JP3673361B2 - Combustion equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a combustion apparatus such as a water heater.
[0002]
[Prior art]
FIG. 6 shows an example in which the water heater 1 is installed indoors. This type of water heater rotates the combustion fan to supply gas fuel to the burner, ignites the burner to form a flame, and heats the water passing through the heat exchanger, creating hot water at a set temperature, This hot water is led to a desired hot water supply place such as a kitchen. Note that a CO sensor 28 is provided on the exhaust side of the water heater 1 so that the CO concentration in the exhaust gas is detected by the CO sensor 28 and combustion is stopped when the CO concentration reaches a dangerous concentration. Is provided.
[0003]
[Problems to be solved by the invention]
Normally, in this type of water heater, when the burner is ignited, the combustion fan is ignited with the rotation speed of the fan corresponding to the gas supply amount at the time of ignition, but the recent residence has high airtightness. For example, when the ventilation fan 2 or the range hood is activated, the pressure in the room becomes negative, and when the burner is ignited, there is a problem that the supply amount of the combustion fan becomes insufficient and an ignition error occurs. It was.
[0004]
When this ignition error occurs, the ignition operation is repeated again. However, since the re-ignition operation is also performed at the same rotation speed of the combustion fan, when the ventilation fan 2 and the range hood are continuously driven, Since the supply of air is insufficient again, an ignition mistake occurs again, and there is a problem that the ignition flame cannot be stably obtained even if the ignition operation is repeated.
[0005]
The present invention has been made in order to solve the above-described problems. The purpose of the present invention is to ensure that an ignition flame is stably formed by subsequent re-ignition when an ignition error occurs, and in the combustion operation after ignition, An object of the present invention is to provide a combustion apparatus capable of performing good combustion control by appropriately controlling the fan air volume in accordance with the CO concentration in the gas and the degree of negative pressure in the room.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention takes the following measures. That is, the first invention comprises a burner that burns fuel, ignition means that ignites the burner, a flame detection sensor that detects the flame of the burner, a combustion fan that supplies and exhausts burner combustion, and this combustion In the combustion apparatus having an air volume control unit for controlling the air volume of the fan, the air volume control unit has a standard fan air volume control data for normal combustion operation, and the fan air volume is increased more than the standard fan air volume control data. A plurality of fan air volume control data including fan air volume control data for increasing the first stage air volume and fan air volume control data for increasing the second stage air volume obtained by increasing the fan air volume from the fan air volume control data for increasing the first air volume. The plurality of fan air volume control data includes the fan air volume control data for increasing the first stage air volume, and the fan air on the air volume side smaller than the air volume control data. The control data is weak negative pressure side air volume control data, which includes the fan air volume control data for increasing the second stage air volume, and the fan air volume control data on the larger air volume side than the air volume control data is classified as strong negative pressure side air volume control data. Of the first stage air volume increasing fan air volume control data and the second stage air volume increasing fan air volume control data on the classification side different from the air volume control data used for ignition when the ignition flame at the start of combustion disappears A means for solving the problem is provided with an ignition retry control unit that performs ignition using the air volume control data on one side.
[0007]
A second invention is a burner that burns fuel, ignition means that ignites the burner, a flame detection sensor that detects the flame of the burner, a combustion fan that supplies and exhausts burner combustion, and this combustion fan In the combustion apparatus having an air volume control unit for controlling the air volume of the air, the air volume control unit includes standard fan air volume control data for normal combustion operation, and a fan air volume that is increased from the standard fan air volume control data. A plurality of fan air volume control data including fan air volume control data for increasing the first stage air volume and fan air volume control data for increasing the second stage air volume obtained by increasing the fan air volume from the fan air volume control data for increasing the first air volume. The plurality of fan air volume control data includes fan air volume control data for increasing the first stage air volume, and fan air volume control on the air volume side smaller than the air volume control data. The airflow control data is weak negative pressure side airflow control data, and the fan airflow control data for the second stage airflow increase is included, and the fan airflow control data on the larger airflow side is classified as strong negative pressure side airflow control data. , An air volume control data monitoring storage unit for monitoring and storing which fan air volume control data was used when the combustion operation was stopped, a time measuring means for measuring the time elapsed after the combustion stop, When the combustion operation is resumed before the given criterion time elapses, ignition is performed using the fan air volume control data that was used when the combustion operation was stopped in the previous combustion operation, and when the flame goes out, it is used for that ignition. Of the first stage air volume increasing fan air volume control data and the second stage air volume increasing fan air volume control data of the classification side different from the air volume control data which has been Ignition retry control unit for performing the ignition using the air volume control data of rectangular side is a means for solving the problems with the configuration provided.
[0008]
Furthermore, a third invention is the one having the configuration of the second invention, wherein a threshold value is provided on the lower side of the detection signal level of the flame detection sensor, and the detection signal level of the flame detection sensor is less than the threshold value. A fan air volume control data switching unit is provided for switching the fan air volume control data to the fan air volume control data on the air volume down side when the air flow is below the level, and the air flow control data monitoring storage unit stores the detection signal level of the flame detection sensor when combustion is stopped. A cancellation time exceeding the time required to decrease to the combustion stop level after passing the threshold level is given, and the air volume control data monitoring storage unit is used at the combustion time before the cancellation time from the combustion stop time. The fan airflow control data that was used was stored as the fan airflow control data that was used when the combustion stopped. It is a means to solve the problems with.
[0009]
Further, the fourth invention is the one provided with the configuration of the first, second or third invention, wherein a CO sensor for detecting the CO concentration in the exhaust gas is installed on the exhaust side of the combustion device, and burner ignition is performed. In the subsequent combustion operation, the fan air volume control data switching control unit that switches the fan air volume control data to the air volume up side as the CO concentration detected by the CO sensor increases is provided as means for solving the problem. .
[0010]
Further, a fifth aspect of the invention includes the structure of the first, second, or third aspect of the invention, wherein the flame detection sensor is formed by a frame rod, and is output from the frame rod during combustion operation after burner ignition. When the rod current is captured and the frame rod current exceeds the preset upper threshold value, the fan air flow control data is switched to the air flow up side, and the frame rod current is set below the preset lower threshold value. The fan air volume control data switching control unit that switches the fan air volume control data to the air volume down side when it exceeds the air flow side is a means for solving the problem.
[0011]
Furthermore, a sixth invention is the one provided with the configuration of the first, second or third invention, wherein the flame detection sensor is formed by a frame rod, and is output from the frame rod during combustion operation after burner ignition. When the rod current is captured and the frame rod current rise change amount exceeds the rise change reference value within the preset reference time, the fan air volume control data is switched to the air volume up side. The fan air volume control data switching control unit that switches the fan air volume control data to the air volume down side when the descent change reference value is exceeded within a preset reference time is a means for solving the problem.
[0012]
Further, according to a seventh aspect of the present invention, the flame detection sensor is formed by a frame rod, and the frame output from the frame rod during combustion operation after burner ignition is provided with the configuration of the first, second or third aspect of the invention. When the rod current is captured and the frame rod current rise change amount exceeds the rise change reference value within the preset reference time, the fan air volume control data is switched to the air volume up side. Fan air volume control that switches the fan air volume control data to the air volume up side when a preset lowering change reference value is exceeded within a minute setting time that is narrower than the reference time for judging the amount of increase in the frame rod current. The data switching control unit is provided as a means for solving the problem.
[0013]
Further, the eighth invention is the one having the configuration of the fourth invention, wherein the flame detection sensor is formed by a frame rod, and the fan air volume control data switching control unit receives the fan air volume control data as the CO concentration increases. In addition to the basic function of switching to the air volume up side, the fan air volume control data is switched to the air volume up side when the frame rod current exceeds the preset upper threshold value, and the frame rod current is preset to the lower side. A function to switch the fan air volume control data to the air volume down side when the threshold value is exceeded, and when the frame rod current rise change amount exceeds the rise change reference value within a preset reference time A function to switch the fan air volume control data to the air volume up side and a reference time in which the amount of change in the frame rod current drop is set in advance The function to switch the fan air volume control data to the air volume down side when the descent change reference value is exceeded and the time width of the descent change amount of the frame rod current is narrower than the reference time for judging the rise change amount of the frame rod current One or more additional functions, including a function to switch the fan air volume control data to the air volume up side when the preset lowering change reference value is exceeded within a minute setting time, are specified within the combustion heat quantity control range. In the combustion operation within the low combustion capacity range below the value, the fan air volume control data is controlled to be switched by a combination of the basic function and the additional function, thereby solving the problem.
[0014]
In the present invention, when an ignition mistake occurs at the start of combustion, the first stage air volume increasing fan air volume control data and the second stage air volume increasing fan belong to a different classification from the air volume control data at the time of the ignition error. Ignition is performed using fan air volume control data on one side of the air volume control data. Therefore, when the degree of negative pressure in the room is high, an ignition error occurs due to insufficient supply when initial ignition is performed with the fan air flow control data on the low negative pressure side. By performing ignition using the second stage air volume increasing fan air volume control data, sufficient air supply required for ignition can be supplied, and an ignition flame can be reliably formed.
[0015]
In addition, when the level of negative pressure in the room is low and the initial ignition is performed using the fan air volume control data on the low negative pressure side, the air volume becomes excessive and the ignition flame is blown out, causing an ignition error. Next, the ignition is performed using the first-stage air volume increasing fan air volume control data on the weak negative pressure side, so that the excessive air volume is eliminated and the ignition flame can be stably formed.
[0016]
During the combustion operation after ignition, when the CO concentration detected by the CO sensor becomes high, the fan air volume control data switching control unit switches the fan air volume control data to data on the air volume up side. When the indoor negative pressure level is determined and the indoor negative pressure level increases, the fan air volume control data switching control unit similarly switches the fan air volume control data to the air volume up side, releasing the indoor negative pressure. When this is done, the fan air volume control data is switched to the air volume down side in order to eliminate excess air volume. Thus, a suitable combustion operation is performed by appropriate air volume control corresponding to the degree of negative pressure in the room.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. FIG. 2 shows a mechanical configuration of a combustion apparatus according to an embodiment of the present invention. The combustion apparatus according to the present embodiment relates to a water heater, and a main body 4 of the water heater is accommodated in the appliance case 3. The appliance case 3 is provided with an air supply port 5, and air is guided from the air supply port 5 to the air introduction port 6 of the main body 4 through a filter (not shown).
[0018]
The main body 4 has a combustion chamber 7, and a burner 8 such as a semi-Bunsen burner of the type that burns using primary air and secondary air is installed on the lower side of the combustion chamber 7. A gas passage 10 is connected to the fuel gas and the fuel gas is supplied to the burner 8 through the gas passage 10.
[0019]
The gas passage 10 is provided with solenoid valves 11 and 12 for opening and closing the passage and a proportional valve 13 for controlling the gas supply amount to the burner 8 by the valve opening amount. The proportional valve 13 is controlled by the control device 14 so that the valve opening amount (gas supply amount), that is, the combustion heat amount (combustion capacity) of the burner 8 is controlled in accordance with the magnitude of the valve opening drive current applied. Is.
[0020]
In the vicinity of the burner 8, there are provided a spark plug 15 as an ignition means for igniting the burner 8 and a frame rod 16 for detecting the flame of the burner 8. As shown in FIG. 7, the flame rod 16 is installed at a height position where the inner flame of the flame generated in the burner 8 comes into contact. By applying a voltage to the flame rod 16, ions ionized in the inner flame are propagated. Thus, the frame rod current flows from the frame rod 16 to the ground end 17 on the burner 8 side. In other words, the frame rod 16 functions as a flame detection sensor that outputs a flame rod current by contacting the flame.
[0021]
A hot water supply heat exchanger 18 is provided on the upper side of the combustion chamber 7, a water supply pipe 20 is connected to the inlet side of the hot water heat exchanger 18, and a hot water supply pipe is connected to the outlet side of the hot water heat exchanger 18. 21 is connected. The hot water supply pipe 21 is connected to an external pipe, the external pipe is led to a desired hot water supply place such as a kitchen, and a hot water tap (not shown) is provided on the outlet side. In the figure, 22 is a feed water flow sensor that detects the feed water flow rate, 23 is a feed water temperature sensor that detects the feed water temperature, 24 is a tap water temperature sensor that detects the hot water temperature, and 25 is a water amount control valve that controls the hot water flow rate. Show.
[0022]
A combustion fan 26 for supplying and exhausting burner combustion is provided on the upper side of the combustion chamber 7. The rotation of the combustion fan 26 is detected by a fan rotation detection sensor 27.
[0023]
A CO sensor 28 is provided in the exhaust passage on the downstream side of the combustion fan 26, and the CO sensor 28 detects the CO concentration in the exhaust gas. When the water heater of this embodiment is installed indoors, an exhaust duct is connected to the outlet side of the exhaust passage 30, and as shown in FIG. 6, the exhaust gas is discharged outside the room.
[0024]
A remote control 31 is signal-connected to the control device 14. The remote controller 31 includes a temperature setter for setting the hot water supply temperature, and a display unit for displaying appropriate information from the control device 14 (for example, a hot water supply temperature and an error signal).
[0025]
FIG. 1 shows a main part of the control device 14. As shown by a solid line in the first embodiment of the control configuration, a combustion control unit 32, an air volume control unit 33, a data storage unit 34, an air volume control, and the like. A data monitoring storage unit 35 and an ignition retry control unit 36 are provided.
[0026]
The combustion control unit 32 calculates a feedforward heat amount required to increase the feedwater temperature to a hot water supply set temperature set by the remote controller 31 and the like, and a feedforward heat amount that corrects a deviation of the hot water supply temperature (outflow temperature) with respect to the hot water set temperature. The total heat amount obtained by the addition is calculated, and the proportional valve current (valve opening drive current) to the proportional valve 13 is controlled so that the combustion heat amount of the burner 8 becomes this total heat amount.
[0027]
That is, combustion control data indicating the relationship between the proportional valve opening and the combustion heat quantity (combustion capacity) as shown in FIG. 5 is given to the combustion control section 32, and the combustion control section 32 determines the maximum combustion heat quantity Max and the minimum The proportional valve opening is controlled within the range of the combustion capacity with the combustion heat amount Min. For example, when the amount of combustion heat obtained by calculation is P, the proportional valve opening is obtained as Q from the control data of FIG. 5, and the proportional valve current is supplied to the proportional valve 13 so as to obtain this proportional valve opening Q. It controls as much as possible. In the control data shown in FIG. 5, the proportional valve opening corresponding to the minimum amount of combustion heat is set to 0%, the proportional valve opening corresponding to the maximum amount of combustion heat is set to 100%, and the proportional valve opening is set from 0% to 100%. A control form is adopted in which the combustion heat quantity is controlled within the range of the minimum combustion heat quantity and the maximum combustion heat quantity.
[0028]
The air volume control unit 33 is provided with air volume control data as shown in FIG. The air volume control data is stored in the data storage unit 34. In FIG. 3, the horizontal axis indicates the proportional valve opening (combustion heat amount), and the vertical axis indicates the fan rotation speed (fan air volume). The data of A in FIG. 3 is standard fan air volume control data for normal combustion operation, and the data of C is the first stage air volume increasing fan air volume shifted in the direction of increasing the fan air volume than the standard fan air volume control data. B is control air flow control data for increasing the second stage airflow, which is further increased from the fan airflow control data for increasing the first stage airflow. This is fan air volume control data shifted in the up direction.
[0029]
As can be seen from the data shown in FIG. 3, when the fan air flow control data B to E is changed at the minimum input (at the time of the minimum proportional valve opening), the fan rotation speed changes greatly, whereas at the maximum input the fan rotation. The numbers are not changed much. This is uniquely found by the applicant of the present invention, which is different from that which is generally carried out with the air-fuel ratio kept constant. In other words, the burner is originally a burner that can burn at the maximum input (rated input) and controls the air volume so that it does not disappear even if the fuel is reduced. In other words, it means that the lower the input (lower combustion heat amount), the more the air flow control will be lost if it is not performed accurately. In other words, in the correlation with a constant air-fuel ratio, each line is parallel, but in this application, the spacing between the lines increases as the proportional valve opening decreases, and the spacing between the lines increases as the proportional valve opening increases. (Each line does not need to be gathered at one point, and the imaginary line of each line intersects somewhere in the large proportional valve opening direction).
[0030]
In the normal combustion operation, the air volume control unit 33 obtains the fan rotation speed (fan air volume) corresponding to the proportional valve opening using the control data of A so that the fan rotation speed (fan air volume) can be obtained. The rotation of the combustion fan 26 is controlled. By this air volume control, an air volume commensurate with the combustion heat quantity (gas supply quantity) is obtained, and combustion control in which the combustion heat quantity and the air volume match is achieved. The air volume control unit 33 has a control function for switching the fan air volume control data in the air volume increasing direction when the CO concentration exceeds a preset reference value based on the CO detection density of the CO sensor 28.
[0031]
In this embodiment, the fan air volume control data for A and C are classified as control data on the weak negative pressure side, and the fan air volume control data for B, D, and E are classified as control data on the strong negative pressure side. In the present specification, the weak negative pressure side means the state of the indoor pressure when the range hood or the ventilation fan 2 is not activated. When the combustion fan 26 is rotated in a sealed state, the indoor air is Since it is discharged, the room becomes slightly negative pressure, so the term of weak negative pressure side is used. On the other hand, the strong negative pressure side means the state of the indoor pressure when at least one of the range hood and the ventilation fan 2 is in the activated state, that is, the negative pressure state in which the indoor pressure is stronger than the weak negative pressure state. Means.
[0032]
The air volume control data monitoring storage unit 35 monitors and stores which data is used in time series among the fan air volume control data of A to E shown in FIG. 3 during the combustion operation.
[0033]
The ignition retry control unit 36 has a circuit configuration including an initial ignition control unit 39, and the initial ignition control unit 39 controls the ignition by first driving the spark plug 15 at the start of the combustion operation, The initial ignition control unit 39 performs ignition by designating the standard fan airflow control data A as the fan airflow control data, or by the data monitored and stored in the airflow control data monitoring storage unit 35, Ignition operation is controlled by designating the same fan air flow control data as the fan air flow control data used at the end.
[0034]
This initial ignition operation is performed in cooperation with the combustion control unit 32 and the air volume control unit 33, and uses the air volume control data designated by the initial ignition control unit 39 to open the proportional valve opening of the startup gas supply amount at the time of ignition. The combustion fan is rotated at a fan rotational speed (fan air volume) corresponding to the degree, and in this state, a spark is blown to the fuel gas ejected from the burner 8 by the spark plug 15 to perform ignition.
[0035]
The ignition retry control unit 36 detects the flame rod current from the frame rod 16, detects whether the initial ignition performed by the initial ignition control unit 39 is successful, and performs ignition retry operation in the case of ignition failure. Control.
[0036]
That is, when an ON signal (flame detection level current) is applied from the frame rod 16, it is determined that a flame is formed by the initial ignition and the ignition operation is successful, and when an OFF signal is applied from the frame rod 16, the ignition is performed. Judged as a mistake (ignition failure).
[0037]
The ignition retry control unit 36 is given classification information of a plurality of fan air volume control data shown in FIG. In this embodiment, as described above, the fan air volume control data for A and C are classified (grouped) as weak negative pressure side air volume control data, and the fan air volume control data for B, D, and E are classified as strong negative pressure side air volume control data. Is classified (grouped).
[0038]
Strong negative pressure side air volume control data indicates that when the ventilation fan 2 or range hood is driven and the room is in a negative pressure state, the air volume is secured to compensate for the lack of air volume of the combustion fan 26 due to the negative pressure in the room. The control data, and the weak negative pressure side air volume control data is that the ventilation fan 2 and the range hood are in a stopped state, and the room is slightly negative pressure by the rotation of the combustion fan 26, or the window is opened. For example, the control data supplies an appropriate amount of air necessary for combustion in a state where the negative pressure state is eliminated.
[0039]
When the ignition retry control unit 36 determines that the initial ignition has failed, the ignition retry control unit 36 determines whether the fan air volume control data used during the initial ignition is control data on the strong negative pressure side or control data on the weak negative pressure side. However, in the case of the strong negative pressure side air volume control data, the strong negative pressure side air volume control data was used even though the room was not at high negative pressure, so the ignition flame was blown off due to excessive air volume. When the re-ignition is performed, the first stage air volume increasing fan air volume control data C, which is the fan air volume control data on the weak negative pressure side opposite to the fan air volume control data at the time of initial ignition, is designated. Ignition operation is performed.
[0040]
Conversely, when it is determined that the initial ignition has failed using the fan air flow control data on the low negative pressure side, the negative pressure is weak although the range hood and the ventilation fan 2 are driven and the room is at a high negative pressure. The pressure side fan airflow control data was specified and the initial ignition was performed, so it was determined that the ignition flame had extinguished due to the airflow shortage. The re-ignition (ignition retry) operation is controlled by designating the second stage air volume increasing fan air volume control data B which is the pressure side fan air volume control data.
[0041]
These reignition control operations are performed in accordance with the proportional valve opening corresponding to the gas supply amount at the time of ignition using the designated fan air volume control data in the same manner as the initial ignition control operation by the initial ignition control unit 39. The number of fan rotations is controlled so that the fan air volume is obtained, and in this state, fuel gas is supplied to the burner 8 and sparks are blown off by the spark plug 15 to perform an ignition operation.
[0042]
According to this embodiment, when the initial ignition fails, it is determined whether the fan air volume control data used during the initial ignition belongs to the strong negative pressure side or the weak negative pressure side. Since the re-ignition is performed using either the first-stage air volume increasing fan air volume control data C or the second-stage air volume increasing fan air volume control data B, which is different from the ignition timing, the initial ignition is the air volume. When the ignition fails due to excessive air flow, re-ignition is performed using the air volume control data C for the first stage air volume increase with the smaller air volume, and when the initial ignition fails due to insufficient air volume, the second stage air volume increase fan with a larger air volume. Since the ignition retry operation is performed using the air volume control data B, an air volume that can be ignited without insufficient or excessive air volume is supplied at the time of re-ignition. The ignition flame can be reliably formed Te, in which high ignition retry control reliability can be realized.
[0043]
Next, a second embodiment of the control configuration of the present invention will be described. The control configuration of the second embodiment is provided with time measuring means 37 such as a clock mechanism and a timer as shown by a broken line in FIG. 1, and also gives a determination reference time to the ignition retry control unit 36, and ignition retry control. The unit 36 detects the time from when the combustion operation is stopped using the time measuring means 37, and when the combustion operation is restarted within the determination reference time from the time of combustion stop, the initial ignition control unit 39 performs the previous combustion operation. When the initial ignition is performed using the fan air volume control data used at the time of the combustion stop of this, and the initial ignition fails, the fan air volume control data used at the time of the initial ignition belongs to the same as in the first embodiment. Reignition is performed using the first stage air volume increasing fan air volume control data C or the second stage air volume increasing fan air volume control data B on the classification side different from the classification, and an ignition flame is reliably formed. When the combustion operation is resumed after the determination reference time has elapsed since the previous combustion stop, the standard fan air volume control data A for normal combustion operation or the fan air volume control for increasing the first stage air volume The initial ignition is performed using the data C, and the other configuration is the same as that of the first embodiment.
[0044]
In the second embodiment, when the combustion operation is resumed after the determination reference time has elapsed from the previous stop of the combustion operation, the initial ignition performed using the fan air volume control data A or C is performed. In the same manner as in the first embodiment, when the fan air flow control data A and C are unsuccessful, the re-ignition is controlled by specifying the fan air flow control data B whose classification is opposite to that of the fan air flow control data.
[0045]
In this second embodiment, for example, a value of 5 minutes 30 seconds is given as the determination reference time. Normally, when the combustion operation is resumed within this determination reference time, the previous combustion is stopped. Therefore, when the combustion operation is resumed within the judgment reference time, the fan air volume control data selected and used as the optimum combustion state data at the previous combustion operation is used. The initial ignition is performed to increase the success rate of the initial ignition.
[0046]
Next, a third embodiment of the control configuration will be described. In the third embodiment, as shown by the chain line in FIG. 1, a fan air volume control data switching unit 38 is provided to switch and set the fan air volume control data according to the level of negative pressure in the room. The method of detecting the fan air volume control data used at the end of the previous combustion operation by the air volume control data monitoring storage unit 35 is changed, and the other configuration is the same as that of the second embodiment.
[0047]
According to the examination by the present inventor, when the pressure in the room becomes negative and the amount of air supplied by the combustion fan 26 decreases, the flame shown in FIG. 7 extends upward, the frame rod current increases, and vice versa. By eliminating the negative pressure of the flame, the flame contracted to its original state, and the phenomenon that the flame rod current decreased was found. Focusing on this point, in the third embodiment, as shown in FIG. 4, an upper threshold is set at the upper level position of the frame rod current, and the lower (lower) level position of the frame rod current is set. The lower threshold is set, and the fan air flow control data switching unit 38 compares the frame rod current taken from the frame rod 16 with the upper and lower thresholds, and the frame rod current exceeds the upper threshold. If it is determined that the room is in a negative pressure state, the fan airflow control data is switched to the control data on the fan airflow increase side, and when the frame rod current falls below the lower threshold, It is determined that the pressure has been released, and the fan airflow control data is switched to the fan airflow down side, that is, the original fan airflow control data before the fan airflow is increased. It has been completed.
[0048]
The air volume control unit 33 uses the fan air volume control data switched by the fan air volume control data switching unit 38 to control the fan air volume during the combustion operation.
[0049]
By the fan air flow control data switching setting operation of the fan air flow control data switching unit 38, for example, as shown in FIG. 4, a combustion stop command is output from the combustion control unit 32, and the solenoid valves 11 and 12 are closed to stop the combustion. In this case, the flame rod current passes through the lower threshold value downward and enters a combustion stop state at a level lower than the lower threshold value. That is, by providing the fan air volume control data switching unit 38, when the flame rod current crosses the lower threshold value downward when combustion stops, the fan air volume control data switching unit 38 Since the fan air volume control data is erroneously determined to have been released and the fan air volume control data is switched and set in the direction in which the fan air volume decreases, the air volume control data monitoring storage unit 35 uses the fan air volume control data used when the combustion is stopped. As a result, the fan air volume control data switched by the fan air volume control data switching unit 38 in the air volume down direction is monitored and stored as the fan air volume control data used at the end of the combustion operation.
[0050]
For this reason, when the combustion operation is restarted within the determination reference time from the time when combustion is stopped and the initial ignition control unit 39 performs initial ignition, the initial ignition control unit 39 is used at the end of the previous combustion operation. Since the fan air volume control data mistakenly monitored and stored by the air volume control data monitoring storage unit 35 is believed to be correct and is designated as the fan air volume control data at the time of initial ignition, the probability of failure of the initial ignition The problem of increase will arise.
[0051]
In the third embodiment, in order to solve such a problem, a cancellation time Δt as shown in FIG. _CAN Is given. This cancellation time Δt _CAN Is the time Δt from when the flame rod current crosses the lower threshold value until the combustion is stopped when the combustion is stopped. _F More specifically, it is given by a time value larger than _F And this Δt _F The larger value is the cancellation time Δt _CAN Is given as the value of.
[0052]
The air volume control data monitoring storage unit 35 stores the flame rod current at the time of combustion stop in time series, and the level value P of the flame rod current at the time of combustion stop. _FIN Cancellation time Δt from when the combustion stopped _CAN The air volume control data that was used just before the time of the time, i.e., the fan air volume control data that was used before the flame rod current crossed the lower threshold value downward when the combustion stopped was The fan air volume control data that has been used is monitored and stored. In other words, the cancellation time Δt _CAN The same result as that obtained by erasing the monitoring storage data of the fan air flow rate control data in between is obtained.
[0053]
In this third embodiment, even if the flame rod current crosses the lower threshold value downward and the fan air volume control data is set to be switched to the air volume down side at the time of combustion stop, Since the fan air volume control data is correctly monitored and stored by the air volume control data monitoring storage unit 35 as the fan air volume control data used at the time of combustion stop, it is used by the initial ignition control unit 39 at the previous combustion stop when the next combustion restarts. Since the correct fan air flow control data is specified as the fan air flow control data that has been set and the initial ignition operation is performed, the probability of the success of the initial ignition operation can be increased, and the initial ignition with few ignition mistakes can be performed. It will be.
[0054]
In addition to the fan air volume control data given in the form shown in FIG. 3, as shown in FIG. 9, the fan air volume control data of X = 0 corresponding to the fan air volume control data A in FIG. The fan air volume control data of X = 2 and X = 4 may be provided in the form of parallel control lines.
[0055]
Next, the fan air volume control configuration during the combustion operation after ignition will be described. FIG. 8 shows a control configuration of the combustion fan 26 after ignition. A fan air volume control data switching control unit 40 is provided in association with the air volume control unit 33 that controls the fan air volume of the combustion fan 26 according to the fan air volume control data. ing. The fan air volume control data switching control section 40 receives the signals from the CO sensor 28 and the frame rod 16 and detects the fan air volume control data used by the air volume control section 33 as the CO concentration detected by the CO sensor 28 and the frame rod. The fan air volume control data is switched and controlled according to the negative pressure state of the indoor combustion environment detected by 16 currents, and has one or more of the following functions.
[0056]
The first function is a function of switching and setting the fan air volume control data stepwise to the fan air volume increasing side as the CO concentration detected by the CO sensor 28 increases. An example of the operation of this function will be described with reference to the flowchart of FIG. 13. First, in step 101, it is determined whether or not the CO concentration is equal to or higher than the upper limit value. Enhanced. In this flowchart, the fan air volume control data shown in FIG. 9 is described as an example, and the number X in the flowchart corresponds to the X value of each fan air volume control data shown in FIG.
[0057]
The upper limit value of the CO concentration may be given as an upper limit value when reaching a CO dangerous concentration when a person is exposed to the atmosphere of the CO concentration detected by the CO sensor 28, or high CO The concentration threshold value may be given, or the CO concentration of blood hemoglobin when a person is exposed to the CO concentration atmosphere detected by the CO sensor 28 is calculated and calculated every unit time t. The upper limit value of the integrated value of the ratio t / T of the blood hemoglobin CO concentration to the unit time t with respect to the danger arrival time T may be given.
[0058]
On the other hand, when the CO concentration is less than the upper limit value in step 101, it is determined in step 103 whether or not the CO concentration is less than the specified value. If the CO concentration is less than the specified value, the fan air volume control data is set to the one-stage air volume down side. Switch. At this time, it is determined in step 105 whether or not the fan airflow control data becomes X = 0 data. When X = 0 fan airflow control data is obtained, the fan airflow control data is set to be higher than that of X = 0. The air volume is set to X = 1 data, which is one stage above.
[0059]
In step 107, it is determined whether or not the fan air flow control data has reached the value of X = 5 by switching the fan air flow control data to the one-step air flow up side in step 102, and when the value of X = 5 is reached, the fan air flow is increased. Even if this is done, it is not expected to prevent the generation of high-concentration CO gas.
[0060]
When X does not reach 5 in the step 107, the combustion fan is controlled with the fan rotation speed (fan airflow) corresponding to the combustion amount (combustion heat amount) based on the fan airflow control data obtained by increasing the airflow by one step in the step102. In step 110, the value of X is registered as the negative pressure intensity in the room. In step 111, it is determined whether an on signal is applied from the feed water flow rate sensor 22, and when the on signal is applied, the operations in and after step 101 are repeated. On the other hand, when an off signal is output from the feed water flow rate sensor 22, it is determined that the hot water tap is closed, and combustion is stopped. In step 112, the elapsed time from the time of combustion stop is measured using a timer or the like, and it is determined whether it is within 10 minutes after the combustion stop. When the combustion operation is resumed within 10 minutes after the combustion is stopped, it is estimated that the indoor negative pressure state is the same as the X value registered in the step 110, and the fan air flow control of the registered X value is performed. The combustion operation is performed using the data, but when 10 minutes have elapsed after the combustion is stopped, the fan air volume control data of X = 0 which is the fan air volume control data in the standard mode is set to prepare for the next combustion operation.
[0061]
In the flowchart shown in FIG. 13, when the pressure in the room becomes negative, a shortage of air supply occurs, and the CO concentration increases according to the degree of negative pressure in the room. The fan air volume control data corresponding to the intensity of the negative pressure in the room is selected and specified, the shortage of air supply due to the negative pressure in the room is eliminated, and a good combustion operation is performed.
[0062]
The second function of the fan air flow control by the fan air flow control data switching control unit 40 is to detect the frame rod current output from the frame rod 16 and to determine the degree of negative pressure in the room based on this frame rod current. This function switches and sets control data. That is, as shown in FIG. 10, the data storage unit 34 is provided with the relationship data of the proportional valve opening (combustion heat quantity) and the flame rod current as a threshold value, and the degree of the negative pressure in the room is determined based on this relationship data. This is a function for controlling the fan air volume control data to be gradually switched to the fan air volume up side as it increases, and to switch the fan air volume control data to the fan air volume down side in stages as the degree of negative pressure decreases.
[0063]
The relational data shown in FIG. 10 gives a lower threshold value to the lower side of the frame rod current and an upper threshold value to the upper side. In the example of FIG. 10, the lower threshold value is given by the lower fixed threshold value and the lower variable threshold value, and the upper threshold value is given by the upper variable threshold value and the upper fixed threshold value. These upper and lower fixed threshold values are given as constant values whose values do not vary depending on the proportional valve opening, and the upper and lower variable threshold values increase as the proportional valve opening increases. These lower threshold values may be given as lower fixed threshold values, lower variable threshold values, or proportional valve opening categories. Accordingly, the lower fixed threshold value and the lower variable threshold value may be properly used. Similarly, the upper threshold value may also be given by the upper fixed threshold value, or may be given by the upper variable threshold value. The upper fixed threshold value and the upper variable threshold value are set according to the proportional valve opening category. Can be used properly.
[0064]
During the operation of the second function, the fan air volume control data switching control unit 40 takes in the frame rod current from the frame rod 16, and when the frame rod current exceeds the upper threshold value, the room is in a negative pressure state. The fan air flow control data is switched to the air flow up side, and when the frame rod current falls below the lower threshold value (when it goes down), the negative pressure in the room changes in the release direction. The fan air volume control data is switched to the fan air volume down side and set.
[0065]
FIG. 14 is a flowchart showing the operation of the second function. That is, in step 201, it is determined whether or not the frame rod current exceeds the upper threshold value. When the frame threshold current exceeds the upper threshold value, the fan air volume control data is increased by one step to the fan air volume increasing side. Is determined to have exceeded the lower threshold value, it is determined that the negative pressure condition in the room has been released, and the fan air volume control data is switched to the one-stage fan air volume down side. The up / down switching operation of the fan air volume control data is the same as the operation shown in FIG. 13, and the same operation is given the same step number and its duplicate description is omitted.
[0066]
The present inventor has verified the relationship between the degree of negative pressure in the room and the frame rod current by experiment. When the pressure in the room is reduced to a negative pressure, the combustion flame extends upward due to insufficient supply of air, and the flame rod When the magnitude of the current increases and the negative pressure in the room is released, the shortage of air supply is eliminated, and the flame contracts to the original state, and the phenomenon that the frame rod current decreases is identified. The operation of the second function is that a negative pressure in the room is generated when the frame rod current exceeds the upper threshold value, and a negative pressure is generated when the frame rod current exceeds the lower threshold value. It is judged that the degree of release or negative pressure has decreased, and fan air volume control data is switched according to the degree of negative pressure in the room, and good combustion is achieved by controlling the fan air volume according to the degree of negative pressure in the room It ensures driving.
[0067]
The third function of the fan air volume control configuration by the fan air volume control data switching control unit 40 is a function of detecting a negative pressure situation and a negative pressure release situation in the room based on the amount of change in the frame rod current. (A) of FIG. 11 detects the indoor negative pressure occurrence state based on the amount of increase in the frame rod current and switches and sets the fan air volume control data to the fan air volume up side. F _th1 (For example, 1.1 μA) and the reference time T given to the reference value for the increase _th1 (For example, 0.6 seconds) is given, and the fan air volume control data switching control unit 40 determines that the amount of increase in the frame rod current is the reference time T _th1 Within the period of time, the rising change reference value F _th1 When the air pressure exceeds the value, for example, the range hood or the ventilation fan is activated during the combustion operation, and it is determined that the room has become negative pressure, and the fan air volume control data X is switched to the air volume increasing side ((X + 1) side). Set.
[0068]
(B) of FIG. 11 is a function for detecting the release of the negative pressure in the room based on the amount of decrease in the frame rod current, and the data storage unit 34 stores the reference value F for the decrease in frame rod current. _th2 And a reference time T given to the reference value for the downward change _th2 And the fan air volume control data switching control unit 40 determines that the amount of change in the decrease in the frame rod current is the determination time T. _th2 Within the period of time, the descent change reference value F _th2 When the pressure exceeds the value, it is determined that the negative pressure in the room has been released (or changed in the negative pressure decreasing direction), and the fan air volume control data X is switched to the fan air volume down side ((X-1) side).
[0069]
FIG. 12 shows the function of switching and setting the fan air volume control data in the direction of increasing the fan air volume by detecting a sudden negative pressure change in the room based on the sudden decrease change amount of the frame rod current. In this function, the data storage unit 34 stores the frame rod current falling change reference value F. _th0 (For example, 0.7 μA) and the determination time T shown in FIG. _th2 Minute set time ΔT with a narrower time range than _th (For example, 0.1 second) is provided, and the fan air flow control data switching control unit 40 has a frame rod current of a minute setting time ΔT. _th Descent change reference value F within _th0 For example, when the indoor hood is open and the combustion operation is performed with the range hood activated, the door is suddenly closed and the room suddenly becomes negative pressure and the combustion flame It is determined that the flame rod current has suddenly dropped and is about to disappear (the flame has become extremely small). In this case, the fan air volume control data X is switched to the fan air volume up side ((X + 1) side) in order to eliminate the shortage of air supply due to sudden negative pressure generation.
[0070]
When the fan air volume control data is switched and set by any function by the fan air volume control data switching control section 40, the air volume control section 33 uses the fan air volume control data thus set to change the air volume control of the combustion fan 26. I do.
[0071]
The fan air volume control data switching control unit 40 is provided with one or more functions among the plurality of functions to set the fan air volume control data according to the negative pressure condition in the room. In the low combustion capacity range where the proportional valve opening) is lower than the specified value of the control range (for example, proportional valve opening 30%), the combustion performance is more susceptible to negative pressure in the room. The first function (basic function) based on the CO detection signal of the CO sensor and the one or more functions (additional functions) based on the frame rod current are combined, and based on detection of the negative pressure in the room by the CO sensor. Combined with fan air volume control data setting and fan air flow control data switching setting based on detection of indoor negative pressure level by frame rod current, according to indoor negative pressure level In addition, more accurate fan air flow control is possible.
[0072]
In other words, in the region where the amount of heat of combustion is low (proportional valve opening is small), CO is generated when the deterioration of combustion is detected by collecting CO that has deteriorated due to insufficiency of air flow and is released by the CO sensor. After that, it takes time to be detected by the CO sensor, and there is a risk of misfire during this time. In this respect, the flame rod current reacts instantaneously to the deterioration of combustion, the deterioration of the combustion is quickly detected by the change of the flame rod current, and the air volume is quickly controlled in the combustion improvement direction, thereby preventing misfire. . On the other hand, the flame rod has a flame rod current range in which combustion deterioration can be detected with high sensitivity. If the flame rod current is out of this range, the detection sensitivity of combustion deterioration is lowered. Since the negative pressure detection based on the flame rod current and the negative pressure detection based on the CO concentration detection signal from the CO sensor are used in combination, the negative pressure of the indoor combustion environment can be detected in the entire range of combustion heat control. The pressure state can be detected with high accuracy, and more accurate fan air flow control according to the level of negative pressure in the room becomes possible.
[0073]
In addition, this invention is not limited to the said embodiment example, Various embodiment can be taken. For example, in the above embodiment, the hot water heater has been described as an example of the combustion device. However, the combustion device of the present invention is not a hot water heater that uses gas or petroleum as a fuel, for example, a bathtub, a heater, a cooler, an air conditioner. It is applied to various combustion devices such as a machine and a fan heater.
[0074]
Furthermore, in the above embodiment, as shown in FIG. 2, the combustion fan 26 is provided on the exhaust side and the suction type is used. However, for example, the combustion fan 26 may be provided on the lower side of the burner 8 and may be the extrusion type.
[0075]
Further, the fan air volume control data shown in FIG. 3 may be given by the relationship between the proportional valve opening degree and the fan rotational speed, or may be given by the relation between the proportional valve opening degree and the fan air volume. In the latter case, an air volume sensor (for example, an air speed sensor) for detecting the fan air volume is provided, and a control mode is adopted in which the fan speed is controlled so that the detected air volume becomes a target air volume corresponding to the proportional valve opening.
[0076]
Further, in the embodiment shown in FIGS. 13 and 14, when the fan air volume control data is sequentially increased to the air volume increasing side, X = 0, X = 1, X = 2, X = 3, and X = 4. X is sequentially increased by 1 and when the fan air volume control data is decreased to the air volume down side, X is sequentially decreased by 1 such that X = 4, X = 3, X = 2, and X = 1. The order of increasing and decreasing the air volume control data is not necessarily limited to this. For example, when raising the fan air volume control data, the air volume control data is increased in a procedure such as X = 0, X = 2, X = 3, and X = 4. You may do it.
[0077]
【The invention's effect】
According to the present invention, first stage air volume increasing fan air volume control data that enables ignition to be reliably performed in a room with a weak negative pressure, and ignition to be performed reliably in a room with a strong negative pressure. When the initial stage ignition operation at the start of combustion fails, the second stage air volume increasing fan air volume control data obtained by increasing the fan air volume than the first stage air volume increasing fan air volume control data is provided. Judge whether the fan airflow control data used during the failed initial ignition operation belongs to the weak negative pressure side classification or the strong negative pressure side classification, and use the weak negative pressure side fan airflow control data to perform initial ignition When the operation fails, it is determined that the indoor negative pressure state is a strong negative pressure state. At this time, the second negative air volume control data for increasing the high negative pressure side is designated and reignition is performed. And On the contrary, when the initial ignition fails using the strong negative pressure side fan air volume control data, the negative pressure state is almost released in the room, and in this state, the strong negative pressure fan air volume control data is used. Therefore, it is determined that the initial ignition operation has failed due to the excessive air volume. In this case, the first negative air volume-up fan air volume control data on the low negative pressure side is designated and re-ignition is performed. Even if initial ignition fails using either the pressure side or weak negative side fan air volume control data, at the next re-ignition, the fan air volume control data on the side that provides the appropriate air volume for ignition is specified and re-ignition is performed. Therefore, it is possible to stably form an ignition flame by one reignition operation, and it is possible to ignite reliably without repeating the reignition operation many times, and to improve the accuracy of ignition control. , It is possible to greatly increase the reliability of the ignition control.
[0078]
Also, an air volume control data monitoring storage unit is provided to monitor and store fan air volume control data that was used at the time of the previous combustion stop, and when the combustion operation is resumed within the determination reference time from the time of combustion stop, the air volume control data monitoring is performed. In the invention in which the initial ignition is performed using the fan air volume control data at the time of the previous combustion stop monitored and stored by the storage unit, the same negative pressure in the room as the previous combustion stop or the environment for releasing the negative pressure Since the possibility of initial ignition is high, the probability of successful initial ignition is increased by using the fan air volume control data that was used at the time of the previous combustion stop, thereby reducing the initial ignition failure, The effect that the ignition flame can be efficiently formed by the initial ignition is obtained.
[0079]
Further, when the detection signal level of the flame detection sensor falls below a predetermined threshold value, the fan air volume control data is switched to the air volume reduction side. Fan air flow control data used at the time of combustion just before the time when the combustion was stopped, giving a cancellation time exceeding the time required to decrease to the combustion stop level after crossing the value level downward Is detected as the fan air flow control data used when the combustion is stopped, the detection signal level of the flame detection sensor crosses the threshold value when the combustion stops and the fan air flow control data is on the air flow down side. Even if it is switched to, the fan air volume control data on the air volume down side is used at the previous combustion stop. The fan airflow control data used at the time of combustion before the time when the combustion is stopped is correctly used as the fan airflow control data used when the combustion is stopped. Detection can be set.
[0080]
For this reason, when initial ignition is performed at the time of the next combustion restart, the fan air flow control data used at the end of the previous combustion is correctly specified, and the initial ignition is performed using the correct fan air flow control data. Thus, the initial ignition can be performed without being affected by the operation of the fan air volume control data switching unit, and thereby the probability of success of the initial ignition can be increased.
[0081]
Furthermore, based on the CO concentration detection signal of the CO sensor and the frame rod current output from the frame rod, the degree of indoor negative pressure is detected, and the fan air flow control data is set in the room according to the degree of indoor negative pressure. In the invention provided with a fan air volume control data switching control unit that switches in the direction of increasing the air volume when the pressure level is large, and in the direction of decreasing the air volume when the negative pressure in the room is released (or decreased), Since the fan air volume is controlled according to the negative pressure level, the shortage of air supply due to the negative air pressure in the room is resolved by increasing the air volume, and when the negative air pressure in the room is released, the air volume is reduced and the air volume is reduced. Since the control is performed so as to eliminate the excess, it is possible to perform a good combustion operation without being affected by the change in the negative pressure situation in the room.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a main configuration of an embodiment of the present invention.
FIG. 2 is a system configuration diagram of a combustion apparatus in the present embodiment.
FIG. 3 is an explanatory diagram of fan air volume control data given in the embodiment.
FIG. 4 shows a flame rod current, a lower threshold value, and a cancellation time Δt. _CAN It is explanatory drawing which shows the relationship.
FIG. 5 is an explanatory diagram of combustion control data showing the relationship between the proportional valve opening and the amount of combustion heat.
FIG. 6 is an explanatory diagram of the indoor installation use state of a water heater generally known as a combustion apparatus.
FIG. 7 is an explanatory diagram of an example of burner flame detection by a frame rod.
FIG. 8 is a block configuration diagram of a fan air volume control configuration during a combustion operation after ignition in the present invention.
FIG. 9 is an explanatory diagram of another example of fan air volume control data.
FIG. 10 is an explanatory diagram of a setting example of an upper threshold value and a lower threshold value of the frame rod current.
FIG. 11 is an explanatory diagram of an example in which generation of a negative pressure in a room and release of a negative pressure are detected based on a change amount of a frame rod current.
FIG. 12 is an explanatory diagram of an example in which the occurrence of a sudden negative pressure in a room is detected based on a sudden drop change amount of the frame rod current.
FIG. 13 is a flowchart of an operation for detecting an indoor negative pressure state based on CO concentration and performing air volume control.
FIG. 14 is a flowchart of an operation for detecting an indoor negative pressure situation by a frame rod current and performing air volume control.
[Explanation of symbols]
16 Frame rod
32 Combustion control unit
33 Air flow control unit
35 Airflow control data monitoring and storage unit
36 Ignition retry control unit
38 Fan air flow control data switching section
39 Initial ignition control unit

Claims (8)

Burner for burning fuel, ignition means for igniting the burner, flame detection sensor for detecting the flame of the burner, combustion fan for supplying and exhausting burner combustion, and air volume control for controlling the air volume of the combustion fan In the combustion apparatus, the standard air flow control data for normal combustion operation is included in the air flow control unit, and the first stage air flow increasing fan air flow in which the fan air flow is increased from the standard fan air flow control data. A plurality of fan air volume control data including control data and second stage air volume increasing fan air volume control data obtained by increasing the fan air volume from the first stage air volume increasing fan air volume control data is provided. Fan air volume control data includes fan air volume control data for increasing the first stage air volume. The air flow control data is classified as strong negative pressure air flow control data, including the air flow control data for increasing the second stage air flow. The fan air flow control data on the larger air flow side is classified as strong negative pressure air flow control data. When the flame disappears, the air volume control on one side of the first stage air volume increasing fan air volume control data and the second stage air volume increasing fan air volume control data on the classification side different from the air volume control data used for ignition. A combustion apparatus provided with an ignition retry control unit that performs ignition using data. Burner for burning fuel, ignition means for igniting the burner, flame detection sensor for detecting the flame of the burner, combustion fan for supplying and exhausting burner combustion, and air volume control for controlling the air volume of the combustion fan In the combustion apparatus, the standard air flow control data for normal combustion operation is included in the air flow control unit, and the first stage air flow increasing fan air flow in which the fan air flow is increased from the standard fan air flow control data. A plurality of fan air volume control data including control data and second stage air volume increasing fan air volume control data obtained by increasing the fan air volume from the first stage air volume increasing fan air volume control data is provided. Fan air volume control data includes fan air volume control data for increasing the first stage air volume. As the air volume control data, the fan air volume control data including the second stage air volume increasing fan air volume control data is classified as strong air pressure side air volume control data. An air volume control data monitoring storage unit for monitoring and storing which fan air volume control data is used, a time measuring means for measuring the time elapsed after the stop of combustion, and a judgment criterion given in advance from the stop of the combustion When the combustion operation is resumed before the time elapses, ignition is performed using the fan air volume control data used when the combustion operation was stopped in the previous combustion operation, and when the flame goes out, the air volume control data used for the ignition is The air volume control on one side of the first stage air volume increasing fan air volume control data and the second stage air volume increasing fan air volume control data of different classification sides. Combustor ignition retry control unit for performing the ignition using the chromatography data is provided. A fan is provided with a threshold value on the lower side of the detection signal level of the flame detection sensor, and switches the fan air volume control data to the fan air volume control data on the air volume down side when the detection signal level of the flame detection sensor falls below the threshold value. An air flow control data switching unit is provided, and the air flow control data monitoring storage unit takes a time required for the detection signal level of the flame detection sensor to drop to the combustion stop level after passing the threshold level when combustion is stopped. The air volume control data monitoring storage unit uses the fan air volume control data used at the combustion time before the combustion stop time as the fan air volume control data used at the time of combustion stop. The combustion apparatus according to claim 2, wherein the combustion apparatus is configured to memorize. A CO sensor that detects the CO concentration in the exhaust gas is installed on the exhaust side of the combustion device, and the fan air volume control data increases as the CO concentration detected by the CO sensor increases during the combustion operation after burner ignition. The combustion apparatus according to claim 1, 2 or 3, wherein a fan air volume control data switching controller for switching to the side is provided. The flame detection sensor is formed by a frame rod, which captures the flame rod current output from the flame rod during combustion operation after burner ignition, and the fan air volume when the flame rod current exceeds the preset upper threshold value. A fan air volume control data switching control unit is provided that switches the control air flow to the air volume up side and switches the fan air volume control data to the air volume down side when the frame rod current exceeds a preset lower threshold value. The combustion apparatus according to claim 1, claim 2, or claim 3. The flame detection sensor is formed by a frame rod, captures the flame rod current output from the flame rod during combustion operation after burner ignition, and the rise change reference value within a preset reference time for the rise change amount of the flame rod current The fan air volume control data is switched to the air volume up side when the air pressure exceeds, and the fan air volume control data is switched to the air volume down side when the frame rod current descent change exceeds the descent change reference value within the preset reference time. The combustion apparatus according to claim 1, 2 or 3, wherein a fan air volume control data switching control section for switching to is provided. The flame detection sensor is formed by a frame rod, captures the flame rod current output from the flame rod during combustion operation after burner ignition, and the rise change reference value within a preset reference time for the rise change amount of the flame rod current When the air flow exceeds the fan air flow control data, the fan air flow control data is switched to the air flow up side. 4. A combustion apparatus according to claim 1, further comprising a fan air volume control data switching control section for switching the fan air volume control data to the air volume increasing side when the lowering change reference value is exceeded. The flame detection sensor is formed by a frame rod, and the fan air volume control data switching control unit has a basic function for switching the fan air volume control data to the air volume up side as the CO concentration increases, and an upper side where the frame rod current is set in advance. When the threshold value is exceeded, the fan air volume control data is switched to the air volume up side. When the frame rod current exceeds the preset lower threshold value, the fan air volume control data is set to the air volume down side. A function for switching, a function for switching the fan air volume control data to the air volume increasing side when the frame rod current rising change amount exceeds the rising change reference value within a preset reference time, and a frame rod current falling change amount When the airflow exceeds the descent change reference value within the preset reference time, the fan airflow control data is downloaded. And a change amount of the frame rod current, and the amount of change in the decrease in the frame rod current exceeds the reference value of the change in decrease that is set in advance within a minute setting time narrower than the reference time for judging the amount of change in the increase in the frame rod current. Sometimes it has one or more additional functions with the function of switching the fan air volume control data to the air volume up side, and in addition to the basic function during combustion operation within the low combustion capacity range below the specified value within the combustion heat amount control range The combustion apparatus according to claim 4, wherein the fan air volume control data is switched and controlled by a combination of functions.

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