KR0125959B1 - Combustion system - Google Patents

Abstract

The combustion apparatus includes a combustion signal generation circuit(17) for outputting a signal according to the state of combustion of a combustion portion using a battery(17) as a power source, a microcomputer(16) for controlling the operation of the combustion portion according to the output signal of the combustion signal generation circuit using the battery(17) as a power source, and a power circuit for rapidly charging the battery power and supplying the power to the microcomputer and the combustion signal generation circuit, in which a switching device(21) for periodically connected or cut off as a pulse signal(P) is applied from the microcomputer to the rapid charging path is interposed and the operation of the combustion portion is controlled by the microcomputer according to the output signal of the combustion signal generation circuit when the switching device is connected.

Description

Combustion device

1 is a system configuration diagram illustrating an example of a combustion apparatus according to the present invention.

2 is a circuit diagram of the main parts of the combustion apparatus shown in FIG.

* Description of the symbols for the main parts of the drawings *

1: burner (combustion part) 2: solenoid valve

3: gas supply passage (fuel supply passage) 15: battery

16 microcomputer 17 combustion signal generation circuit

18: auxiliary circuit 19: solenoid valve driving circuit

20: power supply circuit 21: switching transistor (switching element)

The present invention relates to a combustion apparatus such as a gas stove.

In general, in a combustion apparatus such as a gas stove, it is known that various kinds of combustion control are performed by a microcomputer. Such a combustion apparatus usually receives a signal of a sensor such as a thermocouple installed in the vicinity of the burner, and the burner A combustion signal generation circuit is provided which outputs a signal corresponding to the combustion state of the fuel cell, and when a signal corresponding to the burner's misfire state is output from the combustion signal generation circuit, the microcomputer supplies the fuel supply path to the burner. The closing command signal of the solenoid valve is output to the drive circuit of the solenoid valve provided in the middle, and the solenoid valve is closed by the solenoid valve drive circuit, and the fuel supply to a burner is interrupted | blocked.

In the combustion apparatus which performs various combustion control by using a microcomputer as described above, even if a signal corresponding to the burned state of the burner is output from the combustion signal generation passage when the microcomputer is congested due to disturbance or the like, the microcomputer is used. Since the solenoid valve may not be closed as the closing signal of the solenoid valve is not output from the computer, when the signal corresponding to the burner's misfire state is output from the combustion signal generation circuit, It has already been proposed by the present applicant that after a predetermined time has elapsed, an auxiliary circuit for outputting the closing command signal of the solenoid valve to the solenoid valve driving circuit without closing the microcomputer is provided so as to close the solenoid valve ( See Japanese Patent Application Laid-Open No. 5-45035).

By the way, such a type of combustion apparatus includes a method of using a commercial power source or a battery power source as a power source for the microcomputer, the combustion signal generation circuit, the solenoid valve driving circuit, and the like. When operating, the power supply circuit is always supplied with commercial power or forward power to the respective circuits so that the circuits are always started.

However, in the related art, since the power supply is always supplied to the combustion signal generation circuit and the like during the operation of the combustion device, especially in a combustion device using the battery as a power source, the battery is quickly consumed and the battery must be replaced frequently. There is a ham.

In particular, when the auxiliary circuit is provided so that the solenoid valve can be closed during burner burnout as described above, the combustion signal generation circuit sends a signal to both the microcomputer and the auxiliary circuit. Because of the output power consumption is increased, there is a disadvantage that occurs faster than the joining of the battery.

SUMMARY OF THE INVENTION In view of the above background, the present invention provides a combustion signal generation circuit using a battery as a power source or a combustion device in which a microcomputer is used to perform various control of a combustion unit by the microcomputer, thereby minimizing the power consumption of the battery as much as possible. It is an object of the present invention to provide a combustion apparatus that can extend the fuel cell and can reliably shut off the fuel supply to the combustion portion when the combustion portion is fired.

In order to achieve the above object, according to the present invention, a combustion signal generation circuit for outputting a signal according to a combustion state of a combustion unit using a battery as a power source, and an output signal of the combustion signal generation circuit using the battery as a power source. And a microcomputer for controlling the operation of the combustion section, and a combustion device having a microcomputer and a power supply circuit for supplying the battery power to the combustion signal generation circuit, the power supply circuit being configured on the feed path for the combustion signal generation circuit. A switching element which is periodically turned on and off as the pulse signal from the microcomputer is applied is interposed. When the switching element is turned on, the operation of the combustion section is performed by the microcomputer according to the output signal of the combustion signal generation circuit. And configured to be controlled.

A solenoid valve provided in a fuel supply path for supplying fuel to the combustion unit and a closing command signal of the solenoid valve are input from the microcomputer when a signal corresponding to a misfire state of the combustion unit is output from a combustion signal generation circuit. The solenoid valve driving circuit that closes the solenoid valve upon receipt and when the signal corresponding to the misfire state of the combustion section is continuously output from the combustion signal generating circuit for a predetermined time longer than the period of the pulse signal, the solenoid valve driving circuit And an auxiliary circuit for outputting the closing command signal of the solenoid valve to the furnace, wherein the combustion signal generation circuit is such that the output of the auxiliary circuit at the time of non-feeding is equal to the output of the auxiliary circuit in the misfired state of the combustion section. Characterized in that configured.

According to the present invention, as the pulse signal is applied from the microcomputer to the switching element, the switching element is periodically turned on and off, so that the power supply of battery power from the power supply circuit to the combustion signal generation circuit is supplied. Since this is cut off periodically, the power consumption of the combustion signal generation circuit is reduced. In this case, since the switching element performs only conduction / blocking operation, almost no power is consumed. In addition, the conduction / blocking operation of the switching element is performed by a pulse signal from an existing microcomputer, so that a circuit for consuming new power is not required, thereby making it possible to minimize battery consumption. Further, since the operation control according to the combustion state of the combustion unit by the microcomputer is performed only at the power supply to the combustion signal generation circuit, the period of conduction and interruption of the switching element, that is, the period of the pulse signal, is sufficiently shortened. As a result, the operation of the combustion unit according to the combustion state of the combustion unit can be performed without any problem.

In addition, the microcomputer can generally output the above-mentioned pulse signal easily by setting the program, and it is also possible to use the clock signal which the microcomputer normally has as the pulse signal.

Furthermore, when the signal corresponding to the misfire state of the combustion section is output from the combustion signal generation circuit, the combustion command is inputted from the microcomputer to the solenoid valve driving circuit to close the solenoid valve. If the output of the auxiliary circuit in the non-powered state of the signal generation circuit and the output of the auxiliary circuit in the misfired state of the combustion unit are configured to be the same, the microcomputer may runaway or fail at the time of the misfire of the combustion unit. A misfired state of the combustion section from the combustion signal generation arc to the auxiliary circuit even when the pulsed signal is not applied to the switching element so that the switching element is not operated and thus power supply to the combustion signal generation circuit is not performed. Signals corresponding to As the call continues to be output for the predetermined time, the closing command signal of the solenoid valve is output from the auxiliary circuit to the solenoid valve driving circuit. Accordingly, it is possible to close the solenoid valve by the solenoid valve driving circuit to cut off fuel supply to the combustion section. Further, since the predetermined time is longer than the period of the pulse signal, that is, the period of interruption of power supply to the combustion signal generation circuit, when the microcomputer is normal and the combustion unit burns normally, the combustion signal generation circuit is temporarily In the non-powered state, the auxiliary circuit does not output the closing command signal of the solenoid valve, and thus the solenoid valve is not closed.

Hereinafter, an example of the present invention will be described with reference to FIGS. 1 and 2, where FIG. 1 is an explanatory system configuration diagram of a combustion apparatus of the present embodiment, and FIG. 2 is a combustion apparatus shown in FIG. Is a circuit configuration diagram of the main part.

In FIG. 1, the combustion apparatus of the present embodiment is, for example, a gas furnace, in which, 1 is a burner which is a combustion section, and 2 is a gas burner (2) for opening and closing a gas (gas supply passage 3 for supplying fuel) to the burner 1. The solenoid valve installed in the gas supply passage 3 (fuel supply passage), 4 is a gas amount adjusting valve installed in the gas supply passage 3 to adjust the gas supply amount to the burner 1, 5 is the burner 1 Combustion detector installed in the vicinity of burner 1 to detect abnormal combustion such as misfire or lack of oxygen, 6 is an ignition electrode for igniting burner 1, 7 is for detecting cooking temperature of food A temperature detector provided at the center of the burner 1, 8 is a control unit equipped with a microcomputer, etc. described later, 9 is an ignition / fire extinguishing button for performing ignition and fire extinguishing operation of the burner 1. 10 is various automatic cooking For performing operations such as selecting and setting menus It represents a control panel.

The solenoid valve 2 is mechanically opened against a spring (not shown) in conjunction with the ON operation of the ignition / fire extinguishing button 9, and from the control unit 8 to the solenoid 11 of the solenoid valve 2; While it is kept open as it is energized, it is closed by the spring as it blocks the energization to the solenoid 11. Moreover, the opening degree of the gas amount adjustment valve 4 is adjusted by operating the operator 12 connected to it.

The combustion detector 5 is composed of a thermocouple to be described later to output the electromotive force of the thermocouple according to the combustion state of the burner 1 to the control unit (8). In addition, the temperature detector 7 has a built-in temperature sensor, such as a dummy (not shown) to output a signal of the temperature sensor to the control unit 8 in accordance with the cooking temperature of the food.

In addition, the ignition electrode 6 generates an ignition flame by the speaker 13 driven and controlled by the control unit 8 when the burner 1 is ignited. 14 is a solenoid valve for adjusting the gas supply amount to the burner 1 under the control of the control unit 8. In FIG.

Next, the structure of the said control unit 8 is demonstrated with reference to FIG.

In FIG. 2, the control unit 8 operates by using the battery 15 as a power source. The control unit 8 is a microcomputer 16 (hereinafter simply referred to as a microcomputer 16), a combustion signal generation circuit 17, and an auxiliary circuit ( 18), a power supply circuit 20 for supplying power to the battery 15 to the solenoid valve driving circuit 19 for driving the solenoid valve 2, the microcomputer 16, each circuit 17-19, or the like. And a switching transistor 21 serving as a switching element interposed between the power supply circuit 20 and the combustion signal generation circuit 17.

The power supply circuit 20 includes a regulator 22 connected to the battery 15, a switching transistor 23 having an emitter connected to the output point A of the regulator 22, and a base of the transistor 23. A collector connected switching transistor 24 is provided. The base of the transistor 24 is microcomputer 26 which is turned on / off in conjunction with the ON / OFF operation of the resistor 25 and the ignition / extinguishing button 9 at the output point A of the regulator 22. The regulator 22 outputs a constant voltage VR1 (hereinafter referred to as regulator voltage VR1) in which the battery voltage VD is input and the battery voltage VD is stepped down to an appropriate level. The emitter of the transistor 24 is grounded.

In such a configuration, when the ignition / extinguishing button 9 is turned ON, the microcomputer 26 is turned on so that the regulator voltage VR1 (high level voltage) is transmitted through the resistor 25 and the microcomputer 26. It is applied to the base of the transistor 24, so that the emitter and collector of the transistor 24 become conductive. By such conduction, a low-level voltage is applied to the base of the transistor 23 so that the emitter collector of the transistor 23 is conducted. Accordingly, the regulator is connected to the output point B (collector) of the transistor 23. The voltage VR2 which is almost equal to the voltage VR1 is generated. As described above, the power supply circuit 20 sets the voltage VR2 obtained at the output point B of the transistor 23 to the power supply terminal C of the microcomputer 16 or the combustion signal generation circuit 17. The power supply terminal D and the power supply terminal E of the auxiliary circuit 18 are supplied as a power supply voltage. In addition, the power supply circuit 20 generates the voltage VRJ3 and the regulator voltage VR1 generated at the input point F of the transistor 24 when the microcomputer 26 is turned on. The furnace 19 is supplied with power as a power supply voltage.

In this case, the switching transistor 21 is interposed between the power supply terminal D of the combustion signal generation circuit 17 and the output point B of the power supply circuit 20. The base is connected to the output terminal G of the microcomputer 16. The microcomputer 16 outputs a pulse signal P consisting of a signal of high and low binary levels from the output terminal G. In this embodiment, the period of the pulse signal P is set to 100 ms. In one cycle, the low level signal is set to 20 Hz and the high level signal is set to 80 Hz. In addition, the switching transistor 21 has a low level dazzle at the base of the transistor 21 in the conduction state of the transistor 23 of the power supply circuit 20 (state in which the voltage VR2 is generated at the output point B). In addition to conduction when applied, the Gorere signal is blocked when applied. Therefore, as the pulse signal P is applied to the base of the transistor 21, the transistor 21 periodically conducts and cuts off the circuit, and accordingly, the combustion signal generation circuit ( Feeding for 17) will occur periodically.

The combustion signal generation circuit 17 includes a pair of amplifiers 28 and 29 for amplifying an electromotive voltage corresponding to the combustion state of the burner 1 of the thermocouple 27 constituting the combustion detector 5, and By comparing the output voltage of the amplifier 29 with a predetermined reference voltage, signals corresponding to the burned state and the burned state of the burner 1 (including the abnormal burned state due to oxygen deficiency etc.) are obtained at high and low secondary levels. Comparator 30 for outputting a signal is provided. In this case, the output point H of the comparator 30 becomes low when the voltage corresponding to the combustion state (ignition state) of the burner 1 is input from the thermocouple 27 via the amplifier 29. On the other hand, the polarity is designed so that the voltage corresponding to the misfire state of the burner 1 is opened inside the comparator 30 when the voltage corresponding to the burned state is input from the thermocouple 27 through the amplifier 29. The output point H of the comparator 30 is connected to the output point B (voltage VR2) of the power supply circuit 20 via a resistor 31, and thus the burner 1 When a voltage corresponding to the misfire state is input from the thermocouple 27 through the amplifier 29, a high level signal is generated at the output point H of the comparator 30.

The output of the amplifier 28 is input to the input terminal I of the microcomputer 16, and the microcomputer 16 compares the output of the amplifier 28 with the reference voltage in the same manner as the comparator 30. As a result, combustion and misfire of the burner 1 are detected. The reference voltage of the comparator 30 is generated by dividing the battery voltage VD by the resistors 32 and 33, and the amplifiers 28 and 29 and the comparator 30 are separated from the power supply terminal D. It starts by supplying power supply voltage.

The solenoid valve driving circuit 19 includes a pair of switching transistors 35 and 36 connected in series to the solenoid 11 of the solenoid valve 2 via a resistor 34, and the transistor 36 And a switching transistor 38 having a collector connected to the base, wherein the transistors 35 and 36 are input points of the transistor 24 of the power supply circuit 20 to receive a voltage voltage from the power supply circuit 20. (F) is connected in series via a resistor 37. The base of the transistor 35 is connected to the output terminal J of the microcomputer 16, and the base and the emitter of the transistor 38 are respectively the output terminal K and the auxiliary circuit 18 of the microcomputer 16. )

As will be described in detail later, the transistor 35 of such a solenoid valve driving circuit 19 conducts as a low level signal is applied from the output terminal J of the microcomputer 16 to the base of the transistor 36. When the signal of high level (close command signal of the solenoid valve) is applied to the base, it becomes a blocking state. In addition, while the transistor 36 is connected by the microcomputer 16 and the auxiliary circuit 18 to conduct the transistor 38 to the ground side, a low level signal is applied to the base of the transistor 36, while the The transistor 38 is cut off by the microcomputer 16 or the auxiliary circuit 18 so that the base current of the transistor 36 is cut off. The solenoid valve driving circuit 19 maintains the solenoid valve 2 in an open state as the solenoid 11 is energized from the power supply circuit 20 in both conducting states of the transistors 35 and 36. As one of the transistors 35 and 36 is blocked, the solenoid valve 2 that blocks the energization of the solenoid 11 is closed.

The auxiliary circuit 18 includes a NAND circuit 39 for inputting a voltage on the transistor 35 side of the resistor 34 of the solenoid valve driving circuit 19 and an output voltage of the comparator 30, and the NAND thereof. A switching transistor 40 having the output of the circuit 39 as a base input, a delay circuit 41 having the collector output of the transistor 40 as an input, and a NAND circuit having the output of the delay circuit 41 having two inputs; (42) and a switching transistor 43 whose output is the base of the NAND circuit 42. In this case, the delay circuit 41 is composed of a time constant circuit including a resistor 44 and a capacitor 45, and the charge / discharge voltage of the capacitor 45 is output to the NAND circuit 42. The emitter of the transistor 40 is connected to the power supply terminal E to which the voltage VR2 is supplied from the power supply circuit 20, and the transistor 43 has its emitter grounded and its collector It is connected to the emitter of the transistor 38.

As will be described later in detail, the auxiliary circuit 18 has a high level corresponding to the misfire state of the burner 1 from the comparator 30 of the combustion signal generation circuit 17 in the open state of the solenoid valve 2. When the signal is continuously output for a predetermined time determined by the time constant of the delay circuit 41 (40 seconds in this embodiment, for example, a timer time hereinafter), the transistor 38 36), so that energization of the solenoid 11 is cut off and the solenoid valve 2 is closed.

Next, the operation of the combustion apparatus of this embodiment will be described.

When the ignition / extinguishing button 9 is turned ON, the microswitch 26 of the power supply circuit 20 is turned on in conjunction with the transistors 24 and 23 to sequentially conduct as described above. The voltage VR3 applied to the input point F of the () is supplied to the solenoid valve driving circuit 19, and the voltage VR2 generated at the output point B of the transistor 23 is the microcomputer 16. ) Is supplied to the power supply terminal (C), the power supply terminal (E) of the auxiliary circuit (18), and the emitter of the switching transistor (21), and the microcomputer (16), the auxiliary circuit (18), and the switching transistor (21). ) Becomes the start state.

In addition, the input signal of the micro switch 36 is input to the microcomputer 16 through an appropriate circuit (not shown).

In this way, when the microcomputer 16 is started and the input signal of the micro switch 26 is input, the microcomputer 16 outputs high and low voltage signals from the output terminals K and J, respectively, of the transistors 38 and 35. Applied to the base. On the other hand, when the auxiliary circuit 18 starts up, the capacitor 45 of the delay circuit 41 discharges, that is, the voltage of the capacitor 45 becomes a low level voltage, and therefore the output voltage of the NAND circuit 42 This high level is applied, and the high level voltage is applied to the base of the transistor 43.

Then, the transistors 38 and 43 are conducted to the ground side in response to the application of the high level voltage signal to the base of the transistor 38 and the application of the high level voltage signal to the base of the transistor 43. A low level voltage signal is applied to the base of 36.

Therefore, a low voltage voltage is applied to the bases of the transistors 35 and 36 of the solenoid valve driving circuit 19, so that the transistors 35 and 36 are energized to energize the solenoid 11. At this time, the solenoid valve 2 is mechanically opened against a spring (not shown) in conjunction with the ON operation of the ignition / fire extinguishing button 9, and is opened by energizing the solenoid 11. Is maintained, and gas is supplied to the burner 1 by opening the solenoid valve 2.

In addition, in such an operation, the sparker 13 is driven by the control of the microcomputer 16 to cause the spark electrode 6 to generate a spark discharge, and the burner 1 is ignited accordingly.

On the other hand, in parallel with such operation, the microcomputer 16 outputs the pulse signal P from the output terminal G to the base of the transistor 21, and thus a high level voltage is applied to the base of the transistor 21. The signal and the low level voltage signal are periodically applied alternately. For this reason, the transistor 21 periodically conducts and cuts off, and at the time of conduction, the voltage VR2 of the output point B of the transistor 23 of the power supply circuit 20 is changed to the combustion signal generation circuit 17. Is supplied to the power supply terminal D, and the combustion signal generation circuit 17 is activated. In this case, since the period of conduction and interruption of the transistor 21 is sufficiently short as described above, there is no difference from the case where the power is constantly supplied to the combustion signal generation circuit 17, and the power supply is intermittently performed. The amount of power supplied from the power supply circuit 20 to the combustion signal generation circuit 17 can be relatively small, thereby reducing the consumption of the battery 15.

When the combustion signal generation circuit 17 is activated, the combustion signal generation circuit 17 inputs an electromotive voltage signal corresponding to the combustion state of the burner 1 via the amplifier 28 through the input terminal I of the microcomputer 16. The microcomputer 16 detects combustion and misfire of the burner 1 by A / D conversion of the signal and then comparing the signal with a predetermined determination value.

Then, when the signal corresponding to the misfire state of the burner 1 is input from the combustion signal generation circuit 17 and the misfire of the burner 1 is detected, the microcomputer 16 is output from the output terminals K and J. The low level and high level voltage signals (close command signals) are applied to the bases of the transistors 38 and 35, respectively, and the transistors 38 are cut off so that the bases of the transistors 36 of the solenoid valve driving circuit 19 are applied. As the current does not flow, the transistor 36 is cut off, and the transistor 35 of the solenoid valve driving circuit 19 is also cut off. Therefore, the energization to the solenoid 11 is cut off, the solenoid valve 2 is closed, and gas supply to the burner 1 is interrupted | blocked. In addition, only one side of the transistors 35 and 36 may be blocked for such an operation.

By the way, the operation at the time of misfire is operation when the microcomputer 16 operates normally, but when the microcomputer 16 is runaway due to disturbance or the like, the microcomputer 16 does not operate as described above. Transistors 35, 36 and 38 of the solenoid valve driving circuit 19 are kept in a conductive state, so that the energization of the solenoid 11 is maintained, which may cause a situation in which the solenoid valve 2 is not closed. There is.

When the microcomputer 16 is congested in this manner, the pulse signal P from the microcomputer 16 is transferred from the power supply circuit 20 to the base of the transistor 21 which is responsible for feeding the combustion signal generation circuit 17. There is a fear that the transistor 21 remains in a cut-off state without being output and the combustion signal generation circuit 17 becomes inoperable.

However, in the present embodiment, even if the microcomputer 16 is congested or a failure occurs as described above, when the burner 1 is misfired, the solenoid valve 2 can be closed.

That is, first, when the combustion signal generation circuit 17 is normally started (when the pulse signal P is output from the microcomputer 16 to the transistor 21), the burner 1 of the thermocouple 27 is operated. In the case where the electromotive voltage according to the combustion state of the gas becomes a voltage corresponding to the misfire state of the burner 1, as described above, the voltage level of the output point H of the comparator 30 of the combustion signal generation circuit 17 is It becomes a high level.

In addition, when the microcomputer 16 is congested and power is not supplied to the combustion signal generation circuit 17 as described above, and the combustion signal generation circuit 17 becomes inoperable, the output point of the comparator 30 ( The voltage level of H) becomes a high level.

Therefore, when the combustion signal generation circuit 17 is operated, misfire of the burner 1 is generated and the electromotive voltage of the thermocouple 27 becomes a voltage corresponding to the misfire state of the burner 1 or combustion signal generation. When the circuit 17 becomes inoperable, the comparator 30 causes the voltage at the output point H to become a high level voltage, and the high level voltage signal is applied to any of the NAND circuits 39 of the auxiliary circuit 18. It is input to one input terminal.

At this time, when the solenoid 11 is energized, that is, the solenoid valve driving circuit 19 is not driven by the microcomputer 16 to block the energization of the solenoid 11. A high level voltage signal is applied to an input terminal on the other side of the NAND circuit 39 of the auxiliary circuit 18 from upstream of the resistor 34 on the downstream side of the transistor 35.

Therefore, the output voltage of the NAND circuit 39 becomes a low level voltage, and the low level voltage is applied to the base of the transistor 40 of the auxiliary circuit 18, thereby bringing the transistor 40 into a conductive state. The capacitor 45 is charged by the resistor 44 from the power supply terminal E of the auxiliary circuit 18 where power is supplied from the power supply circuit 20. At this time, the charging voltage of the condenser 45 becomes a high level voltage when the timer time (40 seconds in this embodiment) is determined by the capacitance and the resistance value of the resistor 44, and the contact voltage is a NAND circuit ( 42). The output voltage of the NAND circuit 42 is inverted from the high level to the low level by inputting a high level voltage signal to the NAND circuit 42, and the low level voltage is applied to the base of the transistor 43. Therefore, the transistor 43 is turned off, and following this, the transistor 38 of the solenoid valve driving circuit 19 is turned off. When the transistor 38 is turned off as described above, the base current of the transistor 36 does not flow, and the transistor 36 is turned off. Accordingly, the energization of the solenoid 11 is cut off to prevent electrons. The valve 2 is closed.

Accordingly, the electromotive voltage of the thermocouple 27 becomes a voltage corresponding to the misfire state of the burner 1, and the combustion signal is generated when the state continues for the timer time or when the microcomputer 16 runs out or breaks down. If the power supply to the circuit 17 is not continuously performed for the above timer time, energization of the solenoid 11 is cut off by the auxiliary circuit 18 via the solenoid valve driving circuit 19, and the solenoid valve 2 ) Can be closed.

In addition, when the burner 1 burns normally while the microcomputer 16 operates normally, the power supply to the combustion signal generating circuit 17 is intermittently performed as described above. At the output point H of the comparator 30, a voltage signal of a low level corresponding to the combustion state of the burner 1 and a voltage signal of Gorere corresponding to the misfire state of the burner 1 are periodically displayed alternately. The signal is input to the NAND circuit 39 of the auxiliary circuit 18. However, since the timer time of the auxiliary circuit 18 is sufficiently longer than the period of power supply to the combustion signal generation circuit 17 and the interruption thereof, the burner 1 is connected to the output point H of the comparator 30. Since the high level signal corresponding to the actual Asia Pacific appears periodically in a short time, the auxiliary circuit 18 is not operated so that the energization of the solenoid is interrupted by the solenoid valve driving circuit 19, so that the solenoid valve 2 ) Is kept open and combustion of the burner 1 is continued without interruption.

As described above, in the combustion apparatus of the present embodiment, the power supply to the combustion signal generation circuit 17 is intermittently performed from the power supply circuit 20 through the transistor 21, so that the combustion signal generation circuit 17 The power consumption can be reduced to suppress the consumption of the battery 15, and the life of the battery 15 can be relatively extended.

When misfire of the burner 1 occurs even when the microcomputer 16 is congested or in a faulty state, the auxiliary circuit 18 supplies electricity to the solenoid 11 through the solenoid valve driving circuit 19. By closing the solenoid valve (2) can be closed.

In addition, although the detailed description is omitted in the description of the present embodiment, the microcomputer 16 is a circuit connected to the temperature detector 7, a circuit connected to the power supply circuit 20, or the like. 15 is configured to monitor the voltage VD, and for example, when the heating temperature of the food becomes abnormally high temperature, the burner 1 is operated via the solenoid valve driving circuit 19 in the same manner as in the case of misfire. When the valve 2 is closed and the voltage VD of the battery 15 is lowered and a replacement is required, the valve 2 acts to warn by a warning lamp not shown.

In the above-described embodiment, the gas stove has been described as an example, but the present invention can be applied to various combustion apparatuses such as a heater or an oven.

In addition, in the present embodiment, the gas furnace having one burner 1 has been described, but the present invention can also be applied to the gas furnace having a plurality of burners in the same manner as in the present embodiment.

In this embodiment, although the switching transistor 21 is used as the switching element, it is, of course, also possible to use a low current relay or the like.

As can be seen from the above description, according to the present invention, the conductive circuit is periodically turned on and off by applying a pulse signal from a microcomputer which performs control of a combustion section on a path for feeding battery power from the power supply circuit to the combustion signal generation circuit. By interposing a switching element and controlling the operation of the combustion unit by the microcomputer according to the output signal of the combustion signal generation circuit when the switching element is turned on, the power consumption of the battery is kept as small as possible to extend its life. Can be.

When the signal corresponding to the misfire state of the combustion section is output from the combustion signal generation circuit, the closing command signal of the solenoid valve installed in the fuel supply path to the combustion section is output from the microcomputer to the solenoid valve driving circuit. When the solenoid valve is closed by the valve driving circuit, when the signal corresponding to the misfire state of the combustion section is continuously output from the combustion signal generation circuit for a predetermined time longer than the period of the pulse signal, the solenoid valve driving circuit from the auxiliary circuit. Outputting the closing command signal of the solenoid valve to the furnace, wherein the combustion signal generation circuit is configured such that the output of the auxiliary circuit and the output of the auxiliary circuit in the misfired state of the combustion section are equal to each other when the combustion signal generation circuit is not supplied. Therefore, even if the microcomputer is runaway or malfunctions, Even when no power is supplied, if the combustion part is misfired, the solenoid valve can be closed, whereby the fuel supply to the combustion part can be reliably cut off when the combustion part is misfired.

Claims (2)

A combustion signal generation circuit for outputting a signal according to the combustion state of the combustion section using a battery as a power source, and a microcomputer controlling the operation of the combustion section according to an output signal of the combustion signal generation circuit using the battery as a power source, A combustion apparatus having a microcomputer and a power supply circuit for supplying the battery power to the combustion signal generation circuit, wherein a pulse signal from the microcomputer is applied from the power supply circuit to a feed path to the combustion signal generation circuit. And a switching element which is periodically turned on and off, and is configured to control the operation of the combustion section by the microcomputer according to an output signal of the combustion signal generation circuit when the switching element is turned on. 2. The solenoid valve according to claim 1, wherein the solenoid valve provided in the fuel supply path for supplying fuel to the combustion section, and when the signal corresponding to the misfire state of the combustion section is output from the combustion signal generation circuit, When the solenoid valve driving circuit which closes the solenoid valve in response to receiving the closing command signal and the signal corresponding to the misfire state of the combustion part are continuously output from the combustion signal generation circuit for a predetermined time longer than the period of the pulse signal. And an auxiliary circuit for outputting a closing command signal of the solenoid valve to the solenoid valve driving circuit, wherein the combustion signal generation circuit is burned to the output to the auxiliary circuit during non-powering and to the auxiliary circuit in a misfired state of the combustion section. Combustion apparatus, characterized in that the output to the signal generation circuit is configured to be the same.