KR20110132986A - Combustion controll method for regenerative-combustion heat treat furnace - Google Patents

Abstract

PURPOSE: The combustion operation and the heat storage operation are switched, the change of the inner pressure of the heat storage burn-out thermal process furnace or the sudden incomplete combustion is controlled. CONSTITUTION: A combustion control method for regenerative-combustion heat treat furnace(10) comprises the following steps. Supplies an amount of the fuel gas to fuel gas supply pipes(28a,28b) of regenerative burners(20a,20b) in the heat storage burn-out thermal process the fuel gas supply device. When the combustion action and the regenerating motion are switched in a pair of regenerative burners, in the regenerative burner performing combustion action, the amount of the combustion air and the fuel gas provided through the fuel gas supply pipe and an air supply pipe(24a) diminishes. In the regenerative burner performing regenerating motion, the fuel gas and combustion air are provided through the fuel gas supply pipe and an air supply pipe(24b). Disclosed is the combustion of the regenerative burner performing regenerating motion.

Description

Combustion control method in regenerative combustion heat treatment furnace {COMBUSTION CONTROLL METHOD FOR REGENERATIVE-COMBUSTION HEAT TREAT FURNACE}

This application claims the priority based on Japanese Patent Application No. 2010-127570.

The present invention provides a burner section including a fuel gas supply pipe, a heat storage chamber accommodating a heat storage material, an air supply pipe for supplying combustion air to the heat storage chamber, and an exhaust gas discharge pipe for discharging combustion exhaust gas from the heat storage chamber. At least one pair of regenerative burners having a gas is provided, and in one regenerative burner, the combustion air is led from the air supply pipe through the heat storage chamber to the burner section, and the fuel gas is injected from the fuel gas supply pipe at the burner section for combustion. On the other hand, in the other heat storage burner, a heat storage operation is performed in which combustion exhaust gas is led to the heat storage chamber as described above, thereby storing heat of combustion exhaust gas in the heat storage material and discharging it from the exhaust gas discharge pipe. The combustion control method of a regenerative combustion heat treatment furnace which alternates between the combustion operation and the heat storage operation in It is about. In particular, in a regenerative combustion heat treatment furnace in which a fuel gas supply device supplying a predetermined amount of fuel gas supplies fuel gas to a fuel gas supply pipe in each regenerative burner, the combustion operation and the regenerative operation in a pair of regenerative burners are performed. In switching, when a combustion operation of a regenerative burner in a heat storage operation is started, it is characterized by suppressing the occurrence of rapid combustion.

BACKGROUND ART Conventionally, in heat treatment of a material to be treated, a burner portion having a fuel gas supply pipe, a heat storage chamber accommodating the heat storage material, an air supply pipe for supplying combustion air to the heat storage chamber, and combustion exhaust in the heat storage chamber Using a regenerative combustion heat treatment furnace provided with at least a pair of regenerative burners having an exhaust gas discharge pipe for discharging the gas, in one regenerative burner, the combustion air is led to the burner section through the regenerative chamber in the air supply pipe, While the combustion operation is performed by injecting fuel gas from the fuel gas supply pipe in the section, in the other regenerative burner, combustion exhaust gas is led to the heat storage chamber, and the heat of combustion exhaust gas is accumulated in the heat storage material so as to be discharged from the exhaust gas discharge pipe. A heat storage operation for discharging is performed, and the combustion operation and the heat storage operation in the pair of heat storage burners are alternately switched. It has been executed.

In the heat storage combustion heat treatment furnace described above, a plurality of pairs of heat storage burners are provided in the heat treatment furnace to continuously heat-treat the material to be treated, and in each of the heat storage burners, the combustion operation and heat storage are performed. Different timings for switching operations are also used.

In the regenerative combustion heat treatment furnace described above, the fuel gas is supplied to each fuel gas supply pipe in a fuel gas supply device that generally supplies a constant amount of fuel gas in supplying fuel gas to the fuel gas supply pipe in each of the regenerative burners. It is made to supply gas.

Here, in the above-described heat storage combustion type heat treatment furnace, conventionally, Japanese Patent Application Laid-Open No. 10-185176 and Japanese Patent Laid-Open No. 11-11, in order to alternately switch the combustion operation and the heat storage operation in a pair of heat storage burners. As shown in Japanese Patent No. 159744, in a heat storage burner during a combustion operation, after supply of fuel gas from a fuel gas supply pipe is stopped, supply of combustion air from an air supply pipe is stopped, and a heat storage type during heat storage operation. It is known that in the burner, after the supply of combustion air from the air supply pipe is started, the supply of fuel gas from the fuel gas supply pipe is started to start combustion. Further, as shown in Japanese Patent No. 3539093, in the heat storage burner during the combustion operation, the supply of fuel gas and the air for combustion is stopped, and the fuel gas and the air for combustion in the heat storage burner during the heat storage operation. It is known to start supply of and to start combustion.

Here, in each of the publications described above, when the regenerative burner in the regenerative operation starts combustion, the regenerative burner in the combustion operation stops the supply of the combustion gas from the fuel gas supply device as described above. In the fuel gas supply pipe from the gas supply device to the heat storage burner, the gas pressure of the fuel gas is higher than usual, and at the beginning when the heat storage burner during the heat storage operation starts combustion, the fuel gas supply device described above is more than usual. A large amount of fuel gas is supplied to commence combustion.

For this reason, in each of these publications, sudden combustion occurs at the start of combustion in the regenerative burner during the above-described regenerative operation, the pressure in the regenerative combustion heat treatment furnace is greatly changed, or incomplete combustion occurs, and therefore, There was a problem that the combustion could not be made stable. In particular, in the case of using a gas having poor combustibility, for example, propane, as the fuel gas, graphite (soot) is generated due to incomplete combustion, which causes environmental problems, or soot adheres to the material to be treated. There was a problem that was not made.

The present invention has at least one burner section having a fuel gas supply pipe, a heat storage chamber accommodating the heat storage material, an air supply pipe for supplying combustion air to the heat storage chamber, and an exhaust gas discharge pipe for discharging combustion exhaust gas from the heat storage chamber. A pair of regenerative burners are provided, and in one regenerative burner, the combustion air is led from the air supply pipe through the heat storage chamber to the burner section, and the fuel gas is injected from the fuel gas supply pipe at the burner section for combustion operation. In the other regenerative burner, the combustion exhaust gas is led to the above-described heat storage chamber to accumulate the heat of the combustion exhaust gas in the heat storage material and to discharge the exhaust gas from the exhaust gas discharge pipe. To solve the above problem in a regenerative combustion heat treatment furnace which alternates combustion and regenerative operation. Is to make it a task.

That is, in the present invention, in a heat storage combustion type heat treatment furnace in which a fuel gas supply device for supplying a predetermined amount of fuel gas is supplied to a fuel gas supply pipe in each heat storage burner, a pair of heat storage burners In switching the combustion operation and the heat storage operation, it is characterized by suppressing the occurrence of rapid combustion when starting the combustion operation of the heat storage burner in the heat storage operation.

In the present invention, in order to solve the above problems, a burner section including a fuel gas supply pipe, a heat storage chamber accommodating a heat storage material, an air supply pipe for supplying combustion air to the heat storage chamber, and combustion exhaust in the heat storage chamber At least one pair of regenerative burners having an exhaust gas discharge pipe for discharging the gas is provided, and in one regenerative burner, the combustion air is led from the air supply pipe through the heat storage chamber to the burner part, and at the same time, the fuel gas supply pipe in the burner part. While the combustion operation is performed by injecting fuel gas into the fuel cell, the other regenerative burner conducts the combustion exhaust gas to the above-described heat storage chamber to accumulate the heat of the combustion exhaust gas in the heat storage material to discharge the exhaust gas from the exhaust gas discharge pipe. The regenerative combustion heat treatment furnace which alternates between the combustion operation and the heat storage operation in the pair of regenerative burners. In the combustion control method, a fuel gas supply device for supplying a predetermined amount of fuel gas causes fuel gas to be supplied to a fuel gas supply pipe in each of the above-described regenerative burners, and at the same time, the combustion operation and the heat storage in the pair of regenerative burners described above. In switching operations, in the regenerative burner during the combustion operation, before reducing the supply of fuel gas from the fuel gas supply pipe and the supply of combustion air from the air supply pipe, in the regenerative burner during the heat storage operation, the fuel gas supply pipe and the air supply pipe. Started supplying fuel gas and combustion air.

Then, in switching the combustion operation and the heat storage operation in the pair of heat storage burners as described above, in the heat storage burner during the combustion operation, the supply of fuel gas from the fuel gas supply pipe and the supply of combustion air from the air supply pipe are reduced. In the heat storage burner during the heat storage operation, when fuel gas and combustion air are supplied from the fuel gas supply pipe and the air supply pipe to start combustion, the fuel gas supply device supplying a constant amount of fuel gas is supplied to the heat storage burner during the combustion operation. Since the fuel gas is started to the regenerative burner during the heat storage operation while the fuel gas is supplied, the amount of fuel gas supplied to the regenerative burner during the heat storage operation is reduced, and the combustion is started in a state where the fuel gas is low. Done.

Here, as the heat storage combustion heat treatment furnace, a plurality of pairs of heat storage burners may be provided, and the pair of heat storage burners having different timings for switching the combustion operation and the heat storage operation may be used.

Moreover, in the combustion control method of the heat storage combustion type heat treatment furnace of the present invention, in switching the combustion operation and the heat storage operation in a pair of heat storage type burners, the supply of fuel gas from the fuel gas supply pipe is performed in the heat storage type burner during the combustion operation. After stopping the supply of combustion air from the air supply pipe, the exhaust gas discharge pipe discharges the combustion exhaust gas, and stops the operation of discharging the combustion exhaust gas from the exhaust gas discharge pipe in the heat storage burner during the heat storage operation. Thereafter, it is preferable to start the supply of fuel gas from the fuel gas supply pipe and the supply of combustion air from the air supply pipe. In this way, in switching the combustion operation and the heat storage operation, during the switching operation by the switching valve or the like, a part of the combustion air drawn from the air supply pipe to the heat storage chamber is prevented from bypassing the heat storage chamber and being discharged through the exhaust gas discharge pipe. Done.

In the combustion control method of the regenerative combustion heat treatment furnace according to the present invention, the fuel is supplied from the fuel gas supply pipe in the regenerative burner during the combustion operation in switching the combustion operation and the regenerative operation in the pair of regenerative burners as described above. Before reducing the supply of gas and the supply of combustion air from the air supply pipe, in the regenerative burner during the heat storage operation, fuel gas and combustion air are supplied from the fuel gas supply pipe and the air supply pipe to start combustion. When the pressure of the fuel gas in the fuel gas supply pipe which supplies a fuel gas to a heat storage burner by a gas supply device falls, and it starts a combustion by supplying fuel gas to the heat storage burner in a heat storage operation | movement as mentioned above, during this heat storage operation, The amount of fuel gas supplied to the regenerative burner is reduced, and the combustion operation is At the beginning, the occurrence of rapid combustion is suppressed.

As a result, according to the combustion control method of the regenerative combustion heat treatment furnace according to the present invention, when switching the combustion operation and the regenerative operation of the pair of regenerative burners, the pressure in the regenerative combustion heat treatment furnace is greatly changed or incomplete combustion. Is suppressed from occurring and stable combustion can be achieved. In particular, even when propane gas or the like having poor combustibility is used as the fuel gas, graphite (soot) is prevented from being generated, and environmental problems or soot is not attached to the material to be treated.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic sectional drawing which shows the internal state of the heat storage combustion type heat processing furnace in the combustion control method of the heat storage combustion type heat processing furnace which concerns on one Embodiment of this invention.
2 is a schematic plan view of the heat storage combustion type heat treatment furnace described above in the embodiment of FIG. 1.
3 is a schematic explanatory view showing a state in which a combustion operation is performed by one regenerative burner in a pair of regenerative burners, and a regenerative operation is performed by the other regenerative burner.
FIG. 4 is a time chart showing an operation of switching a combustion operation and a heat storage operation in each heat storage burner in each pair of heat storage burners in the embodiment of FIG. 1.
FIG. 5 is a time chart showing a change example of an operation for switching the combustion operation and the heat storage operation in each of the heat storage burners in the pair of heat storage burners in the embodiment of FIG. 1.

EMBODIMENT OF THE INVENTION Hereinafter, the combustion control method of the heat storage combustion type heat treatment furnace which concerns on embodiment of this invention is concretely demonstrated based on an accompanying drawing. In addition, the combustion control method of the heat storage combustion type heat treatment furnace according to the present invention is not particularly limited to those shown in the following embodiments, and can be appropriately changed and implemented without departing from the spirit of the invention.

Here, in this embodiment, as shown in FIG. 1, the to-be-processed material 1 which consists of steel materials guide | induced in the regenerative combustion type heat treatment furnace 10 from the inlet 11 of the regenerative combustion type heat treatment furnace 10. ) Is transported by a walking beam 2 in the heat storage combustion heat treatment furnace 10 and heat treated, and the treated material 1 thus heat treated is exited from the heat storage combustion heat treatment furnace 10. Through 12), it is taken out from the heat storage combustion type heat treatment furnace 10.

In this embodiment, as shown in FIG. 2, in the above-described heat storage continuous heat treatment furnace 10, a pair of heat storage burners 20 having a burner portion 21 and a heat storage chamber 22 are provided. A fuel gas supply device which is arranged so as to face each other, and installs four pairs of regenerative burners 20 in the regenerative combustion heat treatment furnace 10 along the moving direction of the workpiece 1 and supplies a predetermined amount of fuel gas. In 30, fuel gas is supplied to the burner part 21 in each regenerative burner 20. As shown in FIG.

Here, in the above-described pair of heat storage burners 20, as shown in FIG. 3, in one heat storage burner 20a, combustion air is supplied to the heat storage chamber 22a in which the heat storage material 23a is accommodated. While opening the air supply valve 25a installed in the air supply pipe 24a, the gas discharge valve 27a provided in the exhaust gas discharge pipe 26a for discharging the combustion exhaust gas through the heat storage chamber 22a, The combustion air guided in the heat storage chamber 22a through the air supply pipe 24a is heated by the heat storage material 23a housed in this heat storage chamber 22a.

The gas supply valve 29a which supplies the combustion air heated in this way to the burner part 21a and draws fuel gas into the fuel gas supply pipe 28a provided at the center of the burner part 21a is opened. The fuel gas supplied from the above-described fuel gas supply device 30 is injected from the fuel gas supply pipe 28a to perform a combustion operation for burning the fuel gas in the heat storage combustion type heat treatment furnace 10.

On the other hand, in the other heat storage burner 20b, combustion is performed by closing the gas supply valve 29b for supplying fuel gas to the fuel gas supply pipe 28b and the air supply valve 25b provided in the air supply pipe 24b. In addition, the gas discharge valve 27b provided in the exhaust gas discharge pipe 26b for discharging the combustion exhaust gas through the heat storage chamber 22b is opened.

Then, as described above, the combustion exhaust gas after combustion in the heat storage combustion heat treatment furnace 10 is led to the heat storage chamber 22b, and heat of the combustion exhaust gas is transferred to the heat storage material 23b accommodated in the heat storage chamber 22b. The heat storage operation is then performed, and then the combustion exhaust gas is discharged to the outside through the above-described exhaust gas discharge pipe 26b.

In the above-described pair of heat storage burners 20a and 20b, the combustion operation and the heat storage operation as described above are alternately switched.

Moreover, also in each pair of regenerative burners 20, as described above, in each pair of regenerative burners 20a and 20b, the above-described combustion operation and regenerative operation are switched alternately, and each pair of regenerative burners In (20), timings for switching the combustion operation and the heat storage operation are different.

Next, in each of the above-described regenerative burners 20, the operation of switching the combustion operation and the regenerative operation of each pair of regenerative burners 20a and 20b will be described based on the time chart shown in FIG. do.

Here, in switching the combustion operation and the heat storage operation, in the heat storage burner 20a during the combustion operation, an operation of closing the air supply valve 25a and the gas supply valve 29a in the open state is started, and the air supply pipe ( In 24a, the amount of combustion air supplied to the burner unit 21a through the heat storage chamber 22a is gradually reduced, and the amount of fuel gas injected from the fuel gas supply pipe 28a is gradually reduced.

Then, the air supply valve 25a and the gas supply valve 29a are closed so that the combustion air and fuel gas are not supplied, and when the combustion is stopped, the gas discharge valve 27a in the closed state is opened. The heat of the combustion exhaust gas which led to the heat storage chamber 22a is accumulated in the heat storage material 23a accommodated in the heat storage chamber 22a, and then the combustion exhaust gas is transferred to the outside through the exhaust gas discharge pipe 26a described above. Let it drain.

On the other hand, in the thermal storage burner 20b during the thermal storage operation, in the thermal storage burner 20a during the combustion operation, in the open state before the operation of closing the air supply valve 25a and the gas supply valve 29a is started. After closing the existing gas discharge valve 27b and stopping the operation of discharging the combustion exhaust gas to the outside through the exhaust gas discharge pipe 26b, the air supply valve 25b and the gas supply valve 29b in the closed state are stopped. Starts the operation of opening).

In the heat storage burner 20a during the combustion operation, before the operation of closing the air supply valve 25a and the gas supply valve 29a is started, the air is stored in the heat storage burner 20b during the heat storage operation. Combustion air is supplied from the supply pipe 24b to the burner unit 21b through the heat storage chamber, and fuel gas is injected from the fuel gas supply pipe 28b to start combustion.

In this manner, before the operation of closing the air supply valve 25a and the gas supply valve 29a in the heat storage burner 20a during the combustion operation is started, the air supply pipe 24b in the heat storage burner 20b during the heat storage operation. The fuel gas supply device 30 which supplies a predetermined amount of fuel gas when the fuel gas is supplied from the fuel gas supply pipe 28a while the combustion air is supplied from the fuel cell is supplied to the regenerative burner 20a during the combustion operation. In the state where the fuel gas is being supplied, the fuel gas is supplied to the heat storage burner 20b during the heat storage operation.

In the regenerative combustion heat treatment furnace 10 in which four pairs of regenerative burners 20 are provided as in this embodiment, a predetermined amount of fuel gas supplied from the fuel gas supply device 30 is four pairs of regenerative burners. Dispersed and supplied to four regenerative burners 20a which respectively perform a combustion operation in 20 and the regenerative burner 20b during the regenerative operation which starts combustion, and supplies to the regenerative burner 20b during the regenerative operation which starts combustion. The amount of fuel gas to be made becomes smaller than the normal state.

Therefore, when the regenerative burner 20b during the regenerative operation starts combustion, sudden combustion is suppressed, and the pressure in the regenerative combustion heat treatment furnace 10 is greatly changed, or incomplete combustion is prevented from occurring. Therefore, appropriate combustion can be stably achieved.

In addition, in each of the above-described regenerative burners 20, in the switching between the combustion operation and the regenerative operation, the sudden combustion occurs when the regenerative burner 20b during the regenerative operation starts combustion. Therefore, appropriate combustion can be stably achieved. In particular, even in the case of using a propane gas having poor combustibility or the like for fuel gas, graphite (soot) due to incomplete combustion is generated as in the prior art, thereby causing environmental problems, and soot does not adhere to the material to be treated.

In addition, in the heat storage burner 20a during the combustion operation as described above, the air supply valve 25a and the gas supply valve 29a are closed so that the combustion air and fuel gas are not supplied and the combustion is stopped. The gas discharge valve 27a in the closed state is opened, and in the heat storage burner 20b during the heat storage operation, the gas discharge valve 27b in the open state is closed, and then the air supply for the air supply in the closed state is closed. When the valve 25b and the gas supply valve 29b are opened, a part of the combustion air leading from the air supply pipes 24a and 24b to the heat storage chambers 22a and 22b does not go to the heat storage chambers 22a and 22b. The bypass is prevented from being discharged through the exhaust gas discharge pipes 26a and 26b.

As a result, in this embodiment, the ratio of the combustion air supplied into the regenerative combustion heat treatment furnace 10 is reduced, and the ratio of the fuel gas supplied into the regenerative combustion heat treatment furnace 10 and the combustion air is reduced. This fluctuation is prevented, and more appropriate combustion can be made stable.

In the above-described embodiment, in order to alternately switch the combustion operation and the heat storage operation in the pair of heat storage burners 20a and 20b, the air supply valve 25a in the heat storage burner 20a during the combustion operation. Although the gas supply valve 29a is closed and the combustion air and fuel gas are not supplied and the combustion is stopped, the gas discharge valve 27a in the closed state is opened. However, the present invention is not limited thereto.

For example, as shown in FIG. 5, in the heat storage burner 20a during a combustion operation, before starting the operation | movement which closes the air supply valve 25a and the gas supply valve 29a, the heat storage burner in a heat storage operation ( 20b), the operation | movement which opens the air supply valve 25b and the gas supply valve 29b which are in the closed state is started, and at this point in time when combustion can be started by ignition of fuel gas in this regenerative burner 20b. The operation of closing the air supply valve 25a and the gas supply valve 29a in the heat storage burner 20a during the combustion operation can be started.

In this case, the combustion air and fuel gas are not supplied from the air supply valve 25a and the gas supply valve 29a in the heat storage burner 20a during the combustion operation, and the combustion heat storage burner in the heat storage operation before the combustion is stopped. In 20b, the fuel gas ignites and combustion starts, and the pressure in the heat storage combustion type heat treatment furnace 10 is changed when the combustion operation and the heat storage operation of the pair of heat storage burners 20a and 20b are switched. This fluctuation can be suppressed.

Here, in the heat storage burner 20a in the combustion operation described above, the fuel is stored in the heat storage burner 20b during the heat storage operation about the timing of starting the operation of closing the air supply valve 25a and the gas supply valve 29a. In order to allow the gas to ignite properly and to start combustion, in the heat storage burner 20b during the heat storage operation, the flow rate Va of the combustion air supplied from the air supply valve 25b and the gas supply valve ( When the flow rate Vf of the fuel gas supplied from 29b) becomes the flow volume more than the limit of the turn-down which becomes a limit which can perform combustion, air is supplied by the regenerative burner 20a during a combustion operation. The operation of closing the valve 25a and the gas supply valve 29a is started.

1: material to be treated
2: walking beam
10: regenerative combustion heat treatment furnace
11: entrance
12: exit
20, 20a, 20b: regenerative burner
21, 21a, 21b: burner section
22, 22a, 22b: heat storage chamber
23a, 23b: heat storage material
24a, 24b: air supply line
25a, 25b: air supply valve
26a, 26b: exhaust gas discharge pipe
27a, 27b: gas discharge valve
28a, 28b: fuel gas supply pipe
29a, 29b: gas supply valve
30: fuel gas supply device

Claims (3)

At least one heat storage type having a burner section having a fuel gas supply pipe, a heat storage chamber accommodating the heat storage material, an air supply pipe for supplying combustion air to the heat storage chamber, and an exhaust gas discharge pipe for discharging combustion exhaust gas from the heat storage chamber. A burner is provided, and in one regenerative burner, the combustion air is led from the air supply pipe through the heat storage chamber to the burner section, and the fuel gas is injected from the fuel gas supply pipe in the burner section to perform the combustion operation, while the other In the regenerative burner of the present invention, the combustion exhaust gas is led to the above-described heat storage chamber so as to accumulate the heat of the combustion exhaust gas in the heat storage material to discharge the exhaust gas from the exhaust gas discharge pipe, and the combustion operation in the pair of regenerative burners In the combustion control method of a heat storage combustion type heat treatment furnace which alternately switches between heat storage operations, a predetermined amount of fuel gas is supplied. In the fuel gas supplying device, the fuel gas is supplied to the fuel gas supply pipe in each of the above-described regenerative burners, and at the same time the switching operation between the combustion operation and the regenerative operation in the pair of regenerative burners is performed. Before reducing the supply of fuel gas in the fuel gas supply pipe and the supply of combustion air in the air supply pipe, the regenerative burner during the heat storage operation WHEREIN: Fuel gas and combustion air are supplied from the fuel gas supply pipe and the air supply pipe for combustion. Combustion control method of a heat storage combustion heat treatment furnace, characterized in that to initiate. In the combustion control method for a heat storage combustion heat treatment furnace according to claim 1, a plurality of pairs of heat storage burners are provided in the heat storage combustion heat treatment furnace, and the combustion operation and the heat storage operation are switched in each pair of heat storage burners. A combustion control method for a heat storage combustion type heat treatment furnace, wherein the timing is different. In the combustion control method of the heat storage combustion type heat treatment furnace according to claim 1 or 2, the fuel gas in the fuel gas supply pipe is used in the heat storage burner during the combustion operation in switching the combustion operation and the heat storage operation in the pair of heat storage burners. The operation of discharging the combustion exhaust gas from the exhaust gas discharge pipe and stopping the combustion exhaust gas from the exhaust gas discharge pipe in the heat storage burner during the heat storage operation. And a supply control of the fuel gas from the fuel gas supply pipe and the supply of combustion air from the air supply pipe after the stop.

Images