JP3325974B2 - Safety control device for combustion equipment and combustion equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a safety control device for combustion equipment such as a gas water heater and a combustion equipment.

[0002]

2. Description of the Related Art Recently, a gas water heater provided with a CO sensor and a microcomputer for performing safety control based on a CO concentration signal from the CO sensor has been developed. More specifically, the microcomputer determines whether there is a danger to the human body based on the CO concentration, and when it is determined that there is a danger, stops the combustion and activates the alarm unit. By the way, after the above combustion stop,
Natural ventilation lowers the CO concentration in the room, which in turn lowers the risk to the human body, so that it is often safe to resume combustion. Therefore, a safety control device has been developed in which when the operation switch is once turned off and then turned on again, combustion can be restarted and the alarm is stopped.

[0003]

However, in the case where the CO concentration is extremely high, when the operation switch is turned off once and then turned on again, the combustion control is restarted and no alarm is displayed. Sometimes too dangerous.

[0004]

Means for Solving the Problems The invention of claim 1 has been made to solve the above problems, and the gist thereof is as follows: (a) an operation switch 1;
(B) CO concentration detection means 2 as abnormality detection means;
(C) danger determining means 3 for determining whether or not there is danger based on the CO concentration and recognizing the degree of risk in a plurality of stages; (d) canceling means 4 for outputting a cancel signal; The combustion is started when the operation switch is turned on, the combustion is stopped when the operation switch is turned off, and the combustion is stopped when the danger is judged to be dangerous by the danger determination means. In accordance with the level of danger recognized by the danger determination means, if it is determined that the danger level is low, combustion can be restarted when the operation switch is turned on again. If it is determined that the combustion control means 5 receives the cancel signal from the cancel means as an additional condition, the combustion control means 5 enables the combustion to be restarted when the operation switch is turned on again; ) And alarm means 6, and the gist of the safety control apparatus for a combustion apparatus, characterized in (g) when it is determined that the risk in the risk judgment means, further comprising a warning controller 7 for actuating the alarm means. According to the second aspect of the present invention, the alarm control means changes an alarm timing in accordance with the level of the risk recognized by the danger determining means. When the switch is turned off, the operation of the alarm means is stopped, and even if the operation switch is turned on again, the alarm stop state is maintained. While the operation switch is on without receiving a signal, the alarm unit is activated. According to the third aspect of the present invention, the alarm control means activates the alarm means until the operation switch is turned off after the danger determination means determines that the degree of danger is high, and stops the alarm means while the operation switch is off. The alarm means is activated when the operation switch is turned on again. According to a fourth aspect of the present invention, the cancel means includes a clear switch, and the clear switch outputs the cancel signal when turned on. In the invention of claim 5, the canceling means includes a timer, and the timer measures an elapsed time from when the danger determining means determines that the degree of danger is a high level, and the elapsed time reaches a predetermined time. It is characterized in that a cancel signal is output when it has reached. According to a sixth aspect of the present invention, there is provided (a) a burner;
An operation switch, (c) a CO concentration detecting means, and (d) determining whether there is danger based on the CO concentration,
Danger determining means for recognizing the degree of risk in multiple stages;
(E) canceling means for outputting a cancel signal;
(F) Basically, combustion in the burner is started when the operation switch is turned on, combustion is stopped when the operation switch is turned off, and combustion is stopped when the danger determination means determines that there is danger. At the same time, the subsequent restart of combustion is performed in accordance with the level of danger recognized by the above-described danger determining means, and if it is determined that the danger level is low, restarting of combustion is performed when the operation switch is turned on again. Possible,
If it is determined that the danger level is a high-level danger, a combustion control unit that enables restart of combustion when the operation switch is turned on again with an additional condition of receiving a cancellation signal from the cancellation unit; The gist of the present invention is a combustion apparatus comprising: (h) an alarm control means for activating an alarm means when the danger judgment means judges danger. According to a seventh aspect of the present invention, in the combustion apparatus according to the sixth aspect, the alarm control means changes an alarm timing according to the level of the danger recognized by the danger determination means, and is determined to be a low-level danger. When the operation switch is turned off, the operation of the alarm means is stopped, and the alarm stop state is maintained even when the operation switch is turned on again. In this case, the alarm unit is activated at least during a period in which the operation switch is on without receiving the cancel signal. The invention according to claim 8 is the combustion apparatus according to claim 6, wherein the alarm control means activates the alarm means until the operation switch is turned off after the danger determination means determines that the degree of danger is a high level, and The alarm means is stopped while the switch is off, and the alarm means is activated when the operation switch is turned on again. According to a ninth aspect of the present invention, in the combustion apparatus of the sixth aspect, the canceling means includes a clear switch, and the clear switch outputs the cancel signal when turned on. According to a tenth aspect of the present invention, in the combustion equipment of the sixth aspect, the canceling means includes a timer, and the timer measures an elapsed time from when the danger determining means determines that the degree of danger is high. When the elapsed time reaches a predetermined time, a cancel signal is output.

[0005]

According to the first and sixth aspects of the present invention, the danger determining means determines whether or not there is danger based on the CO concentration from the CO concentration detecting means and recognizes the degree of risk in a plurality of stages. The combustion control means performs combustion control according to the level of the danger recognized by the danger determination means. More specifically, the combustion control means enables the restart of combustion when the operation switch is turned on after being turned off after the operation switch is turned off when it is determined that the risk is in the low stage, and when it is determined that the risk is in the high stage. In the above, the combustion restart can be performed when the operation switch is turned on again, with the additional condition of receiving a cancel signal from the canceling means. As described above, after the low-level risk determination, the user can restart combustion by operating the operation switch similar to the normal operation by turning off the operation switch and then turning it on. It is anticipated that the degree of danger to the human body will decrease during the elapsed time until the operation switch is turned on again. On the other hand, after the high-level risk determination, unless the cancel signal is set as an additional condition, even if the operation switch is turned on again, the combustion cannot be restarted. This is to ensure the safety of the user. According to the second and seventh aspects of the present invention, the alarm control means also performs the alarm control according to the level of the danger recognized by the danger determination means. That is,
If the danger determination means determines that the danger level is low, the alarm control means stops the alarm means when the operation switch is turned off, and maintains the alarm stop even when the operation switch is turned on. I do. When it is determined that the degree of danger is a high level, the warning unit is operated at least during a period in which the operation switch is on without receiving a cancel signal from the canceling unit. That is, when the operation switch is turned on again, an alarm is issued to the user.

According to the third and eighth aspects of the present invention, when the operation switch is off, the alarm operation is not performed, and the user is not irritated by an unnecessary alarm. According to the fourth and ninth aspects of the present invention, it is possible to restart the combustion after the danger is determined on condition that the clear switch separate from the operation switch is operated, so that safety can be ensured. In particular, it is preferable to install this clear switch out of the user's eyes. According to the fifth and tenth aspects of the present invention, the combustion cannot be restarted after the danger is determined until a predetermined time has elapsed, so that a reduction in the risk due to natural ventilation or the like can be ensured.

[0007]

[0008]

An embodiment of the present invention will be described below with reference to FIGS. FIG. 2 shows a gas water heater (combustion device). In this gas water heater, a burner 11 is disposed substantially at the center in the casing 10. The burner 11 is supplied with gas through a gas pipe 12 and a gas nozzle (not shown), and is supplied with air sent by a fan 13. These gases and air are mixed in the burner 11, and this mixed gas is blown out from the upper surface of the burner 11. This mixed gas is ignited by discharging an igniter (not shown). The gas pipe 12 is provided with an electromagnetic valve 14 for controlling gas supply. The ignition is confirmed by the flame rod (flame detection sensor) current. This flame rod current is also used to determine whether the flame is lifted.

Above the burner 11, a heat exchanger 15 which is heated by the flame from the burner 11 is arranged. A water supply pipe 16 passes through the heat exchanger 15, and a water tap 17 is provided at a tip of the water supply pipe 16. Therefore, when the tap 17 is opened, hot water from the heat exchanger 15 comes out. The water supply pipe 16 is provided with a flow sensor 18 so that the flow of water when the tap 17 is opened can be detected.

An exhaust port 10a is provided at an upper portion of the casing 10, and the combustion exhaust gas is discharged outside through a chimney 19 connected to the exhaust port 10a. In the vicinity of the exhaust port 10a, a CO sensor 20 (CO
Concentration detecting means, incomplete combustion detecting means, abnormality detecting means), and outputs a signal indicating the CO concentration of the exhaust gas. A signal from the CO sensor 20 is sent to a control unit 30 provided in the casing. The control unit 30 includes the CO sensor 2
It incorporates a microcomputer 31 for processing signals from 0, its interface, a clear switch 32, and the like. The clear switch 32 can be turned on only when a maintenance or repair worker removes the casing 10 and removes the housing of the control unit 30, and the user cannot easily operate the clear switch 32.

An operation panel 40 provided on the outer surface of the casing 10 is connected to the control unit 30. The operation panel 40 includes a liquid crystal display unit 41,
An operation switch 42, a lamp 43, a buzzer 44, and the like are provided. The liquid crystal display section 41 normally displays the set temperature. When the danger due to CO gas increases as described later, the liquid crystal display unit 41 switches to an alarm display,
The lamp 43 flashes, and the buzzer 44 outputs an alarm sound.
Thus, the liquid crystal display 41, the lamp 43, the buzzer 44
Are provided as alarm means.

The microcomputer 31 executes a combustion and alarm control program shown in FIG. Before describing this program, the basic principle of combustion control will be described. The microcomputer 31 assumes that the combustion exhaust gas leaks into the room from the casing 10 and the chimney 19, and based on the CO concentration from the CO sensor 20, the blood hemoglobin CO concentration of the human body (based on the total number of hemoglobin in the blood). The percentage of hemoglobin bound to CO) is estimated. Then, the degree of risk to the human body is determined based on the blood hemoglobin CO concentration.

More specifically, the CO in the exhaust gas is sucked in with the respiratory movement of a person and combines with the hemoglobin in the blood. C
Since hemoglobin bound to O accumulates in the blood, the hemoglobin CO concentration in the blood increases as the CO concentration in the exhaust gas increases and as the elapsed time increases. Therefore, the microcomputer 31 obtains the blood hemoglobin CO concentration by integrating the value obtained by multiplying the CO concentration in the exhaust gas that is periodically detected by the absorption rate of the CO at the human body at this CO concentration. However, when the CO concentration is zero or low, blood hemoglobin C
Since the O concentration attenuates, the blood hemoglobin CO concentration is calculated taking this attenuation into account. Then, a ratio TR between the calculated blood hemoglobin CO concentration and the lowest concentration (hazard reference concentration, for example, 25%) that adversely affects the human body is determined. In this embodiment, the ratio TR is treated as the degree of risk.

Each time the CO concentration is detected, the detected C
When it is assumed that the O concentration is maintained as it is, a time T at which the blood hemoglobin CO concentration will reach the risk reference concentration is obtained from a map, and the detection period t is divided by the time T to obtain t / T. By integrating t / T,
The risk TR may be obtained.

In this embodiment, initially, the risk TR is 0.7.
Considering the above as dangerous, control such as stopping combustion and warning is performed.
However, when the risk TR is 0.7 or more and less than 1.0, it is regarded as a low-level risk, and when the risk TR is 1.0 or more, it is regarded as a high-level risk. Perform corresponding combustion control and alarm control.

The flags and registers used in the control program shown in FIG. 3 will be described. The flag A indicates the fact that the risk is determined to be dangerous and the risk TR is determined to be in the low level, and the flag B indicates the fact that the risk TR is determined to be in the high level. Also, register X is
When it is “1”, it indicates that the risk TR is determined to be 0.7 or more and less than 0.8, and when “2”, the risk TR is 0.8.
This represents the fact that it is determined that the risk is not less than 0.9 and less than 0.9, and represents the fact that it is determined that the degree of risk TR is 0.9 or more and less than 1.0 when “3”.

Next, the control program will be described in detail with reference to FIG. This control program is powered on (plugging the power plug of the gas water heater into an outlet)
Starts with. First, initialization is performed except for the register X and the flag B (step 101). The meaning of this initialization will be described later. Next, it is determined whether the flag B is set (step 102). Normally, a negative determination is made here and the routine proceeds to step 103. Step 103
Then, it is determined whether or not the operation switch 42 has been turned on. When a negative determination is made, the flag A is cleared in step 104, the alarm is stopped, and the process returns to step 103 again. The meaning of step 104 will be described later. When a positive determination is made in step 103, the hot water tap 1
It is determined based on a signal from the flow sensor 18 whether or not 7 has been opened ( step 105). In the case of a negative decision,
Execute step 104 and return to step 103. As described above, until the operation switch 42 is turned on by the user and the tap 17 is opened, the combustion control is not started, and the combustion is ready.

The user turns on the operation switch 42,
When the tap 17 is opened, an affirmative determination is made in steps 103 and 105.
Proceed to 06. In step 106, it is determined whether the flag A has been set. Normally a negative decision is made here,
Proceed to start combustion. That is, the fan 13 is rotated and the solenoid valve 14 is turned on to start gas supply (step 107), discharge the igniter to ignite,
When the flame rod current is detected, a desired gas is supplied (step 108).

Next, the CO concentration is detected based on the signal from the CO sensor 20, and the above-described risk TR is calculated (step 109). Next, it is determined whether or not the register X is "0" (step 110). Normally, the value of the register X is “0”, so an affirmative determination is made here, and the routine proceeds to step 111. In step 111, it is determined whether or not the degree of risk TR is less than 0.7. Normally, the degree of risk is less than 0.7, so an affirmative determination is made here, and the routine proceeds to step 112. In step 112, it is determined whether or not the tap 17 is open. If a positive determination is made, the process returns to step 109. As described above, when the combustion is performed under the condition that almost no CO gas is generated, the steps 109 to 109 are performed while the hot water tap 17 is opened.
The loop of 112 is repeatedly executed, and the combustion is continued. In step 109, the CO detection and the risk level TR are performed periodically (for example, every 10 seconds) only once per loop.
Time is managed so that calculations are performed.

If the tap 17 is closed during the above combustion control, a negative determination is made in step 112, so the routine proceeds to step 113, where the solenoid valve 14 is turned off to stop gas supply. That is, the combustion is stopped. Thereafter, the process returns to step 103, and the combustion preparation state described above is established.

When incomplete combustion occurs, C in the exhaust gas
The O concentration increases, and the risk TR increases with time and may reach 0.7. In this case, a negative determination is made in step 117, and the process proceeds to step 114,
Here, it is determined whether or not the degree of risk TR is less than 0.8. CO
If the concentration is not very high and the risk TR which is the integrated value increases relatively slowly, a negative determination is made here and the routine proceeds to step 115. In step 115, the register X is set to "1". In the next step 116, an alarm is executed and the flag A is set. Then, the process proceeds to the next step 113 to stop the gas supply. As described above, when the danger level reaches the predetermined level of 0.7 or more but the low-level danger level is reached, the warning and the stop of the combustion are executed to ensure the safety of the user. The mode of the alarm is as described above.
In addition to the blinking and the buzzer sound output from the buzzer 44, the display unit 41 displays that the low-level danger level has been reached by a code or a character. Thereafter, the process returns to step 103.

Immediately after the low-level danger is detected as described above, the operation switch 42 remains on and the tap 17 remains open.
In the case of 5, the determination is affirmative and the routine proceeds to step 106. Here again, since the flag A is set, the determination is affirmative and the routine returns to step 103. Therefore, steps 103 and 1
Steps 05 and 106 are repeatedly executed, and the alarm display is continued.

In the situation described above, if the user notices the alarm and turns off the operation switch 42, a negative determination is made in step 103, and the process proceeds to step 104, where the flag A is cleared and the alarm is stopped. Thereafter, steps 103 and 104 are repeatedly executed, and the same combustion preparation state as described above is obtained. In the present embodiment, even if the operation switch 42 remains on, when the tap 17 is closed, a negative determination is made in step 105, so that step 10
4 can be executed, and thereafter, steps 103, 105, 104
Is repeatedly executed to be in a combustion ready state. However, the user generally turns off the operation switch 42 after the alarm,
Both operations of closing the tap 17 should be performed.

After the alarm, when the user turns on the operation switch 42 again and opens the tap 17 again, an affirmative decision is made in steps 103 and 105 and step 1
The process proceeds to step 06, where a negative determination is made because the flag A has already been cleared, and the ignition operation (steps 107 and 10) is performed.
8) is executed to calculate the CO concentration and calculate the degree of risk TR (step 109). Next, it is determined whether or not the register X is "0" (step 110). As described above, in the combustion after the register X is set to "1", a negative determination is made here, and further, an affirmative determination is made in step 117, and the routine proceeds to step 118. In step 118, it is determined whether or not the degree of risk TR is less than 0.8. If incomplete combustion has not occurred, the degree of risk TR has not increased, so an affirmative determination is made here and the routine proceeds to step 112, where the hot water tap 17
It is determined whether or not is open. When the determination is affirmative, the process returns to step 109. Thus, after the risk TR is determined to be 0.7 or more and less than 0.8 (low-level risk) and the register X becomes "1", the operation switch 42 is turned on and the tap 17 is turned off. In response to the opening of the combustion, the combustion can be resumed without an alarm, and the combustion is continued by repeating steps 109, 110, 117, 118, and 112 in order until the degree of risk TR becomes 0.8 or more. be able to.

After restart of combustion in the state where the register X is "1", when incomplete combustion occurs again and the degree of risk TR becomes 0.8 or more, a negative determination is made in step 118 and the routine proceeds to step 119 where It is determined whether or not the risk TR is less than 0.9. If the degree of risk TR rises gently, an affirmative determination is made here, the register X is set to "2" in step 120, an alarm and a flag A are set (step 116), and gas supply is stopped in the same manner as described above. After executing (Step 113), the process returns to Step 103. Regarding the restart of combustion when the register X is "2",
Is the same as when “1”, so the description is omitted.

In the case of combustion in the state where the register X is "2", a negative determination is made in steps 110 and 117, so that the routine proceeds to step 121, where an affirmative determination is made, and
Proceeding to 22, it is determined whether or not the degree of risk TR is less than 0.9. When the incomplete combustion has not occurred, the degree of risk TR has not increased, so that an affirmative determination is made here, and the routine proceeds to step 112. Thus, steps 109, 110, 117,
By repeating steps 121, 122, and 112 in order, combustion can be continued.

After restart of combustion in the state where the register X is "2", when incomplete combustion occurs again and the degree of risk TR becomes 0.9 or more, a negative determination is made in step 122 and the routine proceeds to step 123 where It is determined whether the risk TR is less than 1.0. If the degree of risk TR rises slowly, an affirmative determination is made here, the register X is set to "3" in step 124, the alarm and the flag A are set (step 116), and the gas supply is stopped as described above. After executing (Step 113), the process returns to Step 103. Regarding the restart of combustion when the register X is "3",
Is the same as when “1”, so the description is omitted.

In the case of combustion in the state where the register X is "3", a negative judgment is made in steps 110, 117 and 121, so that the routine proceeds to step 125, where the degree of risk TR is 1.0.
It is determined whether it is less than. When the incomplete combustion has not occurred, the degree of risk TR has not increased, so that an affirmative determination is made here, and the routine proceeds to step 112. Thus, step 10
Combustion can be continued by repeatedly executing 9, 110, 117, 121, 125, and 112 in order.

Next, a case where it is determined that the degree of risk is high is described. After the restart of combustion in the state where the register X is "3", when the incomplete combustion occurs again and the risk TR becomes 1.0 or more, a negative determination is made in step 125 and the gas supply is stopped (step 126). , The timer X is started, the register X is set to "0", and the flag B
Is set (step 127), and the process proceeds to step 130. If the degree of danger TR suddenly increases, steps 114, 119, and 1 are performed even when combustion is performed in any state of the register X of "0", "1", and "2".
If a negative determination is made in 23, the process can proceed to step 126.

In step 130, it is determined whether or not the operation switch 42 is on. The above switch 123,
Immediately after a negative determination is made in 125, the operation switch 42 is in the ON state, so that an affirmative determination is made and an alarm is executed (step 131). The mode of the alarm is different from the case of the low-level danger level. That is, the cycle of the blinking of the lamp 43 is increased, the buzzer sound from the buzzer 44 is increased or increased, and the display section 41 displays that the danger of the high stage has been reached by a code or a character. When the user notices the alarm and turns off the operation switch 42, the operation proceeds to step 130.
Is negative, the process proceeds to step 132 to stop the alarm. Therefore, the user is not frustrated by the continuation of this alert. Step 131 (or 132)
Next, it is determined whether or not the clear switch 32 has been turned on (step 133). If a negative determination is made here, it is determined whether or not a predetermined time, for example, 4 hours, has elapsed (step 134). If a negative determination is made here, the process returns to step 130. Until a worker called by the user for repair turns on the clear switch 32 or until four hours have elapsed, even if the operation switch 42 is turned off and on again, the loop cannot be exited,
The combustion stop state is not released. The operation switch 42
Since the alarm is executed when is turned on again, the user can recognize that the combustion stop state is not released due to danger.

As described above, when it is determined that the risk is of a high level, the restart of combustion is more strictly regulated and an alarm is issued as compared with the case of determining the risk of a low level, so that the safety of the user can be ensured. When the clear switch 32 is turned on or when a predetermined time has elapsed, an affirmative determination is made in step 133 or step 134, and the process exits the loop and proceeds to step 135, where the flag B is cleared and then the process proceeds to step 103. Return. As a result, the state returns to the normal combustion preparation state.

When the user unplugs the power plug, the microcomputer 31 stops the combustion and alarm control. However, since the microcomputer 31 is supplied with power from the backup power supply, the values of the flags and the registers are retained. When the user plugs in the power plug again and the microcomputer resumes the program of FIG.
01, the register X and the flag B are not initialized. Then, in the next step 102, the flag B
Is determined to be 1 or not. If the combustion has been stopped by the high-level risk determination, an affirmative determination is made here and the routine proceeds to step 130. Therefore, when the power is turned off and on,
As in the case where the operation switch 42 is turned off or on, the combustion stop state cannot be released.

The present invention is not limited to the above embodiment, and various embodiments are possible. For example, in the above embodiment, the alarm means includes the display unit 41, the lamp 43, and the buzzer 44, but only one of them may be used. At the time of high-level risk judgment,
An alarm may be issued regardless of whether the operation switch is on or off.
The alarm may be issued by all of the lamp 1, the lamp 43, and the buzzer 44, and the alarm may be issued only by the display 41 when the operation switch is turned off. In the specification of the present application, "ON" of the operation switch
Means a state in which the ON signal of the operation switch is held by a flip-flop or the like, or a state in which the microcomputer stores the ON signal, in addition to a state in which the ON state is maintained by itself. There is also. As the abnormality detecting means, a gas sensor such as an O ₂ sensor may be used in addition to the CO gas sensor, and a gas amount sensor, an air amount sensor,
A flowing water switch installed in a bath water supply pipe, a bath thermistor, a fan rotation sensor, a temperature fuse installed in a heat exchanger, a frame rod, or the like may be used. The gas sensor may be provided not on the exhaust side but on the intake side. The present invention can be applied not only to gas-fired equipment but also to combustion equipment using other fuels such as petroleum.

[0034]

As described above, according to the first and sixth aspects of the present invention, the warning is issued and the combustion is stopped at the time of the danger judgment, whether the judgment is at the low level or at the high level. In the case of low-level danger judgment, combustion can be resumed by operating the same operation switch as in normal operation, and in the case of high-level danger judgment, a cancel signal must be added as an additional condition. For example, even if the operation switch is operated, the combustion cannot be restarted. Claim 2,
In the invention of the seventh aspect, when the combustion is stopped by the low-level risk determination, the user can restart the operation without receiving a warning. However, when the combustion is stopped by the high-level risk determination, the user operates the operation switch. Then, an alarm is issued to the user, so that the safety of the user can be further ensured.
According to the third and eighth aspects of the present invention, when the operation switch is off, the alarm operation is not performed, and the user is not irritated by an unnecessary alarm. According to the fourth and ninth aspects of the present invention, it is possible to restart the combustion after the danger is determined on condition that the clear switch separate from the operation switch is operated, so that safety can be ensured. According to the fifth and tenth aspects of the present invention, the combustion cannot be restarted after the danger is determined until a predetermined time has elapsed, so that a reduction in the risk due to natural ventilation or the like can be ensured.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a basic configuration of the present invention.

FIG. 2 is a schematic diagram of a water heater according to an embodiment of the present invention.

FIG. 3 is a flowchart showing a combustion control and display control program executed by the microcomputer of FIG. 2;

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Operation switch 2 ... Abnormality detection means 3 ... Danger judgment means 4 ... Cancellation means 5 ... Combustion control means 6 ... Warning means 7 ... Warning control means 20 ... CO sensor (CO concentration detection means, incomplete combustion)
Detection means, abnormality detection means) 31 microcomputer 32 clear switch (cancel means) 41, 43, 44 alarm means 42 operation switch

────────────────────────────────────────────────── ─── Continuation of front page (56) References JP-A-55-118530 (JP, A) JP-A-63-3123 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) F23N 5/24 107 F23N 5/26 101

Claims (10)

(57) [Claims] (1) an operation switch; (b) a CO concentration detecting means; (c) a danger determination of judging whether or not there is a danger based on the CO concentration and recognizing the danger level in a plurality of stages. (D) canceling means for outputting a cancel signal; and (e) basically starting combustion when the operation switch is turned on, and stopping combustion when the operation switch is turned off,
In addition, when the danger is determined to be dangerous by the danger determining means, the combustion is stopped, and the subsequent combustion is restarted according to the level of the danger recognized by the danger determining means. When the operation switch is turned on again, the combustion switch can be restarted, and when it is determined that the risk is at a high level, the operation switch is set as an additional condition that the cancellation signal from the cancellation means is received. Combustion control means for enabling combustion restart when turned on again; (f) alarm means; and (g) alarm means when the danger determination means determines that danger is present.
And a warning control means for operating the stage . 2. The warning control means according to claim 1, wherein
Depending on the stage of the perceived danger, the warning time is different,
If it is determined that the risk is low,
When the switch is turned off, the alarm
Even if the operation switch is turned on again,
Is maintained, and the risk is determined to be a high
At least without receiving a cancellation signal.
Activate the alarm means while the switch is on
The safety control of a combustion device according to claim 1, wherein
apparatus. 3. The alarm control means according to claim 1, wherein the danger judgment means is high.
After judging the degree of danger , activate the alarm means until the operation switch is turned off, stop the alarm means while the operation switch is off, and activate the alarm means when the operation switch is turned on again. The safety control device for a combustion device according to claim 1. 4. The safety control device for a combustion apparatus according to claim 1, wherein the canceling means includes a clear switch, and the clear switch outputs the cancel signal when turned on. 5. The canceling means includes a timer. The timer measures an elapsed time from when the danger determining means determines that the danger level is high , and the elapsed time reaches a predetermined time. 2. The safety control device for a combustion apparatus according to claim 1, wherein a cancel signal is output at the time. 6. A burner, (b) an operation switch, (c) a CO concentration detecting means, and (d) whether or not there is a danger based on the CO concentration. Danger determining means for recognizing in stages, (e) canceling means for outputting a cancel signal, and (f) basically starting combustion by the burner when the operation switch is turned on, and when the operation switch is turned off. Stopping the combustion, and stopping the combustion when it is determined to be dangerous by the danger determination means, and restarting the subsequent combustion according to the level of the danger recognized by the danger determination means, If it is determined to be dangerous, combustion can be restarted when the operation switch is turned on again,
If it is determined that the degree of danger is a high level, a combustion control means for enabling restart of combustion when the operation switch is turned on again, with the additional condition of receiving a cancel signal from the cancel means; And (h) an alarm when it is determined that the danger is determined by the danger determination means.
And a warning control means for operating the means . 7. The alarm control means according to claim 1, wherein
Depending on the stage of the perceived danger, the warning time is different,
If the risk is determined to be low, After driving switch
When the switch is turned off, the alarm
Even if the operation switch is turned on again,
Is maintained, and the risk is determined to be a high
At least without receiving a cancellation signal.
Activate the alarm means while the switch is on
The combustion device according to claim 6, wherein: 8. The alarm control means according to claim 1, wherein the danger judgment means is high.
After judging the degree of danger , activate the alarm means until the operation switch is turned off, stop the alarm means while the operation switch is off, and activate the alarm means when the operation switch is turned on again. The combustion device according to claim 6 , wherein: 9. The combustion apparatus according to claim 6 , wherein the canceling means includes a clear switch, and the clear switch outputs the cancel signal when turned on. 10. The canceling means includes a timer,
The timer measures an elapsed time from when the danger determining means determines that the danger level is high , and outputs a cancel signal when the elapsed time reaches a predetermined time. Item 7. The combustion device according to Item 6 .