KR101536814B1 - Combustion device - Google Patents

Abstract

A combustion apparatus in which a post-purge operation is performed after a combustion stop is performed, is provided, wherein a combustion operation can be stably performed by effectively preventing condensation on the surface of a nozzle of a nozzle manifold.
A combustion apparatus includes a gas burner (1) for burning fuel gas supplied from a nozzle manifold (8), a combustion fan (50), and an outside air temperature detecting section (90) for detecting an outside air temperature In executing the post purge operation for rotating the combustion fan 50 after the combustion is stopped, the post purge exhaust air flow rate is set corresponding to the outside air temperature.

Description

COMBUSTION DEVICE

The present invention relates to a combustion apparatus for executing a post purge operation for rotating a combustion fan for a predetermined time after a combustion stop.

In the combustion apparatus having the gas burner for burning the fuel gas and the combustion fan for supplying the combustion air to the gas burner, in order to discharge the combustion exhaust gas generated by the combustion operation or to cool the inside of the apparatus, The post-purge operation for continuously rotating the combustion fan for a predetermined time is executed even after the combustion is stopped. In general, the operation time of the combustion fan in the post-purge operation is set to a predetermined time from the combustion stop in consideration of the internal volume of the apparatus and the capability of the combustion fan. However, The post-purge operation may be terminated as the inside of the apparatus is insufficiently cooled. For this reason, for example, a temperature sensor for detecting the temperature of the hot water heated by the combustion of the gas burner is provided, and a post-purge operation time of the combustion fan is changed based on the hot water temperature detected by the temperature sensor A heating apparatus has been proposed (for example, Patent Document 1).

Patent Document 1: Japanese Patent Application Laid-Open No. 11-101449

However, in a combustion apparatus adopted for a hot water heater or the like, a plurality of flat gas burners are arranged adjacently in one direction to form a combustion section. In each gas burner having the above structure, fuel gas is supplied from a plurality of nozzles provided in the nozzle manifold.

On the other hand, in the combustion apparatus in which the exhaust port for discharging the combustion exhaust gas is open to the outside, the gas burner and the nozzle manifold inside the apparatus communicate with the outside through the exhaust port. As a result, if a strong wind blows outdoors, the discharge of the combustion exhaust gas from the exhaust outlet is obstructed, and the warm and moist combustion exhaust gas flows backward into the apparatus due to the wind coming from the exhaust outlet.

If the reverse flow of the combustion exhaust gas occurs when the outside air temperature is low, since each nozzle of the nozzle manifold corresponds to the gas inlet provided in each gas burner, the moisture and the like in the exhaust gas discharge condenses on the surface of the nozzle , Nozzle clogging is apt to occur. Therefore, there arises a problem that when the post-purge operation is insufficient in addition to the abnormal state of the motor or the like, and the above-described reverse flow occurs, the combustion failure occurs in the next combustion operation. Particularly, when the combustion operation is for a short time, since the combustion is stopped in a state in which the gas burner is not sufficiently heated, the nozzle surface of the nozzle manifold also does not rise in temperature, and condensation tends to occur.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and an object of the present invention is to provide a combustion apparatus in which a post-purge operation is performed after stop of combustion, effectively preventing condensation on the nozzle surface of the nozzle manifold, And to provide a combustion device capable of executing combustion.

A gas burner for burning a fuel gas supplied from a nozzle manifold, a combustion fan for supplying air for combustion to the gas burner, an outside air temperature detecting unit for detecting an outside air temperature, An exhaust passage for discharging the generated combustion exhaust gas from an exhaust port communicating with the outside and a control section for controlling the post purge operation of the combustion fan for discharging the exhaust gas after the combustion of the gas burner is stopped, Is a combustion device for setting the post-purge air discharge amount of the combustion fan based on the outside air temperature detected by the outside air temperature detection section.

Condensation at the nozzle surface of the nozzle manifold is liable to occur when the exhaust gas flows backward in a state where the outside air temperature is low and the temperature inside the apparatus is low. Therefore, it is possible to prevent the condensation by setting the post-purge exhaust air volume of the exhaust gas discharged by the post-purge operation of the combustion fan corresponding to the outside air temperature.

Preferably, in the above combustion apparatus, the control section sets the post purge discharge air flow rate further based on the combustion time of the gas burner.

If the gas burner is burned for a certain period of time, the nozzle surface of the nozzle manifold for supplying the fuel gas to the gas burner also rises in temperature due to heat transfer, so that condensation is less likely to occur even when the outside air temperature is low. Therefore, if the post-purge air flow rate is set on the basis of both the outside air temperature and the combustion time of the gas burner, the post purge operation can be efficiently performed.

In the above combustion apparatus, the setting of the post purge discharge air volume is set by the post purge operation time of the combustion fan and / or the post purge operation flow volume of the combustion fan.

Since the amount of the combustion exhaust gas discharged by the post purge operation is determined by the operation time and the operation flow rate of the combustion fan, the post purge exhaust air volume can be set by using either or both of them as setting elements.

Preferably, the control unit sets the post-purge operation time of the combustion fan when the outside air temperature detected by the outside air temperature detection unit is equal to or higher than the first determination temperature in the setting of the post- And when the burning time of the gas burner is equal to or more than the first determination time even if the outside air temperature detected by the outside air temperature detection unit is less than the first determination temperature, the post fuzzy operation time of the combustion fan is set to the initial post purge operation time And when the outside air temperature detected by the outside air temperature detection unit is less than the first determination temperature and the combustion time of the gas burner is less than the first determination time, the post-purging operation time of the combustion fan is set to be longer than the initial post- Set long.

According to the above combustion apparatus, when the outside air temperature at which condensation is difficult to occur on the nozzle surface is equal to or higher than the first judgment temperature, the post-purging operation time of the combustion fan is set as the initial post- Even if the burning time of the gas burner is long, since the surface of the nozzle of the nozzle manifold is heated and condensation hardly occurs, the post-purge operation time of the combustion fan is set as the initial post- It is possible to prevent condensation. On the other hand, when the outside air temperature is lower than the first judging temperature and the burning time of the gas burner is short, the temperature of the nozzle manifold is not increased and the condensation is more likely to occur, By setting the time longer than the initial post purge operation time, it is possible to reliably discharge the exhaust gasgas to the outside of the apparatus.

Preferably, the control unit is further operable to set the temperature of the gas burner to a predetermined value in a retracted time period retracted from the combustion stop for a predetermined time, even if the outside temperature detected by the outside temperature detection unit is less than the first determination temperature and the combustion time of the gas burner is less than the first determination time The post fuzzy operation time of the combustion fan is set as the initial post purge operation time when the total burning time of the gas burner is equal to or longer than the second determination time and the outside air temperature detected by the outside air temperature detection unit is less than the first judgment temperature When the burning time of the gas burner is less than the first judging time and the total burning time of the gas burner in the retracted time retraining after a certain period of time from the combustion stop is less than the second judging time, Is set longer than the initial post purge operation time.

Even if the combustion operation is completed within a short period of time, if the combustion operation is performed for a certain period of time or more recently, condensation is unlikely to occur because the nozzle surface of the nozzle manifold is exhausted. Therefore, according to the above combustion apparatus, since the post-purge operation time is set not only in the current combustion operation but also in the combustion operation executed so far, the condensation can be prevented more efficiently.

Preferably, in the above combustion apparatus, the control unit sets the post-purge operation time of the combustion fan to be longer as the outside air temperature decreases in setting the post-purge exhaust air amount.

According to the above combustion apparatus, since the post-purge operation time of the combustion fan is set to be longer in conjunction with the decrease in the outside air temperature, the condensation can be reliably prevented.

Preferably, the combustion apparatus includes an internal temperature detection unit for detecting the temperature in the vicinity of the nozzle, an exhaust temperature detection unit for detecting the temperature of the exhaust gas near the exhaust port, and a carbon monoxide concentration detection unit for detecting the carbon monoxide concentration in the apparatus Wherein the control unit includes at least one detection unit selected from the group consisting of a nozzle vicinity temperature detected by the internal temperature detection unit, a temperature of the combustion exhaust gas detected by the exhaust temperature detection unit, and a carbon monoxide concentration detected by the carbon monoxide concentration detection unit The post-purge operation time of the combustion fan is set based on at least one detection result selected from the group.

According to the above combustion apparatus, since the residual of the exhaust gasgas in the apparatus can be directly detected, condensation can be more reliably prevented.

As described above, according to the present invention, in the combustion apparatus in which the post purge operation is performed after the combustion is stopped, the dew condensation on the nozzle surface of the nozzle manifold can be effectively prevented, and the combustion operation can be performed stably .

1 is a schematic side view showing an example of a gas burner and a nozzle manifold according to an embodiment of the present invention.
2 is a schematic plan view showing an example of a gas burner according to an embodiment of the present invention.
3 is a schematic diagram showing an example of a combustion apparatus according to an embodiment of the present invention.
4 is a control flow chart showing an example of the control operation of the post purge operation in the combustion apparatus according to the embodiment of the present invention.
5 is a control flowchart showing another example of the control operation of the post purge operation in the combustion apparatus according to the embodiment of the present invention.

Hereinafter, the combustion apparatus of the present embodiment will be described in detail with reference to the drawings.

Fig. 1 is a schematic side view showing an example of a gas burner and a nozzle manifold according to an embodiment of the present invention, Fig. 2 is a schematic plan view showing an example of a gas burner according to an embodiment of the present invention, Fig. Fig. 2 is a schematic diagram showing an example of a combustion apparatus according to an embodiment;

As shown in Figs. 1 and 2, the combustion apparatus of the present embodiment includes a plurality of (sixteen in this embodiment) gas burners 1 as a combustion section, And a gas supply means (2) for supplying the gas.

Each of the gas burners 1 is of the same shape formed flat and is a so-called dark burner in which a pair of upper and lower gas inlet openings 3 and 4 are opened as shown in Fig. A dense gas flow path 5 through which a gas rich mixer flows is formed continuously downstream of the gas introducing port 3 on the upper side and a dilute gas flow path 6 through which an air rich mixer flows is formed downstream of the lower gas introducing port 4, Are continuously formed. As shown in Fig. 2, the gas burners 1 are arranged adjacent to each other in one direction, and constitute one combustion section 7. [

1, the gas supply means 2 includes a nozzle manifold 8 and a solenoid valve 9 for supplying fuel gas to each nozzle chamber 15 partitioned by partitions (not shown) . The nozzle manifold 8 has two upper and lower nozzles 12 and 13 and a plurality of nozzles 12 and 13 are provided corresponding to the gas burner 1 along the arrangement direction of the gas burners 1 have. The nozzle 12 at the upper end is a thick nozzle facing the gas inlet 3 on the upper side of the gas burner 1 and leading to the gas channel 5 of the gas burner 1. The diameter of the jet hole is relatively small. The lower nozzle 13 is a dilute nozzle opposed to the lower gas inlet 4 that leads to the dilute gas passage 6 of each gas burner 1 and the diameter of the outlet is larger than the diameter of the outlet of the upper nozzle 12 As shown in Fig. The fuel gas ejected from the nozzles 12 and 13 opposed to the respective gas introduction ports 3 and 4 is introduced into the upper and lower gas burners 1 and the primary air for combustion is also sucked do.

A gas flow hole 21 is formed on the lower side of the nozzle manifold 8 and an upstream side of each gas flow hole 21 is communicated with the gas flow passage 21 through the solenoid valve mounting portion 27 of the nozzle manifold 8 And a solenoid valve 9 for opening and closing the hole 21 is mounted. Each of the solenoid-operated valve mounting portions 27 is hollow and communicates with the gas supply pipe 30 shown in Fig. 1 although not shown in detail.

3 is a schematic diagram showing an example of the combustion apparatus of the present embodiment. As shown in the figure, a casing 10 is accommodated in a casing 100. A heat exchanger 40, the gas burner 1 for heating the heat exchanger 40, and a nozzle manifold 8 are accommodated in the cylinder 10.

A combustion fan (50) for supplying combustion air into the cylinder (10) is provided at a part of the bottom wall of the cylinder (10) and is rotationally driven by a motor (M). An exhaust port 60 for discharging the combustion exhaust gas to the outside of the casing 100 is formed at an upper end of the cylinder 10 and an exhaust port 61 is formed inside the exhaust port 60 and the inside of the cylinder 10 It is communicating. The gas supply pipe 30 for supplying the fuel gas to the nozzle manifold 8 passes through the bottom wall of the cylinder 10 on the upstream side and the gas supply pipe 30 is supplied with a signal from the control unit C A gas proportional valve 71 and a source gas solenoid valve 72 for controlling the supply of the fuel gas are provided.

The heat exchanger 40 is installed on the upper side of the gas burner 1 in the cylinder 10 and the water supply pipe 81 and the hot water pipe 82 are connected to the heat exchanger 40. Although not shown, a water flow sensor is provided in the water supply pipe 81, and a hot water temperature thermistor is provided in the hot water discharge pipe 82. Thus, when the water supply terminal of the faucet or the like is opened and the water flow is detected in the water flow sensor installed in the water supply pipe 81, the combustion fan 50 is rotated, and the raw gas valve 72, The proportional valve 71 and the solenoid valve 9 are opened to ignite the gas burner 1 to start the combustion operation in which the fuel gas is burned and the heat exchanger 40 is heated by the combustion heat. The rotation number of the combustion fan 50 and the supply amount of the fuel gas are adjusted so that the hot water temperature of the hot water detected by the hot water temperature thermistor is controlled to control the combustion of the gas burner 1.

An outside temperature thermistor (outside air temperature detecting portion) 90 for detecting the outside air temperature is provided on the side wall of the casing 100, and the detected outside air temperature signal is outputted to the control portion C. [ The control unit C includes a CPU, a ROM, and a RAM. The control unit C includes a combustion operation control unit for controlling the combustion operation and a post-purge operation control unit for executing the post-purge operation after the combustion operation. A gas proportional valve 71, a source gas solenoid valve 72, a motor M, an outside temperature thermistor 90, a water flow sensor, a hot water temperature thermistor, and the like.

Since the amount of the combustion exhaust gas discharged in the post purge operation is determined by the operation time of the combustion fan 50 and the operation flow rate (operation time x operation flow rate), the post purge exhaust air flow rate can be set by using these as the setting elements . In this embodiment, since the post-purge exhaust air amount is set in correspondence with the outside temperature or the burning time of the gas burner 1, the number of revolutions of the combustion fan 50 during the post purge operation is fixed to the minimum number of revolutions, The purge operation time is changed. Therefore, the post-purge operation control section includes a storage section for storing a data table for setting a post-purge operation time corresponding to the initial post-purge operation time or the temperature of outside air, a storage section for storing a data table for setting a post- A combustion time storage unit for accumulating and storing the total combustion time of the gas burner 1 within a retroactive time, a combustion time of the gas burner 1 within a retroactive time retraced from the combustion stop, A post-purge operation time determination unit for determining a post-purge operation time on the basis of the total combustion time of the post-purge operation time, and a timer unit. The number of revolutions of the combustion fan 50 during the post purge operation and the initial post purge operation time are determined by the internal volume of the apparatus and the ability of the combustion fan 50 and the length of the exhaust path 61 to the exhaust port 60 And is appropriately determined corresponding to the configuration of each combustion apparatus.

Next, the control operation in the case of executing the post purge operation after the combustion operation in the combustion apparatus of the present embodiment will be described with reference to the control flow in Fig. In the combustion apparatus of the present embodiment, the post-purge operation is programmed to be executed each time after the combustion operation.

The gas proportional valve 71 and the solenoid valve 9 are closed by the signal from the control unit C so that the supply of the fuel gas is stopped and the combustion of the gas burner 1 is stopped The controller C first reduces the number of revolutions of the combustion fan 50 to the minimum number of revolutions and starts the timer (ST1). When the outside air temperature detected by the outside temperature thermistor 90 reaches the first judgment temperature (For example, 15 占 폚) or not (ST2). When the outside air temperature is equal to or higher than the first judgment temperature (Yes in ST2), the control unit C rotates the combustion fan 50 until the initial post purge operation time (for example, 15 seconds) (ST8), and then the combustion fan 50 is stopped (ST9). In other words, when the outside air temperature is high, the surface temperature of the nozzles 12, 13 is high and condensation is hard to occur. Therefore, by performing the post-purge operation for a short time, condensation can be effectively prevented.

If the outside air temperature is lower than the first determination temperature (NO in ST2), the control unit C determines whether or not the burning time of the gas burner 1 is equal to or longer than the first determination time (for example, two minutes) ST3). That is, if the gas burner 1 is burned for a predetermined time or more, the surfaces of the nozzles 12 and 13 of the nozzle manifold 8 for supplying the fuel gas to the gas burner 1 are also heated by the heat Therefore, even if the outside air temperature is low, condensation is unlikely to occur. Therefore, if the post-purge operation time is set based on both the outside temperature and the combustion time of the gas burner 1, the post-purge operation can be efficiently performed. Therefore, even if the outside air temperature is lower than the first determination temperature, when the combustion time of the gas burner 1 is equal to or longer than the first determination time (No in ST2, Yes in ST3), the combustion fan 50 is set to the initial post- , And executes a post-purge operation to rotate (ST8).

On the other hand, when the outside air temperature is lower than the first determination temperature and the combustion time of the gas burner 1 is less than the first determination time (NO in ST2, NO in ST3) It is determined whether or not the total burning time of the gas burner 1 within the retracted retrace time (for example, 10 minutes) is equal to or longer than the second determination time (for example, 5 minutes) (ST4). That is, even if the current combustion operation is completed within a short period of time, if the combustion operation is performed for a certain period of time or more recently, the surfaces of the nozzles 12 and 13 of the nozzle manifold 8 are warmed, Condensation is less likely to occur even if it is low. Therefore, it is possible to prevent the condensation more efficiently by setting the post-purge operation time in consideration of not only this combustion operation but also the combustion operation executed up to that time. Therefore, even if the outside temperature is lower than the first judging temperature and the burning time of the gas burner 1 is less than the first judging time, if the total burning time of the recent gas burner 1 is not less than the second judging time (ST2 (No in ST3, Yes in ST4), the post-purging operation of rotating the combustion fan 50 for the initial post-purge operation time is executed (ST8).

On the other hand, when the outside temperature is lower than the first judging temperature and the burning time of the gas burner 1 is less than the first judging time and is less than the total burning time of the latest gas burner 1 or the second judging time (ST2 No in ST3, and No in ST4), there is a high possibility that condensation will occur on the surfaces of the nozzles 12 and 13 of the nozzle manifold 8. Because of this, the control unit C determines the post-purge operation time in accordance with the outside air temperature, so first, it is determined whether or not the outside air temperature is equal to or lower than the first determination temperature and the second determination temperature (for example, 10 DEG C) (ST5).

If the outside temperature is lower than the first determination temperature and the second determination temperature is higher than the second determination temperature (Yes in ST5), the controller C determines that the first post purge operation time (for example, 60 seconds) , The combustion fan 50 is rotated (ST6). If the outside air temperature is lower than the second determination temperature (No in ST5), the controller C determines that the second post-purge operation time (for example, 240 seconds) longer than the first post- , The combustion fan 50 is rotated (ST7). In this way, when the outside air temperature is low and the combustion time and the total combustion time of the gas burner 1 are short and condensation is likely to occur, the post-purge operation time of the combustion fan 50 is set to be longer It is possible to reliably prevent condensation.

(Other Embodiments)

(1) In the above embodiment, the post-purge operation time of the combustion fan 50 is set on the basis of the ambient temperature and the combustion time of the gas burner 1. Instead of or in addition to the combustion time of the gas burner 1 The post-purge operation time may be set by directly detecting the residual of the exhaust gas in the apparatus. That is, at least one detecting unit selected from the group consisting of an internal temperature thermistor (internal temperature detecting unit) for detecting the temperature in the vicinity of the nozzle and a CO sensor (carbon monoxide concentration detecting unit) for detecting the temperature of the combustion exhaust gas in the vicinity of the exhaust port, Based on at least one detection result selected from the group consisting of the temperature near the nozzle detected by the thermistor, the temperature of the combustion exhaust gas detected by the exhaust temperature thermistor, and the carbon monoxide concentration detected by the CO sensor, The time may be set. According to the above combustion apparatus, although separate detecting means are required, it is possible to prevent condensation when the back stream of the combustion exhaust gas is more reliably generated.

5 is a control operation for setting the post-purge operation time based on the temperature in the vicinity of the nozzle instead of the combustion time of the gas burner 1, and performing the post-purge operation after the combustion operation. Steps ST21 to ST22 and ST27 to ST28 for executing the initial post-purge operation time and the post-purge operation when the outside air temperature is equal to or higher than the first determination temperature after the combustion stop are the same as the steps ST1 to ST2 , And ST8 to ST9), only the other portions will be described.

If the outside temperature is lower than the first judgment temperature (No in ST22), the control section C judges whether or not the near-nozzle temperature detected by the internal temperature thermistor is equal to or higher than the first nozzle judgment temperature (for example, 15 deg. C) ST23). If the ambient temperature in the vicinity of the nozzle is equal to or higher than the first nozzle determination temperature (NO in ST22 and YES in ST23), the control unit C sets the combustion fan 50 to the initial post- (ST27). That is, when the gas nozzle 1 is burned for a predetermined time, if the temperature near the nozzle is high, condensation does not easily occur even if the outside air temperature is low, so that the combustion fan 50 can be operated for a short period of initial post- The post-purge operation can be performed efficiently.

On the other hand, when the outside air temperature is lower than the first judging temperature and the near-nozzle temperature is lower than the first nozzle judging temperature (No in ST22, No in ST23), the surface of the nozzles 12 and 13 of the nozzle manifold 8 Condensation is likely to occur. For this reason, the control unit C determines whether or not the nozzle vicinity temperature is lower than the first nozzle determination temperature and is equal to or higher than the second nozzle determination temperature (for example, 10 DEG C) (ST24).

If the outside air temperature is lower than the first nozzle determination temperature and the second nozzle determination temperature is higher than the second nozzle determination temperature (Yes in ST24), the controller C sets the first post purge operation time (e.g., 60 seconds) longer than the initial post purge operation time The combustion fan 50 is rotated until the time from the stop of the combustion is elapsed (ST25). If the outside air temperature is lower than the second nozzle determination temperature (No in ST24), the controller C determines that the second post-purge operation time (for example, 240 seconds) longer than the first post- , The combustion fan 50 is rotated (ST26). Thus, condensation can be reliably prevented.

5, the post-purge operation time is set on the basis of the ambient temperature and the temperature in the vicinity of the nozzle, but the post-purge operation time may be set in the same manner on the basis of the temperature of the exhaust gas and the carbon monoxide concentration. It is also possible to combine the burning time of the gas burner 1 described above and the detection results thereof.

(2) In the above embodiment, the post purge operation flow rate of the combustion fan 50 is fixed and the post purge operation time is changed in setting the post purge discharge air flow rate. However, the post purge operation time is fixed, The post-purge operation flow rate of the combustion fan 50 may be changed corresponding to the combustion time of the gas burner 1 and the post-purge operation time and the post-purge operation flow rate of the combustion fan 50 may be changed. However, in order to increase the post purge air flow rate, it is necessary to increase the post purge operation air flow rate by increasing the number of revolutions of the combustion fan 50 to increase the post purge air flow rate , It is possible to efficiently discharge the combustion exhaust gas and to prevent condensation. In addition, by operating the combustion fan 50 at a low rotational speed, it is possible to reduce noise during the post purge operation.

1 - Gas burner 8 - Nozzle manifold
12,13 - Nozzle 50 - Combustion fan
90 - Outside temperature thermistor (outside temperature detection part) C - Control part

Claims (7)

A gas burner for burning the fuel gas supplied from the nozzle manifold,
A combustion fan for supplying combustion air to the gas burner,
An outside air temperature detection unit for detecting the outside air temperature,
An exhaust passage for exhausting the combustion exhaust gas generated by the combustion of the gas burner from an exhaust port communicating with the outside,
And a control unit for controlling a post-purging operation of the combustion fan to discharge the combustion exhaust gas after the gas burner stops combustion,
Wherein the control unit sets the post-purging air discharge amount of the combustion fan based on the outside air temperature detected by the outside air temperature detection unit and the combustion time of the gas burner, wherein the outside air temperature detected by the outside air temperature detection unit is equal to or higher than the first determination temperature The post-purge operation time of the combustion fan at the time of the initial post-purge operation is set as the initial post-
The post-purge operation time of the combustion fan is set as the initial post-purge operation time when the burning time of the gas burner is not less than the first determination time even if the outside air temperature detected by the outside temperature detection unit is less than the first determination temperature,
The post-purge operation time of the combustion fan is set to be longer than the initial post-purge operation time when the outside air temperature detected by the outside temperature detection unit is less than the first determination temperature and the combustion time of the gas burner is less than the first determination time And the combustion chamber. delete delete delete The method according to claim 1,
Wherein the control unit determines that the gas burner has a total of the gas burners within a retroactive time retreated from the combustion stop for a predetermined time even if the outside air temperature detected by the outside air temperature detection unit is less than the first determination temperature and the combustion time of the gas burner is less than the first determination time The post-purge operation time of the combustion fan is set as the initial post-purge operation time when the combustion time is equal to or longer than the second determination time,
The total burning time of the gas burner within a retrogressive time period after the burning time of the gas burner is less than the first determination time and a certain time back from the combustion stop is less than the first judgment temperature, And the post-purge operation time of the combustion fan is set to be longer than the initial post-purge operation time when the first post-purge operation time is less than the second determination time.
The method according to claim 1 or 5,
Wherein the controller sets the post-purging operation time of the combustion fan to be longer as the outside air temperature is lowered in setting the post-purge exhaust air amount.
The method according to claim 1 or 5,
At least one detecting unit selected from the group consisting of an internal temperature detecting unit for detecting the temperature in the vicinity of the nozzle, an exhaust temperature detecting unit for detecting the temperature of the exhaust gasgas near the exhaust port, and a carbon monoxide concentration detecting unit for detecting the carbon monoxide concentration in the apparatus And,
Wherein the control unit is configured to control the exhaust gas temperature based on at least one detection result selected from the group consisting of a temperature near the nozzle detected by the internal temperature detection unit, a temperature of the exhaust gas detected by the exhaust temperature detection unit, and a carbon monoxide concentration detected by the carbon monoxide concentration detection unit And the post-purge operation time of the combustion fan is set.

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