 while stopping the supply of the air to the radiant tube burner 20 through the air supply pipe 31, And the fuel gas and the combustion air are supplied to the radiant tube burner 20 to burn the fuel gas.

As shown in FIGS. 2 and 3, the radiant tube burner 20 for changing the timing of the radiant tube burner 20 for stopping the combustion as described above and burning the fuel gas, And a radiant tube burner 20 for removing soot by supplying only air for combustion.

The number of the radiant tube burners 20 for stopping the combustion is not particularly limited. However, in order to heat the strip 1 running in the heat treatment furnace 10 appropriately, The inner temperature is maintained at a predetermined heat treatment temperature, and the number of the radiant tube burners 20 for stopping the combustion is controlled.

For example, as shown in Fig. 4, the combustion of the radiant tube burner 20 is successively stopped while the number of the radiant tube burners 20 for burning the fuel gas is always the same, It is preferable to remove the soot adhering to the burner 20.

When stopping the burning of the plurality of radiant tube burners 20, the radiant tube burners 20 may be stopped at a predetermined number of lines arranged side by side in the running direction of the strip 1, The radiant tube burners 20 may be combined and stopped for each combustion zone.

The ratio of the radiant tube burner 20 for stopping the combustion is set to a value corresponding to the running speed of the traveling strip 1, the installation interval of the radiant tube burner 20, and the opening degree of the control valve 44 It is appropriate to set the radiant tube burner 20 to 10 to 30% of the entirety of the radiant tube burner 20. This is because, if the ratio of the radiant tube burner 20 for stopping the combustion is small, the effect of removing soot is small. On the other hand, if the proportion of the radiant tube burner 20 is too large, the furnace inner temperature of the heat treatment furnace 10 may be lower than the predetermined heat treatment temperature .

Further, in the case of using the radiant tube burner 20 for controlling the ON / OFF of the combustion for the temperature adjustment, even if the radiant tube burner 20 for stopping the combustion is not changed in the above- It is also possible to supply only the combustion air to the radiant tube burner 20 for turning off the combustion so that the soot in the radiant tube burner 20 is removed.

In the radiant tube burner 20 for supplying the fuel gas and the combustion air to burn the fuel gas, the air ratio mu of the combustion air drawn by the radiant tube burner 20 is set to a low value of 1.05 to 1.10 Value, the temperature of the flame at the time of combustion is lowered, and the generation of NO _{x at} the time of combustion is suppressed.

When the air ratio mu of the combustion air is set to a low value of 1.05 to 1.10 and the fuel gas is burned, soot is generated in the radiant tube burner 20. However, as described above, The supply of the fuel gas to the radiant tube burner 20 is stopped when the tube burner 20 and the radiant tube burner 20 for stopping the combustion are changed to appropriate timings and the radiant tube burner 20 4, only a proper amount of combustion air is supplied through the bypass pipe 43 provided with the control valve 44, so that the radiant tube burner 20, as described above, The soot generated in the radiant tube burner 20 is decomposed by the reaction with the combustion air and the soot is removed from the radiant tube burner 20.

As a result, it is possible to appropriately prevent the generation of NO _x in the radiant tube burner 20 for burning the fuel gas, and even if soot is generated in the radiant tube burner 20 at the time of combustion, When the combustion in the tube burner 20 is stopped, the soot in the radiant tube burner 20 is removed by reaction with the combustion air as described above, and soot is adhered to the radiant tube burner 20 So that stable burning can be properly performed in each radiant tube burner 20 while suppressing the generation of NO _x .

Further, in the case where only the combustion air is supplied to the radiant tube burner 20 in which the combustion is stopped as described above, since the temperature in the radiant tube burner 20 is prevented from lowering, The combustion air heated by heat exchange with the combustion exhaust gas can be used.

Further, in the above embodiment, when an appropriate amount of combustion air is supplied to the radiant tube burner 20 in which combustion is stopped, the combustion air is supplied to the individual air supply pipe 41 leading to the radiant tube burner 20 The bypass pipe 43 is provided so as to bypass the installed on-off valve 42 and the control valve 44 is provided in the bypass pipe 43. However, the radiant tube burner 20 ) Is not limited to such a method.

5, as the control means for controlling the supply amount of the combustion air to be supplied to the radiant tube burner 20, an individual air supply pipe (not shown) for leading the combustion air to the radiant tube burner 20 41 is provided with a flow rate adjusting valve 45 and the flow rate regulating valve 45 is controlled by the combustion control device 50 so as to control the combustion air to be supplied to the radiant tube burner 20 can do.

In such a case, when the radiant tube burner 20 is operated to perform combustion, an appropriate amount of combustion air as described above is supplied to the radiant tube burner 20 through the flow rate control valve 45, So that combustion with less generation of NO _x is achieved. On the other hand, at the time of stopping the combustion of the radiant tube burner 20, the air for combustion supplied to the radiant tube burner 20 is reduced through the flow rate control valve 45, The soot of the radiant tube burner 20 is decomposed by reacting with the supplied combustion air so that the soot is removed from the inside of the radiant tube burner 20. [

Although not shown, the amount of the fuel gas to be supplied to the radiant tube burner 20 is changed by using a flow rate adjusting valve in place of the open / close valve 32 provided in the individual gas supply pipe 31, It is also possible to individually adjust the amount of combustion in the tube burner 20.

Also in the conventional continuous heat treatment furnace, the supply of the fuel gas to the radiant tube burner 20 and the supply of the fuel gas to the individual gas supply tube 31, which leads the fuel gas to the radiant tube burner 20, The supply amount of the combustion air to be supplied to the radiant tube burner 20 is set to an individual air supply pipe 41 for leading the combustion air to the radiant tube burner 20 And a combustion control device 50 for separately controlling the combustion and the stop of the radiant tube burners 20 is provided in the combustion control device 50, By controlling the combustion and the stop of each radiant tube burner 20 individually as in the above embodiment, it is possible to obtain the same effect as that of the above-described embodiment.

1: strip
10: Heat treatment furnace
11: roll
12: Entrance
13: Exit
20: Radiant tube burner
30: gas guide pipe
31: Individual gas supply pipe (individual fuel supply pipe)
32: opening / closing valve
40: air guide pipe
41: Individual air supply pipe
42: opening / closing valve
43: Bypass pipe
44: Control valve
45: Flow regulating valve
50: Combustion control device

Claims (8)

A plurality of radiant tube burners are arranged side by side along the running direction of the strip running in the heat treatment furnace, the fuel and combustion air are supplied to the radiant tube burners, the fuel is burned in the radiant tube burners, A combustion control device for controlling the combustion and the stop of each of the radiant tube burners is provided, and the combustion control device controls the combustion control device The radiant tube burner for stopping the combustion in the radiant tube burner and for changing the radiant tube burner for stopping the combustion and the burning air supplied for suppressing the generation of NO _x The air ratio mu of the combustion air is reduced and the combustion is performed, In the agent tube burner, the combustion control method to a continuous heat treatment which comprises supplying air for combustion to remove the soot generated in the Radiant tube burner. In the description of claim 1,
An individual fuel supply pipe for individually supplying fuel to each radiant tube burner is provided with an on-off valve for changing the supply and stop of the fuel, and an individual air supply pipe for individually supplying combustion air to each radiant tube burner, And a control means for controlling a supply amount of combustion air to be supplied to the tube burner. In the description of claim 1 or claim 2,
Characterized in that the number of radiant tube burners for stopping the combustion is controlled so that the furnace inner temperature of the heat treatment furnace is maintained at a predetermined heat treatment temperature when the combustion control device stops the combustion in some radiant tube burners A method for controlling combustion in a continuous heat treatment furnace. In the description of claim 1 or claim 2,
Wherein the air ratio mu of the combustion air to be supplied to the radiant tube burner performing the combustion operation is set to 1.1 or less. In the description of claim 1 or claim 2,
Characterized in that the amount of combustion air to be supplied to the radiant tube burner which stops the combustion operation is made smaller than the amount of combustion air to be supplied to the radiant tube burner for performing the combustion operation . In the description of claim 1 or claim 2,
Wherein the combustion air to be supplied to the radiant tube burner which stops the combustion operation is heated in advance. A plurality of radiant tube burners are arranged side by side along the running direction of the strip running in the heat treatment furnace, the fuel and combustion air are supplied to the radiant tube burners, the fuel is burned in the radiant tube burners, A combustion control device for individually controlling the combustion and the stop of each radiant tube burner is additionally provided to an existing continuous heat treatment furnace for successively heat treating the strip running on the inside of the radiant tube burner, At the same time of stopping the combustion of the gradient tube burner, in the Radiant tube burner to change the Radiant tube burner stops the combustion and carry out the combustion operation of the combustion for supplying to suppress the generation of NO _x air The air ratio mu is reduced and the combustion is performed, while the radiant In the probe burner, it adapted to a continuous heat treatment method characterized in that supplying the air for combustion to remove the soot generated in the Radiant tube burner.



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