JP2857324B2 - 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 burner amount 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. The number of revolutions of the combustion fan for supplying the combustion air is controlled to an instructed number of revolutions determined according to the required amount of combustion, and the fuel to the burner is controlled according to the required amount of combustion or the actual number of revolutions of the combustion fan. What controls the opening degree of the proportional valve provided in the supply path is generally known.

[0003] This type of combustion apparatus is based on the premise that the rotation speed of the combustion fan and the air flow (air supply amount) from the combustion fan to the burner always correspond to each other in a fixed relationship. Although it is controlled to the instructed number of revolutions, in actuality, if the intake and exhaust ports of the combustion chamber containing the burner are clogged, the load on the combustion fan changes from the initial normal case. Even if the number of revolutions of the combustion fan is the same, the actual air flow from the combustion fan to the burner changes as compared with a normal case.

For this reason, in recent years, the actual air flow to the burner has been detected from time to time by an air flow sensor disposed in an air passage from the combustion fan to the burner, and the detected air flow has been set at a set air flow corresponding to the required combustion amount of the burner. A method of controlling the number of revolutions of a combustion fan so as to correspond to (for example, Japanese Utility Model Laid-Open No. 1-129561, Japanese Utility Model Application Laid-open No.
No. 143251).

By controlling the number of revolutions of the combustion fan using the air flow sensor as described above, even if the air supply and exhaust ports of the combustion chamber are clogged to some extent, the air flow corresponding to the required combustion amount of the burner can be reduced. Although it can be supplied from the combustion fan to the burner, the following inconvenience occurs particularly when the clogging of the exhaust port progresses to some extent.

That is, for example, in a gas water heater, when the exhaust port is clogged to some extent, the exhaust in the combustion chamber is not smoothly performed, and the pressure in the combustion chamber increases. In this case, by controlling the combustion fan using the air flow sensor so that the air flow from the combustion fan to the burner matches the set air flow as described above, the air flow to the burner corresponds to the required combustion amount of the burner. Although you can,
Even if the opening degree of the proportional valve is controlled to supply the fuel gas corresponding to the air volume to the burner, the pressure in the combustion chamber becomes higher than the pressure of the fuel gas, so that the fuel gas is not easily ejected from the burner. Become. For this reason, it is difficult for the burner to be supplied with an amount of fuel gas corresponding to the amount of air supplied to the burner, making it difficult to obtain an appropriate amount of combustion, and possibly causing incomplete combustion. Further, when the exhaust port is clogged to a certain extent, a part of the exhaust gas may leak from the combustion chamber to an inappropriate location such as indoors without being exhausted to an appropriate location such as outdoors through the exhaust port. is there.

Therefore, when the exhaust port of the combustion chamber is clogged, it is automatically grasped by any method.
It was desired to stop the combustion operation. In addition, even if the air supply port is clogged to some extent, the above-described inconvenience does not occur even if the air supply port proceeds to some extent, and therefore, it is preferable to continue the combustion operation.

Based on the above background, the present inventors have studied the relationship between the number of revolutions of the combustion fan and the actual air flow when the exhaust port and the air supply port are clogged. Such knowledge was obtained.

That is, the relationship between the number of revolutions of the combustion fan and the actual air volume is such that there is no clogging of the exhaust port and the air supply port.
In a normal state, the relationship is as shown by a solid line a in FIG. When the exhaust port or the air supply port is clogged, for example, the relationship shown by a solid line b in FIG. 5 is obtained, and the air volume at an arbitrary rotation speed is smaller than that in a normal case (solid line a). Become. In this case, the slope of the solid line b (the value of the ratio of the air flow rate to the number of rotations) basically decreases as the degree of clogging of the exhaust port and the air supply port increases, but this tendency is
The same applies to the case where the exhaust port and the air supply port are clogged.

On the other hand, in a single combustion operation, when the air supply port is clogged, the relationship between the number of revolutions of the combustion fan and the actual air volume does not change much from the beginning to the end of the combustion operation. However, in the case of clogging of the exhaust port, the relationship between the number of revolutions of the combustion fan and the actual air volume was, for example, a relationship shown by a solid line b at the beginning of the combustion operation, but the combustion operation proceeds. Then, for example, a relationship shown by a virtual line c in FIG. 5 is obtained. That is, in the case of clogging of the exhaust port, the air volume at an arbitrary rotation speed drops relatively more at the stage where the combustion operation has progressed than at the initial stage of the combustion operation, and the rotation speed and the air volume of the combustion fan. The slope of the straight line indicating the relationship of (1), when the combustion operation has progressed to some extent, decreases relatively more than in the initial stage of the combustion operation.
The reason is considered as follows. That is, as the combustion operation proceeds, the temperature in the combustion chamber increases significantly from the initial stage of the combustion operation, and the exhaust gas expands. When the exhaust port is clogged, the exhaust resistance also increases greatly, the load on the combustion fan increases, and the air volume at an arbitrary rotation speed decreases relatively more than in the initial stage of the combustion operation. On the other hand, when the air supply port is clogged, the exhaust gas is smoothly discharged. Therefore, even if the combustion operation proceeds, the temperature of the exhaust gas does not increase so much as compared with the initial stage of the combustion operation, and the combustion fan The relationship between the rotational speed and the actual air volume does not change much from the beginning to the end of the combustion operation.

Therefore, during the combustion operation, the actual air flow at an arbitrary predetermined rotational speed or the value of the ratio of the air flow to the rotational speed is monitored in the initial stage of the combustion operation and at a stage where the combustion operation has progressed to some extent, and the change is observed. It is considered that the clogging of the exhaust port can be grasped separately from the clogging of the air supply port.

[0012]

SUMMARY OF THE INVENTION The present invention has been made in view of the above background, and is directed to a combustion apparatus for controlling the number of revolutions of a combustion fan so that the airflow detected by an airflow sensor matches a set airflow. An object of the present invention is to provide a combustion device capable of grasping a clogged port by distinguishing it from a clogged air supply port and performing an appropriate operation accordingly.

[0013]

In order to achieve the above object, a first aspect of the present invention is to provide a combustion chamber containing a burner, an air supply port and an exhaust port communicating with the combustion chamber, and the burner. A combustion fan provided on the air supply port side to blow combustion air to the air supply, an air flow sensor for detecting an air flow from the combustion fan to the burner, and a detection detected by the air flow sensor during the combustion operation of the burner. A fan control means for controlling the number of revolutions of the combustion fan so that the air volume matches a set air volume for obtaining a required combustion amount of the burner. An initial detection air volume obtained by the air volume sensor corresponding to the predetermined rotation speed and a subsequent rotation speed of the combustion fan corresponding to the predetermined rotation speed of the combustion fan during the combustion of the burner thereafter. Means for calculating the amount of change between the detected air volume during combustion obtained and the amount of change between the initial detected air volume and the detected air volume during combustion obtained by the air volume change amount calculating means. And operation stop means for stopping the combustion operation when the pressure exceeds the limit.

The fan control means includes storage means for storing in advance the relationship between the air flow rate and the number of revolutions of the combustion fan when the load of the combustion fan is normal as reference data, and the reference value during combustion operation of the burner. Reference rotation speed setting means for obtaining a reference rotation speed of the combustion fan corresponding to the set air flow based on data, and deviation calculation means for obtaining a deviation between the set air flow and a detection air flow obtained by the air flow sensor, By controlling the rotation speed of the combustion fan with the reference rotation speed as a reference designated rotation speed and correcting the rotation speed of the combustion fan according to the deviation between the set airflow and the detected airflow, the detected airflow is set to the set value. The combustion fan is controlled so as to match the air flow rate, and the air flow rate change amount calculation means calculates the reference rotation speed at the beginning of the combustion operation of the burner. An initial deviation obtained by the deviation calculating means in response to a predetermined set airflow at which the predetermined rotation speed is obtained; and an in-combustion deviation obtained by the deviation calculating means in correspondence to the predetermined set airflow during combustion of the burner. Is obtained as a change amount between the initial detected air volume and the detected air volume during combustion.

Further, the fan control means includes means for controlling the number of revolutions of the combustion fan to the predetermined number of revolutions at an early stage of the start of the combustion operation. Means for giving the obtained air volume as the predetermined set air volume to the deviation calculation means, wherein the air volume change amount calculation means is provided when the combustion fan is controlled to the predetermined rotation speed at the beginning of the combustion operation. Means for obtaining the deviation output from the deviation calculating means as the initial deviation; and, during subsequent combustion of the burner, the fan control means sets the combustion at the reference rotational speed corresponding to the set airflow for obtaining the required combustion amount. The difference (N0 / Nx) of the ratio between the reference rotation speed (Nx) and the predetermined rotation speed (N0) is added to the deviation output from the deviation calculating means when the fan is controlled. Characterized in that it comprises a means for determining the combustion deviation by multiplying.

Alternatively, the fan control means includes means for controlling the number of revolutions of the combustion fan to the predetermined number of revolutions at an early stage of the start of the combustion operation. Means for obtaining, as the initial detected airflow, the airflow detected by the airflow sensor when the combustion fan is controlled to the predetermined rotation speed, and the actual rotation speed (N) of the combustion fan during subsequent combustion of the burner.
x) and the value of the ratio (N0 / Nx) of the predetermined rotation speed (N0).
) Is multiplied by the airflow detected by the airflow sensor at the actual rotation speed (Nx) to obtain the airflow detected during combustion.

Further, the fan control means controls the rotation speed of the combustion fan to the predetermined rotation speed at the time of pre-purge or at the time of slow ignition of the burner.

According to a second aspect of the present invention, there is provided a combustion chamber accommodating a burner, an air supply port and an exhaust port communicating with the combustion chamber, and A combustion fan provided on the air supply port side to blow air, an air volume sensor for detecting an air volume from the combustion fan to the burner, and a detected air volume detected by the air volume sensor during a combustion operation of the burner. A fan control means for controlling the number of revolutions of the combustion fan to match a set air volume for obtaining a required combustion amount of the burner, wherein the air volume sensor detects the number of revolutions of the combustion fan during the combustion operation. A first calculating means for obtaining a value of a ratio of the detected air flow; a ratio value (H0) obtained by the first calculating means at an initial stage of the combustion operation of the burner; Second determining the amount of change between the resulting ratio value (H1) by the first computing means in the medium
And operation stop means for stopping the combustion operation when the variation of the ratio value (H0, H1) obtained by the second calculation means exceeds a predetermined amount. And

Further, the value of the ratio (H0) at the beginning of the start of the combustion operation of the burner is a value of the ratio at the time of prepurge or at the time of slow ignition of the burner.

[0020]

In the first aspect of the present invention, when the exhaust port is clogged and has progressed to some extent, the detected air volume obtained by the air volume sensor at an arbitrary rotation speed of the combustion fan is: As the combustion operation progresses, the detected air volume decreases relatively significantly with respect to the initial detected air volume of the combustion operation.
Therefore, the amount of change between the initial detected air volume and the in-combustion detected air volume at the predetermined rotation speed becomes large, and when the amount of change exceeds a predetermined amount, the exhaust port clogging proceeds to some extent, and the combustion operation is started. Can be determined to be in a state that may cause trouble. In such a case, by stopping the combustion operation by the operation stop means, a situation in which an inappropriate combustion operation is performed is eliminated.
When the exhaust port is normal and the air supply port is clogged, the amount of change between the initial detected air volume and the detected air volume during combustion is not so large, and stays below the predetermined amount. . Therefore, at this time, the combustion operation continues without stopping. In this case, the combustion operation is properly performed by controlling the rotation speed of the combustion fan so that the detected air volume obtained by the air volume sensor matches the set air volume.

In this case, the control by the fan control means for making the air volume detected by the air volume sensor coincide with the set air volume during the combustion operation is performed, for example, by comparing the air volume and the rotation speed of the combustion fan when the load of the combustion fan is normal. The relationship is stored and held in advance as reference data, and the combustion fan is controlled with the reference rotation speed determined in accordance with the set airflow based on the reference data during the combustion operation as the reference designated rotation speed. This is performed by correcting the rotational speed of the combustion fan in accordance with the deviation between the combustion fan and the detected air flow. In this case, in the initial stage of the start of the combustion operation of the burner, the deviation obtained by the deviation calculation means corresponding to a predetermined set airflow at which the reference rotation speed becomes the predetermined rotation speed of the combustion fan and the combustion of the burner The difference between the initial detected air volume and the detected air volume during combustion is determined as the change between the detected air volumes by calculating the difference between the detected air volume and the difference obtained by the deviation calculating means in accordance with the predetermined set air volume. Desired. That is, for example, when the predetermined set air volume is given to the fan control means at the beginning of the combustion operation, the fan control means first controls the rotation speed of the combustion fan to the predetermined rotation speed, and at this time, calculates the deviation The initial deviation obtained by the means is a deviation between the predetermined set airflow and the initial detected airflow. Similarly, when the predetermined set air volume is given to the fan control means during combustion, the fan control means first controls the rotation speed of the combustion fan to the predetermined rotation speed, and at this time, the deviation calculation means Is the deviation between the predetermined set airflow and the detected airflow during combustion. Accordingly, the difference between these deviations is the difference between the initial detected air volume and the detected air volume during combustion, which corresponds to the amount of change between the two detected air volumes. With this configuration, the deviation calculation means of the fan control means for performing control for matching the detected air volume of the air volume sensor to the set air volume is effectively used to obtain a change amount (difference) between the initial detected air volume and the detected air volume during combustion. Be utilized.

Further, the fan control means controls the number of revolutions of the combustion fan to the predetermined number of revolutions at an early stage of the combustion operation, and the control data corresponds to the predetermined number of revolutions at the time of the control. Means for giving the obtained air volume as the predetermined set air volume to the deviation calculation means, first, when the combustion fan is controlled to the predetermined rotation speed at the beginning of the combustion operation, the deviation calculation means The output deviation is obtained as the initial deviation. During the subsequent combustion, the set air volume for obtaining the required combustion amount is given to the fan control unit, and the fan control unit adjusts the rotation speed of the combustion fan so that the air volume detected by the air volume sensor matches the set air volume. Control. In this case, in general, the set airflow for obtaining the required combustion amount is different from the predetermined set airflow. Therefore, when the set airflow for obtaining the required combustion amount is given to the fan control unit, the fan control unit Although the rotation speed of the combustion fan to be controlled (= reference rotation speed) is not always the predetermined rotation speed, the deviation between the set airflow and the detected airflow obtained by the deviation calculating means at that time is determined by the rotation of the combustion fan. It is almost proportional to the number (see FIG. 5). Therefore, when obtaining the deviation during combustion, the deviation output from the deviation calculation means when the combustion fan is controlled to the reference rotation speed corresponding to the set air flow for obtaining the required combustion amount by the fan control means. By multiplying a ratio value (N0 / Nx) between the reference rotation speed (Nx) and the predetermined rotation speed (N0), the deviation during combustion can be estimated by a proportional calculation. Then, by comparing the difference between the in-combustion deviation thus obtained and the initial deviation with the predetermined amount, the clogging of the exhaust port is grasped. In addition, if the deviation during combustion is obtained by the calculation as described above, during combustion of the burner, combustion is performed such that a set airflow corresponding to the required combustion amount is always obtained regardless of the predetermined set airflow and the predetermined rotation speed. It is possible to control the rotation speed of the fan.

In the first aspect of the present invention, the amount of change between the initial detected air volume and the air volume during combustion is obtained without using the deviation obtained by the deviation calculating means of the fan control means as described above. It is also possible. That is, the initial detected airflow is obtained by the airflow sensor by controlling the rotation speed of the combustion fan to the predetermined rotation speed at the beginning of the combustion operation. As for the detected air volume during combustion, the actual air volume of the combustion fan at any time during the combustion of the burner is substantially proportional to the rotation speed (see FIG. 5). Therefore, if the detected air volume of the air volume sensor at a certain point during combustion is multiplied by the value (N0 / Nx) of the ratio of the actual rotation speed (Nx) of the combustion fan at that time to the predetermined rotation speed (N0), By the calculation, the detected air volume during combustion at the predetermined rotational speed (N0) is estimated. Then, by comparing the amount of change between the detected combustion air volume thus obtained and the initial detection air volume with the predetermined amount,
As described above, it is possible to grasp the clogging of the exhaust port. Further, if the detected air volume during combustion is obtained by the calculation as described above, during the combustion of the burner, the set air volume corresponding to the required combustion air volume is always irrespective of the predetermined rotation speed for obtaining the detected air volume during combustion. It is possible to control the number of revolutions of the combustion fan so that it can be obtained. The detected air volume during combustion can be obtained from the air volume sensor by controlling the rotation speed of the combustion fan to the predetermined rotation speed, for example, as needed during the combustion of the burner.

In the early stage of the combustion operation, the control of the number of revolutions of the combustion fan to the predetermined number of revolutions is preferably performed at the time of prepurge or at the time of slow ignition of the burner. With this configuration, after the combustion of the burner is started in order to obtain the initial detected air volume, the appropriate air volume control of the combustion fan is performed by the fan control unit, so that the initial detected air volume is obtained at a suitable timing. It becomes possible.

Next, in a second aspect of the present invention, when the exhaust port is clogged and progresses to some extent, the ratio of the ratio of the air volume detected by the air volume sensor to the rotation speed of the combustion fan is determined. The value, that is, the slope of the straight line indicating the relationship between the number of revolutions of the combustion fan and the air flow rate, decreases relatively significantly with respect to the initial detected air flow rate of the combustion operation as the combustion operation proceeds. Therefore, the amount of change between the value of the ratio (H0) at the beginning of the combustion operation and the value of the ratio (H1) during the subsequent combustion of the burner becomes large, and the amount of change exceeds a predetermined amount. In this case, it can be determined that the exhaust port clogging progresses to some extent, which may hinder the combustion operation. In such a case, by stopping the combustion operation by the operation stop means, a situation in which an inappropriate combustion operation is performed is eliminated. In this case, since the ratio values (H0, H1) do not depend on the rotation speed of the combustion fan, the ratio values (H0, H1)
Is determined, the rotation speed of the combustion fan may be arbitrary. When the exhaust port is normal and the air supply port is clogged, the value of the ratio of the detected air volume to the rotation speed does not change much between the initial stage of the combustion operation and the subsequent combustion. The amount of change in the value of the ratio between the two remains below the predetermined amount. Therefore, at this time, the combustion operation continues without stopping. In this case, the combustion operation is properly performed by controlling the rotation speed of the combustion fan so that the detected air volume obtained by the air volume sensor matches the set air volume.

The value of the ratio (H0) at the initial stage of the start of the combustion operation of the burner is, for example, the value of the ratio at the time of pre-purge or at the time of mild ignition of the burner, as in the first embodiment. , At an appropriate timing, the value of the ratio (H
0) is obtained.

[0027]

1 and 2 show an example of the first embodiment of the present invention.
A description will be given with reference to FIG. FIG. 1 is a system configuration diagram of the combustion apparatus of the present embodiment, and FIG. 2 is a block configuration diagram of a main part of the apparatus of FIG.

Referring to FIG. 1, a combustion apparatus according to the present embodiment is a water heater, 1 is a water heater body including a heat exchanger 2 and a burner 3 for heating the same, 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;
Reference numerals 8 and 9 denote an opening / closing solenoid valve and a gas proportional valve interposed in the gas supply pipe 7 in order from the upstream side, 10 denotes a combustion fan that blows combustion air to the burner 3, and 11 denotes a fan motor that drives the combustion fan 10. , 12 is a rotation speed sensor composed of a Hall element or the like for detecting the rotation speed of the combustion fan 10, 13 is an air flow sensor for detecting the air flow from the combustion fan 10 to the burner 3, and 14 is An operation unit 15 for performing settings and the like is provided with a fan motor 11, an electromagnetic valve 8, and a gas proportional valve in accordance with a set temperature of hot water set by the operation unit 14 and detection signals of the sensors 5, 6, 12, and 13. A controller for controlling the valve 9 and the like, 16 is an igniter for igniting the burner 3, and 17 is a flame rod for detecting a combustion state such as the presence or absence of misfire of the burner 3.

The burner 3 is accommodated in a combustion chamber 18 formed in the water heater main body 1 below the heat exchanger 2, and the combustion chamber 18 has an exhaust port 19 provided in an upper part of the water heater main body 1.
And an air supply port 20 provided at a lower portion thereof communicate with each other. The combustion fan 10 is provided on the side of the air supply port 20, and the air volume sensor 13 is disposed in an air passage 21 extending from the air supply port 20 to the combustion chamber 18.

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. In addition, the air volume sensor 13
For example, a hot wire type air flow sensor is used. In addition, the air volume sensor
In addition to the hot wire type, there are a thermal type, a Karman vortex type, a vane type, and the like.

Referring to FIG. 2, the controller 15 is constituted by an electronic circuit including a microcomputer and the like, and has a functional configuration that includes a set temperature given from the operation unit 14 and an incoming water temperature sensor ( (Not shown), the required amount of combustion of the burner 3 required to make the hot water temperature match the set temperature from the hot water temperature detected by the temperature sensor 6 and the hot water temperature detected by the temperature sensor 6. And a required amount of combustion calculated by the calculation unit 22, and an air volume (amount of supply of combustion air) from the combustion fan 10 to the burner 3 corresponding to the required amount of combustion determined by the calculation unit 22
And a fan control unit that controls the number of revolutions of the combustion fan 10 via the fan motor 11 in accordance with the detected air volume detected by the air volume sensor 13 and the set air volume set by the air volume setting unit 23. 24, a valve control unit 25 for controlling the degree of gas supply to the burner 3 by controlling the degree of opening of the gas proportional valve 9 according to the number of revolutions of the combustion fan 10 detected by the revolution number sensor 12, and the like. The air volume detected by the air volume sensor 13 (initial detected air volume) at the beginning of the operation (hot water supply operation) and the air volume sensor 1 during the combustion of the burner 3
3 is obtained by an air volume change amount calculation unit (air volume change amount detection means) 26 for obtaining a difference from the detected air volume (air volume detected during combustion) as a change amount between the detected air volumes, and an air volume change amount calculation unit 26. The stop command unit 27 that stops the combustion fan 10 via the fan control unit 24 and shuts off the gas supply to the burner 3 via the solenoid valve 8 according to the difference between the initial detected air volume and the combustion detected air volume. And

Here, corresponding to the configuration of the first embodiment of the present invention, the fan control section 24 constitutes a fan control means 28 in combination with the fan motor 11 and the rotation speed sensor 12, and the stop command section 27 is provided with an electromagnetic The operation stop means 27a is configured together with the valve 8 and the fan control unit 24. The fan controller 24 includes a deviation calculator (deviation calculator) 2 for calculating a deviation between the set air volume and the air volume detected by the air volume sensor 13.
9, a storage unit (storage means) 30 in which reference data indicating the relationship between the air flow rate and the rotation speed of the combustion fan 10 in a normal state is stored in advance, and the combustion fan corresponding to the set rotation speed based on the reference data. A reference rotation speed setting unit (reference rotation speed setting means) 31 for obtaining a reference rotation speed of 10 and a correction unit 32 for correcting the rotation speed of the combustion fan 10 according to the deviation obtained from the deviation calculation unit 29. ing.
The reference data stored and held in the storage unit 30 is the data indicated by the solid line a in FIG.

Further, the air volume change amount calculating section 26 includes an initial deviation extracting section 33 for extracting a deviation (initial deviation) obtained from the deviation calculating section 29 at the beginning of the combustion operation, and a deviation calculating section during the combustion of the burner 3. During-combustion deviation extracting unit 34 for extracting the deviation obtained from the unit 29 to obtain the during-combustion deviation
And a subtraction unit 35 for calculating the difference between the initial deviation and the combustion deviation as the difference between the initial detected air volume and the combustion detected air volume.
And

When the flow of water through the water pipe 4 is started, the controller 15 detects this through the flow rate sensor 5, and
In response to the detection of the water flow, the combustion fan 10 is rotationally driven by the fan control unit 24 via the fan motor 11, and the solenoid valve 8 of the gas supply pipe 7 is opened to start gas supply to the burner 3. Further, the burner 3 is ignited via the igniter 16, thereby starting the combustion operation (hot water supply operation) of the burner 3. At this time, prior to the ignition of the burner 3, the fan control unit 24
Is rotated at a predetermined rotation speed (about 50% of the maximum rotation speed) for a certain period of time to perform pre-purge, and subsequently, moderate ignition of the burner 3 is performed.

When it is detected that the flow of water through the water pipe 4 has stopped, the controller 15 closes the solenoid valve 8 to cut off the gas supply to the burner 3, and the fan control unit 24 controls the combustion by the fan control unit 24. The fan 10 is stopped, and the hot water supply operation is stopped. The operation of ending the hot water supply operation is performed in the same manner when the flame rod 17 detects misfire of the burner 3 during the hot water supply operation.

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

As described above, when starting the hot water supply operation,
The controller 15 causes the fan control unit 24 to rotate the combustion fan 10 at a predetermined rotation speed N0 shown in FIG.
In this state, pre-purge and mild ignition of the burner 3 are performed. At this time, the air volume setting unit 23 gives the set air volume Fa0 corresponding to the predetermined rotation speed N0 to the deviation calculation unit 29 of the fan control unit 24 in the reference data indicated by the solid line a in FIG.
The deviation calculator 29 calculates a deviation between the set air volume Fa0 and the detected air volume obtained by the air volume sensor 13 at this time. In this case, if the air supply port 20 or the exhaust port 19 is clogged, the relationship between the rotation speed of the combustion fan 10 and the air flow rate is, for example, as shown by a solid line b in FIG. At this time, the detected air volume is “Fb0” (<Fa0), and the deviation calculated by the deviation calculating unit 29 is (Fa0−
Fb0).

The initial deviation extracting unit 33 of the air volume change amount computing unit 26 calculates the deviation (Fa0-Fb0) obtained by the deviation computing unit 29 at the time of prepurge, for example, at the beginning of the hot water supply operation (combustion operation). The deviation is extracted and stored in a memory (not shown).

Next, when the burner 3 is ignited and the combustion operation is started, the controller 15 causes the necessary combustion amount calculation unit 22 to change the tapping temperature detected by the temperature sensor 6 to the set temperature set by the operation unit 14. The required combustion amount of the burner 3 required to make them coincide with each other is obtained from time to time on the basis of input water temperature, outlet water temperature, flow rate detection data, and the like. Further, the air volume setting unit 23 of the controller 15 sets the air volume from the combustion fan 10 to the burner 3 corresponding to the required combustion amount calculated by the required combustion amount calculation unit 22 according to a predetermined data table or the like, and sets the air volume. Fan control unit 24
Give to.

At this time, the fan control unit 24 sets the given setting based on the reference data (data indicated by the solid line a in FIG. 5) stored in the storage unit 30 by the reference rotation speed setting unit 31. The reference fan speed corresponding to the air volume is set to the combustion fan 1
It is set as the reference instruction speed of 0. Specifically, FIG.
, When the given set airflow is “Fax”, the reference rotation speed Nx is set as the reference instruction rotation speed. The fan control unit 24 basically feeds back the rotation speed of the combustion fan 10 while monitoring the actual rotation speed of the combustion fan 10 with the rotation speed sensor 12 such that the rotation speed of the combustion fan 10 becomes the reference designated rotation speed Nx. Control.

In this case, if the exhaust port 19 and the air supply port 20 are not clogged and the load of the combustion fan 10 is normal, the detected air volume obtained by the air volume sensor 13 is obtained by performing the above control. That is, the actual air volume to the burner 3 is the set air volume Fax. However, the exhaust port 19
And the air supply port 20 is clogged, and the relationship between the rotation speed of the combustion fan 10 and the air volume is, for example, a relationship shown by a solid line b in FIG. Even if it is controlled to the reference rotation speed Nx, the airflow sensor 13
Is “Fbx” (<Fax).
It does not match the set air volume Fax. Then, in such a case, the fan control unit 24 determines the deviation (Fax-Fax−) between the set airflow amount Fax obtained by the deviation calculation unit 29 and the detected airflow amount Fbx.
Fbx), the correction unit 32 corrects the rotation speed of the combustion fan 10 based on the reference instruction rotation speed Nx,
As a result, the rotation speed of the combustion fan 10 is corrected and controlled to a rotation speed Nxb (see FIG. 5) such that the detected airflow finally matches the set airflow Fax.

On the other hand, the valve controller 25 of the controller 15
Controls the amount of gas supplied to the burner 3 by controlling the opening of the gas proportional valve 9 in parallel with the control of the combustion fan 10 as described above. In this case, basically, the valve control unit 2
5 is a combustion fan 1 detected by the rotation speed sensor 12.
The opening of the gas proportional valve 9 is controlled in accordance with the actual rotation speed of zero. Therefore, when the exhaust port 19 is not clogged and the load of the combustion fan 10 is normal, the rotation speed of the combustion fan 10 and the actual air volume correspond to each other. By controlling the opening degree of the gas proportional valve 9 in accordance with the rotation speed of the fan 10, the gas supply amount to the burner 3 corresponds to the air flow to the burner 3 controlled to the set air flow, and the burner 3 Burns with the required amount of combustion.

However, for example, the exhaust port 19 and the air supply port 20
Is blocked, the rotation speed of the combustion fan 10 is controlled so that the detected air volume and the set air volume match as described above. The rotation speed of the fan 10 increases and decreases. Therefore, if the opening degree of the gas proportional valve 9 is simply controlled in accordance with the rotation speed of the combustion ann 10, even if the air volume to the burner 3 is the same,
The degree of opening of the gas proportional valve 9 changes in accordance with the rotation speed of the combustion fan 10, and the amount of gas supplied to the burner 3 changes.

Therefore, the valve control unit 27 of the controller 14
When the detected airflow of the airflow sensor 13 is smaller than the set airflow to cancel the correction of the rotation speed of the combustion fan 10, the rotation speed of the combustion fan 10 is increased by the fan control unit 24. The opening of the valve 9 is determined by the combustion fan 10
The opening degree according to the number of rotations, and in the opposite case,
The opening of the gas proportional valve 9 is made larger than the opening corresponding to the rotation speed of the combustion fan 10. As a result, the amount of gas supplied to the burner 3 corresponds to the actual air volume (detected air volume) to the burner 3, and the burner 3 burns smoothly with the required combustion amount.

During such a combustion operation, the in-combustion deviation extraction unit 34 of the air volume change amount calculation unit 26 uses the fan control unit 24 to control the combustion fan 10 to operate the reference rotation speed corresponding to the set air volume as described above. Is the reference instruction speed,
When the engine speed is controlled to the reference rotation speed, the combustion deviation extracting unit 34 at that time extracts a deviation between the set air volume and the detected air volume obtained by the deviation computing unit 29, and performs the combustion during combustion as described below from the deviation. Find the deviation. That is, referring to FIG. 5, at a certain point during the above-described combustion operation, the relationship between the rotation speed of the combustion fan 10 and the air flow rate is caused by clogging of the exhaust port 19 and the like, for example, as shown by a virtual line c in FIG. 5. In this state, if, for example, the set air volume Fax is given to the fan control unit 24, the fan control unit 24
The number of revolutions of the combustion fan 10 is controlled to the reference number of revolutions Nx corresponding to the set air volume Fax. At this time, the air volume sensor 13
Is “Fcx”, and the deviation calculated by the deviation calculating unit 29 is (Fax−Fcx). This deviation (Fax
−Fcx) is extracted by the in-combustion deviation extracting unit 34. The in-combustion deviation extracting unit 34 calculates the rotational speed of the combustion fan 10 (= reference rotational speed Nx) detected by the rotational speed sensor 12 and the initial deviation calculation at the start of the combustion operation as described above. The initial deviation (Fa0-F)
The value (N0 / Nx) of the ratio to the predetermined rotational speed N0 of the combustion fan 10 at the time when b0) is extracted is obtained, and the value of the ratio (N0 / Nx) is further obtained.
0 / Nx) is multiplied by the deviation (Fax-Fcx), and the value obtained by the multiplication is obtained as the deviation during combustion. As is apparent with reference to FIG. 5, the deviation during combustion obtained in this manner is the current state (the state of the virtual line c in FIG. 5).
In the above, the deviation obtained by the deviation calculating unit 29 when the rotation speed of the combustion fan 10 is controlled to the predetermined rotation speed N0 at the set airflow rate Fa0 at the time of extracting the initial deviation (Fa0-Fb0) is calculated by a proportional calculation. It is obtained presumably. Accordingly, the deviation during combustion is represented by Fc0 assuming that the detected airflow of the airflow sensor 13 when the combustion fan 10 is driven at the predetermined rotation speed N0 in the state of the virtual line c in FIG.
(Fa0-Fc0).

When the in-combustion deviation (Fa0-Fc0) is obtained in this manner, the air volume change amount calculating section 26 then calculates the initial deviation (Fa0) obtained by the initial deviation calculating section 33 as described above.
−Fb0) is subtracted by the subtraction unit 35 from the deviation during combustion (Fa0−Fc0). The value obtained by this subtraction is (Fb0−F
c0), the detected air volume Fb0 obtained by the air volume sensor 13 when the rotation speed of the combustion fan 10 is set to the predetermined rotation speed N0 at the start of the combustion operation, and the rotation speed of the combustion fan 10 during combustion of the burner 3. It shows the difference from the detected airflow Fc0 obtained by the airflow sensor 13 when the predetermined rotation speed N0 is set.

In this combustion operation, if the exhaust port 19 is clogged, as described above, the inclination of the straight line indicating the relationship between the rotation speed of the combustion fan 10 and the air flow, or an arbitrary rotation speed When the combustion operation of the burner 3 progresses, the air flow at the point (A) decreases relatively significantly compared to the case of the initial stage of the combustion operation. The relationship shown by the solid line b in FIG. 5 at the time of the obtained prepurge is changed to the relationship shown by the virtual line c in FIG. 5, for example, during combustion.

Therefore, in such a case, the difference between the detected air volume Fb0 and the detected air volume Fc0 obtained by the subtractor 35 becomes relatively large.

On the other hand, when the exhaust port 19 is not clogged or the degree of the clogging is small and the air supply port 20 is clogged, the relationship between the number of revolutions of the combustion fan 10 and the air volume is determined by the combustion operation. Does not change so much from the beginning of the process, the difference between the detected air volume Fb0 and the detected air volume Fc0 obtained by the subtracting section 35 is relatively small. This is also true in a case where there is no clogging of both the exhaust port 19 and the air supply port 20 and the port is normal.

Therefore, the stop command unit 2 of the controller 15
7 compares the difference (Fb0-Fc0) between the detected air volume Fb0 and the detected air volume Fc0 obtained by the subtractor 35 with a predetermined value, and the difference (Fb0-Fc0) exceeds the predetermined value. In this case, the solenoid valve 8 is closed and the burner 3
Gas supply to the fan control unit 24
The operation of the water heater is stopped through the combustion fan 10 via this. As a result, in a state in which the clogging of the exhaust port 19 has progressed to some extent and there is a risk of causing incomplete combustion, the water heater automatically stops the combustion operation.

In addition, there is no clogging of the exhaust port 19 and the air supply port 2
When the clogging of 0 occurs, the difference (Fb0-Fc0) between the detected air volume Fb0 and the detected air volume Fc0 does not exceed the predetermined value, and therefore, the above-described combustion operation of the water heater continues.

Next, another example of the first embodiment of the present invention is shown in FIG.
A description will be given with reference to FIG. FIG. 3 is a block diagram of a main part of the apparatus of the present embodiment. Note that the apparatus of the present embodiment is a water heater having the same system configuration as the water heater of FIG. 1, and in the following description, the same components as those of the water heater of FIG. The detailed description is omitted.

Referring to FIG. 3, in the water heater according to the present embodiment, the controller 15 shown in FIG. 1 includes a necessary combustion amount calculating section 22 and an air volume setting section 23 as in the above-described embodiment. , Fan control unit 24, valve control unit 25, air volume change amount calculation unit (air volume change amount calculation unit) 26, and stop command unit 27
It has. Here, corresponding to the configuration of the first aspect of the present invention, the fan control unit 24 configures a fan control unit 28 in combination with the fan motor 11 and the rotation speed sensor 12, and the stop command unit 27 includes an electromagnetic valve. 8 and fan control unit 24
Together with this, the operation stop means 27a is configured.

In this case, the air volume change amount calculation unit 26 includes an initial detection air volume extraction unit 36 and a combustion air volume extraction unit 37 for extracting the initial detection air volume and the combustion air volume detected from the air volume sensor 13, respectively. And a subtraction unit 38 for calculating a difference between the air volume and the detected air volume during combustion. Except for the air volume change amount detection unit 26, the other configuration and operation are exactly the same as those of the above-described embodiment.

Next, the operation of the water heater of this embodiment will be described mainly on the operation different from that of the above-described embodiment.

In the water heater of this embodiment, at the start of the hot water supply operation (combustion operation), the fan control unit 24 controls the combustion fan 10 by the fan control unit 24 at the time of the prepurge and at the time of mild ignition of the burner 3 in the same manner as in the above embodiment. It is driven at a predetermined rotational speed N0 via a fan motor 11. At this time, the air volume detected by the air volume sensor 13 is extracted as the initial air volume by the initial air volume extraction unit 36 and stored in a memory (not shown). Here, at the time of extracting the initial detection air volume,
The relationship between the number of revolutions of the combustion fan 10 and the air flow is shown by the solid line b in FIG.
In this case, the initial detected air volume to be extracted is Fb0.

Next, when the combustion of the burner 3 is started, the rotation speed of the combustion fan 10 is controlled by the fan control unit 24 so that the set airflow and the airflow detected by the airflow sensor 13 coincide with each other, as in the above-described embodiment. The valve control unit 25 controls the opening degree of the gas proportional valve 8 so that the gas is supplied to the burner 3 in an amount corresponding to the air volume.
Burns at the required combustion amount.

During the combustion of the burner 3, the air volume detected by the air volume sensor 13 is successively extracted by the air volume detection section 37 during combustion. In this case, when the detected air volume is extracted, the rotation speed of the combustion fan 10 is set to a predetermined rotation speed N when the initial detected air volume is extracted.
It is not always 0. Therefore, the detected air volume during combustion extraction unit 37 multiplies the extracted air volume by multiplying the extracted air volume by the ratio of the predetermined rotation speed N0 to the rotation speed of the combustion fan detected by the rotation speed sensor 12 when the detected air volume is extracted. The detected air volume of the air volume sensor 13 at the rotational speed N0 is presumably obtained as the detected air volume during combustion.

More specifically, referring to FIG. 5, it is assumed that the current relationship between the rotation speed of the combustion fan 10 and the air flow rate is a relationship indicated by a virtual line c in FIG. Assuming that the rotation speed of the combustion fan 10 is Nx and the airflow detected by the airflow sensor 13 is Fcx, the detected airflow during combustion extraction unit 37 determines the value of the ratio of the predetermined rotation speed N0 to the actual rotation speed Nx of the combustion fan 10. By multiplying the detected airflow Fcx by (N0 / Nx), the detected airflow Fc0 of the airflow sensor 13 at the predetermined rotation speed N0 is obtained as the detected airflow during combustion.

The detected air volume during combustion Fc0 thus obtained
Is given to the subtraction unit 38 together with the initial detected airflow Fb0, and the difference (Fb0-FC0) between the two is obtained by the subtraction unit 38.

Here, when the exhaust port 19 is clogged, the relationship between the number of revolutions of the combustion fan 10 and the air volume at a certain point during the combustion of the burner 3 is determined by the solid line b in FIG. The relationship shown in FIG. 3 becomes a relationship shown by a virtual line c in FIG. Therefore, similarly to the above-described embodiment, the difference (F
b0−FC0) is relatively large.

Therefore, similarly to the above-described embodiment, when the difference (Fb0−FC0) between the detected air volumes obtained by the subtraction unit 38 exceeds a predetermined value, the stop command unit 27 closes the solenoid valve 8. At the same time, the operation of the combustion fan 10 is stopped via the fan control unit 24, thereby stopping the combustion operation.

When the air supply port 20 is clogged, or when the exhaust port 19 and the air supply port 20 are not clogged normally, the combustion operation is continued as in the above-described embodiment.

In each of the embodiments of the first aspect of the present invention described above, the difference between the initial detected air volume and the detected air volume during combustion is determined. Alternatively, the combustion operation may be stopped by determining the amount of change between the above and comparing the value with a predetermined value to grasp the clogging of the exhaust port 19.

In each embodiment of the first aspect,
Although the initially detected air volume is obtained at the time of pre-purge, the initially detected air volume may be obtained at the time of slow ignition of the burner 3. Further, the initial detected air volume may be obtained in the initial stage after the combustion of the burner 3 is started. In this case, the initial detected air volume may be estimated and calculated by the same calculation as the in-combustion detected air volume. It is also possible.

In each embodiment of the first aspect,
Although a water heater has been described as an example of a combustion device, it is needless to say that the first aspect of the present invention can be applied to other combustion devices such as a fan heater.

Further, in the other embodiment of the first aspect, the rotation speed of the combustion fan 10 is corrected according to the deviation between the set air volume and the detected air volume in order to make the set air volume coincide with the detected air volume. However, the rotation speed of the combustion fan 10 may be corrected according to the ratio between the set air volume and the detected air volume.

Next, an example of the second embodiment of the present invention will be described with reference to FIGS. FIG. 4 is a block diagram of a main part of the apparatus of the present embodiment. Note that the apparatus of the present embodiment is a water heater having the same system configuration as the water heater of FIG. 1, and in the following description, the same components as those of the water heater of FIG. The detailed description is omitted.

Referring to FIG. 4, in the water heater of the present embodiment, controller 15 shown in FIG.
In the same manner as in the embodiment of the embodiment, the required combustion amount calculation unit 2
2, air volume setting unit 23, fan control unit 24, valve control unit 2
5 and a stop command unit 27. Here, corresponding to the configuration of the second aspect of the present invention, the fan control unit 24 configures a fan control unit 28 in combination with the fan motor 11 and the rotation speed sensor 12, and the stop command unit 27 includes an electromagnetic valve. 8
And the fan control unit 24 to constitute the operation stopping means 27a.

Further, the controller 14 is different from the embodiment of the first embodiment in that the ratio between the rotation speed of the combustion fan 10 detected by the rotation speed sensor 12 during the hot water supply operation and the air volume detected by the air volume sensor 13 is different. First to sequentially determine the value of
The arithmetic unit 39 calculates the ratio between the value of the ratio obtained by the first arithmetic unit 39 at the beginning of the hot water supply operation, for example, at the time of prepurge, and the value of the ratio obtained by the first arithmetic unit 39 during the subsequent combustion of the burner 3. A second calculating section 40 for sequentially calculating the difference (amount of change) and providing the difference to the stop command section 27.

The first operation unit 39 and the second operation unit 4
The operation of the configuration except for 0 is the same as that of the embodiment of the first aspect.

Next, the operation of the water heater of the present embodiment will be described mainly on the operation different from that of the embodiment of the above-described first embodiment.

When the hot water supply operation is started as described above,
The first calculation unit 39 obtains a value of a ratio between the rotation speed of the combustion fan 10 detected by the rotation speed sensor 12 and the airflow detected by the airflow sensor 13 from time to time until the operation is completed. Then, first, at the time of pre-purge at the start of the hot water supply operation, the second arithmetic unit 40 stores and holds the value of the ratio between the rotational speed and the detected air volume obtained by the first arithmetic unit 39 in a memory (not shown). deep. Specifically, referring to FIG. 5, assuming that the relationship between the number of revolutions of combustion fan 10 and the air flow rate at the beginning of the hot water supply operation is a relationship shown by solid line b in FIG. Of the combustion fan 10 at the time
The value of the ratio of the detected air volume F0 to (= predetermined rotation speed) (F0
/ N0, which will be described with reference numeral H0).
It is. The value H0 of this ratio indicates the slope of the solid line b.

Next, when the combustion of the burner 3 is performed as described above, the second arithmetic unit 40 calculates the ratio value obtained every moment from the first arithmetic unit 39 and the ratio value obtained during the prepurge. The difference from H0 is obtained and given to the stop command unit 27.

More specifically, assuming now that the relationship between the rotation speed of the combustion fan 10 and the air flow is the relationship indicated by the imaginary line c in FIG. 5, if the rotation speed of the combustion fan 10 is Nx, the detected air flow is Is Fcx, and the value of the ratio (Fcx / Nx, hereinafter,
This will be described with reference numeral H1) and the ratio value H
The difference (H0−H1) from 0 is obtained by the second arithmetic unit 40.

Here, in the case where the exhaust port 19 is clogged, as the combustion of the burner 3 progresses, the relationship between the number of revolutions of the combustion fan 10 and the air flow is represented by a solid line b in FIG. What was the relationship shown is the virtual line c in FIG.
And the slope of a straight line indicating the relationship between the rotation speed of the combustion fan 10 and the air flow, that is, the value of the ratio of the air flow to the rotation speed of the combustion fan 10 decreases relatively significantly. Therefore, when the exhaust port 19 is clogged, the difference (H0-H1) of the ratio values obtained by the second arithmetic unit 40 becomes relatively large as the burner 3 burns.

Then, the stop command section 27 compares the difference (H0-H1) of the ratio values with a predetermined value, and when the difference exceeds the predetermined value, the stop command section 27 is completely different from the embodiment of the first embodiment described above. Similarly, the combustion operation is stopped. At this time, the combustion operation may be stopped and an abnormal state may be notified. This is the same in the embodiment of the first aspect described above.

If the exhaust port 19 is not clogged or the degree of the clogging is small, the difference (H0−H1) of the ratio is equal to the predetermined value even if the air supply port 20 is clogged. In this case, the combustion operation (hot water supply operation) is performed as described in the above-described embodiment of the first embodiment. That is, the fan control unit 24
The number of rotations of the combustion fan 10 is controlled so that the set airflow and the airflow detected by the airflow sensor 13 match, and gas corresponding to the airflow is supplied to the burner 3.
The opening of the gas proportional valve 8 is controlled by the valve control unit 25, and the burner 3 burns at the required combustion amount.

In this embodiment, the difference between the ratio value H0 at the beginning of the operation and the ratio value H1 during combustion is determined. However, the ratio between the ratio values H0 and H1 is determined. It is also possible to determine the clogging of the exhaust port 19 and stop the combustion operation by obtaining the calculated value and comparing it with a predetermined value.

In this embodiment, the ratio H
Although the value of the ratio at the time of pre-purge was set to 0, the value of the ratio at the time of mild ignition of the burner 3 may be used. Further, the value of the ratio at an arbitrary initial point after the start of combustion of the burner 3 may be used. May be used.

Although the present embodiment has been described by taking a water heater as an example of a combustion device, the second aspect of the present invention can be applied to other combustion devices such as a fan heater. Of course.

Further, in the present embodiment, the rotation speed of the combustion fan 10 is corrected according to the deviation between the set air volume and the detected air volume in order to make the set air volume and the detected air volume coincide with each other. The rotation speed of the combustion fan 10 may be corrected according to the ratio between the detected air flow rate and the detected air flow rate.

[0083]

As is apparent from the above description, according to the first aspect of the present invention, the initial detected air volume obtained by the air volume sensor at the initial stage of the combustion operation corresponding to the predetermined rotation speed of the combustion fan is determined. During the subsequent combustion, when the amount of change between the detected air volume during combustion obtained by the air volume sensor corresponding to the predetermined rotation speed of the combustion fan exceeds a predetermined amount,
Since the combustion operation is stopped by the operation stop means, the combustion operation can be automatically stopped in the case of clogging of the exhaust port where exhaust leakage or incomplete combustion may occur, and the exhaust operation can be stopped. If there is no clogging or the degree of clogging is small, the air volume sensor detects the set air volume corresponding to the required combustion volume of the burner, not only in the normal case, but also when the air supply port is clogged to some extent. By controlling the number of revolutions of the combustion fan by the fan control means so that the air volume coincides, the combustion operation of the burner can be performed smoothly, so that clogging of the exhaust port can be distinguished from clogging of the air supply port and the like. It is possible to provide a combustion device that can be grasped and can perform an appropriate operation corresponding to it, and is excellent in safety and usability.

In order to control the number of revolutions of the combustion fan so that the air volume detected by the air volume sensor matches the set air volume, the number of revolutions of the combustion fan is corrected according to the deviation between the set air volume and the detected air volume. By using the deviation between the set air volume and the detected air volume to determine the amount of change between the initial detected air volume and the detected air volume during combustion, the configuration for controlling the combustion fan can be effectively utilized. Can be.

Further, at the beginning of the combustion operation, an initial deviation is obtained from the deviation calculating section of the fan control means as the predetermined number of rotations and the predetermined air volume of the rotation speed and the predetermined air volume of the combustion fan. In
From the deviation obtained from the deviation calculation unit at an arbitrary set air volume, the combustion deviation corresponding to the predetermined rotation speed and the predetermined air flow is estimated by calculation, and the difference between the initial deviation and the combustion deviation is calculated. By calculating as the amount of change between the initial detected air volume and the detected air volume during combustion,
During the combustion of the burner, the set air volume and the detected air volume always correspond to the required combustion air volume, irrespective of the process for obtaining the air flow volume during combustion, as long as the clogging of the exhaust port has not progressed to some extent. Thus, the combustion operation can be performed accurately and smoothly.

In the early stage of the combustion operation, the number of revolutions of the combustion fan is controlled to a predetermined number to obtain an initial detected air volume from an air volume sensor, and during the subsequent combustion of the burner, the fan control means is used. The above-described operation can be performed with a simple configuration by obtaining the detected airflow during combustion at the predetermined rotation speed by calculation from the airflow detected by the airflow sensor at an arbitrary rotation speed of the controlled combustion fan, During the combustion of the burner, the set air volume and the detected air volume always correspond to the required combustion air volume, irrespective of the process for obtaining the air flow volume during combustion, as long as the clogging of the exhaust port has not progressed to some extent. Thus, the combustion operation can be performed accurately and smoothly.

Further, by controlling the rotation speed of the combustion fan to a predetermined rotation speed at the time of prepurge or moderate ignition to obtain the initial deviation or the initially detected air volume, the normal combustion operation can be performed while performing the normal combustion operation. The initial deviation or the initial detected air volume can be easily obtained at an appropriate timing.

According to the second aspect of the present invention, the value of the ratio of the air flow rate detected by the air flow rate sensor to the rotational speed of the combustion fan obtained by the first arithmetic unit at the beginning of the combustion operation and the subsequent combustion In the meantime, a change amount between the value of the ratio of the detected air flow rate of the air flow sensor to the rotation speed of the combustion fan obtained by the first calculation unit is obtained by the second calculation unit, and when the change amount exceeds a predetermined amount. When the combustion operation is stopped by the operation stop means, the combustion operation can be automatically stopped in the case of exhaust gas clogging that may cause exhaust leakage or incomplete combustion, and If there is no clogging of the exhaust port or the degree of clogging is small, the air volume can be adjusted to the set air volume corresponding to the required combustion amount of the burner, even if the air supply port is clogged to some extent, not to mention the normal case. By controlling the number of revolutions of the combustion fan by the fan control means so that the airflow detected by the sensor matches, the combustion operation of the burner can be performed smoothly. It is possible to provide a combustion device excellent in safety and usability, as well as being able to perform an accurate operation in accordance with it. The value of the ratio can be obtained very easily because the number of rotations of the combustion fan may be arbitrarily set.Also, during combustion of the burner, unless the clogging of the exhaust port progresses to some extent, the value is always obtained. Control can be performed such that the set airflow corresponding to the required combustion amount and the detected airflow coincide with each other, so that an accurate and smooth combustion operation can be performed.

Further, the value of the ratio at the beginning of the combustion operation is obtained at the time of pre-purge or at the time of mild ignition, so that the value of the ratio at the beginning of the combustion operation can be easily obtained at an appropriate timing. .

[Brief description of the drawings]

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

FIG. 2 is a block configuration diagram of a main part of the water heater of FIG. 1;

FIG. 3 is a block diagram of a combustion device (water heater) according to another example of the first embodiment of the present invention.

FIG. 4 is a block diagram of a combustion device (water heater) according to an example of a second embodiment of the present invention.

FIG. 5 is a diagram showing a relationship between the number of rotations of a combustion fan of the water heater of FIG. 1 and the air volume;

[Explanation of symbols]

3 burner, 10 combustion fan, 13 air flow sensor, 1
Reference Signs List 8: combustion chamber, 19: exhaust port, 20: air supply port, 26: air flow rate change calculation means, 27a: operation stop means, 28: fan control means, 29: deviation calculation means, 30: storage means, 31
... Reference rotational speed setting means, 39.
Second calculation means.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) F23N 5/18 101 F23N 3/08 F23N 5/24 104

Claims (7)

(57) [Claims] A combustion chamber accommodating a burner; an air supply port and an exhaust port communicating with the combustion chamber; a combustion fan provided on the air supply port side for blowing combustion air to the burner; An air flow sensor for detecting the air flow from the combustion fan to the burner; and the combustion fan for adjusting the air flow detected by the air flow sensor during the combustion operation of the burner to a set air flow for obtaining a required combustion amount of the burner. A fan control means for controlling the rotation speed of the combustion device,
The initial detection air volume obtained by the air volume sensor corresponding to the predetermined rotation speed of the combustion fan at the beginning of the combustion operation of the burner and the predetermined rotation speed of the combustion fan during the subsequent combustion of the burner. An air volume change amount calculating means for obtaining a change amount between the detected air volume during combustion obtained by the air volume sensor, and a change amount between the initial detected air volume and the detected air volume during combustion obtained by the air volume change amount calculating means. A combustion device comprising: operation stop means for stopping a combustion operation when a predetermined amount is exceeded. 2. The fan control means according to claim 1, wherein said fan control means stores in advance the relationship between the air flow rate and the rotation speed of said combustion fan when the load of said combustion fan is normal, as reference data, and said reference value during combustion operation of said burner. Reference rotation speed setting means for obtaining a reference rotation speed of the combustion fan corresponding to the set air flow based on data, and deviation calculation means for obtaining a deviation between the set air flow and a detection air flow obtained by the air flow sensor, By controlling the rotation speed of the combustion fan with the reference rotation speed as a reference designated rotation speed and correcting the rotation speed of the combustion fan according to the deviation between the set airflow and the detected airflow, the detected airflow is set to the set value. The combustion fan is controlled so as to match the air volume, and the air volume change amount calculating means determines that the reference rotation speed is equal to or less than the reference speed at the beginning of the combustion operation of the burner. A difference between an initial deviation obtained by the deviation calculating means corresponding to a predetermined set airflow which is a rotation speed and a combustion deviation obtained by the deviation calculating means corresponding to the predetermined set airflow during combustion of the burner. 2. The combustion apparatus according to claim 1, wherein the difference is obtained as a change amount between the initial detected air volume and the detected air volume during combustion. 3. The fan control means includes means for controlling the number of revolutions of the combustion fan to the predetermined number of revolutions at an early stage of the start of the combustion operation. Means for applying the obtained air volume to the deviation calculation means as the predetermined set air volume,
The air volume change amount calculating means includes means for obtaining, as the initial deviation, a deviation output from the deviation calculating means when the combustion fan is controlled to the predetermined number of revolutions at an early stage of the combustion operation; and During the combustion, the deviation output from the deviation calculating means when the combustion fan is controlled to the reference rotation speed corresponding to the set airflow for obtaining the required combustion amount by the fan control means is set to the reference rotation speed ( 3. The combustion apparatus according to claim 2, further comprising means for obtaining the in-combustion deviation by multiplying a ratio value (N0 / Nx) of the ratio (Nx) to the predetermined rotational speed (N0). 4. The fan control means includes means for controlling the number of revolutions of the combustion fan to the predetermined number of revolutions at an early stage of the start of the combustion operation.
Means for obtaining, as the initial detection airflow, the airflow detected by the airflow sensor when the combustion fan is controlled to the predetermined rotation speed at the beginning of the combustion operation, and the actual operation of the combustion fan during the combustion of the burner thereafter. By multiplying the ratio (N0 / Nx) of the ratio of the rotational speed (Nx) to the predetermined rotational speed (N0) by the detected airflow of the airflow sensor at the actual rotational speed (Nx), the detected airflow during combustion is obtained. 2. The combustion apparatus according to claim 1, further comprising: means for determining. 5. The combustion apparatus according to claim 3, wherein said fan control means controls the number of revolutions of said combustion fan to said predetermined number of revolutions at the time of pre-purge or at the time of slow ignition of said burner. 6. A combustion chamber containing a burner, a supply port and an exhaust port communicating with the combustion chamber, and a combustion fan provided on the supply port side for blowing combustion air to the burner. An air flow sensor for detecting the air flow from the combustion fan to the burner; and the combustion fan for adjusting the air flow detected by the air flow sensor during the combustion operation of the burner to a set air flow for obtaining a required combustion amount of the burner. A fan control means for controlling the rotation speed of the combustion device,
A first calculating means for obtaining a value of a ratio of an air volume detected by the air volume sensor to a rotation speed of the combustion fan during the combustion operation;
A second calculation for calculating an amount of change between the ratio value (H0) obtained by the calculating means and the ratio value (H1) obtained by the first calculating means during the subsequent combustion of the burner. Means, and operation stop means for stopping the combustion operation when the change amount of the ratio value (H0, H1) obtained by the second calculation means exceeds a predetermined amount. Combustion equipment. 7. The ratio value (H0) at the initial stage of the start of the combustion operation of the burner is a ratio value at the time of pre-purge or at the time of ignition of the burner.
A combustion device as described.