JPH10176827A - Combustion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a combustion device capable of burning, keeping a definite ratio of air and a fuel gas constant even if then occur changes in an air flow to a burner produced by a fast external disturbance. SOLUTION: This combustion device is provided with a combustion chamber 18 which houses a burner 3, a combustion fan 10 which sends combustion air to the burner 3, a rotary speed detection means 12 which detects the numbers of revolution of the combustion fan 10, a gas proportional valve 9 which can change the flow rate of a fuel gas to be fed to the burner 3, an air volume sensor 13 which detects the volume of combustion air to the burner 3 from the combustion fan 10 and a fan control means 22 which controls the rotary speed of the combustion fan 10 so that the detection air flow to be detected with the air flow sensor 13 may be identical to a target air flow predetermined so as to provide a required amount of combustion of the burner 3 during combustion operation time of the burner 3. In this case, a gas proportional valve control means 23, which sets the opening of the gas proportional valve 9, is provided so as to keep the percentage of the flow rate of combustion air detected with the air flow sensor 13 and the supply flow rate of the fuel gas within a specified range.

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 For example, in a water heater, a burner amount required to match a tapping temperature set by a user with an actual tapping temperature detected by a tapping temperature sensor is calculated, and the burner burn amount is calculated. There is known an apparatus which supplies combustion air and fuel gas at a flow rate corresponding to the combustion amount. In the water heater, the number of rotations of a combustion fan that supplies combustion air is controlled according to the amount of combustion of the burner,
An opening degree of a gas proportional valve provided in a fuel supply path to the burner is controlled according to the combustion amount or the actual rotation speed of the combustion fan.

[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. Control. However, in practice, when the load of the combustion fan changes from the initial normal state due to clogging of the air supply port and exhaust port of the combustion chamber containing the burner, the rotation speed of the combustion fan becomes the same. However, the actual air volume of the combustion air from the combustion fan to the burner changes.

For this reason, in recent years, the actual flow rate of combustion air to the burner is occasionally detected by a flow rate sensor arranged in a ventilation passage from the combustion fan to the burner, and the detected flow rate corresponds to the required combustion rate of the burner. (Japanese Utility Model Laid-Open No. 1-129561, Japanese Utility Model Laid-Open No. 60-14) has been proposed to control the number of revolutions of a combustion fan so as to match the set air volume.
No. 3251).

[0005] 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, it is possible to produce a combustion air having an air flow corresponding to the required combustion amount of the burner. Air can be supplied to the burner from the combustion fan. Therefore, stable combustion can be performed while maintaining the ratio of air to fuel gas during combustion within a certain range.
However, since the response frequency of the combustion fan is low, when the air flow to the burner changes due to a fast disturbance, the control of the rotation speed of the combustion fan cannot follow the change, and the ratio of combustion air to fuel gas fluctuates. . For this reason, in particular, there is a disadvantage that a stable combustion state cannot be maintained in an all-primary combustion type combustion apparatus that performs combustion by mixing all of the amount of air required for complete combustion as fuel air with fuel gas.

[0006]

SUMMARY OF THE INVENTION The present invention solves the above-mentioned disadvantages, and maintains the ratio of air to fuel gas during combustion within a predetermined range even when the amount of air to the burner changes due to fast disturbance. An object of the present invention is to provide a combustion device capable of performing stable combustion.

[0007]

SUMMARY OF THE INVENTION In order to achieve the above objects, the present invention provides a combustion chamber containing a burner, a combustion fan for blowing combustion air to the burner, and detecting a rotation speed of the combustion fan. Rotation speed detecting means, a gas proportional valve for varying a flow rate of fuel gas supplied to the burner, an air flow sensor for detecting an air flow of combustion air from the combustion fan to the burner, And a fan control means for controlling the number of revolutions of the combustion fan so that a detected air volume detected by an air volume sensor matches a target air volume set to obtain a required combustion volume of the burner. Gas proportional valve control means for setting the degree of opening of the gas proportional valve is provided such that the ratio between the detected air volume of combustion air detected by the air volume sensor and the supply flow rate of the fuel gas maintains a predetermined range value. It is characterized in.

Generally, the upper limit of the response frequency of the air flow sensor is about 10 Hz, but the upper limit of the response frequency of the change in air flow rate by the fan motor is about 0.1 Hz. for that reason,
In the control of the fan motor by the fan control means,
Fluctuations in the amount of combustion air due to disturbance at a speed exceeding 0.1 Hz cannot be suppressed. In such a case, according to the present invention, the degree of opening of the gas proportional valve is adjusted by the gas proportional valve control means such that the ratio between the flow rate of the combustion air and the supply flow rate of the fuel gas maintains a predetermined range value. You. Therefore, the ratio between the detected air flow rate of the combustion air and the supply flow rate of the fuel gas is changed with respect to the fluctuation of the flow rate of the combustion air from about 1 Hz to several Hz, which is the upper limit of the response frequency of the gas flow rate change by the gas proportional valve. Good combustion can be performed while maintaining the value in the predetermined range.

A combustion chamber accommodating a burner; a combustion fan for blowing combustion air to the burner; rotation speed detection means for detecting a rotation speed of the combustion fan; and a flow rate of fuel gas supplied to the burner. A gas proportional valve that varies the amount of combustion air flowing from the combustion fan to the burner; a flow rate sensor that detects the flow rate of combustion air from the combustion fan to the burner; and a detected flow rate detected by the flow rate sensor during combustion operation of the burner. Fan control means for controlling the number of revolutions of the combustion fan so as to match a target air volume set in order to obtain the gas proportion according to the number of revolutions of the combustion fan detected by the number of revolutions detection means. A gas proportional valve control unit for setting a valve opening degree, wherein the gas proportional valve control unit is configured to perform the combustion by the fan control unit during the combustion operation of the burner. When a correction for increasing or decreasing the rotation speed of the fan is made, the opening of the gas proportional valve is set so as to cancel the increase or decrease in the rotation speed, and the detection of combustion air detected by the air volume sensor is performed. The opening degree of the gas proportional valve is set so that the ratio between the detected air volume of the combustion air and the supply flow rate of the fuel gas falls within the predetermined range value when the variation amount of the air volume deviates from a predetermined range value. According to the present invention, when dust or the like is present in the air supply port or the exhaust port, that is, when the amount of combustion air flowing from the combustion fan to the burner fluctuates, the fan control means controls the combustion air. The rotation speed of the combustion fan is corrected in order to make the detected air volume coincide with the target air volume. At this time, since the gas proportional valve control means sets the opening of the gas proportional valve according to the rotational speed of the combustion fan, the current instruction value is also changed according to the correction of the rotational speed of the combustion fan. In such a case, the gas proportional valve control means sets the opening of the gas proportional valve so as to cancel the increase or decrease in the rotational speed due to the correction of the rotational speed of the combustion fan. Therefore, even if the combustion fan changes the rotation speed of the combustion fan in order to match the detected air volume of the combustion air with the target air volume, the opening of the gas proportional valve is kept substantially constant. The ratio of air to fuel gas during combustion does not change, and a favorable combustion state can be maintained.

[0010] As described above, the upper limit of the response frequency of the gas flow rate change by the gas proportional valve is higher than the upper limit of the response frequency of the air flow rate change by the combustion fan. Therefore, even when the air volume of the combustion air changes at a speed that cannot be followed by the control of the combustion fan by the fan control unit, instead of increasing or decreasing the air volume of the combustion air, the gas proportional valve By adjusting the degree of opening of the proportional valve, it is possible to perform good combustion while maintaining the ratio between the amount of combustion air and the flow rate of fuel gas within a predetermined range.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention is shown in FIGS.
This will be described with reference to FIG. FIG. 1 is a configuration diagram of a water heater that is a combustion device of the first embodiment, FIG. 2 is a control block diagram of the water heater shown in FIG. 1, and FIG. 3a is an air flow sensor provided in the water heater shown in FIG. FIG. 3B is a graph showing a current instruction value to the gas proportional valve corresponding to FIG. 3A.

Referring to FIG. 1, reference numeral 1 denotes a water heater main body having a built-in heat exchanger 2 and a burner 3 for heating the heat exchanger, 4 denotes a water pipe installed through the heat exchanger 2, and 5 denotes a water pipe 4. Flow rate sensor that detects the flow rate of water flowing through the heat exchanger 2 on the upstream side of the heat exchanger 2.
Reference numeral 6 denotes a temperature sensor for detecting the tapping temperature of water flowing through the water pipe 4 downstream of the heat exchanger 2, 7 a gas supply pipe for supplying fuel gas to the burner 3, and 8 and 9 upstream of the gas supply pipe 7. An on-off solenoid valve and a gas proportional valve interposed in order from the side, 10 is a combustion fan for blowing combustion air to the burner 3, 11 is a fan motor for driving the combustion fan 10, and 12 is the number of revolutions of the combustion fan 10 A rotation speed sensor 13 constituted by a Hall element or the like for performing the operation, an air flow sensor 13 for detecting an air flow of combustion air from the combustion fan 10 to the burner 3, 14
Is an operation unit for the user to set tapping temperature, etc., 15
Is a controller for controlling the fan motor 11, the solenoid valve 8, the gas proportional valve 9 and the like according to the set temperature of hot water set by the operation unit 14 and the detection signals of the sensors 5, 6, 12, and 13; An igniter 17 for igniting the burner 3 is a frame 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 1
An exhaust port 19 provided at an upper portion of the water heater main body 1 and an air supply port 20 provided at a lower portion thereof communicate with 8. The combustion fan 10 is provided on the air supply port 20 side, and the air volume sensor 13 is disposed in a ventilation passage 21 extending from the air supply port 20 to the combustion chamber 18.

Note that 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. The air volume sensor 13 is, for example, a hot wire type air volume sensor. It should be noted that a thermal sensor, a Karman vortex sensor, a vane sensor, or the like can be used for the air flow sensor.

The controller 15 includes a fan control unit 22
And gas proportional valve control means 23. When the user starts using hot water, the controller 15 outputs the hot water temperature set by the operation unit 14, the amount of hot water flowing through the water pipe 4 detected by the flowing water sensor 5, and the actual temperature detected by the temperature sensor 6. The required combustion amount of the burner 3 is determined from the hot water temperature of the burner. The fan control means 22 calculates a target rotation speed of the combustion fan 10 necessary for obtaining a flow rate of the combustion air to the burner 3 in accordance with the required combustion amount, and the combustion fan 10 rotates at the target rotation speed. The fan motor 11 is controlled so as to perform the operation. Further, the gas proportional valve control means 23 adjusts the opening of the gas proportional valve 9 in accordance with the detected air volume value of the combustion air detected by the air volume sensor 13.

Next, the operation of the controller 15 will be described with reference to the control block diagram of FIG. As shown in FIG.
The control block of the controller 15 in the first embodiment includes a fan control block 30 corresponding to the fan control means 22 and a gas proportional valve control block 31 corresponding to the gas proportional valve control means 23.

The fan control block 30 controls the fan motor 11 so that the combustion fan 10 rotates at a target rotation speed determined according to the required combustion amount. Normally, the rotation speed of the fan motor 11 and the air volume of the combustion air to the burner 3 detected by the air volume sensor 13 correspond to each other in a fixed relationship. Therefore, the target rotation speed and the actual rotation speed of the fan motor 11 detected by the rotation speed sensor 12 are compared at the first addition point 33 by the feedback loop shown in A, and the first rotation speed is determined based on the comparison result.
If the rotation speed of the fan motor 11 is kept constant via the fan motor drive circuit section 35 by increasing or decreasing the output voltage to the PWM conversion section 34, the flow rate of the combustion air to the burner 3 is kept constant. be able to. Therefore, the air flow sensor 1
Even if the output from 3 is input to the fan motor rotation speed correcting means 37, the target rotation speed is not changed. still,
The PI control unit 36 and the loop C are for improving the stability of the rotation speed control of the fan motor 11.

However, when dust or the like is clogged in the air supply port 20 or the exhaust port 19, the dust or the like acts as a load, hinders the flow of combustion air, and the rotation speed of the fan motor 11 is kept constant. In some cases, the flow rate of combustion air to the burner 3 may be reduced. Feedback loop B
Is used to eliminate such inconvenience.
The air flow sensor 13 provided near 0 detects the air flow of the combustion air actually supplied to the burner 3, and when the air flow decreases due to a load caused by dust or the like, the fan motor rotation speed correction means 37 uses a feedback loop B. The target rotation speed is increased in accordance with the decrease in the air volume. This allows
Since the command voltage value to the first PWM conversion unit 34 increases, the rotation speed of the fan motor 11 increases, and the decrease in the flow rate of the combustion air to the burner 3 caused by the increase in load due to dust or the like is compensated for. The flow rate of the combustion air can be kept constant.

On the other hand, the detected airflow of the combustion air from the airflow sensor 13 is input to the current command value calculating means 40 constituting the gas proportional valve control block 31 (path D). The current instruction value to the gas proportional valve 9 is calculated so that the ratio between the flow rate of the working air and the supply flow rate of the fuel gas falls within a predetermined range value.

The above operation will be described with reference to the graphs of FIGS. 3A and 3B. In the normal combustion operation, when the load such as dust gradually changes in the exhaust port 19 and the air supply port 20 over time. And so on, as from 0 to T ₁ and T _{2 in} FIG.
Due to the fan control block 30, the output fluctuation of the air volume sensor 13 (the fluctuation of the air volume of the combustion air to the burner 3) is from U ₁ to
It is suppressed to a range of U _2. And this fixed range U
₁ ~U ₂ current instruction value I ₁ for setting the supply flow rate of the fuel gas corresponding to is calculated by the current instruction value calculation means 40. As a result, the ratio between the flow rate of the combustion air to the burner 3 and the supply flow rate of the fuel gas is kept within a certain range, and good combustion is performed.

When the frequency exceeds the upper limit (about 0.1 Hz) of the response frequency of the air flow rate change by the fan motor 11 as shown by T _{1 to} T ₂ in FIG.
When 0 reduction of the combustion air which can not be suppressed in the control is detected by the airflow sensor 13, i.e., reduction of the combustion air in excess of the range of V ₁ ~V ₂ which is set arbitrarily by the current instruction value calculation means 40 When detected by the air volume sensor 13, the current instruction value calculating means 40 decreases the current instruction value according to the decrease in the combustion air, as shown in FIG. 3B. As a result, the opening of the gas proportional valve 9 decreases, and the flow rate of the combustion gas to the burner 3 decreases. Upper limit of response frequency of gas flow rate change by gas proportional valve 9 (1 to several Hz
) Is higher than the upper limit (about 0.1 Hz) of the response frequency of the air flow rate change by the fan motor 11, so that even when the flow rate of the combustion air changes at a speed that cannot be followed by the control by the fan control block 30. By the operation of the current command value calculating means 40, stable combustion can be performed while maintaining the ratio of the flow rate of the combustion air to the burner 3 and the flow rate of the fuel gas within a predetermined range.

Although FIGS. 3A and 3B show the case where the air volume detected by the air volume sensor 13 is reduced due to disturbance, the gas proportional valve 9 is used when the air volume detected by the air volume sensor 13 increases.
By increasing the opening degree of the fuel gas to increase the flow rate of the fuel gas to the burner 3, the ratio between the flow rate of the combustion air to the burner 3 and the flow rate of the fuel gas can be maintained within a predetermined range.

Next, a second embodiment of the present invention will be described with reference to FIGS. The device configuration of the second embodiment is the same as that of the first embodiment shown in FIG.
Only the configuration of FIG. 4 is a control block diagram illustrating the operation of the controller 15.

As shown in FIG. 4, the control block of the controller 15 in the second embodiment includes a fan control block 30 corresponding to the fan control means 22 and a gas proportional valve control function corresponding to the gas proportional valve control means 23. Block 50
Consists of The configuration and operation of the fan control block 30 are the same as those in the first embodiment. The rotation speed of the fan motor 11 is controlled so that the detection value of the air flow rate of the combustion air by the air flow rate sensor 13 is kept within a predetermined range. I do.

On the other hand, the gas proportional valve control block 50 determines the flow rate of the combustion air to the burner 3 and the supply flow rate of the fuel gas in accordance with the rotation speed of the fan motor 11 detected by the fan motor rotation speed sensor 12. The opening of the gas proportional valve 9 is adjusted so that the ratio maintains a predetermined range value. That is, the current instruction value calculating means 40 constituting the gas proportional valve control block 50 calculates the current instruction value for adjusting the opening of the gas proportional valve 9 according to the rotation speed of the fan motor 11, ON / OFF according to the current instruction value in the PWM converter 41
The pulse waveform of the ratio is generated, and the gas proportional valve 9 is driven via the gas proportional valve drive circuit section 42 with the pulse waveform.

When dust or the like is clogged in the air supply port 20 or the exhaust port 19 and the fan motor rotation speed correction means 37 controls the rotation of the fan motor, the air volume of the combustion air becomes constant. Nevertheless, a state occurs in which the rotation speed of the fan motor 11 changes. At this time, the current instruction value calculating means 40 determines the current instruction value to the gas proportional valve 9 according to the number of revolutions of the fan motor 11, so that the ratio between the flow rate of the combustion air and the supply flow rate of the fuel gas changes. I do. For this reason, the combustion state may be deteriorated and incomplete combustion may occur. The current instruction value changing means 43 is for preventing such a situation from occurring, and inputs the correction amount of the target rotation speed by the fan motor rotation speed correction means 37 (path E) and changes the correction amount. The current instruction value from the current instruction value calculation means 40 is changed so as to cancel. Thus, even when the target rotation speed is corrected by the fan motor rotation speed correction means 37, the ratio between the amount of combustion air and the supply flow rate of fuel gas can be kept constant.

However, when the flow rate of the combustion air to the combustion chamber 18 changes at a speed exceeding the upper limit (about 0.1 Hz) of the response frequency of the change in the air flow rate by the fan motor 11 due to some disturbance, the fan control block 30 performs the process. The control of the fan motor 11 cannot suppress a change in the flow rate of the combustion air.

In order to cope with a change in the air volume of the combustion air which cannot be suppressed by the control of the fan motor 11, the current instruction value changing means 43 inputs the air volume of the combustion air from the air volume sensor 13 (path F). Then, the current instruction value is changed according to the change in the flow rate of the combustion air. The operation of the current instruction value changing means 43 will be described with reference to FIGS. 3A and 3B.
During normal combustion operation, the air flow sensor 1 is controlled by the fan control block 30 as shown after 0 to T ₁ and T ₂ in FIG.
3 output fluctuation (fluctuation of air volume of combustion air to burner 3)
Is suppressed to a certain range of U _{1 to} U ₂ .

Then, the frequency exceeds the upper limit (about 0.1 Hz) of the response frequency of the air flow rate change by the fan motor 11 as shown by T _{1 to} T ₂ in FIG.
When 0 fluctuation of the combustion air which can not be suppressed in the control of is detected by the airflow sensor 13, i.e., the output of airflow sensor 13 over a range of V ₁ ~V ₂ set arbitrarily by the current instruction value changing unit 43 When the current value changes, the indicated current value changing means 43 decreases the indicated current value I ₁ calculated by the indicated current value calculating means 40 as shown in FIG. 3B.
That is, the opening degree of the gas proportional valve 9 is reduced to reduce the flow rate of the combustion gas to the burner 3. The upper limit of the response frequency of the gas flow rate change by the gas proportional valve 9 (about 1 to several Hz) is larger than the upper limit of the response frequency of the air flow rate change by the fan motor 11 (about 0.1 Hz). Even when the flow rate of the combustion air changes at a speed that cannot be followed by the control, the operation of the current instruction value changing means 43 determines the ratio between the flow rate of the combustion air to the burner 3 and the flow rate of the fuel gas. Stable combustion can be performed while maintaining the range value.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a water heater that is an open combustion device according to a first embodiment of the present invention.

FIG. 2 is a control block diagram according to the first embodiment of the present invention.

FIG. 3 is a graph showing output fluctuations of an air flow sensor provided in the water heater shown in FIG. 1;

FIG. 4 is a control block diagram according to a second embodiment of the present invention.

[Explanation of symbols]

1 ... water heater, 2 ... heat exchanger, 3 ... burner, 4 ... water pipe,
5: running water sensor, 6: temperature sensor, 7: gas supply pipe, 8
... open / close solenoid valve, 9 ... gas proportional valve, 10 ... combustion fan, 1
DESCRIPTION OF SYMBOLS 1 ... Fan motor, 12 ... Rotation speed sensor, 13 ... Air volume sensor, 14 ... Operation part, 15 ... Controller, 16 ... Igniter, 17 ... Frame rod, 18 ... Combustion chamber, 19 ...
Exhaust port, 20 air supply port, 21 air blow passage, 22 fan control means, 23 gas proportional valve control means, 30 fan control block, 31 gas flow control block, 33 first
, A first PWM conversion unit, 35, a fan motor drive circuit unit, 36, a PI control unit, 37, a fan motor rotation speed correction unit, 38, a second addition point,
40: current instruction value calculation means, 41: second PWM converter, 42: gas proportional valve drive circuit section, 43: current instruction value change means, 50: gas proportional control valve control block

Claims (2)

[Claims] A combustion chamber accommodating a burner; a combustion fan for blowing combustion air to the burner; rotation speed detection means for detecting a rotation speed of the combustion fan; and a flow rate of fuel gas supplied to the burner. A gas proportional valve that varies the amount of combustion air flowing from the combustion fan to the burner; a flow rate sensor that detects the flow rate of combustion air from the combustion fan to the burner; and a detected flow rate detected by the flow rate sensor during combustion operation of the burner. And a fan control means for controlling the number of revolutions of the combustion fan so as to match a target air volume set to obtain a target air volume, wherein a detected air volume of combustion air detected by the air volume sensor and a fuel gas A gas proportional valve control means for setting an opening degree of the gas proportional valve so that a ratio of the gas proportional valve to a supply flow rate is maintained in a predetermined range value. 2. A combustion chamber accommodating a burner, a combustion fan for blowing combustion air to the burner, rotation speed detecting means for detecting a rotation speed of the combustion fan, and a flow rate of fuel gas supplied to the burner. A gas proportional valve, a flow rate sensor for detecting a flow rate of combustion air from the combustion fan to the burner, and a detected flow rate detected by the flow rate sensor during a combustion operation of the burner. Fan control means for controlling the rotation speed of the combustion fan so as to match the target air volume set for obtaining, according to the rotation speed of the combustion fan detected by the rotation speed detection means,
A gas proportional valve control means for setting the degree of opening of the gas proportional valve, wherein the gas proportional valve control means comprises:
When a correction for increasing or decreasing the number of revolutions of the combustion fan is made by the fan control means, the opening degree of the gas proportional valve is set so as to cancel out the increase or decrease of the number of revolutions, and detected by the air volume sensor. When the fluctuation amount of the detected air volume of the combustion air deviates from a predetermined range value, the gas proportional ratio is set so that the ratio between the detected air volume of the combustion air and the supply flow rate of the fuel gas falls within the predetermined range value. A combustion device characterized by setting an opening of a valve.