JPH06307634A - Combustion device - Google Patents

Abstract

PURPOSE:To provide a combustion device such as a gas cooking heater provided with a control circuit having a battery as its power supply and with an ignition sparking device in which a necessity of replacing the battery can be indicated accurately and positively. CONSTITUTION:In a combustion device provided with a control circuit 17 having a battery 13 as its power supply and an ignition sparking device, there are provided a lighting-up driving circuit 23 for lighting-up and driving the LED lamp 14 when the battery voltage VD is reduced to a predetermined value approximately equal to a limited value where the control circuit 17 can operate, and a latch circuit 35 for continuing the lighting-up and driving operation.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a combustion device such as a gas stove.

[0002]

2. Description of the Related Art For example, a gas stove is equipped with a control circuit including a temperature detection circuit for detecting the heating temperature of a food to be heated and a combustion detection circuit for detecting combustion / misfire of a burner. If the heating temperature detected by the burner becomes abnormally high, or if the burner misfire or misfire is detected by the combustion detection circuit, the solenoid valve provided in the gas supply path to the burner is closed to drive the burner. It is known to shut off the gas supply to the burner and thereby extinguish the burner.

In this type of gas stove,
It is also generally known that a battery is used as a power source of the control circuit, and in such a gas stove using a battery as a power source, a low current type solenoid valve with low power consumption is used, The solenoid valve can be held open even with a large current, but when the battery voltage drops to a certain extent, the operation of the control circuit becomes unstable and the solenoid valve cannot be accurately driven to close. Therefore, the battery voltage is detected and monitored, and when the battery voltage drops to a predetermined value, the indicator lamp is turned on to let the user know that the battery needs to be replaced. It is known to have been made. In this case, the display lamp is turned on, for example, when the battery voltage drops to a voltage near a limit value at which the operation of the control circuit becomes unstable.

By the way, in this type of gas stove, it is known that a sparker for ignition is used and a battery common to the control circuit is used as a power source of the sparker. When the display lamp is simply turned on when the battery voltage drops below a predetermined value as described above, there are the following inconveniences.

That is, while the sparker is driven only during the ignition operation, it generally consumes a large amount of power. Therefore, during the ignition operation, the voltage of the battery for supplying the power to the sparker drops once, When the drive of the sparker is stopped, the battery voltage rises again.

Therefore, only while driving the sparkler,
When the battery voltage drops below a predetermined value for turning on the display lamp and the driving of the sparkler is stopped, the battery voltage may rise again to a value higher than the predetermined value.
In such a case, there is a possibility that the operation of the control circuit becomes unstable even temporarily and it becomes impossible to drive the solenoid valve. Therefore, the user is urged to replace the battery. Is preferred.

Concretely, for example, the O of the ignition / extinguishing button
In the case where the solenoid valve is mechanically opened against the spring by N operation and kept open by energizing the solenoid, the sparker drives when the ignition / fire extinguishing button is turned ON, and the battery voltage increases. There is a risk that the operation of the control circuit will become unstable and the open valve holding current of the solenoid valve will not be able to flow to the solenoid, in which case the user will ignite in response to ignition of the burner. -When the ignition operation of the fire extinguishing button is released, the solenoid valve closes and the burner extinguishes.

Further, for example, in the case of electrically opening and maintaining the valve of the solenoid valve, the operation of the control circuit is unstable due to a large decrease in the battery voltage during the operation of the sparker. Therefore, there is a possibility that the valve opening current of the solenoid valve may not be passed. In this case, conversely, even if an ignition mistake occurs, there is a possibility that the control circuit cannot detect the misfire and the solenoid valve cannot be closed.

However, in the conventional device in which the display lamp is simply turned on when the battery voltage drops below a predetermined value, the battery voltage remains below the predetermined value only when the sparker is driven as described above. In this case, the display lamp is turned on when the sparker is driven, but the display lamp is turned off after the driving of the sparker is stopped. For this reason, the user often overlooks the lighting of the display lamp, and there is an inconvenience that the user cannot surely recognize the necessity of battery replacement.

[0010]

DISCLOSURE OF THE INVENTION The present invention solves such inconvenience, and in a combustion device such as a gas stove equipped with a control circuit using a battery as a power source and a sparker for ignition, a battery when the voltage of the battery drops An object of the present invention is to provide a combustion device capable of accurately and reliably performing the necessity of replacement.

[0011]

In order to achieve such an object, the present invention provides a control circuit for controlling the operation of a combustion section by using a battery as a power source, a sparker for igniting the combustion section by using the battery as a power source, and In a combustion device equipped with a battery voltage detecting means for detecting a battery voltage, when the battery voltage detected by the battery voltage detecting means falls below a predetermined value substantially equal to an operable limit value of the control circuit, And a notification continuation unit for continuing the notification by the notification unit regardless of the value of the battery voltage after the notification is generated.

Further, it is characterized in that a combustion inhibiting means for disabling the combustion operation of the combustion section is provided when the battery voltage drops below the predetermined value.

[0013]

According to the present invention, when the sparker is driven when the combustion section is ignited and the voltage of the battery once drops below the predetermined value at the time of driving, the notification means notifies the user of that fact. Then, the notification is continued by the notification continuation unit even if the battery voltage rises above the predetermined value due to the stoppage of the driving of the sparkler. Therefore, once the battery voltage drops below the predetermined value, continuous notification is given to the user, whereby the user can surely recognize the necessity of battery replacement.

Further, when the combustion inhibiting means is provided, when the battery voltage drops to the predetermined value substantially equal to the operable limit value of the control circuit, the combustion inhibiting means disables the combustion operation of the combustion section. As a result, it is possible to prevent the situation where the combustion device is operated with the battery voltage, which makes the operation of the control circuit unstable.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An example of the present invention will be described with reference to FIGS. FIG. 1 is an explanatory system configuration diagram of a combustion apparatus of this embodiment, and FIG. 2 is a circuit configuration diagram of a main part of the combustion apparatus of FIG.

1 and 2, the combustion apparatus of this embodiment is, for example, a gas stove and a burner 1 which is a combustion section.
An opening / closing solenoid valve 3 and a gas amount adjusting valve 4 for adjusting the gas supply amount are provided in a gas supply path 2 for supplying gas to the. In this case, the solenoid valve 3 is mechanically opened against a spring (not shown) in conjunction with the ignition operation of the ignition / extinction button 12 for performing the ignition / extinction operation of the burner 1, and the solenoid The open state is maintained by energizing 5 and the drive is closed by shutting off the energization. Further, the opening of the gas amount adjusting valve 4 is adjusted, for example, by operating the operator 6 connected thereto.

Further, the gas stove of this embodiment is provided with a control unit 7 composed of various electronic circuits described later, and this control unit 7 has a solenoid 5 of the solenoid valve 3.
And a temperature detector 8 provided at the center of the burner 1 to detect the heating temperature of the cooked food, and a combustion detector provided near the burner 1 to detect combustion / misfire of the burner 1. 9, a sparker 11 provided near the burner 1 for causing a spark discharge to the ignition electrode 10, and the ignition / extinction button 1
The micro switch 18 which is opened and closed by the operation 2 and the sparker switch 11a which is closed by the ON operation (ignition operation) of the ignition / fire extinguishing button 12 are connected.

In this case, the control unit 7 is started by using the battery 13 (shown in FIG. 2) as a power source through the microswitch 18, and the control unit 7 further includes the consumption level of the battery 13 (battery). An LED lamp 14 for notifying the user of the voltage state 13) is connected.

The sparkler 11 is an ignition / extinguishing button 1.
The sparker switch 1 which is closed by turning on the switch 2
It is adapted to be driven by the battery 13 via 1a. Then, the ignition / extinguishing button 12 after the ignition of the burner 1
By releasing the ON operation of the
1a is opened and the sparker 11 is deactivated, the burner 1
The useless operation of the sparker 11 is stopped during the ignition. The opening / closing of such a sparker switch 11a is controlled by using a heart cam mechanism as disclosed in Japanese Patent Publication No. 1-59498 by the applicant of the present application, for example. In addition, the parka 11
May be stopped by using a timer that is started by turning on the ignition / extinguishing button 12, for example.

The temperature detector 8 has a built-in thermistor 15 (shown in FIG. 2) which is a temperature sensor, and is used for cooking when a cooking pot or the like containing food to be cooked is placed on the burner 1. The pan is contacted, and at this time, a signal corresponding to the heating temperature of the cooking pan or the like is output from the thermistor 15 to the control unit 7.

Further, the combustion detector 9 has a built-in thermocouple 16 (shown in FIG. 2) which is a combustion detection sensor, and the thermocouple 16 outputs a signal corresponding to the amount of heat generated by the burner 1 to the control unit 7. Output to.

The control unit 7 is connected to the ON / OFF operation of the ignition / extinguishing button 12 by the micro switch 18 described above.
It is designed to be activated by the battery 13 via
Upon activation thereof, the solenoid 5 is energized and the solenoid valve 3 is energized.
Is driven to open, and gas is supplied to the burner 1. At this time, as described above, the sparker 11 is driven by the battery 13 via the sparker switch 11a that is closed by the ON operation (push operation) of the ignition / fire extinguishing button 12 to cause spark discharge to the ignition electrode 10, As a result, the burner 1 is ignited.

Further, as will be described later in detail, the control unit 7 detects the combustion / misfire of the burner 1 by the output signal of the thermocouple 16, and the heating temperature of the cooked food by the burner 1 and the disconnection of the thermistor 15. Failure of the thermistor 1
5 output signal, burner 1 misfire detected by thermocouple 1
6, when the heating temperature of the cooked food detected through the thermistor 15 becomes higher than a predetermined reference temperature, or when the wire breakage of the thermistor 15 is detected, The solenoid valve 3 is driven to be closed via the solenoid 5.

Further, the control unit 7 monitors the voltage of the battery 13, and drives the LED lamp 14 or the solenoid valve 3 via the solenoid 5 when the voltage drops to a predetermined reference voltage. It is designed to be closed.

Next, the main circuit configuration of the control unit 7 will be described in detail with reference to FIG.

Referring to FIG. 2, the control unit 7 includes
Control circuit 1 for controlling opening / closing of solenoid valve 3 as described above
7 (details will be described later), and the control circuit 17
While the battery 13 operates using the battery 13 as a power supply, the power supply voltage that allows the battery 13 to operate normally is determined. If the power supply voltage drops below the operable limit voltage, normal operation cannot be expected. Therefore, when the battery 13 is exhausted and its output voltage decreases to some extent, the control circuit 17 may not operate normally, and the opening / closing control of the solenoid valve 3 may not be normally performed.

Therefore, the control unit 7 sequentially monitors the voltage of the battery 13 during the operation of the gas stove, and when the voltage drops to a certain extent, the LED lamp 14 informs the user of that fact, or a solenoid valve. 3 is driven to be closed.

The structure relating to the monitoring and control of the voltage of the battery 13 will be described below.

The battery 13 includes the ignition / extinguishing button 12 described above.
A micro switch 18 which is turned on / off in conjunction with (see FIG. 1) is connected, and a battery voltage V _D generated at a point P at a subsequent stage of the micro switch 18 is supplied to the control circuit 17 as its power supply voltage. ing. The battery voltage V
_D is also supplied to the sparker 11 via the sparker switch 11a.

Further, in the subsequent stage of the micro switch 18,
A regulator 19 that receives the battery voltage V _D as an input and generates a constant voltage is connected, and the output voltage V of the regulator 19 is connected.
_R (hereinafter, referred to as regulator voltage V _R ) is supplied as a voltage for generating a reference voltage in a comparator (details will be described later) included in the control circuit 17.

On the other hand, the control unit 7 of the present embodiment, the comparators 20 and 21 for comparing the battery voltage V _D with a predetermined judgment voltage, respectively, and the LED lamp 14 blinking drive according to the output of the comparator 20. Drive circuit 2
2 and the LED lamp 1 according to the output of the comparator 21.
The battery voltage V _D is detected by the voltage of the lighting drive circuit 23 for lighting and driving the No. 4 and the capacitor 25 connected to the point P via the resistor 24, and will be described later when the battery voltage V _D becomes a predetermined value or less. Drive signal (low level signal) for solenoid valve 3 of
And a battery voltage monitoring circuit 26 for outputting

Each of the comparators 20 and 21 constitutes a battery voltage detecting means 27, and each of the comparators 20 and 21 has a dividing resistor 28 or 29 to which the battery voltage V _D is connected at the point P. Is entered via
Judgment voltages of different levels are input through the three dividing resistors 30, 31, 32 connected to the output side of the regulator 19. In the present embodiment, the rated value of the battery voltage V _D in the new state of the battery 13 is, for example, 3 V, the determination voltage in the comparator 20 is set to, for example, 2.65 V, and the determination voltage in the comparator 21 is, for example, 1.
It is set to 9V. The control circuit 17 sets the battery voltage V _{D to} approximately 1.9 V which is the judgment voltage of the comparator 21.
It is assumed that the device can operate normally until the value decreases.

Each of the comparators 20 and 21 has its own
Each judgment voltage and battery voltage V _DCompare with
Pond voltage V_DHigh and low binary level corresponding to the judgment voltage
A bell signal is sent to each of the blinking drive circuit 22 and the lighting driver.
The signal is output to the driving circuit 23. In this case, blink
The drive circuit 22 has a battery voltage V_DIs the judgment of the comparator 20
The signal indicating that the voltage has dropped to 2.65 V is
The LED lamp 1 when output from the comparator 20
4 is driven to blink. Also, lighting drive circuit
Reference numeral 23 is an indicator for the present invention together with the LED lamp 14.
The battery voltage V, which constitutes the stage 34,_DCompare
Indicates that the voltage has dropped to the judgment voltage (1.9 V) of the power supply 21.
When the output signal is output from the comparator 21, the L
The ED lamp 14 is driven to light up.

In this case, the comparator 21 has a latch circuit 35 that holds the output when the signal indicating that the battery voltage V _D has dropped to the determination voltage (1.9 V) of the comparator 21 is output. Are connected. The latch circuit 35 corresponds to the lighting drive circuit 2
The notification continuation means for continuing the lighting of the LED lamp 14 by No. 3 is configured.

The output of the comparator 21 is also input to a first timer circuit (details will be described later) of the control circuit 17 which outputs a closing drive signal for the solenoid valve 3.

Further, the comparators 20 and 21, the blinking drive circuit 22, and the lighting drive circuit 23 use the battery voltage V _D as the power supply voltage similarly to the control circuit 17, and are 1.9 V which is the judgment voltage of the comparator 21. It is assumed that the battery can operate normally until the battery voltage V _D drops to some extent.

The battery voltage monitoring circuit 26 uses the battery voltage V
_D is used as a power supply voltage, and in this case, the circuit 26 reduces the battery voltage V _D to a voltage (about 1 V in this embodiment) that is lower than the determination voltage of the comparator 21, which is 1.9 V. It is supposed that it can operate normally until. Then, the battery voltage monitoring circuit 26 outputs a closing drive signal of the solenoid valve 3 to a solenoid valve drive circuit described later when the battery voltage V _D drops to 1.7 V or less, for example.

Next, the structure of the control circuit 17 will be described in detail.

In FIG. 2, the control circuit 17 includes a thermocouple circuit 36 for generating a voltage signal according to the heat generation amount of the burner 1 by the thermocouple 16, and a burnout of the burner 1 by an output signal of the thermocouple circuit 36. .First and second detection of misfire
Combustion detection circuits 37, 38, a thermistor circuit 39 for generating a voltage signal according to the heating temperature of the cooked food by the thermistor 15, and first and first detecting the heating temperature of the cooked food by the output signal of the thermistor circuit 39. 2 temperature detection circuits 40, 41, a disconnection detection circuit 42 for detecting the disconnection of the thermistor 15 based on the output signals of the thermistor circuit 39, the first combustion detection circuit 37 and the first temperature detection circuit 40, and the electromagnetic waves in response to the signals. A first timer circuit 43 that outputs a signal for opening and closing driving of the valve 3, a second timer circuit 44 that receives a signal from the disconnection detection circuit 42 and outputs a signal for opening and closing driving of the solenoid valve 3, and two switching circuits. Transistor 45,
And a solenoid valve drive circuit 47 having 46.

In this embodiment, the first timer circuit 43 and the solenoid valve drive circuit 47 are the combustion inhibiting means 4 according to the present invention.
8 is configured.

The first and second combustion detection circuits 37, 38
Have the same configuration, and these detection circuits 37, 38
Is provided with a comparator 49 for comparing the output voltage of the thermocouple circuit 36 according to the calorific value of the burner 1 with a reference voltage for combustion / misfire determination. And these detection circuits 3
7, 38 detects whether the burner 1 is in the combustion state or the misfire state by comparing the output voltage of the thermocouple circuit 36 with the reference voltage for the combustion / misfire determination by the comparator 49, The comparator 49 outputs a voltage signal of high and low binary levels in response to the detection of misfire. In the following description, a voltage signal having a level corresponding to the combustion state of the burner 1 will be referred to as a combustion detection signal, and a voltage signal having a level corresponding to the misfire state of the burner 1 will be referred to as a misfire detection signal.

The output of the first combustion detection circuit 37 is input to the first timer circuit 43, and the output of the second combustion detection circuit 38 is input to the disconnection detection circuit 42.

The first and second temperature detection circuits 40 and 41
Has the same basic configuration, and includes a comparator 50 that compares the output voltage of the thermistor circuit 39 according to the heating temperature of the cooked food by the burner 1 with a reference voltage corresponding to a reference temperature for overheating determination. ing. Then, these detection circuits 40 and 41 detect whether the cooking temperature of the cooked food is higher or lower than the reference temperature by comparing the output voltage of the thermistor circuit 39 with the reference voltage for overheating determination by the comparator 50, and the heating is performed. The comparator 50 outputs a voltage signal of high and low binary levels according to the level of the temperature. In the following description, the voltage signal of the level corresponding to the case where the heating temperature of the cooked food is higher than the reference temperature is the overheating detection signal, and the voltage signal of the level corresponding to the case where the heating temperature is lower than the reference temperature is normally heated. It is called a detection signal.

In this case, in this embodiment, the reference temperature for overheat determination of the first temperature detection circuit 40 and the reference temperature for overheat determination of the second temperature detection circuit 41 are set to different values. In the first temperature detection circuit 40, for example, 26
The reference temperature is 0 ° C., and in the second temperature detection circuit 41, for example, 290 ° C. is the reference temperature.

The output of the first temperature detection circuit 40 is input to the first timer circuit 43, and the output of the second temperature detection circuit 41 is input to the base of the transistor 46 of the solenoid valve drive circuit 48. Further, the overheating detection signal and the normal heating detection signal which are the outputs of the second temperature detection circuit 41 are low level and high level signals, respectively, and these signals respectively drive the solenoid valve 3 to be closed as described later. It is used as a signal and an open drive signal. Further, the overheating detection signal and the normal heating detection signal of the first temperature detection circuit 40 are
It is input to the first timer circuit 43.

The disconnection detection circuit 42 includes the thermistor 15
The thermistor circuit 39 is provided with a comparator 51 that compares the output voltage of the thermistor circuit 39 with a reference voltage for disconnection determination according to the voltage across the terminals of the thermistor circuit 39.
By comparing the output voltage of the above with the reference voltage for disconnection determination, it is detected whether or not the thermistor 15 is disconnected, and a high / low binary level voltage signal is output from the comparator 51 according to the detection of disconnection / non-disconnection. I am trying to output. In this case, the output of the second combustion detection circuit 38 is also input to the comparator 51, and the comparator 51 detects the disconnection of the thermistor 15 and the second combustion detection circuit 38. The voltage signal of the same level is output when the misfire is detected by, and the voltage signal of the other level is output in other cases. Hereinafter, the voltage signal of the level corresponding to the disconnection of the thermistor 15 or the misfire of the burner 1 is referred to as a disconnection / misfire detection signal.

The output of the disconnection detection circuit 42 is input to the second timer circuit 44. In this case, as described above, the output of the second combustion detection circuit 38 is the disconnection detection circuit 42.
Since the disconnection detection circuit 42 and the second combustion detection circuit 38 simultaneously output the disconnection detection signal and the misfire detection signal, respectively, the respective signals input to the second timer circuit 44 are not erased. Absent.

The first timer circuit 43 outputs a misfire detection signal from the first combustion detection circuit 37, outputs an overheat detection signal from the first temperature detection circuit 40, or monitors the battery voltage. Constant circuit 53 having a capacitor 52 that charges and discharges with a predetermined time constant when a signal indicating that the battery voltage V _D has dropped to the determination voltage (1.9 V) is output from the comparator 21 for
And a comparator 54 that compares the voltage of the capacitor 52 with a reference voltage for determining output timing.
The time constant of the time constant circuit 53 is the misfire detection signal from the first combustion detection circuit 37, the overheat detection signal from the first temperature detection circuit 40, or the battery voltage V _D from the comparator 21 is 1.9V. The voltage of the capacitor 52 is set to a predetermined value when a signal indicating that the voltage has dropped to a constant value is continuously output for a predetermined time (7 seconds in this embodiment, hereinafter referred to as a timer time).

The comparator 54, which produces the output of the first timer circuit 43, receives the misfire detection signal, the overheat detection signal, or the signal indicating that the battery voltage V _D has dropped to 1.9 V from the timer. When it is continuously output for a period of time, this is detected by the voltage of the capacitor 52, and a closing drive signal for the solenoid valve 3 is output in response thereto. At other times, an open drive signal for the solenoid valve 3 is output. Is output. In this case, the comparator 54
Is a high / low binary level signal, the closing drive signal of the solenoid valve 3 is at a high level, and the open drive signal is at a low level.

The second timer circuit 44 has the same basic configuration as the first timer circuit 43, and includes a time constant circuit 56 having a capacitor 55 and a comparator 57. Then, the second timer circuit 44 includes the first timer circuit 4
As in the case of 3, a predetermined time in which the disconnection / misfire detection signal from the disconnection detection circuit 42 is determined by the time constant of the time constant circuit 56 (for example, 10 seconds, hereinafter referred to as timer time).
When it is continuously output, the comparator 57 outputs a closing drive signal for the solenoid valve 3, and at other times, an open drive signal for the solenoid valve 3 is output. In this case, the comparator 57 is provided with the polarity such that the closing drive signal of the solenoid valve 3 becomes low level and the opening drive signal becomes high level, contrary to the comparator 54 of the first timer circuit 43.

In the solenoid valve drive circuit 47, the solenoid 5 of the solenoid valve 3 is connected to the switching transistors 45 and 46.
Are connected in series, and transistors 45 and 46
When both are in the conductive state (ON state), the solenoid 5
Is electrically energized from the battery 13 to maintain the solenoid valve 3 that is mechanically opened in the open state, and the transistors 45, 46
When either one of them is in a shut-off state (OFF state), the solenoid 5 is de-energized to close and drive the solenoid valve 3.

In this case, the transistor 45 is of the PNP type and is connected to the timer circuit 43 with the output of the first timer circuit 43 as a base input. As a result, the transistor 45 becomes conductive when the low-level signal that is the open drive signal for the solenoid valve 3 is output from the first timer circuit 43, and the high-level signal that is the close drive signal for the solenoid valve 3 is turned on. The output is cut off.

On the other hand, the transistor 46 is of the NPN type, and the output of the second timer circuit 44 and the second
The output of the temperature detection circuit 41 and the battery voltage monitoring circuit 26
With the output of and as a base input, these circuits 44, 41,
It is connected to 26. As a result, the transistor 4
6 is in a conductive state when a high level signal that is an open drive signal for the solenoid valve 3 is output from any of the second timer circuit 44, the second temperature detection circuit 41, and the battery voltage monitoring circuit 26, and the solenoid valve 6 When the low level signal, which is the closing drive signal of No. 3, is output, the cutoff state is set.

Further, in this embodiment, the second timer circuit 44, the second temperature detecting circuit 41 and the battery voltage monitoring circuit 2 are provided.
A delay circuit 58 is provided between the output point of 6 and the base of the transistor 46 to apply the outputs of these circuits 44, 41 and 26 to the base of the transistor 46 with a slight time delay. The delay circuit 58 is composed of a resistor 59 and a capacitor 60,
The output of the second timer circuit 44, the second temperature detection circuit 41, and the battery voltage monitoring circuit 26 charges and discharges the capacitor 60 via the resistor 59, and the voltage of the capacitor 60 is applied to the base of the transistor 46. . As a result, the outputs of the second timer circuit 44, the second temperature detection circuit 41, and the battery voltage monitoring circuit 26 are applied to the base of the transistor 46 with a delay of a time constant determined by the resistance value of the resistor 59 and the capacitance of the capacitor 60. It Therefore,
For example, in the conductive state of the transistor 46 (state in which the base input is at a high level), the output of any one of the second timer circuit 44, the second temperature detection circuit 41, and the battery voltage monitoring circuit 26 changes from the high level to the low level for a moment due to noise or the like. In the case where the level is changed, the instantaneous low level signal is not applied to the base of the transistor 46,
The conduction state of the transistor 46 is maintained.

In this embodiment, the delay time of the output of the second timer circuit 44, the second temperature detecting circuit 41 and the battery voltage monitoring circuit 26 by the delay circuit 58 is set to a sufficiently short value of about several milliseconds. There is.

Further, in this embodiment, when the battery voltage V _D drops to a voltage (about 1.5 V in this embodiment) lower than 1.7 V which is the judgment voltage of the battery voltage monitoring circuit 26, the transistor A transistor cutoff circuit 61 for cutting off the transistor 46 is provided at the input portion to the base of the transistor 46. The transistor cutoff circuit 61 generates a voltage obtained by dividing the battery voltage V _D by a pair of dividing resistors 62 and 63 connected to the base of the transistor 46 via the delay circuit 58.
Is applied to the base of the transistor via a delay circuit 58, and a voltage such that the transistor 46 is cut off when the battery voltage V _D drops to about 1.5 V is applied to the base of the transistor 46. The resistance values of the dividing resistors 62 and 63 are set so that the voltage is applied.

Next, the operation of the gas stove of this embodiment will be described.

In the gas stove of this embodiment, when the ignition / fire extinguishing button 12 is turned on, the micro switch 18 is turned on in association with the ON / OFF button, whereby the battery voltage is supplied from the battery 13 to the respective circuits of the control unit 7. V _D is supplied to activate each circuit.

At this time, the solenoid valve 3 is mechanically opened against the spring (not shown) in conjunction with the ON / OFF operation of the ignition / extinguishing button 12, and at the same time, the timer circuits 43 and 44 First, an open drive signal for the solenoid valve 3 is output, whereby each of the transistors 45, 46 of the solenoid valve drive circuit 47 is output.
Is turned on and the battery 5 is applied to the solenoid 5 of the solenoid valve 3.
The solenoid valve 3 is maintained in the open state. Then, when the solenoid valve 3 is driven to open, gas supply to the burner 1 is started. In parallel with this, as described above, by operating the ignition / fire extinguishing button 12, the sparkler 11 is operated.
Are driven by the battery voltage V _D via the sparker switch a, which causes ignition sparks on the ignition electrode 10.

At this time, each combustion detection circuit 37, 38 outputs a misfire detection signal because the electromotive force of the thermocouple 16 is small between the time when the burner 1 ignites and the initial stage when the burner 1 ignites. Then, the misfire detection signal of the first combustion detection circuit 37 is input to the first timer circuit 43, and the second combustion detection circuit 3
The misfire detection signal 8 is input to the second timer circuit 44 via the disconnection detection circuit 42.

Then, the first timer circuit 43 continues to output the misfire detection signal of the first combustion detection circuit 37 for the timer time (7 seconds) of the timer circuit 43, that is, within the timer time. If the electromotive force of the thermocouple 16 does not exceed a predetermined value, the closing drive signal (high level signal) of the solenoid valve 3 is transferred to the transistor 45 of the solenoid valve drive circuit 47.
To the base of the transistor 45 to turn off the transistor 45. As a result, the solenoid 5 of the solenoid valve 3 is de-energized, the solenoid valve 3 is closed, and the gas supply to the burner 1 is shut off.

Similarly, the second timer circuit 44 has the thermocouple 16 within the timer time (10 seconds) of the timer circuit 44.
If the electromotive force of the solenoid valve does not exceed a predetermined value, the solenoid valve drive circuit 4 outputs a close drive signal (low level signal) for the solenoid valve 3.
7 to the base of the transistor 46 to turn off the transistor 46 and drive the solenoid valve 3 to close. still,
At this time, since the output of the timer circuit 44 is applied to the base of the transistor 46 via the delay circuit 58, a slight time delay occurs, but the delay time is longer than the timer time (10 seconds) of the timer circuit 44. Since the time is sufficiently short, such as several milliseconds, the transistor 46 is almost ready when the timer time elapses.
A closing drive signal is applied to the base of the.

In this case, the timer time (7 seconds) of the first timer circuit 43 is equal to the timer time (10 seconds) of the second timer circuit 44.
Second), the solenoid valve 3 is normally driven to be closed according to the timer time of the first timer circuit 43, the first timer circuit 43 or the like fails, and the output of the first timer circuit 43 is output from the solenoid valve 3. When the level of the open drive signal is maintained, the solenoid valve 3 is driven to close according to the timer time of the second timer circuit 44.

In the operation at the time of ignition, the timer time of the first timer circuit 43 or the second timer circuit 44
If the burner 1 is ignited within the timer time of, and the electromotive force of the thermocouple 16 exceeds a predetermined value, this is detected by the first combustion detection circuit 37 or the second combustion detection circuit 38, and these A combustion detection signal is output from the circuits 37 and 38. In this case, the first timer circuit 43 and the second timer circuit 44 basically continue to operate the solenoid valve 3
The open drive signal of is output.

The operation described above is similarly performed when the burner 1 misfires for some reason after the start of combustion of the burner 1.

On the other hand, when the cooked food is heated by the combustion of the burner 1, the heating temperature is detected by the first and second temperature detection circuits 40 and 41 through the thermistor circuit 39. Then, the first temperature detection circuit 40 outputs a low-level overheat detection signal to the first timer when the detected heating temperature is equal to or higher than 260 ° C. which is the reference temperature for overheat determination of the circuit 40. Output to the circuit 43. At this time, the first
The timer circuit 43 outputs the closing drive signal of the solenoid valve 3 to the transistor 45 when the overheat detection signal is continuously output from the first temperature detection circuit 40 for the timer time (7 seconds). As a result, the transistor 45 is cut off, the solenoid valve 3 is driven to close, and the combustion of the burner 1 is stopped to prevent overheating. At this time, the heating temperature temporarily exceeds the reference temperature due to fluctuations in the combustion flame of the burner 1 or the like, and the overheat detection signal is output from the first temperature detection circuit 40 for a short time (<7 seconds). However, in such a case, since the continuous output time of the overheat detection signal is shorter than the timer time of the first timer circuit 43, the timer circuit 43 does not output the close drive signal, and therefore, The solenoid valve 3 is maintained in the open state.

Further, the second temperature detecting circuit 41, when the detected heating temperature is 290 ° C. or higher, which is higher than the reference temperature for overheating determination of the first temperature detecting circuit 40,
The low-level overheat detection signal is output to the base side of the transistor 46 without passing through the timer circuit. Then, this low level overheat detection signal is applied to the base of the transistor 46 via the delay circuit 58. In this case, since the overheat detection signal is applied to the base of the transistor 46 via the delay circuit 58, although it is applied to the base of the transistor 46 with a slight delay from the output point of the overheat detection signal, The delay is about several milliseconds. Therefore, for example, in the case where the heating temperature suddenly exceeds 290 ° C from the reference temperature of 260 ° C of the first temperature detecting circuit 40 within the timer time (7 seconds) of the first timer circuit 43. , A low level signal is immediately applied to the base of the transistor 46, which causes the transistor 4
6 is shut off, and the solenoid valve 3 is driven to close. still,
At this time, an overheat detection signal may be output from the second temperature detection circuit 41 on a one-off basis due to noise or the like, but such a one-time overheat detection signal is removed by the delay circuit 58 and the transistor 46 of the transistor 46 is removed. It is not applied to the base and therefore the solenoid valve 3 is never driven to close.

Further, when the thermistor 15 is disconnected during the operation of the gas stove as described above, the disconnection is detected by the disconnection detection circuit 42. At this time, the disconnection detection circuit 42 detects the disconnection detection signal. Is output to the second timer circuit 44. Then, the second timer circuit 44
Outputs the closing drive signal of the solenoid valve 3 to the base of the transistor 46 when the disconnection detection signal is continuously output for the timer time (10 seconds). As a result, the transistor 46 is turned off and the solenoid valve 3 is driven to close.

Next, the operation relating to the monitoring of the battery voltage V _D will be described.

In the operation of the gas stove as described above, when the battery 13 is exhausted and the battery voltage V _D thereof drops to 2.65 V which is the judgment voltage of the comparator 20, this is detected by the comparator 20. ,
The comparator 20 outputs a signal indicating this to the blinking drive circuit 22. At this time, the blinking drive circuit 22 is set to L
The ED lamp 14 is driven to blink, thereby making the user aware that the battery 13 will soon need to be replaced.
It should be noted that the burner 1 is driven by the sparker 11 using the battery 13 as a power source.
Since the battery voltage V _D during the ignition operation for the ignition is below the determination voltage of the comparator 20 due to the power supply to the sparker 11, the operation of the various circuits described above becomes unstable. If the voltage drops to such a level that the sparkler 11 becomes inoperative after the ignition operation, the battery voltage V _D may rise above the determination voltage again. Then, in such a case, the LED lamp 14 blinks only when the sparker 11 is activated, while the LED lamp 14 is activated after the ignition operation.
The lamp 14 is turned off again, and the user often overlooks the blinking of the LED lamp 14. Therefore, in the present embodiment, the determination voltage (2.65 V) of the comparator 20 is set relatively high so that the LED lamp 14 blinks early.

At the stage where the LED lamp 14 blinks in this way, the battery voltage V _D is still a voltage at which the control circuit 17 and the like can normally operate, so the user can continue to use the gas stove to some extent. can do.

Further, when the battery voltage V _D is the above-mentioned comparator 2
When the voltage drops to 1.9 V, which is the determination voltage of 1, this is detected by the comparator 21, and the comparator 21 outputs a signal indicating that to the lighting drive circuit 23. At this time, the lighting drive circuit 23 drives the LED lamp 14 to light, thereby making the user recognize that the battery 13 needs to be replaced.

In this case, in this embodiment, the comparator 2
In No. 1, the output is held by the latch circuit 35 once the battery voltage V _D drops to 1.9 V. Therefore, the battery voltage V _D is supplied by the power supply to the sparker 11 during the ignition operation. _The voltage _D becomes lower than the judgment voltage (1.9 V) of the comparator 21 and becomes a voltage at which the operation of the above-mentioned various circuits may become unstable, and the battery voltage V _D is judged again after the ignition operation. Even when the voltage rises above the voltage, the signal indicating that the battery voltage V _D has dropped to 1.9 V continues to be output from the comparator 21, and therefore L
The ED lamp 14 lights continuously. As a result, if the battery voltage V _D drops to such a voltage that the operation of the various circuits described above may become unstable even for a short time, the user is required to replace the battery 13. It can be surely recognized.

The latch circuit 35 is a circuit having a buffer formed of transistors, which is similar to a known circuit. Such a latch circuit is a comparator 2
It can also be provided on the 0 side.

At this time, the output of the comparator 21 indicating that the battery voltage V _D has dropped to 1.9 V is also input to the first timer circuit 43. At this time, the comparator 2
Since the output of 1 is maintained by the latch circuit 35,
The timer circuit 43 outputs a closing drive signal of the solenoid valve 3 to the transistor 45 of the solenoid valve drive circuit 47 when the timer time (7 seconds) has elapsed from the output time point of the comparator 21. As a result, the transistor 45 is turned off, the solenoid valve 3 is driven to close, and the burner 1 is prohibited from burning.

By the way, when the battery voltage V _D drops to a level at which the operation of the comparators 20 and 21 becomes unstable (for example, about 1.8 V) due to the operation of the sparker 11 as described above, The comparator 21 and the first timer circuit 43 do not operate as described above, and the solenoid valve 3
However, there is a possibility that a situation in which the drive is not closed by the comparator 21 or the first timer circuit 43 occurs. However, in the present embodiment, the battery voltage monitoring circuit 26 that can normally operate up to a battery voltage V _{D of} about 1 V is provided, and the battery voltage monitoring circuit 26 uses the battery voltage V _D.
When the voltage drops to 1.7 V or less, the close drive signal (low level signal) is output to the base of the transistor 46 via the delay circuit 58. As a result, the transistor 46 is turned off and the solenoid valve 3 is driven to close.

Further, in this embodiment, even if the battery voltage monitoring circuit 26 should fail, if the battery voltage V _D drops to about 1.5 V, the transistor shutoff circuit 61 causes the solenoid valve 3 to operate. It can be closed. That is, when the battery voltage V _D drops to about 1.5 V, the dividing resistor 63 of the transistor cutoff circuit 61 is used.
Applies a low-level voltage to the base of the transistor 46, which turns off the transistor 46 and drives the solenoid valve 3 to close. And at this time, the L
Since the ED lamp 14 is turned on, the user can recognize that the operation of the gas burner has stopped because the battery voltage V _D has dropped.

[0078] Thus, in the gas stove of the present embodiment, it is possible to recognize the appropriately user of the drop of the battery voltage V _D, reliably solenoid valve 3 with a decrease of the battery voltage V _D closed Can be driven.

In the embodiments described above, the gas stove has been described, but it goes without saying that the present invention can be applied to a combustion device such as a water heater or a heater.

[0080] Further, in this embodiment, the LED lamp 14 is used as notification means for notifying decrease in the battery voltage V _D, and so as to blink-lighting this in accordance with the degree of decrease in the battery voltage V _D However, the order of blinking and lighting may be reversed, or the emission color of the LED lamp 14 is changed (for example, changed from yellow to red) according to the degree of decrease in the battery voltage V _D. Alternatively, for example, a buzzer or the like may be used as the notification means, and the tone color may be changed according to the degree of decrease in the battery voltage V _D.

Further, in this embodiment, the latch circuit 35 is provided only on the comparator 21 side, but the latch circuit is also provided on the comparator 20 side so that the LED lamp 14 blinks when the battery voltage V _D drops below a predetermined value. May be continued, and in this case, the determination level of the comparator 20 may be set lower than that in the present embodiment.

[0082]

As is apparent from the above description, according to the present invention, when the battery voltage detected by the battery voltage detecting means falls below a predetermined value substantially equal to the operable limit value of the control circuit, With the notification means,
By making the notification continue by the notification continuation means regardless of the value of the battery voltage after the occurrence of the notification, the battery voltage once drops below the predetermined value due to the operation of the sparker, and then again When the battery voltage rises above the predetermined value, the notification means can continuously notify, and the necessity of battery replacement when the battery voltage decreases can be accurately and reliably performed.

When the battery voltage drops to the above-mentioned predetermined value, the combustion operation of the combustion section is disabled, so that the operation of the control circuit becomes unstable due to the battery voltage drop. Can be prevented.

[Brief description of drawings]

FIG. 1 is an explanatory system configuration diagram of an example of a combustion apparatus of the present invention.

FIG. 2 is a circuit configuration diagram of a main part of the combustion apparatus of FIG.

[Explanation of symbols]

1 ... Burner (combustion part), 13 ... Battery, 17 ... Control circuit,
20, 21 ... Comparator (battery voltage detection means), 34
... informing means, 48 ... combustion prohibiting means.

Claims (2)

[Claims] 1. Combustion comprising a control circuit for controlling the operation of a combustion section by using a battery as a power source, a sparker for igniting the combustion section by using the battery as a power source, and a battery voltage detecting means for detecting the voltage of the battery. In the device, when the battery voltage detected by the battery voltage detecting means falls below a predetermined value substantially equal to the operable limit value of the control circuit, an informing means for informing that effect, and the informing means for informing A combustion device, comprising: a notification continuation means for continuing the notification regardless of the value of the battery voltage after the notification is generated. 2. The combustion apparatus according to claim 1, further comprising combustion inhibiting means for disabling combustion operation of the combustion section when the battery voltage drops below the predetermined value.