JP2735465B2 - Incomplete combustion detector for 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 an apparatus for detecting incomplete combustion using a CO sensor in a combustion apparatus, particularly in a gas water heater.

[0002]

2. Description of the Related Art Conventionally, in this type of apparatus, a CO sensor is provided in an exhaust passage connected to a combustion chamber of a gas water heater.
The incomplete combustion state is detected by the output of the CO sensor. The power of the CO sensor is turned on at the same time that the power cord of the combustion device is connected to the power source. The CO sensor includes a heater for heating the CO sensor, and is heated to a predetermined temperature to detect the CO concentration.

[0003] Because the CO sensor is constantly heated, the service life is usually about three years, which is shorter than the service life of the combustion equipment. Therefore, there is a disadvantage that the CO sensor cannot be used while the combustion equipment can be used.

Further, a CO sensor using a metal oxide semiconductor (SnO ₂ ) or zirconia shows high sensitivity not only to CO but also to H _2. Large current flows to the CO sensor in response to CO and H ₂ contained in the CO, and the life of the CO sensor may be greatly shortened.

[0005]

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and an object of the present invention is to provide an incomplete combustion detecting device in which the useful life of a CO sensor is extended.

[0006]

In order to achieve the above object, the present invention provides a burner provided in a combustion chamber, fuel supply means for supplying fuel to the burner, ignition means for igniting the burner, A combustion sensor is provided in a combustion device including an exhaust passage provided downstream of the combustion chamber, and a CO sensor provided in the exhaust passage and an output of the CO sensor for determining incomplete combustion of the combustion device. a complete combustion determining means, in incomplete combustion detecting apparatus and a combustion control means for controlling the combustion condition of the combustion apparatus based on the determination of the incomplete combustion determination means, wherein even after operation start of the combustion equipment After a lapse of a predetermined time from the ignition of the burner, C
CO sensor control means is provided for starting energization of the O sensor and stopping energization of the CO sensor when the operation of the combustion equipment ends, and the burner combustion amount is small during the predetermined time.
The length is set to be as long as possible .

[0007]

Further , the CO sensor control means of the present invention has
In another aspect, the predetermined time is a time until the ignition of the burner is completed .
You.

Also, the CO sensor control means of the present invention
In another aspect, the CO sensor control means starts energizing the CO sensor when a use operation in which the CO sensor is not energized is repeated a predetermined number of times or more within a second predetermined time longer than the predetermined time. It is characterized by.

[0010]

According to the present invention, the CO sensor control means controls the start and end timing of energization of the CO sensor. Burning
When starting the operation of the baking equipment, turn off the power to the CO sensor.
Delaying the start as much as possible will extend the life of the CO sensor.
The CO sensor control means is
After a predetermined time from the start of operation of the baking equipment, the CO sensor
Turn on electricity. In this case, the larger the combustion amount of the combustion equipment, the more C
The detection start of the O sensor is started early, and when the combustion amount is small,
Since the detection may be started later, the predetermined time is
To extend. Thereby, during operation of the combustion equipment,
Power is supplied to the CO sensor, and the
It is shortened compared to the past.

[0011]

Further, by setting the time after ignition completing a predetermined time, with delays the energization start time of the CO sensor, fuel multimers contained in the raw gas as in a city gas, etc. H ₂ prevents abnormal current from flowing to the CO sensor.

Further, when the use operation within the predetermined time is repeated a predetermined number of times or more within the second predetermined time, the CO sensor is immediately energized. This makes it possible to detect an incomplete combustion state even when the CO concentration in the combustion chamber rises due to repeated use within a short period of time within a predetermined time.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory sectional view of a water heater provided with the present embodiment, and FIG. 2 is a flowchart for explaining the operation of the present embodiment. FIGS. 3 to 6 are flow charts for explaining the operation of the other embodiments.

As shown in FIG. 1, a forced combustion gas water heater A includes a gas burner 2 that burns in a combustion housing 1.
The combustion fan 3 supplies combustion air X of the gas burner 2 to the combustion housing 1. In addition, water heater A
The combustion control device 4 supplies gas to the gas burner 2, ignites the gas burner 2, and controls the combustion fan 3. The combustion housing 1 is provided with a combustion air inlet (not shown) below and a discharge port 6 for discharging the combustion exhaust gas Z to the outside above. Further, a heat exchanger 7 is disposed above the gas burner 2 in the combustion housing 1. The gas burner 2 includes a burner group 8 that forms a flame, and a nozzle pipe 10 that is located below the burner group 8 and that has an ejection port 9. The fuel gas Y is supplied to the gas burner 2 through the gas pipe 11. The combustion fan 3 has turbo-type blades.

The combustion control device 4 includes a water regulator 12, a water sensor 13, a thermistor 14, an original gas solenoid valve 15, a main solenoid valve 16, a governor type gas proportional solenoid valve 17, an igniter 18, a frame rod 19, and a CO sensor. 20 and a controller 21 for controlling them. The incomplete combustion detection device of the present invention includes a CO sensor 20 and a controller 21. The controller 21 includes the combustion control unit 2
2. CO sensor control means 23, incomplete combustion determination means 24
A microcomputer provided with:

Next, the controller 21 of the combustion control device 4
The basic operation of will be described.

The controller 21 is a hot water tap (not shown).
Is detected by the water amount sensor 13 and the combustion control means 22 controls the source gas solenoid valve 15, the main solenoid valve 16, and the proportional solenoid valve 17 to open, and the fuel gas is supplied to the gas burner 2. Then, the combustion fan 3 is driven to ignite and burn the gas burner 2. Further, the CO sensor control means 23
To start energizing the CO sensor 20.

Further, when the hot water tap is closed, the controller 21 detects this by the water amount sensor 13, and the combustion control means 22 causes the original gas solenoid valve 15 and the main solenoid valve 1.
6. Control to close the proportional solenoid valve 17, stop driving the combustion fan 3, and extinguish the gas burner 2.

When the CO sensor 20 detects the CO concentration based on a predetermined standard during the combustion of the gas burner 2, the controller 21 activates the combustion control means 22 by the incomplete combustion determination means 24, and the original gas solenoid valve 15, Main solenoid valve 1
6. The proportional solenoid valve 17 is controlled to be closed, the driving of the combustion fan 3 is stopped, and the gas burner 2 is extinguished. Further, C
The energization of the CO sensor 20 is stopped by the O sensor control means 23.

After the hot water tap is opened, the CO sensor 20
The energization is started by the CO sensor control means 23 at any time between a and e in FIG.

After the hot water tap is closed, energization of the CO sensor 20 is stopped by the CO sensor control means 23 at any time between f and i in FIG.

In the present invention, a predetermined extension time is provided after the ignition of the burner 2 in order to delay the start of energization of the CO sensor 20 as much as possible. The extension time may be a fixed time, for example, three minutes, but is set according to the combustion amount. For example, as shown in FIG.
The CO sensor 20 is not energized until the gas amount proportional control is performed.
2, the detection value of the combustion amount (input) is integrated based on the fuel gas supply amount, and C is maintained until the integrated value exceeds a predetermined value.
An extended time during which no power is supplied to the O sensor is provided. Since the current of the proportional solenoid valve 17 changes according to the amount of combustion, the combustion control means 22 detects the amount of combustion (input) based on the current flowing at this time. Alternatively, the combustion amount may be detected based on the rotation speed of the combustion fan 3 corresponding to the combustion amount.

Therefore, the CO sensor control means 23 integrates the combustion amount (input) based on the current value of the proportional solenoid valve 17. The integrated value at this time increases with time. Then, the CO sensor control means 23 supplies power to the CO sensor 20 when the integrated value becomes equal to or more than the predetermined value, and the incomplete combustion determination means 24 determines incomplete combustion based on the output from the CO sensor 20.

The operation of the CO sensor control means 23 at this time will be described in more detail as follows. The CO sensor control means 23 does not energize the CO sensor 20 until the combustion amount (input) becomes equal to or more than the amount required to determine incomplete combustion. That is, when the amount of combustion is small, even if CO is generated, the amount is extremely small, so that it is not necessary to determine incomplete combustion. However, even if the amount of combustion is small, it is necessary to determine incomplete combustion if CO is accumulated and the concentration is increased by continuing combustion for a long time. In addition, when the combustion amount is large, it is necessary to determine incomplete combustion even for short-time combustion. As described above, the timing at which the determination of incomplete combustion is required depends on the magnitude of the combustion amount. Therefore, when the determination of incomplete combustion is unnecessary, the CO sensor 20 is not energized and the incomplete combustion is determined. If the CO sensor 20 is energized in the state where the determination is required, the CO sensor 20
The power supply time to the CO sensor 20 can be shortened, and the life of the CO sensor 20 can be extended.

Further, in the present invention, the above-mentioned extended time may be set to a time after ignition of the burner 2 until completion of ignition. For example, as shown in FIG. 4, the flame on the gas burner 2 is detected by the flame rod 19, and when the flame is detected, the combustion control means 22 outputs the flame control signal from the flame rod 19. Start the second timer,
The igniter 18 is turned off, and the proportional solenoid valve 17 performs gas amount proportional control. When the time-up signal of the 3-second timer is sent from the combustion control means 22 to the CO sensor control means 23, the CO sensor control means 23
The energization to 0 is started. This is because raw gas may remain in the combustion housing 1 until flames are uniformly formed in the burner group 8. Therefore, the CO sensor is activated three seconds after the start of ignition of the gas burner 2. Turning on 20 prevents occurrence of an abnormal current of the CO sensor when a large amount of H ₂ is contained in the raw gas. Thereby, the CO sensor 20 is made of a metal oxide semiconductor (SnO ₂ ).
Even when the zirconia or zirconia is used, the CO sensor can be protected when the raw gas remains, and the energization time to the CO sensor is shortened as a result, so that the life of the CO sensor can be extended.

Further, in the present invention, in order to delay the start of energization of the CO sensor 20 as much as possible, an extension time is provided after the ignition of the burner 2 in accordance with the combustion amount. If the ignition operation is performed many times within the extension time, the CO concentration gradually increases in the incomplete combustion state. In such a case, the CO sensor 20 is energized without an extension time. To do it.
For example, as shown in FIGS. 5 and 6, when the hot water tap is opened and the water amount sensor 13 detects this, the use operation is C
The counting is performed by the counting means provided in the O sensor control means 23, and the one-hour timer means and the three-minute timer means provided in the CO sensor control means 23 are started. Next, the combustion fan 3 is driven, the ignition operation is started by the igniter 18, the gas control valves 15, 16, 17 are opened to ignite the burner group 8, the flame is detected, and the combustion state is proportionally controlled.

As shown in FIG. 6, when the usage operation is less than a predetermined number of times, when the hot water tap is kept open until the timer time of the 3-minute timer means expires, the CO sensor 2
The energization is started to 0, and the incomplete combustion state is detected in the same manner as described above. At this time, the count number of the counter means is cancelled. However, when the hot water tap is closed by the end of the timer time of the three-minute timer means and the timer time of the one-hour timer means has not expired, the combustion is stopped and the CO sensor 20 is not energized. This one
After a predetermined number of times or more of the short-time use operation is performed during the timer time of the time timer means, the power supply to the CO sensor 20 is started regardless of the elapse of the three-minute timer time of the three-minute timer means. Then, an incomplete combustion state is detected. In this way, even when the use operation for less than 3 minutes is repeated and the CO concentration in the combustion chamber increases, this can be detected. However, if the short-time use operation is not repeated a predetermined number of times or more within the timer time of the one-hour timer means, the CO concentration in the combustion chamber slightly increases during this short-time use operation, so After the elapse of the timer time of the timer means, the counting of the use operation is cancelled, and the counting of the use operation is started again.
Reset the time timer means.

[0029]

As is apparent from the fact above, according to the present invention, the present invention is to energize the CO sensor only during the operation of the combustion equipment by the CO sensor control unit, moreover, the CO sensor control
Means for a predetermined time after the start of ignition of the burner
By delaying the energization of the sensor, the CO sensor
Life can be extended. By setting this extended time longer as the amount of combustion is smaller, the start of energization of the CO sensor can be delayed according to the amount of combustion.

Further, by setting the extension time until the ignition completion of the burner, the abnormal current flows in the CO sensor by a large amount of H ₂ raw gas remaining in the combustion chamber before ignition of the burner is completed And the life of the CO sensor can be extended.

Further, if the ignition operation is repeated within the extended time and the CO concentration in the combustion chamber rises, the extended time is canceled and the CO sensor is energized. The incomplete combustion state can be detected.

Therefore, according to the present invention, it is possible to provide an incomplete combustion detection device capable of extending the service life of the CO sensor to approach the service life of the combustion equipment.

[Brief description of the drawings]

FIG. 1 is an explanatory sectional view of a water heater provided with this embodiment of the present invention.

FIG. 2 is a flowchart for explaining the operation of the embodiment.

FIG. 3 is a flowchart for explaining the operation of another embodiment.

FIG. 4 is a flowchart for explaining the operation of another embodiment.

FIG. 5 is a flowchart for explaining the operation of another embodiment.

FIG. 6 is a flowchart for explaining the operation of another embodiment.

[Explanation of symbols]

A: water heater (combustion equipment), 1: combustion housing (combustion chamber), 2: gas burner (burner), 17: proportional solenoid valve (fuel supply means), 18: igniter (ignition means),
20: CO sensor, 22: combustion control means, 23: CO sensor control means, 24: incomplete combustion determination means.

 ──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-5-26439 (JP, A) JP-A-62-729 (JP, A) JP-A-3-140709 (JP, A) JP-A 61-1986 295425 (JP, A) JP-A-58-214714 (JP, A) JP-A-63-80447 (JP, U)

Claims (3)

(57) [Claims] 1. A burner provided in a combustion chamber, fuel supply means for supplying fuel to the burner, ignition means for igniting the burner, and an exhaust passage provided downstream of the combustion chamber. A CO sensor provided in the combustion device; a CO sensor provided in the exhaust passage; an incomplete combustion determination unit configured to determine incomplete combustion of the combustion device based on an output of the CO sensor; And combustion control means for controlling the combustion state of the combustion device based on the incomplete combustion detection device, after the operation of the combustion device is started and when the burner is ignited.
A CO sensor control means for starting energization of the CO sensor after a lapse of a predetermined time from when the operation of the combustion device is terminated, and stopping the energization of the CO sensor when the operation of the combustion device is completed , wherein the combustion amount of the burner is small during the predetermined time. As long as
An incomplete combustion detection device for combustion equipment, characterized in that it is specified . 2. A burner provided in a combustion chamber;
Fuel supply means for supplying fuel to the burner;
Igniting means for igniting, provided on the downstream side of the combustion chamber
A CO sensor provided in a combustion device having an exhaust passage, the CO sensor provided in the exhaust passage,
Failure to determine incomplete combustion of the combustion equipment based on the output of the
A complete combustion determining means, and an incomplete combustion determining means.
Control means for controlling the combustion state of the combustion equipment
The incomplete combustion detection device comprising:
After a predetermined time has elapsed from the start of energization of the CO sensor,
When the operation of the combustion equipment is completed, energize the CO sensor.
A CO sensor control means for stopping is provided, and the predetermined time is maintained until ignition of the burner is completed.
Incomplete combustion of combustion equipment characterized by time in the air
Detection device. 3. A burner provided in a combustion chamber;
Fuel supply means for supplying fuel to the burner;
Igniting means for igniting, provided on the downstream side of the combustion chamber
A CO sensor provided in a combustion device having an exhaust passage, the CO sensor provided in the exhaust passage,
Failure to determine incomplete combustion of the combustion equipment based on the output of the
A complete combustion determining means, and an incomplete combustion determining means.
Control means for controlling the combustion state of the combustion equipment
Incomplete combustion detection device comprising: after the start of operation of the combustion equipment, and when the burner is ignited
After a predetermined time has elapsed from the start of energization of the CO sensor,
When the operation of the combustion equipment is completed, energize the CO sensor.
CO sensor control means for stopping is provided, and the CO sensor control means is provided with a second sensor that is longer than the predetermined time.
Use operation in which the CO sensor is not energized within the specified time is specified
If it is repeated more than times, turn on the power to the CO sensor.
Incomplete combustion detection device for combustion equipment characterized by starting
Place.