KR0125786B1 - Combustion device - Google Patents

Abstract

This invention includes a temperature detection circuit(21) for outputting a closing driving command signal for an electronic control valve(3) when a heating temperature of an object is over the first reference temperature, and a temperature detection circuit(22) for outputting a closing driving signal for the electronic control valve(3) when the heating temperature becomes over the second reference temperature beyond the first reference temperature. The signal of the temperature detection circuit(21) is input to a timer circuit(24). The timer circuit(24) outputs the closing driving signal to an electronic valve driving circuit(28) to close the electronic control valve(3) when the closing driving command signal of the temperature detection circuit(21) continues for a predetermined time. The closing driving signal of the temperature detection circuit(22) is directly outputted to the electronic control valve driving circuit(28) and the electronic control valve(3) is closed by the above output.

Description

Combustion device

1 is an explanatory system configuration diagram showing an example of the combustion apparatus of 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: gas supply path (fuel supply path)

3: electronic control valve 5: solenoid

15: Thermistor (temperature sensor) 21, 22: Temperature detection circuit

24: timer circuit 26, 27: switching transistor

28: solenoid valve driving circuit

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

For example, a gas detecting circuit is provided with a temperature detecting circuit for detecting a heating temperature of a food to be heated in contact with a container of the food through a temperature sensor such as a thermistor. It is known to output a signal indicating an overheating state from the temperature detection circuit and close and drive the electronic control valve installed in the gas supply path to the burner according to the output via the electronic control valve driving circuit.

In this type of gas stove, a timer circuit is provided between the temperature detection circuit and the solenoid control valve driving circuit, and the timer is output when the signal indicating the overheating state is continuously output from the temperature detection circuit for a predetermined time (timer time). It is known to output the closing drive signal of the electronic control valve from the circuit to the electronic control valve driving circuit so as to close the driving control of the electronic control valve. This is because the signal indicating the overheating state is output from the temperature detection circuit for a relatively short time due to the fluctuation of the combustion flame or the electric fluctuation, so that the electronic control valve is not closed. The timer time is usually set to about a few seconds.

However, in this type of conventional gas stove, since the electronic control valve is closed and driven when the detected heating temperature continues to exceed the reference temperature for overheating determination during the timer time of the timer circuit, fluctuations in the combustion flame and electrical It is possible to avoid the closing operation of the solenoid control valve due to noise. Even if the heating temperature rises sharply during the timer time, the solenoid control valve cannot be closed unless the timer time has elapsed. There was a problem that, unless burned, the burner continued to increase the heating temperature. In such a case, if the timer time is shortened, the solenoid control valve can be quickly closed, but there is a problem that the solenoid control valve is often closed and driven by noise or the like.

However, in this type of gas stove, since only one temperature detection circuit is provided, if the temperature detection circuit fails for any reason, the electronic control valve may not be closed even if overheating of food occurs. There was.

Accordingly, the present invention has been made to solve the above problems, and in a combustion apparatus such as a gas furnace, when an overheating of a heated object occurs, the electronic control valve installed in the fuel supply to the combustion unit is excluded while the influence of noise or the like is eliminated. It is an object of the present invention to provide a combustion apparatus that can close and drive smoothly and as surely as possible, and can quickly close and close the electronic control valve in the event of a sudden overheating.

According to a preferred embodiment of the combustion apparatus according to the present invention for achieving the above object, an opening and closing electromagnetic control valve installed in a fuel supply path for supplying fuel to the combustion unit, and the heating temperature of the heated object by the combustion of the combustion unit A temperature detecting circuit that detects and outputs an overheating detection signal when the detected temperature is equal to or higher than a predetermined reference temperature; and when the overheating detection signal is continuously output from the temperature detecting circuit for a preset timer time. A combustion device comprising a timer circuit for outputting a closed drive signal and an electronically controlled valve drive circuit for closing and closing the electronic control valve in response to the output of the signal. Of the solenoid control valve when the detection temperature is equal to or higher than the second reference temperature higher than the reference temperature. And a second temperature detection circuit for outputting a signal for operation to the electronic control valve driving circuit portion.

And a second delay circuit for inputting the closing drive signal to the electronic control valve driving circuit when the closing driving signal is continuously output for a predetermined time shorter than the timer time of the timer circuit from the second temperature detecting circuit. It is characterized in that it is provided between the temperature detection circuit and the electronic control valve drive circuit.

The delay circuit may include a capacitor in which the closing drive signal of the second temperature detection circuit is charged via a resistance, and inputs the voltage of the capacitor to the electronic control valve driving circuit.

The temperature detecting circuits may be connected in parallel to a single temperature sensor provided at a position contacting the heated object to detect a heating temperature of the heated object by an output signal of the sensor.

The electronic control valve is an electronic control valve which is opened and driven by the energization of the solenoid and is closed by the interruption of the energization. The electronic control valve driving circuit includes the timer circuit and the second temperature detection circuit. A pair of switching transistors, each of which shuts off the closing driving signal as a base input, is connected in series with the solenoid.

In addition, the switching transistors are configured to be brought into a conductive state by the base inputs having high and low reverse levels.

According to the present invention configured as described above, basically, when the heating temperature of the object to be heated becomes equal to or higher than the reference temperature of the first temperature detection circuit and the state continues for the timer time of the timer circuit, the electronic control valve is released from the timer circuit. A control signal for closing driving is outputted to the driving circuit, so that the electromagnetic control valve driving circuit closes the electronic control valve. At this time, when the heating temperature rapidly rises within the timer time and becomes equal to or greater than the second reference temperature of the second temperature detecting circuit, a closing driving signal is output from the second temperature detecting circuit detecting circuit to the electronic control valve driving circuit. An electronic control valve driving circuit closes the electronic control valve. Therefore, when the heating temperature rises rapidly, the solenoid control valve can be quickly closed. Also, if one of the first temperature detection circuit and the second temperature detection circuit fails, and the other temperature detection circuit is normal, when the object to be heated is in an overheated state, it is closed for driving from the timer circuit or the second temperature detection circuit. Since the signal is output to the electronic control valve driving circuit, the electronic control valve can be closed.

When the delay circuit is provided between the second temperature detection circuit and the electronic control valve driving circuit, the closing drive signal of the second temperature detection circuit is input to the electronic control valve driving circuit with a slight delay from the output time point. Therefore, when the close driving signal is output from the second temperature detection circuit by a noise or the like, it is possible to avoid the situation where the solenoid control valve is driven. In addition, since the delay time for the closing drive by the delay circuit is shorter than the timer time, when the heating temperature rises rapidly, the electronic control valve can be driven as described above.

Further, the delay circuit includes a capacitor in which the closing drive signal of the second temperature detection circuit is charged via a resistance, and is closed by the delay circuit when the voltage of the capacitor is input to the electronic control valve driving circuit. The delay time of the drive signal is determined by the time constant of the resistor and the capacitor. In this way, the delay circuit is constituted by a resistor and a capacitor, which makes the configuration of the delay circuit extremely simple.

In addition, by connecting each of the temperature detection circuits to a single temperature sensor in parallel and sharing the output signal of the sensor, the device configuration can be simplified.

The electronic control valve is an electronic control valve which is opened and driven by energization to the solenoid and is closed by the interruption of the energization. The electronic control valve circuit is used for closing the timer circuit and the second temperature detection circuit. When a pair of switching transistors are connected in series to the solenoid in order to cut off the signals as the base inputs, the switching transistors are cut off when the closing drive signal is input to the base of any one of the switching transistors, and the current is supplied to the solenoid. Is blocked, and the electronic control valve is closed. On the contrary, even if one or both of the switching transistors fail, if the failure is a failure to cut off between the emitter and the collector of the transistor, the solenoid may be shut off and the electronic control valve may be closed. In addition, in the case where the failure is a short circuit between the emitter and the collector of the transistor, if one switching transistor is normal, the electronic control valve can be closed and driven by an overheated state of the object to be heated.

When the switching transistors are configured to be in a conductive state by the base inputs having high and low reverse levels, for example, the electronic control valve can be closed even if both the timer circuit and the second temperature detection circuit fail.

That is, in the case where the timer circuit or the second temperature detection circuit is faulty, these outputs are often shorted to the power supply side or the ground side, and are often the same level of output. Therefore, in this case, a signal having a level for blocking the transistor is applied to one base of the pair of switching transistors, and accordingly, the transistor is turned off and the energization to the solenoid is cut off, so that the electronic control valve is closed. Will be driven.

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

In FIG. 1 and FIG. 2, the combustion apparatus of this embodiment is a gas furnace, for example, and opens and closes an electronic control valve to the gas supply path 2 (fuel supply path) which supplies gas (fuel) to the burner 1 which is a combustion part. (3) and a gas flow control valve 4 for adjusting the gas supply amount is provided. In this case, the electromagnetic control valve 3 is mechanically opened in response to a spring (not shown) in conjunction with the ignition operation of the ignition / fire extinguishing button 12 for performing the ignition and fire extinguishing operation of the burner 1. In addition, the open state is maintained by energizing the solenoid 5, and closed driving is performed by interruption of the energization. In addition, the opening amount of the gas amount adjusting valve 4 is adjusted by, for example, operating the operation panel 6 connected thereto.

In addition, the gas furnace of this embodiment is provided with a control unit 7 constituted by the various electronic circuits described above. The control unit 7 is a solenoid 5 of the electronic control valve 3 and a heated object. The temperature detector 8 installed at the center of the burner 1 to detect the heating temperature of the food, and the combustion detector 9 installed near the burner 1 to detect combustion and misfire of the burner 1, and the burner. An ignition device 11 for generating a spark discharge in the ignition electrode 10 provided in the vicinity of (1), a micro switch 42 which is opened and closed by the operation of the ignition / extinguishing button 12, and an ignition / extinguishing button ( The ignition switch 11a which is closed by the ON operation (ignition operation) of 12) is connected.

In this case, the control unit 7 is a battery 13 (shown in FIG. 2) as a power source to start the micro switch 42 via the power source. The LED lamp 14 for notifying the user of the mode (voltage state of the battery 13) is connected.

The ignition device 11 is driven by the battery 13 via the ignition switch 11a which is closed by the on-operation of the ignition / extinguishing button 12. Then, after the burner 1 is ignited, the ignition switch 11a is opened by releasing the on-operation of the ignition / extinguishing button 12 so that the ignition device 11a becomes inoperable. The useless operation of 11) is stopped. Such opening and closing of the ignition switch 11a is controlled by using a HEART CAM mechanism, for example, as disclosed in Japanese Patent Laid-Open No. 1-59498 by the applicants of the present invention. In addition, the ignition device 11 may be stopped using, for example, a timer that is started by an on operation of the ignition / extinguishing button 12.

The temperature detector 8 incorporates a temperature sensor (THERMISTOR 15; shown in FIG. 2), which is a temperature sensor, and is mounted when a cooking container or the like in which food is stored on the burner 1 is mounted. In contact with the cooking vessel or the like, a signal corresponding to the heating temperature of the cooking vessel is output from the thermistor 15 to the control unit 7.

The combustion detector 9 incorporates a thermocouple 16 (shown in FIG. 2), which is a combustion detection sensor, and transmits a signal according to the heat generation amount of the burner 1 from the thermocouple 16 to the control unit 7. Will output

The control unit 7 is operated by the battery 13 via the microswitch 42 linked to the on-operation of the ignition / fire extinguishing button 12. The solenoid 5 is activated by the start of the control unit 7. Is energized to open and drive the solenoid control valve 3 so as to supply gas to the burner 1. At this time, as described above, the ignition device 11 is driven by the battery 13 via the ignition switch 11a which is closed by the on-operation (pushing operation) of the ignition / extinguishing button 12, so that the ignition electrode 10 To generate a spark discharge, thereby igniting the burner 1.

In addition, as will be described in detail later, the control unit 7 detects combustion and misfire of the burner 1 by means of the output signal of the thermocouple 16, and also the heating temperature of the food by the burner 1, The disconnection failure of the thermistor 15 is detected by the output signal of the thermistor 15, and when the misfire of the burner 1 is detected through the thermocouple 16 or through the thermistor 15, When the heating temperature of the detected food becomes a high temperature higher than a predetermined reference temperature or when disconnection of the thermistor 15 is detected, the electronic control valve 3 is closed and driven by the solenoid 5. have.

The control unit 7 senses the voltage of the battery 13 and drives the LED lamp 14 when the voltage drops to a predetermined reference voltage or the solenoid (the solenoid valve 3). 5) It is to close the drive.

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

In FIG. 2, the control unit 7 includes a thermocouple circuit 17 for generating a voltage signal different from the heat generation amount of the burner 1 by the thermocouple 16, and an output signal of the thermocouple circuit 17. The first and second combustion detection circuits 18 and 19 for detecting combustion and misfire of the burner 1, and the thermistor circuit 20 for generating a voltage signal according to the heating temperature of the food by the thermistor 15. ), The first and second temperature detection circuits 21.22 for detecting the heating temperature of the food by the output signal of the demister circuit 20 and the output signals of the demister circuit 20 A first timer receiving a signal from the disconnection detecting circuit 23, the first combustion detecting circuit 18, and the first temperature detecting circuit 21 for detecting disconnection and outputting a signal for opening / closing driving of the electronic control valve 3. Receives a signal from the circuit 24 and the disconnection detecting circuit 23 and outputs a signal for opening / closing driving of the electronic control valve 3. It is provided with a second timer circuit 25 and a second electronically controlled valve drive circuit with a switching transistor (26, 27) (28).

The timer circuit corresponding to the configuration of the present invention is the first timer circuit 24.

The first and second combustion detection circuits 18 and 19 have the same configuration, and these detection circuits 18 and 19 determine the output voltage of the thermocouple circuit 17 according to the calorific value of the burner 1 in combustion and misfire determination. Comparator 30 is compared with the reference voltage for the circuit.

These detection circuits 18 and 19 compare the output voltage of the thermocouple circuit 17 with the reference voltage for combustion and misfire determination by the comparator 30 to detect whether the burner 1 is in the combustion state or the misfire state. And a high and low two-level voltage signal is output from the comparator 30 in accordance with the detection of combustion and misfire. In the following description, when the voltage signal at the level corresponding to the combustion state of the burner 1 is a combustion detection signal, the voltage signal at the level corresponding to the misfire state of the burner 1 is called a misfire detection signal.

The output of the first burn detection circuit 18 is input to the first timer circuit 24 and the output of the second burn detection circuit 19 is input to the disconnection detection circuit 23.

The first and second temperature detection circuits 21 and 22 have the same basic configuration, and are for determining the output voltage of the demister circuit 20 according to the heating temperature of the food by the burner 1 and heating. The comparator 31 is compared with the reference low pressure corresponding to the reference temperature. These detection circuits 21 and 22 detect the elevation of the heating temperature of the food by comparing the output voltage of the demister circuit 20 with the reference voltage for overheating determination by the comparator 31, and the heating is performed. The voltage signal of the high and low two-value level is output from the comparator 31 according to the high and low temperature. In the following description, the voltage signal at the level corresponding to the case where the cooking temperature is higher than the reference temperature is called the overheat detection signal, and the voltage signal at the level corresponding to the temperature lower than the reference temperature is called the normal heating detection signal. do.

In this case, the reference temperature for the overheating determination of the first temperature detection circuit 21 and the reference temperature for the overheating determination of the second temperature detection circuit 22 are set to different values, and in this embodiment, the first temperature detection circuit is used. In (21), for example, 260 ° C is set as the reference temperature, and in the second temperature detection circuit 22, for example, 290 ° C is set as the reference temperature.

The output of the first temperature detection circuit 21 is input to the first timer circuit 24 and the output of the second temperature detection circuit 22 is connected to the base of the transistor 27 of the electronic control valve driving circuit 28. Is entered. In addition, the overheat detection signal and the normal heating detection signal, which are outputs of the second temperature detection circuit 22, are low level and high level signals, respectively, and these signals are the closing drive signal of the electronic control valve 3 and the following, respectively. It is used as an open drive signal. Furthermore, the overheat detection signal of the first temperature detection circuit 21 is input to the first timer circuit 24 as a closing drive command signal of the electronic control valve 3.

The disconnection detecting circuit 23 includes a comparator 32 for comparing the output voltage of the demister circuit 20 according to the terminal-to-terminal voltage of the demister 15 with a reference voltage for disconnection determination, and the comparator 32 By comparing the output voltage of the thermistor 20 with the reference voltage for disconnection determination, it is detected whether or not the thermistor 15 is disconnected, and from the comparator 32 according to the detection of disconnection and non-disconnection, A voltage signal of a value level is output. In this case, the output of the second combustion detection circuit 19 is also input to the comparator 32. The comparator 32 has a case where the disconnection of the demister 15 is detected and the second combustion detection circuit. When misfire is detected by (19), voltage signals of the same level are output, and voltage signals of different levels are outputted in other cases. Hereinafter, the voltage signal of the level corresponding to disconnection of the demister 15 or misfire of burner 1 is called disconnection and misfire detection signal.

The output of the disconnection detecting circuit 23 is input to the second timer circuit 25. In this case, as described above, since the output of the second burn detection circuit 19 is input to the disconnection detection circuit 23, the disconnection detection signal and the misfire detection signal from the disconnection detection circuit 23 and the second combustion detection circuit 19, respectively. Is output, the respective signals input to the second timer circuit 25 are not removed.

The first timer circuit 24 has a predetermined time constant when a misfire detection signal is output from the first combustion detection circuit 18 or a burner overheat detection signal is output to the first temperature detection circuit 21. And a comparator 35 for comparing the voltage of the capacitor 33 with a reference voltage for output timing determination, with a time constant circuit 34 having a capacitor 33 for charging and discharging. The time constant of the time constant circuit 34 is a predetermined time (7 seconds in this embodiment) for the misfire detection signal from the first combustion detection circuit 18 or the overheat detection signal from the first temperature detection circuit 21. The voltage of the capacitor 33 is set to a predetermined value when output is continuously performed for a while).

The comparator 35 generating the output of the first timer circuit 24 has a misfire detection signal from the first combustion detection circuit 18 or an overheat detection signal from the first temperature detection circuit 21. When it is continuously output for a period of time, this is detected by the voltage of the condenser 33, and accordingly, the open drive signal of the solenoid control valve 3 is output. During the rest of the time, the open drive of the solenoid control valve 3 is output. It is supposed to output a signal. In this case, the output of the comparator 35 is a fixed two-value signal, the closing drive signal of the solenoid control valve 3 is at a high level, and the opening drive signal is at a low level.

The second timer circuit 25 has the same basic configuration as the first timer circuit 24 and includes a time constant circuit 37 having a capacitor 36 and a comparator 38. Similarly to the first timer circuit 24, the second timer circuit 25 has a predetermined time from which the disconnection and misfire detection signals are determined by the time constant of the time constant circuit 37 from the disconnection detection circuit 23 (this In the embodiment, for example, the closing drive signal of the solenoid valve 3 is output from the comparator 38 when it is continuously output for 10 seconds; Open drive signal is output. In this case, the comparator 38 is designed with a polarity such that the closing drive signal of the solenoid control valve 3 is low level and the opening drive signal is high level, as opposed to the comparator 35 of the first timer circuit 24.

The solenoid valve 5 of the solenoid control valve 28 is connected to the solenoid 5 of the solenoid valve 3 in series so that both of the transistors 26 and 27 are in a conducting state (on). State, the solenoid 5 is energized from the battery 13 and mechanically opened in the open state, and either of the transistors 26, 27 is cut off (off state). The solenoid 5 is cut off when closing, and the solenoid control valve 3 is closed.

In this case, the transistor 26 is of PNP type and is connected to the timer circuit 24 with the output of the first timer circuit 24 as a base input. Accordingly, the transistor 26 is brought into a conductive state when a low level signal, which is an open drive signal of the electronic control valve 3, is output from the first timer circuit 24, and the transistor 26 is a closed drive signal of the electronic control valve 3. It is to be cut off when a high level signal is output.

On the other hand, the transistor 27 is of NPN type and is connected to these circuits 25 and 22 using the output of the second timer circuit 25 and the output of the second temperature detection circuit 22 as base inputs. . Accordingly, the transistor 27 is brought into a conductive state when a high level signal, which is an open drive signal of the electronic control valve 3, is output from the second timer circuit 25 or the second temperature detection circuit 22, and the electronic control is performed. When the low level signal which is the close drive signal of the valve 3 is output, it is in the interruption state.

Therefore, the transistors 26 and 27 are designed so that their conduction interruption is caused by signals of opposite levels to each other.

In addition, between the output point of the second timer circuit 25 and the second temperature detection circuit 22 and the base of the transistor 27, the output of these circuits 25 and 22 is slightly delayed at the base of the transistor 27. The delay circuit 39 is applied for applying with. The delay circuit 39 is constituted by the resistor 40 and the capacitor 41, and the capacitor 41 is connected to the capacitor 40 by the output of the second timer 25 and the second temperature detection circuit 22. ) Is charged and discharged, and the voltage of the capacitor 41 is applied to the base of the transistor 27. Accordingly, the output of the second timer 25 and the second temperature detection circuit 22 is the base of the transistor 27 with a delay of the time constant portion determined by the resistance of the resistor 40 and the capacitance of the capacitor 41. Is applied to. Thus, for example, in the conduction state of the transistor 27 (state in which the base input is high level), when the output of the second temperature detection circuit 22 is changed from the high level to the low level in a moment due to noise or the like, the instantaneous low level signal is generated. Since it is not applied to the base of the transistor 27, the conduction state of the transistor 27 is maintained.

In this embodiment, the output delay time of the second timer circuit 25 and the second temperature detection circuit 22 by the delay circuit 39 is set to a sufficiently short value of several m seconds, and the first timer circuit ( It is set to a value sufficiently shorter than the timer time (7 seconds) of 25).

By the way, in the present embodiment, the above-described various circuits of the control unit 7 operate with the battery 13 as a power supply, while a power supply voltage capable of normal operation is determined and the power supply voltage is lower than the voltage that can operate. If degraded, normal operation cannot be expected. Therefore, when the battery 13 is consumed and its output voltage is lowered to some extent, the combustion detection circuits 18 and 19, the solenoid control valve driving circuit 28, etc. do not operate normally, so that the solenoid control valve 3 can be normally driven. There is a risk of missing.

Thus, in the present embodiment, the control unit 7 sequentially monitors the voltage of the battery 13 during the operation of the gas furnace, and if the voltage is lowered to some extent by the LED lamp 14, Or the solenoid valve 3 is closed.

Next, the structure regarding voltage monitoring and control of such a battery 13 is demonstrated.

Referring to FIG. 2, the battery 13 is connected to a micro switch 42 which is turned on / off in conjunction with the ignition / extinguishing button 12, which occurs at the P point at the rear end of the micro switch 42. The battery voltage V _D is supplied as the power supply voltage to the comparator 30 and the electronic control valve driving circuit 28 of the combustion detection recalls 18 and 19. Although not shown, the battery voltage V _D is also supplied to the ignition device 11 via the ignition switch 11a.

In addition, a regulator 43 for generating a constant voltage by inputting a battery voltage V _D as an input to the rear end of the micro switch 42 is connected, and the output voltage [V _R ; The regulator voltage (V _R ) hereinafter) is supplied as a reference voltage generation voltage in the comparator 30 and the like of the combustion detection circuits 18 and 19.

On the other hand, the control unit 7 of the present embodiment includes the comparators 44 and 45 for comparing the battery voltage V _D with a predetermined determination voltage, respectively, and the LED lamp 14 in accordance with the output of the comparator 44. A flashing drive circuit 46 for driving a flashing light, a lighting drive circuit 47 for driving the LED lamp 14 on and off according to the output of the comparator 45, and a capacitor connected to the resistor 48 at the P point. the by a voltage of 49 detects the battery voltage (V _D) and the battery voltage (V _D) at this time of a predetermined value or less connected to the base of transistor 27 to the electronic control valve driving circuit 28, the On the input side of the delay circuit 39, a battery voltage monitoring circuit 50 for outputting the closing drive signal (low level signal) of the electromagnetic control valve 3 is provided.

In each of the comparators 44 and 45, the battery voltage V _D is inputted through the division resistors 51 and 52 connected to the point P, and the three division resistors connected to the output side of the regulator 43 53, 54, and 55 are inputted at different levels of determination voltage. In the present embodiment, the standard value of the battery voltage V _D in the new state of the battery 13 is, for example, 3 V, and the determination voltage at the comparator 44 is set at 2.65 V, for example. The determination voltage is set to 1.9V, for example. In addition, the combustion detection circuits 18 and 19, the electronic control valve driving circuit 28, and the like can operate normally until the battery voltage V _D drops to about 1.9 V, which is the determination voltage of the comparator 45. FIG.

Each of the comparators 44 and 45 compares the respective determination voltages with the battery voltages V _D , and flashes the signals of two levels of high and low depending on the magnitude of the determination voltages of the battery voltages V _D , respectively. It outputs to the drive circuit 46 and the lighting drive circuit 47. In this case, the flashing drive circuit 46 turns off the LED lamp 14 when a signal indicating that the battery voltage V _D has fallen to the determination voltage (2.65 V) of the comparator 44 is output from the comparator 44. It is supposed to be blinking. The lighting drive circuit 47 lights the LED lamp 14 when a signal indicating that the battery voltage V _D has fallen to the determination voltage (1.9 V) of the comparator 45 is output from the comparator 45. It is supposed to drive.

In the present embodiment, the comparator 45 has a latch for holding the output when the signal indicating that the battery voltage V _D has fallen to the determination voltage (1.9 V) of the comparator 45 is output from the comparator 45. The circuit 56 is connected.

In addition, the output of the comparator 45 is input to the first timer circuit 24, and the first timer circuit 24 has a battery voltage V _D from the comparator 45 with a punch positive voltage (1.9 V). The closing drive signal of the solenoid control valve 3 is output to the transistor 26 of the solenoid control valve drive circuit 28 even when a signal indicating that the signal is lowered below is output.

As described above, the latch circuit may be provided on the comparator 44 side to hold the output of the comparator 44.

The comparators 44 and 45, the flashing drive circuit 46 and the lighting drive circuit 47 use the battery voltage V _D as the power supply voltage, similarly to the comparator 30 of the combustion detection circuits 18 and 19, and the like. In this way, it is possible to operate normally until the battery voltage V _D drops to about 1.9 V, which is the determination voltage of the comparator 45.

The battery voltage monitoring circuit 50 uses the battery voltage V _D as a power supply voltage. In this case, the circuit 50 may have a voltage lower than 1.9 V, which is the determination voltage of the comparator 45 (1 V in this embodiment). To normal operation until the battery voltage V _D decreases. The battery voltage monitoring circuit 50 is configured to transmit the closing drive signal of the solenoid control valve 3 to the transistor 27 of the solenoid control valve drive circuit 28, for example, when the battery voltage V _D drops to 1.7 V, for example. It outputs to the base side.

In this embodiment, the transistor 27 is cut off when the battery voltage V _D drops to a voltage higher than 1.7V (about 1.5V in this embodiment) of the battery voltage monitoring circuit 50. The transistor blocking circuit 57 is provided at an input portion of the transistor 27 to the base. The transistor blocking circuit 57 divides the voltage formed by dividing the battery voltage V _D by a pair of split resistors 58 and 59 connected to the base of the transistor 27 via the delay circuit 39. The delay circuit 39 is applied to the base of the transistor 27 through the delay circuit 39. When the battery voltage V _D drops to about 1.5 V, the voltage that causes the transistor 27 to be cut off is the transistor. The resistance values of the split resistors 58 and 59 are set to be applied to the base of (27).

Next, the operation of the gas furnace of the present embodiment will be described.

When the ignition / digestion burner 12 is operated in the gas furnace of the present embodiment, the microswitch 42 is fed in conjunction with the ignition / digestion burnt 12, and accordingly, the battery 13 is connected to each circuit of the control unit 7. The battery voltage V _D is supplied to activate each circuit.

At this time, the electronic control valve 3 is mechanically opened in response to the on-operation of the ignition / extinguishing button 12 and resists a spring (not shown). The open drive signal of the control valve 3 is output, whereby the transistors 26 and 27 of the solenoid control valve drive circuit 28 are brought into a conductive state, so that the solenoid 5 of the solenoid valve 5 of the solenoid control valve 3 is connected to the battery 13. Since the electric control valve 3 is energized, the electromagnetic control valve 3 is kept open. Then, the gas supply to the burner 1 is started by the opening drive of the electronic control valve 3. In parallel with this, as described above, the ignition device 11 is driven through the ignition switch 11a by the operation of the ignition / extinguishing button 12, whereby the ignition flame is applied to the ignition electrode 10. FIG. Will be produced.

At this time, each of the combustion detection circuits 18 and 19 outputs a misfire detection signal because the electromotive force of the thermocouple 16 is small during the time until the burner 1 is ignited and in the initial stage when the burner 1 is ignited. The misfire detection signal of the first burn detection circuit 18 is input to the first timer circuit 24 and the misfire detection signal of the first burn detection circuit 19 is connected to the second timer via the disconnection detection circuit 23. It is input to the circuit 25.

The first timer circuit 24, when the misfire detection signal of the first combustion detection circuit 18 is continuously output for the timer time (7 seconds) of the timer circuit 24, that is, the thermocouple 16 within the timer time. If the electromotive force of the?) Does not exceed the predetermined value, the closing drive signal (high level signal) of the solenoid control valve 3 is output to the base of the transistor 26 of the solenoid control valve drive circuit 28, and the transistor is shut off. Will be made. Accordingly, the energization of the solenoid 5 of the solenoid control valve 3 is interrupted and the solenoid control valve 3 is closed and driven so that the gas supply to the burner 1 is blocked.

Similarly, when the electromotive force of the thermocouple 16 does not exceed the predetermined value within the timer time (10 seconds) of the timer 25, the second timer circuit 25 closes the drive signal (low level) of the solenoid control valve 3. Signal) is output to the base of the transistor 27 of the solenoid valve control circuit 28 and the transistor 27 is shut off to close the solenoid control valve 3. At this time, the output of the timer circuit 25 is applied to the base of the transistor 27 via the delay circuit 39, so that a slight time delay occurs. The delay time is the timer time of the timer circuit 25. Since it is about a few m seconds shorter than 10 seconds, the closing drive signal is applied to the base of the transistor 27 when the timer time elapses.

In this case, since the timer time (7 seconds) of the first timer circuit 24 is shorter than the timer time (10 seconds) of the second timer circuit 25, the timer time of the first timer circuit 24 is generally determined. The electromagnetic control valve 3 is closed. Then, for example, the first timer circuit 24 or the corresponding first combustion stop circuit 18 may fail for some reason, and the output of the first timer circuit 24 may cause the opening drive signal of the electronic control valve 3 to fail. If the second timer circuit 25 or the second combustion detection circuit 19 is normal when the level is maintained at the level, the second control circuit 25 is driven to close the drive according to the timer time.

Therefore, the driving signal output circuit 29a including the first timer circuit 24 or the first combustion detection circuit 18 and the second timer circuit 25 or the second combustion detection circuit 19 are included. If any one of the drive signal output circuits 29b is normal, the electronic control valve 3 is closed and driven when the burner 1 is not ignited so that the gas supply to the burner 1 is cut off.

In the present embodiment, since the signal levels at which the transistors 26 and 27 are turned off are different from each other, for example, when the first timer circuit 24 and the second timer circuit 25 both fail, the electronic control valve ( 3) can be closed. That is, in general, when both the first timer circuit 24 and the second timer circuit 25 fail, the output points of the comparators 35 and 38 of the timer circuits 24 and 25 are short-circuited to the ground side or the power supply side. The output level of both timer circuits 24 and 25 often becomes the same level. In this case, since the signal levels at which the transistors 26 and 27 are turned off are different in this embodiment, either transistor 26 or 27 is turned off, so that the solenoid control valve 3 is closed. do. For example, when the output level of both timer circuits 24 and 25 becomes high, the transistor 26 will be cut off and the solenoid control valve 3 will be closed.

In addition, when the burner 1 is ignited within the timer time of the first timer circuit 24 or the timer time of the second timer circuit 25 in such an ignition operation, and the electromotive force of the thermocouple 16 becomes a predetermined value or more. This is detected by the first combustion detection circuit 18 or the second combustion detection circuit 19 and the combustion detection signals are output from these circuits 18 and 19. In this case, the first timer circuit 24 and the second timer circuit 25 continue to output the open drive signal of the electronic control valve 3.

The above-described operation is similarly performed even when the burner 1 is burned up for some reason after the combustion of the burner 1 is started.

On the other hand, when the food by combustion of the burner 1 is heated, its heating temperature is detected by the first and second temperature detection circuits 21 and 22 via the demister circuit 20. The first temperature detection circuit 21 outputs the overheat detection signal to the first time circuit 24 when the detected heating temperature becomes 260 ° C. or more, the reference temperature for overheating determination of the circuit 21. At this time, the first timer circuit 24 transistors the closing drive signal of the electronic control valve 3 when the overheat detection signal is continuously output from the first temperature detection circuit 21 for the timer time (7 seconds). Output to (26). Accordingly, the transistor 26 is cut off, the electronic control valve 3 is closed and driven, and combustion of the burner 1 is stopped to prevent overheating. At this time, if the heating temperature temporarily exceeds the reference temperature due to fluctuations in the combustion flame of the burner 1, the overheat detection signal may be output from the first temperature detection circuit 21 for a short time (7 seconds). 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 24, the timer circuit 24 does not output the closed driving sinusoidal control valve (3). Will remain open.

In addition, the second temperature detection circuit 22 mediates the low-level overheat detection signal when the detected heating temperature becomes 290 ° C. or more higher than the reference temperature for overheating determination of the first temperature detection circuit 21. The output is made to the base side of the transistor 27 without doing so. This low level overheat detection signal is applied to the base of the transistor 27 via the delay circuit 39. In this case, since the overheat detection signal is connected to the base of the transistor 27 via the delay circuit 39, the overheat detection signal is applied to the base of the transistor 27 with a slight delay from the output point of the overheat detection signal. The delay is a few m seconds. Therefore, when the heating temperature exceeds 290 ° C, basically a low level signal is immediately applied to the base of the transistor 27, and the transistor 27 is cut off accordingly, so that the electronic control valve 3 is closed. It will be closed. At this time, the overheat detection signal may be output from the second temperature detection circuit 22 only once due to noise or the like. However, such a single overheat detection signal is removed by the delay circuit 39 and the transistor 27 Since it is not applied to the base of), the solenoid control valve 3 is not closed.

In addition, even when the first temperature detection circuit 21 or the first timer circuit 24 fails, for example, when the heating temperature is abnormally detected by the operation of the temperature detection circuits 21 and 22 as described above. If the second temperature detection circuit 22 is normal, the electronic control valve 3 can be closed by the temperature detection circuit 22. For example, when the heating temperature rises above 260 ° C and the heating temperature rapidly rises within the timer time (7 seconds) of the first timer circuit 24 and reaches 290 ° C or higher, the timer time (7 seconds) Before the elapse of time, the second temperature detection circuit 22 can quickly drive the electronic control valve 3 to prevent sudden overheating.

As described above, when the thermistor 15 is disconnected during the operation of the gas furnace, the disconnection is detected by the disconnection detecting circuit 23, and the disconnection detecting circuit 23 detects the disconnection detection signal. Is output to the second timer circuit 25. The second timer circuit 25 outputs the closing drive signal of the solenoid control valve 3 to the base of the transistor 27 when the disconnection detection signal is continuously output for the timer time (10 seconds). As a result, the transistor 27 is turned off, and the electromagnetic control valve 3 is closed.

In such a case, when the temperature is low at the time of ignition of the burner, or when heating the frozen product, the temperature rise of the thermistor 15 is delayed, and the resistance of the thermistor 15 becomes a large value of several kilowatts. As in the case, the disconnection detection signal may be output from the disconnection detection circuit 23. However, in the present embodiment, when the disconnection detection signal continues for the timer time (10 seconds) of the second timer circuit 25, the solenoid control valve 3 is closed and driven so that the temperature of the demister 15 as described above is maintained. The signal can avoid the situation so that the electronic control valve 3 is closed and driven even though it is not disconnected at low.

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

When the battery 13 is exhausted during operation of the gas furnace as described above, and the battery voltage V _D is lowered to 2.65 V, which is the determination voltage of the comparator 44, this is caused by the comparator 44. When detected, the comparator 44 outputs a signal indicative thereof to the flashing drive circuit 46. At this time, the blinking drive circuit 46 blinks and drives the LED lamp 14, thereby enabling the user to recognize that the battery 13 needs to be replaced soon. In the present embodiment, the burner 1 is ignited by the ignition device 11 which uses the battery 13 as a power source. Therefore, the battery voltage V _D is applied to the ignition device when the ignition operation is performed for the ignition. 11) The voltage of the comparator 44 below the determination voltage of the comparator 44 decreases to a voltage that may cause the operation of the various circuits to become unstable, and no power supply to the ignition device 11 occurs after the ignition operation. (V _D ) may rise above the determination voltage. In this case, the LED lamp 14 blinks as much as the operation time of the ignition device 11, and after the ignition operation, the LED lamp 14 is turned off again so that the user overlooks the blinking of the LED lamp 14. There are many. In this embodiment, therefore, the determination voltage of the comparator 44 is set to be relatively high (2.65 V) and the LED lamp 14 is flickered at an early stage.

In addition, when the battery voltage V _D drops to 1.9 V, which is the determination voltage of the comparator 45, this is detected by the comparator 45, and the comparator 45 generates a signal indicating the lighting drive signal 47. ) At this time, the lighting driving circuit 47 lights the LED lamp 14 and drives the user to recognize that it is necessary to replace the battery 13.

In this case, in the present embodiment, the comparator 45 maintains its output by the latch circuit 56 once the battery voltage V _D drops to 1.9 V. Thus, the ignition device ( 11) The battery voltage V _D is lowered to a voltage at which the operation of the various circuits described above becomes unstable under the determination voltage (1.9 V) of the comparator 45 by the power supply to the comparator 45, and the battery residual pressure again after the ignition operation. (V _D) is continuously output from the determination voltage than the battery voltage (V _D), the decrease in the comparator 45 the signal indicating that up to 1.9V even if the rise because LED lamps 14 are continuously lighted. Accordingly, when the battery voltage V _D is lowered to a voltage that may cause the operation of the various circuits described above to become unstable even for a short time, the user can be surely recognized that the battery 13 needs to be replaced. It becomes possible.

At this time, the output of the comparator 45, which indicates that the battery voltage V _D has decreased to 1.9 V, is also input to the first timer circuit 24, and from the first time circuit 24, the electronic control valve 3 is removed. A close drive signal of is output. As a result, the transistor 26 is turned off, and the electromagnetic control valve 3 is closed.

However, as described above, when the battery voltage V _D is temporarily lowered by the operation of the ignition device 11 to a level (for example, about 1.8 V) where the operation of the relative (44, 45) or the like becomes unstable, the comparator ( 45 and the first timer circuit 24 do not operate as described above, there is a possibility that the solenoid control valve 3 is not closed by the comparator 45 or the first timer circuit 24. .

In the present embodiment, however, the battery voltage monitoring circuit 50 capable of operating normally up to a battery voltage V _D of about 1 V is provided, and the battery voltage monitoring circuit 50 has a battery voltage V _D. When the voltage falls below 1.7 V, the closing drive signal (low level signal) is output to the base of the transistor 27. As a result, the transistor 27 is turned off so that the electronic control valve 3 is closed.

As described above, in the gas furnace of the present embodiment, the battery voltage V _D can be reliably recognized and the electronic control valve 3 can be reliably closed in response to the decrease in the battery voltage V _D. Will be.

In the present embodiment described above, the first timer detection circuit 24 and the first combustion detection circuit 18 and the first temperature detection circuit 21 are used in common, but the first combustion detection circuit 18 and the first temperature are used. The detection circuit 21 may be provided with a timer circuit separately. However, the circuit configuration can be simplified by sharing the first timer circuit 24 with the first combustion detection circuit 18 and the first temperature detection circuit 21 as in the present embodiment. In this case, the timer time of the first timer circuit 24 is preferably set relatively long from the viewpoint of smooth ignition to the burner 1, and is preferably set relatively short from the viewpoint of preventing overheating. In the present invention, the timer time is set to 7 seconds to satisfy both conditions.

In addition, although the gas furnace equipped with the ignition device 11 has been described in the present embodiment, the present invention can be applied to a gas furnace using an ignition piezoelectric element or the like, as well as to a combustion device such as a hot water heater. Of course, the present invention can be applied.

In addition, in the present embodiment, the opening of the solenoid valve 3 is mechanically performed and the opening of the solenoid valve is electrically performed via the solenoid 5. However, the opening and subsequent opening of the solenoid valve 3 is performed. May be held electrically. The opening drive of the electronic control valve in the present invention means a concept including both of them.

In this embodiment, in relation to monitoring the battery voltage V _D , the determination voltage for the flashing light of the LED lamp 14 or the determination voltage for the lighting driving is determined by the battery voltage V _D by the ignition device 11. In the present embodiment, the determination voltage for the flickering operation of the LED lamp 14 is set in the case of a gas furnace using a piezoelectric element for ignition or a gas furnace equipped with a separate power source for the ignition device. It is also possible to set a determination voltage different from the present embodiment, for example, to set lower.

In this embodiment, the battery is used as a power source, but a commercial power source may be used instead of the battery.

As described above, according to the present invention, the first temperature detecting circuit detects the heating temperature of the heated object and outputs a closing drive command signal of the solenoid control valve when the detected temperature becomes equal to or higher than the first reference temperature. When the closing drive command signal is continued for a predetermined timer time, a closing driving signal is output from the timer circuit to the electronic control valve driving circuit to close the driving valve, and the second temperature detection circuit When the heating temperature is detected and the detection temperature is equal to or higher than the second reference temperature higher than the first reference temperature, the closing drive signal is output to the solenoid valve control circuit so that the solenoid valve is closed and driven. When heating occurs, the first temperature detection circuit and the timer circuit are mainly used to eliminate the influence of noise and the like that cause the combustion flame to fluctuate. In addition to that can be driven smoothly close the electromagnetic control valve it is possible to quickly drive the closed electromagnetic control valve and the second temperature detection circuit as the main component in the event of a sudden and heating. Even if one temperature detection circuit fails, the electronic control valve can be closed by the other temperature detection circuit, thereby making it possible to assure the closing control of the electronic control valve in the event of overheating.

In addition, by providing a delay circuit having a short delay time between the second temperature detection circuit and the solenoid control valve driving circuit, the situation in which the solenoid control valve is closed by a single noise or the like can be avoided to the maximum and a sudden overheating can be avoided. In case of occurrence, it is possible to close and operate the solenoid valve without losing reliability.

In addition, since the delay circuit is composed of a resistor and a capacitor, the configuration can be extremely simple and inexpensive.

In addition, it is possible to simplify the device configuration by connecting each temperature detection circuit in parallel with a single temperature sensor and detecting the heating temperature of the heated portion by the output signal of the sensor.

If the solenoid control valve is an solenoid control valve driven by energization to the solenoid and closed by the interruption of the energization, the solenoid control valve drive circuit is used to provide the closing drive signal of the timer circuit and the first temperature detection circuit. By connecting a pair of switching transistors, each of which is cut off as a base input, in series with the solenoid, the electronic control valve can be closed even when a failure occurs that causes the switching transistor to shut off.

In addition, by switching the switching transistors to each other by the low and low level base inputs, failures such as short-circuits between the output points of the timer circuit and the first temperature detection circuit or short circuits between these output points on the power supply and ground sides are provided. In this case, any one of the transistors can shut off and the electronic control valve can be closed.

Claims (6)

An on / off solenoid control valve provided in a fuel supply path for supplying fuel to the combustion section, and a temperature for detecting a heating temperature of the heated object by the combustion of the combustion section and outputting an overheat detection signal when the detected temperature is equal to or higher than a predetermined reference temperature. A detection circuit, a timer circuit for outputting a closing drive signal of the electronic control valve when the overheating detection signal is continuously output for a predetermined timer time which has already been set, and a closing driving signal of the timer circuit. A combustion apparatus comprising an electronically controlled valve drive circuit for closing and driving the electromagnetically controlled valve in response to an output, wherein the heating temperature of the heated object is detected and the electronic temperature is detected when the detected temperature is higher than or equal to a second reference temperature higher than the reference temperature. And a second temperature detection circuit for outputting the closing drive signal of the control valve to the electronic control valve drive circuit section. Combustion apparatus characterized in that it is made. 2. The delay according to claim 1, wherein the closing drive signal is inputted to the electromagnetic control valve driving circuit when the closing driving signal is continuously output for a predetermined time shorter than the timer time of the timer circuit from the second temperature detecting circuit. And a circuit is provided between the second temperature detection circuit and the electronic control valve drive circuit. 3. The delay circuit according to claim 2, characterized in that the delay circuit includes a capacitor in which the closing drive signal of the second temperature detection circuit is charged via a resistance, and the voltage of the capacitor is input to the electronic control valve hole circuit. Combustion apparatus. 2. The temperature detecting circuit of claim 1, wherein each of the temperature detecting circuits is connected in parallel to a single temperature sensor provided at a position contacting the heated object to detect a heating temperature of the heated object by an output signal of the sensor. Combustion apparatus. The electronic control valve of claim 1, wherein the electronic control valve is an electronic control valve which is opened and driven by energization of the solenoid and is closed by driving of the energization, and the electronic control valve driving circuit is the timer circuit and the second temperature detection. And a pair of switching transistors connected in series to the solenoid, the pair of switching transistors each of which shuts off the closing drive signal of the circuit as a base input. 6. The combustion apparatus according to claim 5, wherein the switching transistors are configured to be in a conductive state by a base input of high and low reverse levels.