JP2708931B2 - Ignition timer circuit - Google Patents

Description

The present invention relates to an ignition timer circuit used for a combustion device such as a water heater.

(B) Conventional technology Conventionally, in a combustion device such as a gas water heater, for example,
As disclosed in JP-A-63-62656, an ignition timer circuit for operating an ignition device for a predetermined time at the time of ignition is provided so that ignition can be reliably performed and that the ignition device does not operate more than necessary. .

(C) Problems to be Solved by the Invention Generally, an ignition timer circuit compares a voltage signal of a time constant circuit including a capacitor and a resistor with a reference voltage of a reference bias circuit by a comparator, and turns on a switching element by an output of the comparator. -It is common to operate the ignition device by performing off control. However, when the comparator fails due to an external surge voltage or deterioration of the element and the output of the comparator becomes “H” or “L”, regardless of the magnitude of the voltage signal of the time constant circuit, the ignition device However, there has been a problem that the ignition device continues to operate, the ignition device breaks down, and power is wasted.

The present invention has been made in view of the above-mentioned facts, and has as its object to prevent the ignition device from operating when a circuit element fails, regardless of the voltage signal of the time constant circuit.

(D) Means for Solving the Problems According to the present invention, the first comparator and the second comparator housed in a common package, the inverting input terminal of the first comparator and the second comparator A reference bias circuit for supplying a reference voltage to the non-inverting input terminal, a signal input circuit for supplying a flame detection voltage signal to the non-inverting input terminal of the first comparator and the inverting input terminal of the second comparator, A switching circuit for generating a fuel supply signal when the first comparator and the second comparator emit different predetermined outputs.

(E) Operation In a plurality of comparators housed in a common package, a surge voltage is received or deteriorated from the outside, and the output is “H”.
Alternatively, when a failure that remains at “L” occurs, the case where each outputs the same output is overwhelmingly more than the case where each outputs a different output. For this reason, when a common reference voltage is supplied to input terminals having different polarities of a plurality of comparators, and a voltage signal of a time constant circuit is supplied to other input terminals, and these output different predetermined outputs. If the ignition device is operated at a time, when the plurality of comparators fail and generate an abnormal output, the plurality of comparators do not output different predetermined outputs, and the ignition device does not operate.

(F) Example Hereinafter, an example in which the present invention is applied to a gas instantaneous water heater will be described.

In FIG. 2, (1) is a heat exchanger to which a water channel (2) and a hot water channel (3) are connected, (4) is a gas burner for heating the heat exchanger, (5) is a pilot burner, and (6). Is a water stop valve provided in the water passage, (7) is a diaphragm provided downstream of the water stop valve (6), (8) supplies gas fuel to the gas burner (4) and the pilot burner (5). The gas flow path, (9) is an electromagnetic on-off valve provided in the gas flow path (8), and (10) is a hydraulically responsive gas valve provided on the downstream side of the electromagnetic on-off valve (9). The water pressure responsive valve (10) opens when the diaphragm (7) detects a water pressure of 0.4 kg / cm ² or more, and closes when the diaphragm (7) detects a water pressure of 0.2 kg / cm ² or less. . (11) is the ignition flag,
(12) Gas burner (4) and pilot burner (5)
(13) is a second thermocouple for detecting fin clogging of the heat exchanger (1), (14) is an operation button for ignition and tapping operation, and (15) is a The operation button (14) is connected to the operation lever (16) via the operation lever (16). The water stop valve (6) is opened when the operation button (14) is pressed (ignition, tapping operation), and is stopped after the pressing operation is released. Holds (locks) the opening of the water valve (6) and re-operates (stops) the operation button (14)
An interlocking device that sometimes opens the water stop valve (6). (17)
Activates the ignition plug (11) for a predetermined time when the operation button (14) is first pressed, opens the electromagnetic on-off valve (9), and after a predetermined time has passed, the thermocouples (12) and (13) The control device (17) holds the opening of the electromagnetic on-off valve (9) when the operation button (14) is re-operated. Is to solve.

FIG. 3 shows a circuit configuration of the above-described water heater control device (17). In FIG. 3, (18) is a DC power supply composed of two batteries connected in series, (19) is an ignition switch that is closed when the operation button (14) is pressed, and (20) is an ignition switch.
A constant voltage circuit such as a three-terminal regulator that generates a constant voltage of 1.6 V, (21) a battery check circuit that determines whether the power supply voltage of the DC power supply (18) is 2 V or less, and (22) a power supply voltage
An ignition timer circuit that issues a timer signal for 10 seconds after the ignition switch (19) is turned on when the voltage is 2 V or more,
(23) while the timer signal of the ignition timer circuit (22) is
An ignition device that discharges the ignition plug (11), (24) is a suction timer circuit that emits a timer signal and conducts the transistor (25) for 0.5 second from the time when the ignition timer circuit (22) issues a timer signal, (26) ) Is a suction switch that is closed only when the operation button (14) is fully pressed, (2)
7) turns on the transistors (28) and (29) independently of the thermoelectromotive force of the thermocouples (12) and (13) while the ignition timer circuit (22) is generating the timer signal, and then turns on the thermocouple ( 12)
This is a flame detection circuit that controls on / off of the transistors (28) and (29) by the thermoelectromotive force of (13), and the suction coil (91) of the solenoid on-off valve (9) is composed of the transistor (25) and the suction switch (26) Powered through the holding coil (92)
Are connected so that power is supplied through the transistors (28) and (29).

As shown in FIG. 4, when the operation button (14) is pressed from the initial position A to the point B, the interlocking device (15) operates via the operation lever (16), and the interlocking device (15) is operated. As a result, the water stop valve (6) is opened, and water flows through the water passage (2). Then, when the diaphragm (7) detects a water pressure of 0.4 kg / cm ² or more, the water pressure-responsive gas valve (10) opens. At this point, the ignition switch (19) is turned on, and the control device (16) energizes each circuit. At this time, the battery check circuit (21) checks the power supply voltage of the DC power supply (18), and when the power supply voltage is 2 V or more, the ignition timer circuit (22) issues a timer signal for 10 seconds. Therefore, the ignition plug (11) starts discharging by the ignition device (23). Immediately after this, when the operation button (14) is fully pressed and reaches the point C, the suction switch (26) is turned on. At this time, the suction timer circuit (24) issues a timer signal for 0.5 seconds from the time when the ignition timer circuit (22) issues the timer signal, and outputs the transistor (2
Since 5) is turned on, the solenoid on-off valve (9) has a suction coil (91) with a transistor (25) and a suction switch (26).
And the valve is opened. While the ignition timer circuit (54) is emitting a timer signal, the flame detection circuit (27)
Since the transistors (28) and (29) are turned on, the holding coil (92) is energized via the transistors (28) and (29) even after the energization of the suction coil (91) is cut off. The on-off valve (9) is kept open. In this way, when the operation button (14) is fully pressed, water is supplied to the heat exchanger (1), and the water pressure responsive gas valve (10) and the electromagnetic on-off valve (9) are opened, and the gas flow path is opened. The gas fuel of (8) is supplied to the gas burner (4) and the pilot burner (5). Then, the gas is ignited by the ignition plug (11), and combustion is performed by the gas burner (4) and the pilot burner (5). The combustion gas is heat-exchanged in the heat exchanger (1), and the hot water heated in the heat exchanger (1) is discharged through the tapping path (3).

Next, when the operation button (14) is released, the operation button (14) is returned to a point D in the middle by a stroke regulating body (not shown) provided on the interlocking device (15), and is locked at that position. You. At this time, the ignition switch (19) is kept on, and the suction switch (26) is turned off. When the timer signal of the ignition timer circuit (22) runs out, the ignition plug (11) stops discharging, and the flame detection circuit (27) switches to the thermocouples (12) and (13).
The transistors (28) and (29) are turned on by the thermoelectromotive force of
Control off. That is, the fin is not clogged in the heat exchanger (1), and while the combustion is performed by the gas burner (4) and the pilot burner (5), the thermoelectromotive force of the thermocouple (12) is large and the thermocouple (13) Since the thermal electromotive force of the coil is small, the flame detection circuit (27) keeps the transistors (28) and (29) turned on, and the solenoid on-off valve (9) keeps energizing the holding coil (92), and the valve is opened. Will be maintained. In addition, water stop valve (6)
Is locked with the valve open, and the tapping is continued.

To stop tapping, press the operation button (14) again from the point D to the point C, and then release the hand. The interlocking device (15) is unlocked, and the operation button (14) and the operation lever are released. (16) returns to the initial position. At this time, the ignition switch (19) is turned off, the energization of the holding coil (92) is cut off, the solenoid on-off valve (9) closes the gas flow path (8), and the interlocking device (15) turns off the water stop valve (9). 6) is closed, combustion is stopped, and hot water is stopped. Further, since the diaphragm (7) detects a water pressure of 0.2 kg / cm ² or less, the water pressure responsive gas valve (10) is also closed.

FIG. 1 shows a specific example of the above-described ignition timer circuit (22).

In FIG. 1, (30) is a first comparator, (31) is a second comparator housed in a common package (32) together with a first comparator (30), and (33) is a series connection. A reference bias circuit composed of two resistors (34) and (35), and an intermediate connection point (36) of the resistors (34) and (35) is connected to the first comparator (3
0) and a non-inverting input terminal (30A) of the second comparator (31). (37) is a first time constant circuit comprising a capacitor (38) and a resistor (39) connected in series, and an intermediate connection point (40) is connected to the inverting input terminal (30B) of the comparator (30). Have been. (Four
1) is a capacitor (42) and a resistor (43) connected in series
A second time constant circuit composed of the intermediate connection points (4
4) is connected to the non-inverting input terminal (31A) of the comparator (31). Reverse diodes (45) and (46) are connected in parallel to the resistors (39) and (43), respectively. (Four
7) are PNP transistors (48) and (49) connected in series,
NP with collector connected to base of transistor (49)
This is a switching circuit including an N transistor (50). The output terminal (30C) of the first comparator (30) is connected to the base of the transistor (48), and the output terminal (31C) of the second comparator (31) is an intermediate connection between the transistors (48) and (49). The point (51) is connected to the base of the transistor (50). And the ignition device (23) is a transistor (48)
(49) and the resistor (52).

Ignition switch (19) at the first operation of operation button (14)
Is turned on, a constant voltage V _D (1.6 V) is supplied to the bus (53) of the ignition timer circuit (22). At this time, since the capacitors (38) and (42) have no charge, the intermediate connection point (40)
The voltage at (44) is higher than the voltage at the intermediate connection point (36),
The output voltages of the comparator (30) and the second comparator (31) are "L" (ground level voltage) and "H" (high level voltage), respectively. Then, since the transistor (48) is turned on and the transistor (49) is turned on by turning on the transistor (50), power is supplied to the ignition device (23) via the transistors (48) and (49) and the resistor (52). Then, the ignition plug (11) starts discharging by the ignition device (23). The first time constant circuit (37) and the second time constant circuit (3
8) is set to the same time constant and the capacitor (38)
The voltage at the intermediate connection points (40) and (44) decreases with the charging at (42). Ten seconds after the ignition switch (19) is turned on, the voltage at the intermediate connection point (40) (44) becomes lower than the voltage at the intermediate connection point (36), and the output voltage of the first comparator (30) becomes lower. It becomes "H", and the output voltage of the second comparator (31) becomes "L". Therefore, the transistor (48) is turned off, and the transistor (50) is turned off, so that the transistor (49) is also turned off. Thus, the power supply to the ignition device (23) is cut off and the discharge of the spark plug (11) is stopped. . When the ignition switch (19) is turned off by the second operation of the operation button (14), the electric charges of the capacitors (38) and (42) are transferred to the resistors (34) and (35) of the reference bias circuit (33) and the diode ( Four
5) Discharged immediately via (46), preparing for the next ignition.

According to this embodiment, the reference voltage of the reference bias circuit (33) is applied to the input terminals having different polarities of the first comparator (30) and the second comparator (31) housed in the common package (32). (The voltage of the intermediate connection point (36)) and the voltage signal of the intermediate connection points (40) and (44) of the time constant circuits (37) and (41) to the other input terminals. When the output voltages of (30) and the second comparator (31) are "L" and "H", respectively, the switching device (47) composed of the transistors (50), (48) and (49) causes the ignition device ( 23) is activated to perform discharge, so that a double safety circuit configuration is provided, and a highly reliable ignition timer circuit can be provided. Moreover, even if the comparators (30) and (31) receive a surge voltage, or if a failure occurs in which the output thereof becomes "H" or "L",
In most cases, the outputs of the comparators (30) and (31) in the same package (32) both become “H” or both become “L”,
Since the probability that each output becomes "L" and "H" is extremely low, the ignition device (23) can be prevented from operating when the output of the comparator (30) (31) is abnormal.

In the embodiment described above, the time constant circuits (37) and (41) are provided on the input side of the comparators (30) and (31), respectively, so that these voltage signals are supplied to the comparators (30) and (31). But
This is to cope with a case where one of the capacitors (38) and (42) fails, and a voltage signal of a common time constant circuit may be supplied to the comparators (30) and (31).

(G) Effects of the Invention Since the present invention is configured as described above, the ignition device can be operated only when the two comparators emit different predetermined outputs, and a double safety circuit configuration is provided. In addition to improving reliability, if the output of the comparator becomes abnormal due to a surge voltage or deterioration of the element, the ignition device will not operate and the reliability will increase dramatically. The improvement can be achieved.

[Brief description of the drawings]

FIG. 1 is an electric circuit diagram of an ignition timer circuit showing one embodiment of the present invention, FIG. 2 is a schematic explanatory diagram of a water heater to which the present invention is applied, and FIG. 3 is a block diagram of a control device of the water heater. FIG. 4 is an explanatory diagram showing the relationship between the movement amount of the operation button and the operation of the control device. (22) ... Ignition timer circuit, (23) ... Ignition device, (3
0) ... first comparator, (31) ... second comparator, (3
2) Package, (33) Reference bias circuit, (3
7) A first time constant circuit, (41) a second time constant circuit, (47) a switching circuit.

Claims (1)

(57) [Claims] A reference voltage is applied to a first comparator and a second comparator housed in a common package, a non-inverting input terminal of the first comparator, and an inverting input terminal of the second comparator. A reference bias circuit, a time constant circuit for supplying a voltage signal to an inverting input terminal of the first comparator and a non-inverting input terminal of the second comparator, and a first comparator and a second comparator And a switching circuit for activating the ignition device when a different predetermined output is generated.