JP2857321B2 - Combustion equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a combustion device such as a water heater.

[0002]

2. Description of the Related Art In a water heater, for example, a required combustion amount of a burner required to match a tapping temperature detected via a tapping temperature sensor with a set temperature set by a user is obtained from time to time. Of the proportional valve provided in the fuel supply path to the burner in accordance with the required amount of combustion or the actual number of rotations of the combustion fan, while controlling the number of revolutions to Is generally known.

[0003] This type of combustion apparatus is designed to reduce the number of revolutions of the combustion fan on the assumption that the number of revolutions of the combustion fan and the amount of air blown from the combustion fan to the burner (air supply) always correspond to each other in a fixed relationship. In this case, the load of the combustion fan is changed due to the clogging of the intake port and the exhaust port, or the influence of the outside wind. Are the same, the actual blown air amount (air supply amount) from the combustion fan to the burner changes. Therefore, even if the number of rotations of the combustion fan is controlled to the set number of rotations determined according to the required combustion amount, the actual amount of air blown to the burner is not always maintained at an appropriate amount.

[0004] Therefore, in this type of combustion device,
The air volume sensor (wind speed sensor) placed in the air passage from the combustion fan to the burner detects the actual air volume to the burner from time to time, and also sets the air volume corresponding to the required combustion amount of the burner from time to time and sets it. There is also known one that controls the number of revolutions of a combustion fan so that the actual air volume matches the air volume (for example, Japanese Utility Model Laid-Open No. 1-129561,
See JP-A-60-143251.

[0005] As an air flow sensor used in this type of combustion device, for example, a hot-wire air flow sensor (hot-wire wind speed sensor) as shown in FIG. 3 is known.

This hot wire type air flow sensor has a pair of fixed resistance values of reference resistors a and b, an air flow detecting heating element c made of, for example, a platinum wire, and a temperature compensating resistance made of a platinum wire like the heating element c. and a bridge circuit e composed of
When detecting the amount of air blown by the combustion fan, a heating element c and a temperature compensating resistance d are used.
Are disposed in the ventilation passage. The air flow sensor supplies power to the bridge circuit e through a feedback amplifier h configured using an operational amplifier f and a transistor g,
An electric current is supplied to the heating element c so that the heat radiation amount of the heating element c is always constant. In this state, a signal having a level corresponding to the wind speed of the air passing through the heating element c is output to the output point P of the bridge circuit e.
(Feeding section to the bridge circuit e) is output via the amplifier i.

In such a hot wire type air flow sensor, when the wind speed at the position of the heating element c increases, the heating element c is cooled and the resistance value decreases. The supply current to the circuit e is increased by the feedback amplifier h. For this reason, the output level of the amplifier i increases, and the output level corresponds to the wind speed. Since the air volume at the position of the heating element c is obtained by multiplying the wind speed by the cross-sectional area of the air passage, the air volume can be detected from the output level of the amplifier i. In addition, even if the wind speed is constant, the heat radiation amount of the heating element c changes following the change of the wind temperature.
In such a case, the bridge circuit e is provided with the temperature compensation resistor d so that the output level of the amplifier i, that is, the current supplied to the bridge circuit e does not change with the wind temperature.

In the conventional combustion apparatus provided with such an air flow sensor, the amount of air blown to the burner can be controlled to a set air flow corresponding to the required combustion amount. Since it is not considered that the oxygen concentration of the combustion air changes depending on the temperature (wind temperature) of the supplied combustion air, the following inconveniences have been encountered.

That is, in a combustion device such as a water heater, for example, the air temperature differs between the initial stage of burner combustion and when continuous combustion is performed, and the former has a lower temperature than the latter. When the air temperature increases, the amount of oxygen (oxygen concentration) per unit volume decreases because the combustion air expands.

However, in the conventional combustion apparatus, the amount of air blown to the burner is simply controlled to a set amount of air corresponding to the required amount of combustion, and the set amount of air is determined irrespective of the air temperature. When the temperature is low and when it is high,
Even if the set air volume is the same, the actual amount of oxygen supplied to the burner together with the combustion air will be different.
For this reason, when the air temperature is low and when the air temperature is high, the combustion state of the burner is different even if the actual amount of air blown to the burner is the same.

On the other hand, as described above, in a combustion apparatus which does not include an air volume sensor and controls the number of revolutions of a combustion fan to a set number of revolutions corresponding to a required amount of combustion, for example, Japanese Patent Laid-Open No.
As disclosed by the present applicant in Japanese Patent No. 67918, the temperature of combustion air is detected by a burner by a temperature sensor, and the set rotation speed of a combustion fan is corrected in accordance with the detected temperature to thereby provide oxygen to the burner. There has been known one in which a supply amount is secured to an appropriate amount.

However, in such a combustion apparatus, when the load of the combustion fan changes as described above,
The amount of air blown to the burner, that is, the amount of supplied oxygen, does not always correspond to the set number of revolutions, and therefore, it has been difficult to reliably control the combustion amount of the burner to a desired combustion amount. . Further, in such a combustion device, a temperature sensor for detecting the wind temperature must be separately provided, which is disadvantageous in terms of cost.

[0013]

SUMMARY OF THE INVENTION The present invention is directed to an improvement in such a combustion apparatus, and more specifically, an oxygen amount corresponding to a desired combustion amount of a burner is supplied from a combustion fan by a reliable and simple structure. An object of the present invention is to provide a combustion device that can supply a burner.

[0014]

In order to achieve the above object, the present invention provides an air flow sensor for detecting an air flow from a combustion fan to a burner, and an air flow sensor for detecting the air flow of the combustion fan detected by the air flow sensor. And a fan control means for controlling the number of revolutions of the combustion fan so as to match the set air volume for obtaining the required combustion amount of the combustion fan. The air volume sensor is disposed in an air passage from the combustion fan to a burner. A heating wire type airflow sensor that outputs a signal corresponding to the airflow of the combustion fan from a bridge circuit including a heating element for detecting the airflow and a resistance for temperature compensation, and the temperature compensation resistor is operated when the airflow sensor operates. Temperature detecting means for detecting an air blowing temperature based on a change in resistance value, and a correction means for correcting the set air volume in accordance with the air blowing temperature detected by the temperature detecting means. With the door, said correcting means, and corrects the set air volume so that the oxygen amount corresponding to the required combustion amount of the burners is contained in the air that is blown into the burner from the combustion fan.

[0015] Further, the set air volume is an air volume for obtaining a required combustion amount of the burner at a predetermined air temperature, and the correction means sets the absolute temperature (T _{0) of the} predetermined air temperature. ) And the absolute value (T) of the blown air temperature detected by the temperature detecting means (T).
/ T ₀ ) is multiplied by the set airflow to correct the set airflow.

[0016]

According to the present invention, basically, when the combustion fan is operated, the amount of air blown from the combustion fan to the burner is detected by the air flow sensor, and the detected air flow is used to determine the required combustion of the burner. The number of revolutions of the combustion fan is controlled by the fan control means so as to match a set air volume for obtaining the air volume. At this time, since the resistance value of the temperature compensating resistor of the air flow sensor changes according to the blast temperature of the combustion fan, the temperature detecting means detects the blast temperature by changing the resistance value of the temperature compensating resistor. Then, the correction means corrects the set airflow according to the detected airflow temperature. In this case, the correction means considers a change in the oxygen concentration due to the temperature of the combustion air supplied to the burner, so that the oxygen amount corresponding to the required combustion amount of the burner is included in the air blown by the combustion fan. The set air volume is corrected. Thereby, the amount of air blown from the combustion fan to the burner is controlled such that the amount of oxygen contained therein becomes an amount corresponding to the required amount of combustion. According to the present invention, since the temperature compensation resistor provided in the air volume sensor is used as a sensor for detecting the air temperature, it is not necessary to separately provide a temperature sensor, and the configuration is simple.

In this case, the atmospheric pressure and the oxygen content in the air are
It is considered almost constant, so Boyle-Charles law
According to the unit volume of air supplied to the burner
Oxygen content, that is, the oxygen concentration is the absolute temperature of the blast temperature
Inversely proportional. Therefore, the set air volume is determined in advance.
The required amount of combustion of the burner at the prescribed air temperature
If it is set as the blowing amount for obtaining the
Absolute temperature (T₀) And detected by the temperature detecting means.
The value of the ratio of the blast temperature to the absolute temperature (T) (T / T ₀) Before
By multiplying the set airflow and correcting the set airflow,
At any blast temperature, the oxygen supplied to the burner
The amount can be set to an amount corresponding to the required combustion amount.
You.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One example of the present invention will be described with reference to FIGS. FIG. 1 is a system configuration diagram of the combustion device of the present embodiment, and FIG. 2 is a block configuration diagram of a main part of the combustion device of FIG.

Referring to FIG. 1, the combustion apparatus of the present embodiment is a water heater, 1 is a water heater body having a heat exchanger 2 and a burner 3 for heating the heat exchanger, and 4 is a heat exchanger. 5 is a flow sensor for detecting the flow rate of water flowing through the water pipe 4 upstream of the heat exchanger 2, 6 is the tapping temperature of water flowing through the water pipe 4 downstream of the heat exchanger 2 , A gas supply pipe for supplying gas to the burner 3,
Is a gas proportional valve interposed in the gas supply pipe 7, and 9 is a burner 3
, A fan motor for driving the combustion fan 9, a rotation speed sensor 11 including a Hall element for detecting the rotation speed of the combustion fan 9, and a combustion fan 9. An air flow sensor for detecting the amount of air blown from the air to the burner 3, an operation unit 13 for the user to set a tapping temperature and the like, and 14 a set temperature of the hot water set by the operation unit 13 and the sensors 5, 6 , 11 and 12, a controller for controlling the fan motor 10, the gas proportional valve 8 and the like in accordance with detection signals, etc., 15 an igniter for igniting the burner 3, and 16 a combustion state such as the presence or absence of misfire of the burner 3. This is a frame rod to be detected.

The upstream side of the water pipe 4 is connected to a water pipe (not shown), and the downstream side is connected to a hot water tap (not shown) in a kitchen or a bathroom.

Further, the air volume sensor 12 is the same as that shown in FIG.
This is a hot wire type air flow sensor having the same configuration as that of the above, wherein a heating element c for detecting the air flow and a temperature compensating resistor d composed of a platinum wire of the bridge circuit e are arranged in a ventilation passage 17 from the combustion fan 9 to the burner 3. I have. And the air volume sensor 12
A signal having a level corresponding to the amount of air blown from the combustion fan 9 to the burner 3 is output from the amplifier circuit i to the controller 14. Further, in this embodiment, the voltage generated at the temperature compensation resistor d when the air flow sensor 12 is operated is output to the controller 14 via an amplifier (not shown).

Referring to FIG. 2, the controller 14 is constituted by an electronic circuit including a microcomputer and the like. A required combustion amount calculating unit 18 for calculating a required combustion amount of the burner 3 required to make the discharged water temperature coincide with the set temperature from the hot water temperature detected by the sensor 6 and the flow rate and the like detected by the flow sensor 5.
An air volume setting unit 19 for setting an air volume (a supply amount of combustion air) from the combustion fan 9 to the burner 3 corresponding to the required combustion volume obtained by the arithmetic unit 18;
And a fan for driving the fan motor in accordance with the designated rotation speed determined by the rotation speed determination unit. A drive unit 21 and a valve drive unit 22 that controls the degree of opening of the gas proportional valve 8 according to the rotation speed of the combustion fan 9 detected by the rotation speed sensor 11 are provided.

In this case, the required combustion amount calculating unit 18 calculates the tapping temperature based on detection data such as tapping temperature and flow rate obtained from the temperature sensor 6 and the flow rate sensor 5 from time to time.
The amount of combustion of the burner 3 required to make the temperature equal to the set temperature given from the above is calculated every moment as the required amount of combustion.

The air volume setting section 19 basically determines the air temperature from the combustion fan 9 to the burner 3 at a predetermined temperature (20 ° C. in the present embodiment) at the predetermined temperature. The optimum amount of air blown to the burner 3 for obtaining the required combustion amount is set every moment.

The rotation speed determining unit 20 basically operates as follows.
In a state where there is no clogged exhaust or intake air in the water heater, no clogged air, or the like, and the load on the combustion fan 9 is normal, the commanded rotation speed of the combustion fan 9 necessary to obtain the set airflow is determined every moment. Then, the rotation speed determination unit 20 and the fan drive unit 21 monitor the actual rotation speed of the combustion fan 9 via the rotation speed sensor 11, and the actual rotation speed corresponds to the above-described normal state. The feedback control of the fan motor 10 is performed so as to match the designated rotation speed determined in the above.

Further, the valve drive unit 22 basically operates the rotation speed of the combustion fan 9 detected by the rotation speed sensor 11 (this corresponds to the set airflow in the above-described normal state). The gas proportional valve 8 is controlled with an opening proportionate to the amount of gas supplied from the combustion fan 9 to the burner 3.

In addition to these components, the controller 14 further controls the rotation speed in accordance with the actual air flow from the combustion fan 9 to the burner 3 and the set air flow, which are determined by the output level of the air flow sensor 12. The rotation speed correction unit 23 that corrects the instruction rotation speed determined by the determination unit 20, and the actual air flow from the combustion fan 9 to the burner 3, which is grasped by the output level of the air flow sensor 12, and the set air flow, A proportional valve correction unit 24 for correcting the control amount of the opening degree of the gas proportional valve 8 by the valve drive unit 22;
And a temperature detecting unit (temperature detecting means) 25 for detecting the temperature of the blowing air from the combustion fan 9 to the burner 3 from time to time. An air volume correction unit (correction unit) 26 for correcting the set air volume set by the air volume setting unit 19 according to the air blowing temperature is provided. Here, corresponding to the configuration of the present invention, the rotation speed correction unit 23 includes the fan control unit 27 together with the rotation speed determination unit 20 and the fan driving unit 21.
It constitutes. Details of the rotation speed correction unit 23 and the like will be described later.

When the flow of water to the water pipe 4 is started, the controller 14 detects this through the flow rate sensor 5, and in response to the detection, the rotation speed determining unit 20 and the fan driving unit 21 operate. While driving the combustion fan 9, an electromagnetic valve (not shown) of the gas supply pipe 7 is opened to start supplying gas to the burner 3, and further, the burner 3 is ignited via the igniter 15. Thus, the combustion operation of the burner 3 and the hot water supply are started.

When the controller 14 detects misfire or the like of the burner 3 via the frame rod 16, the controller 14 shuts off the gas supply to the burner 3 and stops the burner 3 from burning.

Next, the operation of the water heater of this embodiment will be described.

When the combustion operation of the burner 3 is started by the flow of water, the controller 14 determines the required combustion amount of the burner 3 required to make the tap water temperature equal to the set temperature by the temperature sensor 6 by the required combustion amount calculating section 18. The flow rate to the burner 3 for obtaining the required required combustion amount is set in accordance with a data table or the like predetermined by the air flow rate setting unit 19. .

Here, as described above, the air volume setting unit 19
Basically, when the air temperature from the combustion fan 9 to the burner 3 is a predetermined temperature (20 ° C.), the air volume for obtaining the required combustion amount is set. When the temperature changes, the amount of oxygen contained per unit volume of the combustion air, that is, the oxygen concentration changes due to expansion and contraction of the combustion air to be blown. For example, when the blowing temperature is higher than a predetermined temperature, the oxygen concentration of the combustion air becomes lower than when the blowing temperature is the predetermined temperature (20 ° C.). Then, in order to reliably obtain the required combustion amount of the burner, it is necessary to make the oxygen supply amount to the burner 3 correspond to the required combustion amount irrespective of the blast temperature to the burner 3.

Therefore, the controller 14 detects the change in the resistance value of the temperature compensating resistor d according to the blast temperature from the voltage generated at the temperature compensating resistor d of the air volume sensor 12 by the temperature detecting section 25, and thereby the combustion is performed. The temperature of air sent from the fan 9 to the burner 3 is detected every moment. Then, the controller 14 corrects the set airflow according to the following equation (1) according to the detected airflow temperature by the airflow correction unit 26.

[0034]

(Equation 1) Here, t is the detected air temperature (° C), and S20 is 20 °.
The set air volume at the blast temperature of C, St is the set air volume at the blast temperature of t ° C. That is, the air volume correction unit 26 sets the set air volume S20 at the blast temperature of 20 ° C. to the absolute temperature of 20 ° C.
Is multiplied by the value of the ratio of the detected blast temperature t ° C to the absolute temperature, thereby correcting the set airflow to obtain the set airflow St at the blast temperature of t ° C.

In this case, since the oxygen content in the air is considered to be substantially constant at the atmospheric pressure, the amount of oxygen per unit volume in the air blown to the burner is determined by the Boyle-Charles law. It is inversely proportional to absolute temperature. Therefore, if the air is blown to the burner 3 with the set airflow St obtained by the correction of the equation (1), the amount of oxygen contained in the blown air will be the one corresponding to the required combustion amount regardless of the airflow temperature. Becomes

Next, the controller 14 sets the actual amount of air blown from the combustion fan 9 to the burner 3 by the rotation speed determining unit 20 and the fan driving unit 21 in accordance with the required amount of combustion as described above. The number of revolutions of the combustion fan 9 is controlled so as to match the air volume St. In this case, the controller 14 basically determines the number of revolutions of the combustion fan 9 for obtaining the set air volume St according to a predetermined data table or the like when the load on the combustion fan 9 is normal. The determination is made by the unit 20, and the fan drive unit 21 performs feedback control on the fan motor 10 so that the actual rotation speed of the combustion fan 9 (which is detected by the rotation speed sensor 11) matches the designated rotation speed. . Thus, when the load on the combustion fan 9 is normal, the rotation speed of the combustion fan 9 is basically controlled such that the actual air flow from the combustion fan 9 to the burner 3 matches the set air flow St. Is done.

However, if there is a clogged exhaust gas, a clogged intake air, or the influence of outside air, the load of the combustion fan 9 fluctuates. In such a case, the rotation speed of the combustion fan 9 is controlled as described above. Only from the combustion fan 9 to the burner 3
In some cases, the actual amount of air blown to the air does not match the set air amount St. Therefore, the controller 14 controls the air flow sensor 1
The actual amount of air blown to the burner 3 detected by 2 and the set air amount St are compared by the rotational speed corrector 23, and the designated rotational speed determined by the rotational speed determiner 20 is corrected so as to eliminate the deviation between the two. Let me know. Specifically, if the actual air volume is smaller than the set air volume, the designated rotation speed is increased,
In the opposite case, the designated rotation speed is reduced. This allows
Regardless of the load fluctuation of the combustion fan 9, the rotation speed of the combustion fan 9 is controlled such that the actual air flow from the combustion fan 9 to the burner 3 matches the set air flow St.

On the other hand, the valve driving section 22 of the controller 14
In parallel with the control of the rotation speed of the combustion fan 9 as described above, basically, the gas proportional valve 8 is controlled in accordance with the actual rotation speed of the combustion fan 9 detected by the rotation speed sensor 11. Control the opening degree. In this case, when the load on the combustion fan 9 is normal, the rotation speed of the combustion fan 9 and the amount of air blow correspond to each other. By controlling the opening of the proportional valve 8, the amount of gas supplied to the burner 3 corresponds to the amount of air blown to the burner 3, and the amount of air blow corresponds to the required amount of combustion. Therefore, the gas supply amount corresponds to the required combustion amount. The burner 3 actually burns at the required combustion amount.

However, when the load of the combustion fan 9 fluctuates, as described above, the rotation speed of the combustion fan 9 is controlled so that the actual air volume and the set air volume coincide with each other. Even if the amount of air blown to the air is the same, the rotation speed of the combustion fan 9 varies. Therefore, as described above, simply controlling the opening of the gas proportional valve 8 according to the rotation speed of the combustion fan 9 follows the rotation speed of the combustion fan 9 even if the amount of air blown to the burner 3 is the same. As a result, the opening degree of the gas proportional valve 8 fluctuates, and the gas supply amount to the burner 3 fluctuates.

Therefore, in parallel with the correction and control of the rotation speed of the combustion fan 9, the controller 14
Accordingly, the opening of the gas proportional valve 8 is corrected via the valve drive unit 22. Specifically, when the actual air volume obtained from the air volume sensor 12 is smaller than the set air volume St, the proportional valve correction unit 24 increases the rotation speed of the combustion fan 9 as described above. The opening of the proportional valve 8 is made smaller than the opening corresponding to the rotation speed of the combustion fan 9. When the actual air flow obtained from the air flow sensor 12 is larger than the set air flow St, the rotation speed of the combustion fan 9 is reduced. Increase the opening from the corresponding opening. As a result, the amount of gas supplied to the burner 3 corresponds to the value determined by the required combustion amount calculation section 18, and the burner 3 burns smoothly with the required combustion amount.

As described above, according to the water heater of this embodiment,
Irrespective of the temperature of the air blown to the burner 3 and the load fluctuation of the combustion fan 9, an amount of oxygen corresponding to the required combustion amount can be supplied to the burner 3, and an amount of gas corresponding to the oxygen amount is supplied to the burner. Thus, the burner 3 can control the combustion amount to a desired required combustion amount.

When correcting the set air volume that regulates the air volume to the burner 3 according to the actual air temperature,
Since the temperature compensation resistor d provided in the air volume sensor 12 is used as a temperature sensor without using an independent temperature sensor for controlling the blowing temperature, the above-described control can be performed with an inexpensive and simple configuration.

In this embodiment, the opening of the gas proportional valve 8 is controlled in accordance with the number of revolutions of the combustion fan 9. The opening of the gas proportional valve 8 may be controlled in accordance with the amount of air blown in this case. In this case, it is not necessary to correct the opening of the gas proportional valve 8 as in the present embodiment.

In this embodiment, the fan drive unit 21 is provided with the rotation speed instruction value and the feedback control is performed by the output of the rotation speed sensor 11. May be directly given, and in this case, the rotation speed sensor 11 can be omitted.

Although the present embodiment has been described by taking a water heater as an example of a combustion device, it goes without saying that the present invention can be applied to other combustion devices such as a fan heater.

[0046]

As is apparent from the above description, according to the present invention, the amount of air sent from the combustion fan to the burner is made to coincide with the set amount of air required to obtain the required amount of combustion of the burner by using the air volume sensor. In addition to controlling the rotation speed of the combustion fan, the air flow sensor is constituted by a hot wire air flow sensor having a temperature compensation resistor, and the temperature compensation resistor is used as a temperature sensor to blow air from the combustion fan to the burner. The temperature is detected and the set air volume is corrected according to the air temperature so that the oxygen amount corresponding to the required combustion amount of the burner is included in the air blown to the burner. Irrespective of the load condition, the amount of oxygen corresponding to the desired combustion amount of the burner can be supplied from the combustion fan to the burner with a reliable and simple configuration.

When correcting the set air volume as described above, the reference set air volume is set as the air volume for obtaining the required combustion volume of the burner at a predetermined air temperature, and By multiplying the value of the ratio of the absolute temperature of the predetermined blowing temperature to the absolute temperature of the detected blowing temperature, the set air volume can be easily corrected.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram of a combustion device (water heater) according to an example of the present invention.

FIG. 2 is a block diagram of a main part of the combustion device of FIG. 1;

FIG. 3 is a circuit configuration diagram of a hot wire type air flow sensor.

[Explanation of symbols]

3 burner, 9 combustion fan, 12 airflow sensor, 25
... temperature detecting section (temperature detecting means), 26 ... air volume correcting section (correcting means), 27 ... fan controlling means.

Continuation of the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) F23N 5/18 101 F23N 1/02 F23N 1/02 104 F23N 3/08 F23N 5/02 350

Claims (2)

(57) [Claims] An air flow sensor for detecting an air flow from a combustion fan to a burner, and an air flow sensor for detecting an air flow of the combustion fan detected by the air flow sensor so as to match a set air flow for obtaining a required combustion amount of the burner. A fan control means for controlling the number of revolutions of the combustion fan, wherein the air flow sensor is a bridge including an air flow detection heating element and a temperature compensation resistor disposed in an air passage from the combustion fan to the burner. A temperature detection unit configured to include a hot-wire type air flow sensor that outputs a signal corresponding to an air flow amount of the combustion fan from a circuit, and that detects an air flow temperature by a change in a resistance value of the temperature compensation resistor when the air flow sensor is operated; Correction means for correcting the set air volume in accordance with the blast temperature detected by the temperature detection means, wherein the correction means adjusts a required combustion amount of the burner. Combustion apparatus characterized by oxygen quantity to correct the set air amount as contained in the air that is blown into the burner from the combustion fan. 2. The method according to claim 1, wherein the set air flow is a blow air flow for obtaining a required combustion amount of the burner at a predetermined blow air temperature, and the correction means includes an absolute temperature (T _{0) of the} predetermined blow air temperature. ) And the absolute value (T) of the blown air temperature detected by the temperature detecting means (T / T ₀ ).
2. The combustion apparatus according to claim 1, wherein the set airflow is corrected by multiplying the set airflow by the following equation.