KR0163465B1 - Combustion instrument - Google Patents

Abstract

It is an object of the present invention to provide a combustion device capable of reliably and simply grasping a deterioration of a CO sensor so that appropriate processing can be performed accordingly. The configuration is a signal level of the CO sensor 14 for detecting a CO concentration. And the abnormality processing means 26 which judges that the degradation of the CO sensor 14 has progressed when this predetermined time continues below the predetermined lower limit level, and performs the combustion prohibition process or the alarm generation process by the indicator 20. The lower limit level is set to a value smaller than the signal level at the steady state based on the signal level at the steady state output by the CO sensor 14 when the gas burner is not in operation or during normal combustion. It is.

Description

Combustion equipment

1 is a system configuration showing a hot water heater which is an embodiment of the combustion apparatus of the present invention.

2 is a block diagram of main parts of the hot water heater shown in FIG.

3 is a flow chart for explaining the operation of the hot water heater shown in FIG.

4 is a diagram showing a signal of a CO sensor used in the hot water heater of FIG.

* Explanation of symbols for main parts of the drawings

7: gas burner (combustion unit) 14: CO sensor

25: operation control means 26: abnormal processing means

The present invention relates to a combustion device having a carbon monoxide (CO) sensor.

For example, in a hot water heater, a CO sensor is installed in the exhaust passage to detect the concentration of CO gas generated due to incomplete combustion, etc., during combustion operation of the burner by means of a signal of the CO sensor output at a level corresponding thereto. It is known that the combustion operation is stopped when the signal level becomes higher than or equal to the predetermined reference value, that is, when the generated CO concentration becomes higher than or equal to the predetermined reference concentration.

In this kind of combustion apparatus, in order to stop the combustion operation accurately due to the generation of CO gas, the signal level of the CO sensor should correspond to the CO concentration actually generated. According to various studies by the present inventors, The sensor deteriorates with time due to the adhesion of oil. And when such deterioration progresses, even if a failure does not occur in the CO sensor itself, the signal level of the CO sensor becomes smaller than the initial stage even when the actual CO concentration is the same.

Therefore, in the state where the deterioration of the CO sensor proceeds as described above, even if the CO concentration actually generated is higher than or equal to the predetermined reference concentration, the signal level of the CO sensor does not become higher than the reference value for stopping the combustion operation. There is a problem that the combustion operation continues even though the concentration is higher than the reference concentration.

On the other hand, in this type of combustor, for example, as disclosed in Japanese Utility Model Publication No. 63-49166, it is possible to determine the presence of a failure of the CO sensor and to prohibit the combustion operation when the CO sensor is broken. It is known to perform abnormal processing. In the combustor disclosed in Japanese Utility Model Laid-Open No. 63-49166, the signal level at the steady state of the CO sensor is set to catch water such as moisture attached to the CO sensor at the initial stage of the energization in which the combustion operation is stopped. By using the property of rising once due to the gas and descending to a stable level, the signal level is maintained above the predetermined reference level continuously for a predetermined time at the initial stage of energization to the CO sensor, and below the predetermined reference level after the predetermined time has elapsed. If the CO sensor is determined to be normal, the CO sensor is judged to be defective in other cases, and abnormal processing such as prohibition of combustion operation is performed.

In addition, in such a combustion apparatus, when the burner is ignited, the CO gas is generated to some extent, and when the signal level of the CO sensor does not become higher than a predetermined reference level during the ignition, it is determined that the CO sensor is broken and burned. Abnormal processing such as prohibition of operation is performed.

Therefore, in order to solve the problem in the case where the deterioration of the above-described CO sensor proceeds, as disclosed in Japanese Utility Model Laid-Open Publication No. 63-49166, the signal of the CO sensor at the initial energization of the CO sensor and at the ignition of the burner. By comparing the level with an appropriate reference level, it is considered to detect the presence or absence of deterioration of the CO sensor and to perform abnormal processing such as prohibiting the combustion operation when the deterioration of the CO sensor is in progress.

However, such a conventional combustion apparatus has the following problems.

That is, in the initial stage of energization of the CO sensor, the degree of increase of the signal level tends to be unstable because it may vary depending on the degree of attachment of miscellaneous gases such as moisture even if the CO sensor is not deteriorated or malfunctions. Therefore, in the initial stage of energization of the CO sensor, even if a constant reference level for determining whether the CO sensor is deteriorated is set, even though the CO sensor is deteriorated, the reference level may be exceeded. It is difficult to know for sure.

In addition, the concentration of CO gas generated during ignition also tends to be irregular depending on various environmental conditions. Therefore, as in the case of initial energization, when the burner is ignited, even if a constant reference level for determining whether the CO sensor is deteriorated is set, the deterioration of the CO sensor may still be exceeded. It is difficult to know with certainty whether there is any deterioration of the CO sensor.

The present invention aims at improving such a combustion device, and in particular, it is an object of the present invention to provide a combustion device that can appropriately handle the deterioration of a CO sensor by reliably and simply grasping it.

In order to achieve the above object, the present invention provides a CO sensor for outputting a signal having a level corresponding to the CO concentration generated during operation of the combustion unit, and when the output of the CO sensor is at or above a predetermined reference level, the operation of the combustion unit. A combustion apparatus comprising an operation control means for stopping the operation, the combustion apparatus comprising: abnormality processing means for performing predetermined abnormality processing when the output of the CO sensor is below a preset lower limit value, wherein the lower limit value is at the time of non-operation of the combustion portion or On the basis of the signal level in the steady state outputted by the CO sensor at the time of normal combustion, the value is set to a value smaller than the signal level in this steady state by the predetermined amount. The predetermined abnormality processing is performed when the output of the CO sensor continues below the lower limit for a predetermined time.

The abnormality treatment by the abnormality treatment means may include a treatment for prohibiting the operation of the combustion section.

The abnormality processing by the abnormality processing means is characterized by including an alarm generation process.

According to the present invention, when the CO sensor is deteriorated due to adhesion of oil or the like and its signal level is lowered than the original signal level and is below the lower limit, predetermined abnormality processing is performed by the abnormality processing means.

At this time, the lower limit value is smaller than the signal level in the steady state by a predetermined amount on the basis of the signal level in the steady state output by the CO sensor during the non-operation or normal combustion of the combustion unit. Since the deterioration of the CO sensor proceeds, the signal level of the CO sensor is surely lowered below the lower limit at least in the non-operational state of the combustion unit or in the normal state of normal combustion, so that the deterioration of the CO sensor proceeds reliably. I can figure it out. In response to the grasping, the abnormality processing is performed so that appropriate processing for deterioration of the CO sensor can be accurately performed.

In addition, when the predetermined abnormal processing is performed when the output of the CO sensor continues to fall below the lower limit for a predetermined time, the signal level of the CO sensor is temporarily lowered due to noise or the like, whereby the abnormal processing is performed. Since it can be avoided, it becomes possible to grasp | deteriorate deterioration of a CO sensor and the corresponding process more reliably and correctly.

In addition, when the abnormal processing by the abnormal processing means includes a process for prohibiting the operation of the combustion unit, it is possible to avoid the situation where the combustion apparatus is used in the state where the CO concentration cannot be accurately detected due to the deterioration of the CO sensor. .

In addition, when the abnormality processing by the abnormality processing means includes an alarm generation process, it is possible to prompt the user of the deterioration of the CO sensor and prompt replacement or repair of the CO sensor.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. 1 to 4. FIG. 1 is a system configuration diagram of a water heater as the combustion device of the present embodiment, FIG. 2 is a main block configuration diagram of the water heater shown in FIG. 1, and FIG. 3 is a flowchart for explaining the operation of the water heater shown in FIG. A diagram showing the output of the CO sensor used in the hot water heater shown in FIG.

In FIG. 1, 1 is a water supply main body, 2 is a water supply pipe installed through the heat exchanger 3 provided in the water supply main body 1, 4 is a water supply pipe 2 in the upstream of the heat exchanger 3. As shown in FIG. The installed quantity sensor, 5 is the downstream temperature of the heat exchanger (3), the tapping temperature sensor installed in the water supply pipe (2), 6 is fuel gas supplied to the gas burner (7) (combustion section) installed in the hot water supply main body (1) The gas supply pipes, 8, 9 and 10, respectively, are installed in the gas supply pipe 6, respectively, in the upstream side of the solenoid valve, the main solenoid valve and the gas proportional valve, and 11 is a combustion supplying combustion air to the gas burner 7. A fan, 12 is an igniter for igniting the gas burner 7, 13 is a flame rod for detecting the ignition of the gas burner 7, 14 is close to the exhaust port 15 of the hot water supply main body 1 to the hot water supply main body 1. The attached CO sensor, 16 is a controller for controlling the operation of the hot water heater, 17 is an operation unit for setting the tapping temperature, etc. by the user.

In this case, the controller 16 is constituted by an electronic circuit including a microcomputer and the like, and is fed / started by connecting it to a commercial power source (not shown) through a power plug. In this case, the controller 16 ) Starts energizing the heater (not shown) built in the CO sensor 14. The CO sensor 14 outputs a signal having a level corresponding to the concentration of the CO gas generated during the combustion operation of the gas burner 7 in the steady state heated by the heater to about 200 ° C.

Moreover, the operation part 17 is provided with the temperature setting switch 18 for setting a tapping temperature, the operation switch 19, the indicator 20, etc. for giving an error display. In this embodiment, the operation switch 19 is of the non-lock type, and each time the operation switch 19 is pressed, the operation node of the hot water heater and the operation stop mode are alternately switched.

In FIG. 2, the controller 16 has a main functional configuration, an energization control unit 21 for controlling energization to the CO sensor 14, and a CO monitoring unit 22 for monitoring the output of the CO sensor 14. As shown in FIG. ), The igniter 12, the solenoid valve according to the detection signal of the tapping temperature sensor 5, the water quantity sensor 4, and the flame rod 13, or the indication signals from the CO monitoring unit 22 and the operation unit 17, and the like. (8), the operation control unit 23 for controlling the main solenoid valve 9, the gas proportional valve 10, the combustion fan 11, and the operation unit 17 in accordance with an instruction signal from the CO monitoring unit 22 or the like. The display unit 20 is provided with a display command unit 24 for causing an error display or the like. In response to the configuration of the present invention, the CO monitoring unit 22 and the operation control unit 23 constitute an operation control unit 25, and the CO monitoring unit 22, the operation control unit 23, and the display command unit 24. And the indicator 20 constitute the abnormality processing means 26.

Next, the operation of the hot water heater of this embodiment will be described with reference to FIGS. 1 to 3.

When the controller 16 is powered, the energization control unit 21 starts energizing the CO sensor 14 to a heater (not shown) to excite the CO sensor 14 (step 1). At this time, the energization control unit 21 starts the timer T1 (see FIG. 2) included therein, and the time until the timer T1 times up (20 seconds in this embodiment), Self-cleaning of the CO sensor 14 is performed (steps 2a to 2c). This self-cleaning is a process for actively excluding the miscellaneous gas attached to the CO sensor 14 at the beginning of energization. For example, the self-cleaning is applied to the heater of the CO sensor 14 to heat the CO sensor 14 to about 400 ° C. By energizing. Then, after conducting such self-cleaning, the energization control unit 21 conducts electricity to the heater so that the heating temperature of the CO sensor 14 is maintained at about 200 ° C. in order to detect the CO concentration by the CO sensor 14. Decreases.

When such energization to the CO sensor 14 is made, the CO sensor 14 outputs a signal at a level as shown by the solid line in FIG. In the state where the heating temperature is maintained at 200 ° C, the convergence is performed at a constant signal level L1. In this embodiment, the signal level L1 in such a steady state is set in advance to the offset value of the CO sensor 14.

In addition, the CO sensor 14 may exclude miscellaneous gases such as moisture by the self-cleaning, but when oil or the like is attached, deterioration proceeds and the level (L) as shown by a virtual line in FIG. This decreases as compared with the normal case.

When the self-cleaning ends, the 20-second timer is started, and when the 20-second timer is timed up (steps 3 and 4), the CO monitor 22 of the controller 16 then sets the signal level L of the CO sensor 14. Is started (step 5), and the signal level L is compared with the predetermined lower limit level L2 (step 6). Here, the lower limit level L2 is a level for determining whether or not the CO sensor 14 is deteriorated. As shown in FIG. 4, the CO sensor during non-operation (combustion stoppage) of the gas burner 7 is shown. On the basis of the normal signal level L1 of (14), it is set at a level slightly smaller than this level L1 by a predetermined level.

Then, in the state where the degradation of the CO sensor 14 has progressed to some extent, the signal level L (the signal level L after Step 4) in the steady state (constantly stable state) of the CO sensor 14 becomes It becomes smaller than lower limit level L2.

In the comparison of step 6, when the signal level L of the CO sensor 14 is larger than the lower limit level L2 (NO in step 6), that is, when the deterioration of the CO sensor 14 is not in progress. After the timer T2, which will be described later, is reset, the operation control unit 23 of the controller 16 can determine whether the operation switch 19 of the operation unit 17 is pressed or not (step 7). It is also possible to determine whether the value of the flag F is 1 or 0 (steps 8a and 8b). Here, the flag F indicates whether the current operation state of the water heater of the present embodiment is the operation mode or the non-operation mode, and F = 0 in the non-operation mode which is the initial state.

Thus, for example, when the operation switch 19 is pressed in the non-operation mode, the flag F is 0 at this time (NO in step 8a), and in this case, the operation control unit 23 operates the gas burner 7. After performing the ignition process (step 9), the flag F is set to 1 (step 10), and the combustion of the gas burner 7 is also controlled (step 11).

In this case, the ignition is performed by supplying fuel gas to the gas burner 7 with the original solenoid valve 8 and the main solenoid valve 9 in an open state, and the combustion fan 10 while driving the igniter ( 12) to ignite the gas burner (7).

In addition, the combustion control is carried out through the tapping temperature sensor 5 and the water quantity sensor 14, respectively, the tapping temperature or the quantity of water flowing through the heat exchanger 3 through the water supply pipe 2 when the gas burner 7 is burned. While detecting, the gas burner 7 is controlled by controlling the opening degree of the gas proportionality valve 10 or the rotation speed of the combustion fan 11 so that the tapping temperature matches the set temperature set by the temperature setting switch 18 of the operation unit 17. ) By controlling the amount of combustion.

When the combustion control of the gas burner 7 is started in this manner, the CO monitoring unit 22 of the controller 16 signals the CO sensor 14 indicating the concentration of CO gas generated during operation of the gas burner 7. The level L is compared with a predetermined reference level (see FIG. 4) (step 12). In this comparison, when the signal level L of the CO sensor 14 is lower than the reference level (NO in step 12), that is, when the gas burner 7 burns normally, the step 6 is performed. After returning to the comparison, basically, the combustion control in step 11 and the monitoring of the signal level of the CO sensor 14 in steps 6 and 12 are continuously performed.

When the operation switch 19 is pushed again (YES in step 7) during this operation, the flag F is equal to 1 (YES in step 8a), so that the operation control unit of the controller 16 23 clears the flag F to 0 (step 13), and then stops the combustion operation of the gas burner 7 (step 14). The combustion operation is stopped by closing the gas supply to the gas burner 7 by stopping the original solenoid valve 8 and the main solenoid valve 9 and closing the combustion fan 11.

In addition, monitoring of the signal level of the CO sensor 14 in step 6 continues as long as the electricity supply to the CO sensor 14 is made even after a combustion operation is stopped.

In the present embodiment, the controller 16 is always energized by the CO sensor 14 in a state of being connected to a power source, but may be energized by the CO sensor 14 only during operation. In this case, self-cleaning may be performed every time the operation is started. However, in this case, the hot water supply cannot be performed quickly when intermittent hot water supply is required at a short time interval such as a shower, so that the CO sensor 14 For example, if the operation is continued for a certain time (for example, 30 minutes) even after the operation is stopped, the output of the CO sensor 14 is immediately monitored by burning without performing self-cleaning when the operation is resumed in the meantime. It is desirable to resume operation quickly.

The operation described above has described the operation in which the CO sensor 14 is normal and the combustion operation of the gas burner 7 is normally performed without causing incomplete combustion or the like. However, for example, the combustion of the gas burner 7 is performed. If incomplete combustion occurs during the generation of CO gas and the CO concentration is high, the signal level of the CO sensor 14 indicating the CO concentration is higher than or equal to the reference level (YES in step 12). In this case, the controller 16 The operation control unit 23 in FIG. 3 stops the combustion operation of the gas burner 7 in the same manner as described above (step 14) in accordance with the instruction of the CO monitoring unit 22 (step 15).

In this case, the display command unit 24 of the controller 16 causes the display unit 20 of the operation unit 17 to display an error indicating that incomplete combustion has occurred according to the instruction from the CO monitoring unit 22 ( Step 16) It is recognized by the user.

In addition, when the CO sensor 14 deteriorates due to adhesion of oil or the like and the deterioration progresses to a certain degree, the signal level L of the CO sensor is in the non-operation state or the normal combustion operation state in which the generation of CO gas is very small. It becomes below lower limit level L2, In this case, the CO monitoring part 22 of the controller 16 starts the timer T2 (refer FIG. 2) contained in it (step 17, 18).

When the signal level L of the CO sensor 14 does not exceed the lower limit level L2 within the time until the timer T2 times up (20 seconds in this embodiment), that is, L≤L2 If the state is continued for 20 seconds (YES in step 19), the CO monitoring unit 22 instructs the operation control unit 23 to prohibit the combustion operation (step 20), and also the display command unit 24. The display 20 is instructed to perform a predetermined display. In this case, when the gas burner 7 is in the combustion operation, the operation control unit 23 performs the combustion prohibition process by taking a process of prohibiting the subsequent operation after stopping the combustion operation as in the case of Step 14.

In addition, the display command unit 24 causes the display 20 to display a predetermined indication indicating that the CO sensor 14 has deteriorated (step 21), thereby alerting the user to the necessity of replacing the CO sensor 14. Generation processing is performed.

Further, when the signal level L of the CO sensor 14 exceeds the lower limit level L2 again before the timer T2 times up (NO in step 6), abnormal processing such as prohibition of combustion operation or the like is performed. Without performing the above, the timer T2 is reset (step 22), and the above-described normal operation is performed.

In addition, when an ignition miss or misfire occurs during the combustion operation of the gas burner 7, it is detected by the controller 16 through the flame rod 13, in which case the controller 16 performs steps 15 and 16. The same processing as is performed.

As described above, in the apparatus of the present embodiment, when the CO sensor 14 deteriorates to some extent and the state in which the CO concentration cannot be detected accurately, the combustion operation of the gas burner 7 is prohibited, and the indicator 20 Since an alarm is generated, it is possible to avoid a situation where the combustion operation of the gas burner 7 is repeated in a state where the CO concentration cannot be detected accurately.

In this case, the lower limit level L2 for determining the deterioration of the CO sensor 14 is a predetermined level higher than this level L1 based on the normal signal level L1 in the normal state of the CO sensor 14. Since the deterioration of the CO sensor 14 has progressed to a certain degree, since at least the signal level L of the CO sensor 14 is almost constant, a non-operation state or generation of CO gas is stable. In a sufficiently small continuous and normal combustion operation state, since the signal level L of the CO sensor 14 becomes less than the lower limit level L2, deterioration of the CO sensor 14 can be grasped reliably. In addition, when the signal level L of the CO sensor 14 is lowered below the lower limit level L2 for a predetermined time (20 seconds), it is judged that the degradation of the CO sensor 14 has progressed, and therefore temporarily due to noise or the like. Since the case where the signal level L is lowered can be excluded, deterioration of the CO sensor 14 can be grasped accurately. In addition, even when the CO sensor 14 breaks down and no signal is output, the signal level L of the CO sensor 14 is continuously below the lower limit level L2. Since the processing and the alarm processing are performed, the situation where the combustion operation of the gas burner 7 is performed in such a failure state can be avoided.

Incidentally, in the present embodiment, the alarm generating process when the CO sensor 14 is deteriorated is performed by the display of the indicator 20, but the alarm may be generated by a buzzer or the like.

In the present embodiment, the lower limit level L2 is set on the basis of the signal level L1 in the steady state of the CO sensor 14 in the normal atmosphere where no combustion of the gas burner 7 is performed. Although set, the lower limit level may be set on the basis of the signal level in the steady state of the CO sensor 14 in the normal combustion operation state (for example, the normal weak combustion state) where the generation of CO gas is sufficiently small. .

In the present embodiment, the combustion operation when the signal level of the CO sensor 14 becomes higher than the predetermined reference level at the time of combustion of the gas burner 7 is stopped, but the signal level of the CO sensor 14 remains constant for a certain time. Subsequently, the combustion operation may be stopped when the predetermined reference level or more is reached.

In this case, even if the constant time indicated when the output of the CO sensor 14 is equal to or higher than the reference level and the timer time of the timer T2 indicated when the output of the CO sensor 14 is lower than or equal to the lower limit, the same time may be used. In this case, the timer T2 may be shared.

In this embodiment, the reading of the signal level L of the CO sensor 14 is started after a predetermined time (20 seconds) has elapsed after the self-cleaning has been completed. The reading of the signal level L of 14 may be started.

In addition, the present embodiment has been described taking the hot water heater as an example, of course, the present invention can be applied to other combustion equipment such as a fan heater.

As can be seen from the above description, according to the present invention, when the output of the CO sensor reaches a predetermined lower limit value or less, a predetermined abnormality processing is performed, and the lower limit value is always applied to the CO sensor during non-operation or normal combustion of the combustion unit. The deterioration of the CO sensor can be grasped simply and easily by setting a value smaller than the signal level in the steady state based on the signal level in the steady state outputted in the normal state. I can do it correctly.

By performing abnormal processing when the output of the CO sensor continues to fall below the lower limit for a predetermined time, the signal level of the CO sensor is temporarily lowered due to noise or the like, so that the abnormal processing can be avoided. It is possible to more reliably and accurately identify the progress of deterioration of the sensor and to deal with abnormalities corresponding thereto.

In addition, the abnormality processing includes a process of prohibiting the operation of the combustion unit, thereby avoiding the situation where the operation of the combustion unit is performed in a state where the detection of the CO concentration by the CO sensor is not performed accurately, thereby coping with deterioration of the CO sensor. As long as the appropriate abnormality treatment can be performed correctly.

In addition, the abnormality processing includes an alarm generation process, so that the user can accurately recognize the progress of the deterioration of the CO sensor.

Claims (3)

A CO sensor for outputting a signal having a level corresponding to the CO concentration generated during operation of the combustion unit; A combustion apparatus comprising: operation control means for stopping the operation of the combustion unit when the output of the CO sensor becomes equal to or greater than a predetermined reference level, the combustion device comprising: a predetermined abnormality processing when the output of the CO sensor becomes equal to or less than a predetermined lower limit set in advance; And the lower limit value is higher than the signal level at this steady state on the basis of the signal level at the steady state output by the CO sensor at normal time during non-operation or normal combustion of the combustion unit. The combustion apparatus characterized by setting a value as small as a predetermined amount, wherein said abnormality processing means performs said predetermined abnormality processing when the output of said CO sensor continues to be below said lower limit for a predetermined time. The combustion apparatus according to claim 1, wherein the abnormality processing by the abnormality processing means includes a process of prohibiting the operation of the combustion section. The combustion apparatus according to any one of claims 1 and 2, wherein the abnormal processing by the abnormal processing means includes an alarm generating process.