JPH0968311A - Combustion equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize the restoration of sensitivity by a method wherein combustion time of a burner is integrated by a combustion time integrating means and a heat cleaning operation is executed in a state where the burner is not burning each time the integrated time reaches a set value to remove matters stuck to the surface. SOLUTION: A control section H has a combustion control means 101 to control the operation of a burner 2 and a fan 4 and judges the state of incomplete combustion by an incomplete combustion judging means 103 based on an output value of a catalyst combustion type CO sensor S. A judgment reference value Vm as reference for the judgment of the incomplete combustion is stored into a judgment reference value memory means 105 as output value of the CO sensor S in a state where the concentration D of CO is predicted to be zero. In this case, heat cleaning operation is executed by a CO sensor control means 102 to heat the catalyst combustion type CO sensor S to a temperature higher (about 600 deg.C) than a set value for detection each time an integrated value of the combustion time of the burner 2 reaches a set integrated time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a catalytic combustion type unburned component detecting means for detecting the concentration of unburned component in combustion gas of a burner in a state where a set temperature for detection or a temperature close thereto is set. Incomplete combustion determination means for determining incomplete combustion of the burner based on the detection information of the unburned component concentration detection means, and the detection setting in a state where the unburned component is predicted to be zero The present invention relates to a combustion apparatus provided with a reference value storage unit that stores a detection value of the unburned component concentration detection unit in a state of being set to a temperature or a temperature close thereto as a reference value for determining the incomplete combustion. .

[0002]

2. Description of the Related Art In the above-described combustion apparatus, conventionally, as shown in Japanese Utility Model Laid-Open No. 5-90418, a CO sensor is used as an unburned component concentration detecting means, and when the burner is not in a combustion state, that is, A state where the unburned component is predicted to be zero, specifically, for example, when the power is turned on to the device or after the burner is extinguished, the sensor output at that time is stored as the determination reference value. Therefore, even if the reference value deviates from the initial setting value (adjustment value at the time of factory shipment) due to, for example, aging, the sensor output when the burner is not in the combustion state is appropriately set. By storing the reference value as a reference value, there is a method that allows the unburned component concentration to be detected accurately.

[0003]

By the way, in this type of combustion apparatus, the combustion gas of the burner contains, for example, sulfide, but the unburned component concentration detecting means is not burned in the combustion gas. In order to detect the component concentration, since it is installed in a place where the combustion gas flows, such a sulfide may adhere to the surface of the detection means, but if such a sulfide adheres, It is known that the detection sensitivity of the unburned component concentration detection means deteriorates. Note that in such sensitivity deterioration, not only the so-called zero-point output (the output when the unburned component is predicted to be zero) changes, but also the change characteristic of the output value with respect to the change in the unburned component concentration is different. It becomes a thing.

However, in the above-mentioned conventional structure, the output when the burner is not in the combustion state is stored and the value is used as the reference value for discrimination. Therefore, the unburned component concentration detection as described above is performed. No measures were taken against the deterioration of the detection sensitivity of the means, and there was the disadvantage that the unburned component concentration could not be detected accurately.

Therefore, as a method of avoiding such a disadvantage, for example, a configuration in which the output value of the unburned component concentration detecting means is corrected in accordance with the integrated value of the burner combustion time can be considered. Even in the above, the combustion state of the burner (the above-mentioned state of the deposits generated) is not always constant, and it is difficult to set the correction coefficient with high accuracy, and it cannot be said that this is a sufficient measure. However, the unburned component concentration could not be detected accurately.

The present invention has been made in view of such a point, and an object thereof is to provide a combustion device capable of detecting the concentration of unburned components with high accuracy for a long period of time.

[0007]

According to the characteristic construction of claim 1, the combustion time of the burner is integrated by the combustion time integration means, and the control means heats each time the integration time reaches the set integration time. The cleaning operation is executed. That is, in the state where the burner is not burning, the unburned component concentration detecting means is set to a temperature higher than the set temperature for detection only during the set time.

With such a high temperature, the adhering matter adhering to the surface is removed, and the sensitivity deteriorated due to the adhering matter is recovered.

The deterioration of sensitivity due to the above-mentioned deposits is caused by
The longer the burner burns, the more it progresses,
The heat cleaning operation performed each time the integrated value of the burner combustion time reaches the set integrated time can prevent excessive progress of sensitivity deterioration.

Further, for example, if the heat cleaning operation is executed every time combustion of the burner is stopped, when the combustion is frequently started and stopped, the unburned component concentration detecting means is heated by high temperature. Although there is a risk of applying thermal stress, the risk of lowering the durability of the unburned component concentration detecting means can be reduced by adopting a configuration that is executed based on the integrated value of the combustion time.

After the heat cleaning operation is completed, the control means determines that the unburned component is in a state of zero and is set to the detection set temperature or a temperature close to the set temperature for detection. The detected value of the fuel component concentration detecting means is stored in the reference value storage means as the reference value for discrimination.

Therefore, since the reference value is stored in a state where the deposit is removed by the heat cleaning operation and the detection sensitivity is restored, the subsequent detection of the unburned component concentration can be performed with high accuracy, resulting in The complete combustion can be accurately determined.

According to the characterizing feature of the second aspect, after the heat cleaning operation is completed, the abnormal state determination means is in a state where the unburned component is predicted to be zero and the set temperature for detection or the set temperature for detection. If the detected value of the unburned component concentration detecting means in the state of being set to a close temperature is out of the set range, it is determined that the unburned component concentration detecting means is malfunctioning.

Therefore, it is possible to accurately determine whether or not the operation abnormality occurs based on the detection value in the proper detection state in which the adhered matter is removed by the heat cleaning operation.

According to the third aspect of the invention, each time the heat cleaning operation is completed, the unburned component is set to a state where it is predicted to be zero, and the temperature is set to the detection set temperature or a temperature close thereto. In the state, since the detection value of the unburned component concentration detecting means is configured to be stored in the deterioration determination value storage means as the deterioration determination value, based on this deterioration determination value, for example, the latest deterioration determination value and By comparing with the previous deterioration determination value, it is possible to determine the sensitivity deterioration after the previous heat cleaning operation until the current heat cleaning operation.

According to the fourth aspect of the present invention, after the first set time has elapsed from the time when the combustion of the burner was stopped, the first discriminating means predicts that the unburned component is zero. Whether or not the detection value of the unburned component concentration detecting means in the state where the temperature is set to the detection setting temperature or a temperature close thereto is within the first setting range set based on the determination reference value. To be determined. Then, after it is determined by the first determining means that the current value is not within the first set range,
After the lapse of the first set time, and further after the lapse of the second set time, the second discriminating means sets the detection set temperature or a temperature close to the detection set temperature in a state where the unburned component is predicted to be zero. In this state, it is determined whether or not the detection value of the unburnt component concentration detecting means is within the second set range set based on the deterioration determination value. This second
If the determination means determines that the combustion time is not within the second set range, the heat cleaning operation is executed regardless of the integration time by the combustion time integration means.

That is, the first discriminating means always detects the output fluctuation based on the discriminating reference value as the newest detection information to make a tentative determination as to whether or not the unburned component concentration detecting means is abnormal. If it is determined by the first determination means that the output is not within the set range, then the output is stable after the second set time has elapsed, and then based on the deterioration determination value. By detecting the output fluctuation, it is possible to accurately determine whether or not the unburned component concentration detecting means has deteriorated after the previous heat cleaning operation.

Therefore, by performing the tentative discrimination by the first discriminating means, when the unburned component concentration detecting means is not deteriorated, the second set time for stabilizing the output elapses each time the burner stops burning. There is no need to wait for a while, and the time required for the determination can be made as short as possible.

Even if the combustion integrated time does not reach the set integrated time, if the deterioration is not within the second set range and the deterioration is large, the heat cleaning operation is executed to surely recover the detection sensitivity. This makes it possible to detect the unburned component concentration with higher accuracy.

Furthermore, after the second set time has elapsed, if the value is within the second set range, the detected value at that time is stored in the determination reference value storage means, so that the subsequent incomplete combustion is performed. In this case, the reference value can be set with higher accuracy.

According to the fifth aspect of the invention, the temperature of the unburned component concentration detecting means in the heat cleaning operation is set to a high temperature at which the adhering sulfide can be decomposed and removed. By removing sulfide,
Reliably detect the detection sensitivity deteriorated due to the adhesion of sulfide.
It can be restored to its original state.

According to the characterizing feature of claim 6, the discriminating reference value which is first stored in the reference value storage means after being installed in the use position is set in the initial reference value storage means as the initial reference value. Is stored as Then, in the determination by the abnormal state determination means performed after the end of the heat cleaning operation, if it is outside the set range set based on the installation initial reference value, it is determined that the operation is abnormal.

That is, the discriminating reference value which is first stored after being installed at the use position is a value in a state where there is no deterioration due to burner combustion, and is set based on the actual output. Since it is a value, by discriminating based on this value, variations due to individual differences, or
It becomes possible to accurately determine whether or not the unburned component concentration detecting means is abnormal in a state in which output fluctuation due to vibration during installation or transportation is not included.

According to the seventh aspect of the invention, the unburned component concentration detecting means is provided because the safety means is provided for executing a predetermined safe operation when the abnormal state determining means determines that the operation is abnormal. When the burner combustion continues even after the detection of the unburned component concentration by the normal condition cannot be performed normally, it is possible to avoid the disadvantages such as the incomplete combustion cannot be discriminated well. The safety of can be secured.

According to the characterizing feature of claim 8, the safety means is constituted so as to restrain the combustion operation of the burner when the abnormal operation state is determined by the abnormal state determining means a set number of times. When the operation abnormality is misjudged only once, if it is configured to immediately restrain the combustion operation of the burner, due to some sudden abnormality,
Even if the operation abnormality is determined, there is a disadvantage that the combustion device cannot be operated unnecessarily and the usability is deteriorated. However, by configuring as described above, such a disadvantage can be avoided. . Moreover, since the abnormality of the unburned component concentration detecting means can be accurately detected, the work efficiency at the time of maintenance work is also improved.

According to the ninth aspect of the present invention, the combustion time integration means is configured to integrate the combustion time with a greater weight as the fuel supply amount increases, as the fuel supply amount to the burner changes. Therefore, as the fuel supply amount increases, the heat cleaning operation is executed in a shorter combustion time. The larger the fuel supply,
The amount of sulfides attached per unit burning time also increases, and the degree of sensitivity deterioration increases, but in such a case, the heat cleaning operation is effectively executed in a short burning time, The progress of deterioration can be suppressed to a minimum.

According to the characterizing feature of the tenth aspect, the control means has a shorter time as the integrated value is larger, based on the integrated value of the combustion time of the burner integrated by the combustion time integrating means. As described above, since the set integrated time is configured to be changed, the total combustion time of the burner,
In other words, if the usage period becomes long, the concentration of unburned components may tend to increase due to aging, etc.,
As the usage period becomes longer, the time interval (set integration time) at which the heat cleaning is executed becomes shorter, so that the progress of sensitivity deterioration can be suppressed in a more appropriate state.

[0028]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a hot water supply apparatus as an example of a combustion apparatus according to the present invention. The hot water supply apparatus includes a water heater Y and a water heater Y.
And a remote controller R. The water heater Y includes a combustion chamber 1, a burner 2 provided inside the combustion chamber 1, and a heat exchanger 3 for heating water.
And an exhaust passage 5 which is connected to the upper part of the combustion chamber 1 and discharges the combustion gas of the burner 2 to the outside of the room, and the combustion air is passed through the burner 2 and the combustion gas of the burner 2 passes through the exhaust passage 5 to the outside of the room. Fan 4 as a ventilation means for discharging to the heat exchanger, a water supply passage 6 for supplying water for heating to the heat exchanger 3, and a hot water supply passage for supplying hot water heated in the heat exchanger 3 to a hot water tap (not shown) 7
And a fuel supply passage 8 for supplying fuel (gas) to the burner 2.

In the water supply passage 6, the amount of water supplied to the heat exchanger 3 Qi
The water supply amount sensor 9 for detecting the
Hot water temperature sensor 1 for detecting the hot water temperature Tx for the hot water tap
0 is provided. The fuel supply passage 8 is connected to a gas supply pipe for general households, and the burner 2 is connected to the fuel supply passage 8.
An electromagnetic proportional valve 11 for adjusting the fuel supply amount Ip to the fuel cell and an on-off valve 12 for intermittently supplying the fuel are provided. An igniter 18 for igniting the burner 2 and a frame rod 19 for detecting the ignition are provided near the burner 2.

The remote controller R is connected to the control unit H by wire or wirelessly, and has an operation switch 13 for instructing the operation and stop of the hot water supply device, a temperature setting switch 14 for setting a set target hot water supply temperature Ts, and various information. Display lamps 15, 16, 17, etc. for displaying are provided. The display lamp 15 is configured to display whether or not the hot water supply device is operating, and the display lamps 16 and 17 are configured to display an abnormal state as described later.

A catalytic combustion type CO sensor S, which is an example of an unburned component concentration detecting means, is provided in the exhaust passage 5 in a state of being in contact with the combustion gas of the burner 2. The CO sensor S is configured to output an output value according to the concentration D of carbon monoxide (CO) as an unburned component contained in the combustion gas.

FIG. 2 shows the configuration of this CO sensor S. The CO sensor S is a protective frame 2 made of stainless steel.
1, the sensor element 23, the temperature compensating reference element 24, and the ambient temperature T of the CO sensor S on the pedestal 22 inside
It is equipped with a temperature sensor 25 that detects _A. The sensor element 23 and the temperature compensating reference element 24 are each composed of a platinum wire carrying a catalyst, and the sensor element 23, the temperature compensating reference element 24, and the resistance elements 26 and 27 are different from those in FIG. As shown in, the bridge circuit state is connected. Then, the sensor element 23 and the temperature compensating reference element 24 are heated to about 200 ° C. as the set temperature for detection by the flow of the current, and the unburned component in contact with the surface thereof is burned by the catalytic action. At this time, since the catalyst carried by the sensor element 23 has selectivity for CO, a difference occurs in the element temperature between the sensor element 23 and the temperature compensating reference element 24. Since the resistance value of a platinum wire changes depending on the temperature, C in the combustion gas
As the O concentration increases, the difference in resistance between the sensor element 23 and the temperature compensating reference element 24 increases. Therefore,
The output value Vs according to the CO concentration in the combustion gas is the voltage value (unit: unit of connection between the sensor element 23 and the temperature compensation reference element 24 and the connection between the resistance elements 26 and 27 in the bridge circuit). Volt). In addition, 28 in FIG. 2 is a connector part with the lead wire connected to the control part H.

The output value Vs of the CO sensor S has a temperature characteristic that it changes according to the ambient temperature T _A even if the CO concentration is the same. FIG. 4 shows the temperature characteristics of the output value Vs when the CO concentration D is predicted to be zero. The solid line L1 in FIG. 4 indicates that the CO sensor S has not deteriorated (at the time of shipment). 2) shows the temperature characteristic of the output value Vs in the state where the CO concentration D of) is predicted to be zero. Further, as the CO concentration D increases, the output value Vs of the CO sensor S increases in a state where the solid line L1 is translated in the direction in which the output value increases. In FIG. 4, the ambient temperature T
The range of _A of 70 to 200 ° C generally corresponds to the region where the burner 2 burns, and the range of 70 ° C or less corresponds to the region where combustion of the burner 2 almost stops.

When the ambient temperature T _A is fixed at a predetermined temperature, the CO concentration D and the output value Vs have a correlation represented by Vs = αD + β. However, α is the CO sensor S
, Β is CO when the ambient temperature T _A is a predetermined temperature.
It is an output value when the density D is predicted to be zero. FIG. 5 shows the correlation between the CO concentration D and the output value Vs, and the solid line M1 in FIG. 5 shows the correlation when the CO sensor S is not deteriorated (initial stage).

As shown by the broken lines L2 and L3 in FIG. 4, when the CO sensor S deteriorates, the output value Vs when the CO concentration D is predicted to be zero is the solid line L1.
Shows a tendency to decrease in a state of parallel movement in the direction in which the output value decreases. If the deviation of the output value Vs when the CO concentration D is predicted to be zero between the deterioration of the CO sensor S and the initial use is ΔV, the CO sensor S
The deviation ΔV tends to increase as the degree of deterioration increases. Also, the sensitivity α of the CO sensor S changes with deterioration, but between the sensitivity α and the deviation ΔV, α = α _C (1-K ₁ × ΔV) (where α _C is an initial value) It has been empirically determined that there is a correlation shown. In other words, the greater the deterioration, the lower the output value when the CO concentration D is predicted to be zero, and the lower the sensitivity α (the gentler the slope). However, K ₁ is a predetermined constant. Therefore, the correlation between the CO concentration D and the output value Vs when the CO sensor S deteriorates is represented by Vs = αD + β = α _C (1-K ₁ × ΔV) D + β.

As shown by a broken line L2 in FIG. 4, when the output value Vs when the CO concentration D is predicted to be zero decreases, the correlation between the CO concentration D and the output value Vs is As indicated by a broken line M2 in FIG. 5, similarly, as indicated by a broken line L3 in FIG.
When the output value Vs decreases when the O concentration D is predicted to be zero, the correlation between the CO concentration D and the output value Vs is as shown by the broken line M3 in FIG.

The control section H is provided with a microcomputer, controls combustion operation of the burner 2 and operation of the fan 4, and controls the energization operation of the CO sensor and information on the detected value. Each time the integrated value of the combustion time of the burner 2 reaches the set integrated time, the temperature of the CO sensor is higher than the set temperature for detection (high temperature at which the adhered sulfide can be decomposed and removed, specifically about 600 °). C) the CO sensor control means 102 for executing the heat cleaning operation, the incomplete combustion determination means 103 for determining the incomplete combustion state on the basis of the output value of the CO sensor S, and the CO in the production and shipping stage of the water heater. A shipping reference value storage unit 104 that stores in advance the output value of the CO sensor S when the concentration D is predicted to be zero as the shipping reference value V _OB.
And a discrimination reference value storage means 105 for storing an output value of the CO sensor S when the CO concentration D is predicted to be zero as a discrimination reference value Vm which is a reference for discrimination of incomplete combustion.
After the hot water supply device is installed at the use position, the initial reference value storage means 106 that initially stores the value stored in the determination reference value storage means 105 as the installation initial reference value, and whether or not the CO sensor has an abnormal operation is determined. Abnormal state determination means 10 for determining
7. Every time the heat cleaning operation is completed, CO
Deterioration determination value storage means 108 that stores the detection value of the sensor as the deterioration determination value, and the first from the time when combustion of the burner is stopped.
After the set time has elapsed, the detected value of the CO sensor is
First discriminating means 109 for discriminating whether or not it is within the first setting range set based on the discrimination reference value (Vm), and the first discriminating means 109 may not be within the first setting range. After the determination, after the first set time has elapsed,
After the second set time has elapsed, the second determination means 11 that determines whether or not the detected value of the CO sensor is within the second set range set based on the deterioration determination value (V _HC ).
0, an integration timer 111 as a combustion time integration means for integrating the combustion time of the burner 2, and a safety means 112 for restraining the combustion operation of the burner when the operation abnormality is determined a predetermined number of times by the abnormal state determination means 107. Has been.

The storage means 104, 105, 106,
Each of the units 108 is composed of, for example, an EEPROM (electrically writable and erasable non-volatile memory) or the like, and the other units described above are provided in the non-volatile memory or the like in a control program format.

The control unit H includes a remote control device R, a fan 4, a water supply amount sensor 9, a hot water supply temperature sensor 10, an electromagnetic proportional valve 11, an intermittent valve 12, an igniter 18, a frame rod 1.
9, the CO sensor S, and the temperature sensor 25 are connected.

When the water supply amount Qi adjusted by the hot water supply plug and detected by the water supply amount sensor 9 reaches the set water amount, the combustion control means 101 executes the ignition control of the burner 2 so that the hot water supply temperature Tx becomes the set target hot water supply temperature Ts. The fuel supply amount Ip of the burner 2 is adjusted so that the rotation speed of the fan 4 is controlled so that the rotation speed of the fan 4 becomes a target rotation speed set in advance for the fuel supply amount Ip. The combustion of the burner 2 is stopped when the amount Qi becomes less than the set amount of water.

As described above, the CO sensor S has a temperature characteristic that it changes according to the ambient temperature T _A even if the CO concentration D is the same. As the characteristic data with respect to the change in the temperature T _A , that is, the output value data is set and stored in the format of the map data shown by the solid line L1 in FIG.

The incomplete combustion discriminating means 103 basically calculates the CO concentration D based on the output value Vs of the CO sensor S by the relational expression Vs = αD + β. That is, based on the deviation ΔV between the initial reference value V _O and the discrimination reference value Vm, α
Change in the _{α = α C (1-K} 1 ΔV) relational expression, and the function F (T _A of atmosphere β temperature T _A and the [Delta] V, delta
V), and the CO concentration D is calculated. Note that α _C (initial value) is stored in advance. Further, the incomplete combustion determination means 103 determines that the incomplete combustion state is the incomplete combustion state when the correction concentration is equal to or higher than the set concentration (for example, 1000 ppm) for the set time (for example, 20 seconds), and the display lamp Lighting 17 indicates that the combustion is incomplete.

That is, the incomplete combustion discriminating means 103 calculates the CO concentration D on the basis of the deviation ΔV, the sensitivity α changed based on the deviation ΔV and the output value Vs to discriminate the incomplete combustion state. Is configured. Immediately after the combustion of the burner 2 starts, a transient incomplete combustion state occurs in the combustion of the burner 2 and the CO concentration D temporarily becomes extremely high. In order not to make a determination, the incomplete combustion determination operation is not executed during the elapse of a set time (for example, 60 seconds) after the start of combustion.

After the heat cleaning operation is completed, the CO sensor control means 102 is set in a state where the CO concentration (concentration of unburned components) is expected to be zero and at the detection set temperature or a temperature close thereto. The detected value of the CO sensor in the open state is the reference value for discrimination (Vm)
Is stored in the discrimination reference value storage means 105 as
Each time the heat cleaning operation is completed, the detection value of the CO sensor in the state where the CO concentration is predicted to be zero and the set temperature for detection or a temperature close to the set temperature is set to the deterioration determination value (V _HC ) is stored in the deterioration determination value storage means 108. Further, when the second discriminating means 110 discriminates that it is within the second set range, the detection value at that time is stored in the discrimination reference value storing means 105.

Therefore, the CO sensor control means 102, when the integration time by the integration timer 111 (combustion time integration means) reaches the set integration time, while the burner 2 is not combusting, while the set time elapses. Performing a heat cleaning operation to bring the unburned component concentration detecting means S to a temperature higher than the set temperature for detection, and
After completion of this heat cleaning operation, C
The detected value of the unburned component concentration detecting means S in a state where the O concentration (unburned component) is predicted to be zero and is set to the set temperature for detection or a temperature close to the set temperature for detection,
The discrimination reference value storage means 1 as the discrimination reference value Vm.
05 will function as a control means to be stored.

The abnormal state discriminating means 107 is based on the deviation between the shipping reference value V _0B and the initial reference value V _0, and is transported, transported, or installed during the period from the production and shipping to the installation at the place of use. It is determined whether or not the output value of the CO sensor S is largely deviated from the shipping reference value V _OB due to vibration or shock generated at the time of determination, and the initial abnormality of the sensor S is determined. , After that, the initial reference value V
It is configured to determine the abnormality of the sensor depending on whether the output value of the CO sensor is within the set range set based on ₀ .

The control operation of the control unit H will be described below with reference to FIG.
~ It demonstrates based on the flowchart shown in FIG. When this water heater is installed at a place of use and a power switch (not shown) provided in the water heater is turned on and the power is turned on, it is determined whether or not the setting flag is set (step 1). Since this setting flag is not set at the initial stage of installation, the process proceeds to step 2 and the shipping reference value V stored in advance in the shipping reference value storage means 104 is set.
_OB is read out and set as the first-time discrimination reference value Vm (step 2). The shipping reference value V _OB is, for example, a temperature corresponding to an ambient temperature T _A of 25 ° C. in the map data stored in advance at the shipping stage. And C
Turn on the O sensor power to start energizing the CO sensor,
The element temperature is heated to about 200 ° C. (set temperature for detection) (step 3). If the ambient temperature T _A is less than 70 ° C. after 2 minutes have passed, the burner 2 is not combusted and the CO concentration D is predicted to be zero. Therefore, the output of the CO sensor S at that time. The value Vs is compared with the shipping reference value V _OB, and if the deviation does not exceed the set amount (0.6 volt), the output value Vs is stored as the determination reference value Vm, and the standby for combustion operation is possible. State (step 4 ~
8). In this case, it goes without saying that a value obtained by correcting Vs (corresponding to, for example, 25 ° C.) is set as Vm by the ambient temperature T _A and compared with the initial reference value V ₀ . Thereafter, if combustion is not started even after 6 minutes have passed and the conditions for reading and storing are satisfied, the determination reference value Vm is rewritten and stored again, and the CO sensor power supply is turned off (steps 9 to 9). 13). If hot water supply is started before 6 minutes have elapsed in step 9, the process proceeds to step 14 described later.

If the ambient temperature T _A exceeds 70 ° C. or the deviation exceeds the set amount (0.6 V), it is determined that the temperature sensor 25 or the CO sensor S has an initial abnormality. The display lamp 16 is turned on to display the abnormality, and the combustion operation of the burner 2 is prohibited until a reset operation such as OFF / ON of the power switch is performed (steps 39, 40, 41).

After that, the hot water supply is started and the water supply amount sensor 9
When the combustion start is instructed by the amount of water supply Qi detected by the above exceeds the set amount of water (step 14), CO
If the power of the sensor S is OFF, turn the power ON,
Ignition control of the burner 2 is executed (steps 15 to 1).
7). That is, the electromagnetic proportional valve 11 and the opening / closing valve 12 are opened to supply the fuel gas to the burner 2, and the igniter 1
8 is ignited, and when ignition is confirmed by the frame rod 19, the ignition operation is stopped. Then, the integration is started by the integration timer 111 and the combustion control is executed (steps 18 and 19). That is, the hot water temperature sensor 1
The hot water supply temperature Tx detected by 0 is the set target hot water supply temperature T
In order to achieve s, the solenoid proportional valve 11 is adjusted and controlled to adjust the fuel supply amount Ip of the burner 2, and the rotation speed of the fan 4 becomes a target rotation speed that is preset with respect to the fuel supply amount Ip. Thus, the rotation speed of the fan 4 is controlled. Further, in addition to the combustion control as described above, the incomplete combustion determination control as described later is executed (step 20). Step 14
If the start of combustion is not instructed and the power switch on the side of the water heater is turned off in step 2, the control ends (step 2).
1).

When the hot water tap is closed and the water supply amount Qi detected by the water supply amount sensor 9 falls below the set water amount, the solenoid proportional valve 11 and the on-off valve 12 are closed to stop the combustion of the burner 2 ( Steps 22 and 23), integration timer 111
And the ventilation by the fan (post-purge) is executed for a set time (5 minutes) after the combustion of the burner 2 is stopped (step 24).
5).

The first after the post-purging (pp) is completed
When the set time (1 minute) has elapsed, it is determined whether or not the set flag is set (steps 26 and 27).
At the time of initial combustion, since the setting flag is not set, the routine proceeds to step 28, and after the second set time (50 minutes) has elapsed since the post-purge was completed, the atmospheric temperature T _A of the CO sensor S is 70 ° C. When it is confirmed that it is less than the value, the output value Vs of the CO sensor S at that time is read (steps 29 and 30). Next, it is judged whether or not the setting flag is set (step 31). Since the setting flag is not set at the time of initial combustion, the routine proceeds to step 32, where the read output value Vs and the shipping reference value V _{OB are set.} If the deviation from is less than the set amount (0.6 V), it is determined to be normal, and the output value Vs at that time is
It is set as the initial reference value V _O in the initial state of installation, and is also set as the determination reference value Vm and the deterioration determination reference value V _HC at that time (step 33). FIG. 4 shows a case where the initial reference value V _O slightly changes with respect to the shipping reference value V _OB .

Then, when the initial reference value V _O is set and stored, the count value N of the abnormality occurrence counter is reset, the setting flag is set, the power of the CO sensor is turned off and the process returns to step 14 to start combustion. It returns to the standby state of the command (steps 34, 35, 36).

The above-described control up to this point is the control of the initial combustion operation of the burner 2 after installation and the operation associated therewith. Therefore, whether or not the installation is in the initial state is determined by the setting flag not being set.

In step 32, the deviation between the read output value Vs and the shipping reference value V _OB is the set amount (0.
If it exceeds 6 volts, it is determined that the CO sensor S is an initial abnormality that has occurred due to vibration during transportation or installation work before installation, and the abnormality occurrence counter is counted up. (Step 37). In the initial state, the count value N of the abnormality occurrence counter is 3 times or less (step 38). Therefore, after the combustion control of the burner 2 is executed again with the setting flag not set,
It is determined whether the deviation between the read output value and the shipping reference value is less than the set amount (0.6 volt) (steps 14 to 32), and the count value N of the abnormality occurrence counter is set to 3 times or more. Then, the display lamp 16 is turned on to display the abnormality, the sensor power is turned off, and the combustion operation of the burner 2 is prohibited until a reset operation such as an OFF / ON operation of the power switch is performed. 39,4
0,41).

After the initial reference value V _O is set, even if the start of combustion is not commanded and the power switch is turned off and then the power switch is turned on again, the setting is made in step 1. Since the flag is set, the routine proceeds to step 14, where the hot water supply operation standby state is entered.

When the combustion start is commanded after the initial reference value V _O is set, the above-described combustion control and incomplete combustion determination control are executed, and when the combustion stop is commanded,
The combustion of the burner 2 is stopped and the post purge is executed (steps 14 to 25). Since the setting flag is set in step 27, the process proceeds to step 42,
After the end of the post-purge, the abnormality occurrence counter is not counted, and the output value Vs of the CO sensor S after the elapse of the first set time (1 minute) is 0.4 in the first set range (centering on the discrimination reference value Vm). If the deterioration is not so large, that is, if the combustion integration time t of the burner 2 by the integration timer 111 exceeds the set time (20 hours), it is determined and exceeded. If not, the sensor power is turned off and the control ends (steps 42, 43, 44, 36). If the abnormality occurrence counter is counted, the output value is outside the first set range, or the combustion integrated time t exceeds the set time, the routine proceeds to step 28. When it is confirmed that the second set time (50 minutes) has passed since the end of the post-purge and the atmospheric temperature T _A of the CO sensor S is lower than 70 ° C., the CO sensor S at that time is checked. The output value is read (steps 28-30). If the ambient temperature T _A of the CO sensor is 70 ° C. or higher, it is determined that the temperature sensor 25 is abnormal, the lamp 16 is turned on to display the abnormality, the sensor power is turned off, and the power switch is turned off / on. Until reset operation such as ON operation is performed,
The combustion operation of the burner 2 is prohibited (steps 39, 40,
41).

Next, it is judged whether or not the setting flag is set (step 31). At this time, since the setting flag has already been set, the routine proceeds to step 45, where the abnormality occurrence counter is not counted, When the combustion integrated time t of the burner 2 does not exceed the set integrated time (20 hours), the read output value Vs is in the second setting range (based on the deterioration determination value, which is set based on the deterioration determination value. 1.
If it is within the range of 0 volt), the output value at that time is stored in the discrimination reference value storage means, and the sensor power supply is turned off (steps 46, 47, 48). And step 45
If the error occurrence counter is being counted in,
If the combustion integrated time t of the burner 2 exceeds the set integrated time (20 hours) in step 46, or if the output value Vs is out of the second set range in step 47, the current supplied to the CO sensor is adjusted. High temperature (approx. 600 ° C) that makes it possible to decompose and remove attached sulfides.
A heat cleaning operation of heating to C) is executed (step 49).

After the heat cleaning operation is executed in step 49, the output value V of the CO sensor S is again measured.
s is read (step 50), and the output value is a voltage range of 1.2 volts (setting range) centering on the initial reference value.
It is judged whether or not it is within the range, that is, whether or not there is an operation abnormality that it is not within the proper range although the heat cleaning is executed (step 51). If the output value is out of the range, it is determined that there is an abnormality, and the abnormality occurrence counter is counted up (step 37). If the number of counts is 3 or more (step 38), the CO sensor S is greatly deteriorated. Assuming that there is an abnormality, the display lamp 16 is lit to indicate the abnormality, the sensor power is turned off, and the combustion operation of the burner 2 is prohibited until a reset operation such as an OFF / ON operation of the power switch is performed (step). 39, 40, 41).

If the output value is within the above range in step 51, the output value is stored in the discrimination reference value storage means 105 as the discrimination reference value Vm, and the deterioration determination value V is also stored.
_{It is} stored in the deterioration determination value storage means 108 as _HC (step 52). If the integration timer exceeds 20 hours, the integration timer is cleared, the abnormality occurrence counter is reset, and the sensor power is turned off (step 5).
3, 54, 55, 36).

Therefore, with the continuation of the hot water supply operation, the heat cleaning operation is executed every time the integrated combustion time of the burner 2 reaches 20 hours, and the deposits such as sulfide contained in the combustion gas of the burner are effective. And the detection sensitivity is restored. Even if the combustion integrated time of the burner 2 has not reached 20 hours, the output value of the CO sensor is out of the first set range in step 43, and further, step 4
In 7, the heat cleaning operation is executed regardless of the integrated combustion time if it is outside the second set range. At this time, if it is within the second set range, the output value is the determination reference value Vm. It will be rewritten and stored.

Next, the incomplete combustion determination control will be described with reference to the flowchart shown in FIG. First, C
The output value Vs of the O sensor S is read (step 61).
Subsequently, the _{β β = F (T A,} ΔV) and sets as changes in the _{α α = α C (1-} K 1 ΔV) becomes equation (step 62). Then, Vs = .alpha.D + beta, i.e., _{[Vs = α C × (1-} K 1 ΔV) × D + F (T A,
ΔV)] is used to calculate the CO concentration D (step 63).

Then, the CO concentration D is changed to a set concentration (for example,
1000 ppm), the counter C ₂ is started, and when the state in which the CO concentration D is higher than the set concentration continues for a set time (for example, 20 seconds) or more, it is determined that the incomplete combustion state, The incomplete combustion state is notified by turning on the display lamp 17, and the combustion operation of the burner 2 is prohibited until the reset operation such as the OFF / ON operation of the power switch is performed (step 64).
~ 68). When the CO concentration D is smaller than the set concentration in step 64 and when the state where the CO concentration D is larger than the set concentration is not continued for the set time or longer in step 66, the clocking counter C ₂ is reset. (Step 60), the process proceeds to Step 22, and the above determination control is repeated until the combustion stop command is given.

The set integration time (20 hours) and the specific set value of each setting range are not limited to the exemplified values, but may be changed appropriately.

When the CO sensor is replaced by a new one, the setting flag is reset by operating a maintenance switch (not shown), and the reference value initially set thereafter is set. It is adapted to be stored as an installation initial reference value (V ₀ ).

[Other Embodiment] (1) The integration timer as the combustion time integration means is
Instead of being reset every time the set time elapses,
As a configuration that accumulates the integrated value of the burner combustion time,
The heat cleaning operation may be performed every time the cumulative integration time increases by the set time. With this configuration, information on the burner cumulative cumulative time is
For example, it can be used for other purposes such as maintenance information.

(2) As the combustion time integration means, the combustion time may be integrated with a greater weight as the fuel supply amount to the burner is larger. With this configuration, the amount of sulfides or the like attached corresponds to the amount of fuel supplied, so that it is possible to obtain the combustion time that is suitable for the substantially deteriorated sensitivity.

(3) The set integration time is fixed at a constant value (20 hours in the above embodiment) as described above, and instead of the burner 2 integrated by the combustion time integration means 111. Based on the integrated value of the combustion time (cumulative use time), the set integrated time may be changed and set so that the larger the integrated value, the shorter the time. For example, if the cumulative usage time of the burner is 1000 hours or less, the set integration time is set to 20 hours, and the cumulative usage time exceeds 1000 hours,
The set integration time may be set to 15 hours until the time reaches 0 hours, and the set integration time may be set to 10 hours when the cumulative usage time exceeds 2000 hours. By doing this, the time interval for performing the heat cleaning operation becomes shorter as the cumulative use time becomes longer, and even if the concentration of the unburned component tends to increase due to secular change, the cleaning is properly performed. As a result, the decrease in detection accuracy can be suppressed for a long time.

(4) The safety means is configured to restrain the combustion operation of the burner when the operation abnormality is determined a predetermined number of times. However, instead of such a configuration, the operation or more is determined even once. Immediately after, the combustion operation of the burner may be restrained, or the set number of times is not limited to three, but may be two, four or more.

(5) As the abnormal state determining means, the detected value in the state where the unburned component is predicted to be zero and the temperature is set to the detection set temperature or a temperature close to the set temperature for detection is based on the determination reference value. If it is outside the set range set, it may be determined that the operation is abnormal, and if it is outside the set range set based on the deterioration determination value, it may be determined that the operation is abnormal.

(6) The heat cleaning operation may be executed only when the cumulative combustion time reaches the preset cumulative time without providing the first judging means and the second judging means.

(7) As a safety measure, when the CO sensor is greatly deteriorated, instead of the configuration in which the lamp is turned on to report the abnormality, the configuration in which the buzzer reports the abnormality, the configuration in which the lamp and the buzzer are used in combination, etc. Various abnormality notification methods can be used.

(8) The present invention can be applied not only to the hot water supply device but also to other combustion devices such as a fan heater.

It should be noted that reference numerals are added to the claims for facilitating the comparison with the drawings, but the present invention is not limited to the configuration of the accompanying drawings by the entry.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a hot water supply device.

FIG. 2 is a sectional view of a CO sensor

FIG. 3 is a circuit configuration diagram of a CO sensor

FIG. 4 is an output value of the CO sensor when the CO concentration D is predicted to be zero.

FIG. 5 is a diagram showing an output value of a CO sensor with respect to CO concentration D.

FIG. 6 is a flowchart of control operation

FIG. 7 is a flowchart of a control operation.

FIG. 8 is a flowchart of a control operation.

FIG. 9 is a flowchart of a control operation.

FIG. 10 is a flowchart of an incomplete combustion determination operation.

[Explanation of symbols]

2 burner 102 control means 103 incomplete combustion determination means 105 determination reference value storage means 106 initial reference value storage means 107 abnormal condition determination means 108 deterioration determination value storage means 109 first determination means 110 second determination means 111 combustion time integration means 112 Safety measure S Unburned component concentration detection means V _O Initial installation reference value V _HC Deterioration determination value Vm Determination reference value

Claims (10)

[Claims] 1. A catalytic combustion type unburned component concentration detecting means (S) for detecting the concentration of unburned component in the combustion gas of the burner (2) in a state where the temperature is set for detection or a temperature close thereto. An incomplete combustion discriminating means (103) for discriminating incomplete combustion of the burner (2) based on the detection information of the unburnt component concentration detecting means (S), and a state in which the unburned component is zero. The detection value of the unburned component concentration detecting means (S) in the predicted state and the temperature set to the detection setting temperature or a temperature close thereto is used as the reference value (Vm) for determining the incomplete combustion. A combustion time integrating means (111) for integrating the combustion time of the burner (2), the combustion time integrating means (105) Accumulated time by (111) Each reaches the set integration time, in a state in which the burner (2) is not burned, while the set time elapses, the unburned component concentration detection means (S)
Is performed at a temperature higher than the set temperature for detection, and after the heat cleaning operation is completed, the unburned component is in a state of being estimated to be zero and The detection value of the unburned component concentration detecting means (S) in a state where the temperature is set to or close to the set temperature is stored in the discrimination reference value storage means (105) as the discrimination reference value (Vm). Combustion device provided with control means (102). 2. After the heat cleaning operation is completed, the unburned component is in a state in which the unburned component is predicted to be zero and is set at the set temperature for detection or a temperature close to the set temperature for detection. An abnormal state determination means (107) for determining that the unburned component concentration detection means (S) is in an abnormal operation if the detected value of the component concentration detection means (S) is outside the set range is provided. Item 1. The combustion device according to Item 1. 3. The control means (102) is set to the detection set temperature or a temperature close to the set temperature in a state where the unburned component is predicted to be zero each time the heat cleaning operation is completed. The detection value of the unburned component concentration detection means (S) in the above state is stored in the deterioration determination value storage means (108) as a deterioration determination value (V _HC ). Combustion device as described. 4. The set temperature for detection or a temperature close to the set temperature for detection in a state where the unburned component is predicted to be zero after a lapse of a first set time from the time when combustion of the burner (2) is stopped. It is determined whether or not the detection value of the unburned component concentration detection means (S) in the state of being set to is within the first setting range set based on the determination reference value (Vm). A first discriminating means (109), and after the first discriminating means (109) discriminates that it is not within the first set range, after a first set time elapses,
Further, after the second set time has elapsed, the unburned component concentration detection is performed in a state where the unburned component is predicted to be zero and the set temperature for detection or a temperature close to the set temperature for detection is set. And a second discriminating means (110) for discriminating whether or not the detected value of the means (S) is within a second set range set based on the deterioration determination value (V _HC ). The means (102) includes the second determination means (11
0), it is configured to execute the heat cleaning operation regardless of the integrated time by the combustion time integration means (111), and wherein the heat cleaning operation is performed. The second determination means (110) is configured to store the detected value in the determination reference value storage means (105) when it is determined to be within the second set range. Combustion device. 5. The combustion apparatus according to claim 1, 2, 3, or 4, wherein the temperature in the heat cleaning operation is set to a high temperature capable of decomposing and removing adhering sulfides. 6. An initial reference for storing a discrimination reference value (Vm) initially stored in the discrimination reference value storage means (105) after being installed in a use position as an installation initial reference value (V ₀ ). A value storage means (106) is provided, and the setting range when being discriminated by the abnormal state discrimination means (107) is set based on the installation initial reference value (V ₀ ). The combustion device according to claim 4 or 5. 7. A safety means (112) for executing a predetermined safety operation when the abnormal state determination means (107) determines that the operation is abnormal, and the safety means (112) is provided.
The combustion device according to 4, 5, or 6. 8. The safety means (112) is configured to restrain the combustion operation of the burner (2) when the abnormal operation state determination means (107) determines that the operation abnormality is a set number of times. The combustion device according to claim 7. 9. The combustion time integrating means (111) changes the fuel supply amount to the burner (2),
The combustion time is integrated with greater weighting as the fuel supply amount increases.
The combustion device according to 5, 6, 7 or 8. 10. The control means (102), based on the integrated value of the combustion time of the burner (2) integrated by the combustion time integration means (111), the shorter the integrated value, the shorter the time. The configuration is such that the set integration time is changed and set so that
The combustion device according to 2, 3, 4, 5, 6, 7, 8 or 9.