KR900008720Y1 - Circuit for detecting false operation of microcomputer - Google Patents

Abstract

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Description

Microcomputer malfunction detection circuit

1 is a detailed view showing an embodiment of a malfunction detection circuit of the present invention.

(A)-(d) of FIG. 2 are operational waveform diagrams of each part of FIG.

3 is a signal flow diagram showing the operation of the microcomputer by the malfunction detection circuit of the present invention.

* Explanation of symbols for main parts of the drawings

1: Microcomputer PL: Pulse signal output terminal

IN: Input terminal TR4: Transistor

D4, D5: Diodes C5, C6: Capacitors

R6, R7: Resistor Vcc2: Power

The present invention relates to a malfunction detection circuit of a microcomputer, and more particularly to a malfunction detection circuit of a microcomputer that is suitable for detecting a malfunction of a microcomputer controlling the operation of a combustion device.

In the combustion apparatus using a conventional microcomputer, the safety measures for the malfunction of the microcomputer are inadequate in hardware. Therefore, an error in the operation program of the microcomputer or the malfunction of the combustion apparatus causes a lot of trouble in the settlement operation of the combustion apparatus. There was a problem.

The present invention, in order to solve the conventional problems as described above, a simple detection of the malfunction detection circuit for detecting the malfunction of the microcomputer as described in detail with reference to the accompanying drawings as follows.

1 is a detailed view showing an embodiment of a malfunction detection circuit of the present invention, and as shown therein, a microcomputer 1 for controlling the overall operation of a combustion device and an AC power source AC are rectified to provide various operating power sources ( A power supply unit 2 consisting of a bridge diode BD supplying Vcc1-Vcc3, a capacitor C1-C4, a resistor R1, and a regulator REG, and an operating power supply from which the power supply unit 2 is output ( Ignition of the reset unit 3 and the power supply Vcc2 by a resistor R2-R5, a constant voltage diode ZD, and an operational amplifier OP for resetting the microcomputer 1 according to the variation of Vcc1). An igniter is driven in accordance with a control signal output from the ignition power supply unit 4 including the resistors R6 and R7 and the transistor TR1 supplied to the power source and the microcomputer 1, and a diode that causes the heater to generate heat and ignite. (D1-D3), resistors R8 and R11, transistors TR2 and TR3, igniter driving relay RY1, and An ignition control unit 5 made of a driving drive relay RY2, a resistor (R12-R14) and a burner which drive a burner motor fan motor and an electronic pump to perform a combustion operation according to the output signal of the microcomputer 1; Combustion control unit 6 comprising a motor driving photocoupler PC1, a fan motor driving photocoupler PC2, and an electronic pump driving photocoupler PC3, and a pulse outputted by the microcomputer 1 during normal operation. The malfunction detection unit 7 includes resistors R15-R17, capacitors C5 and C6, diodes D4 and D5, and transistors TR4 that generate a low potential as a signal and inform the microcomputer 1 of its malfunction. ), And an alarm unit 8 made of a resistor R18 and a light emitting diode LD for alarming the malfunction of the microcomputer 1.

According to the present invention configured as described above, when the AC power source AC is applied, the applied AC power source AC is bridge-rectified by the bridge diode BD and smoothed by the capacitors C1-C3 to output the power sources Vcc1 and Vcc2. In addition, the power supply Vcc3 converted to the constant voltage is output through the regulator REG to supply operating power to the entire circuit.

At this time, when the AC power source AC is initially applied, the power source Vcc1 increases as shown in FIG. 2A and is applied to the non-inverting input terminal (+) of the operational amplifier OP, and inverts the operational amplifier OP. Since the zener voltage Vzd of the constant voltage diode ZD is applied to the input terminal (−), the operational amplifier OP outputs a low potential as shown in FIG. 2B, and the output low potential is a microcomputer 1. Reset terminal The microcomputer 1 is reset to perform an initialization operation.

At this time, when the low potential is output from the operational amplifier OP, the power supply Vcc1 is divided by the resistors R3-R5 and applied to the non-inverting input terminal + of the operational amplifier OP.

Therefore, when the power supply Vcc1 becomes higher than the voltage V2 higher than the zener voltage Vzd, the operational amplifier OP outputs a high potential so that the microcomputer 1 is reset and the combustion operation is performed. To get started.

In this state, when the AC power source AC is changed and the power source Vcc1 is lowered, the voltage applied to the non-inverting input terminal (+) of the operational amplifier OP is lowered, and at this time, the operational amplifier OP Since it is applied to its non-inverting input terminal (+) through the high potential resistor (R5) output from the output to the non-voltage terminal (+) of the operational amplifier (OP), output from the power supply (Vcc1) and operational amplifier (OP) When the high potential is divided by the resistors R3-R5 and applied so that the power supply Vcc1 becomes a voltage V1 lower than the Zener voltage Vzd, the operational amplifier OP outputs a low potential and the microcomputer ( 1) will be reset.

That is, the reset unit 3 has a hysteresis width between the voltage V2 and the voltage V1 and releases the reset of the microcomputer 1 when the power supply Vcc1 becomes higher than the voltage V2. In the state where the reset of the microcomputer 1 is released, the microcomputer 1 is reset when the power supply Vcc1 becomes lower than the voltage V1.

Since the transistor TR1 is turned on by the power supply Vcc2, the power supply Vcc2 is supplied to the ignition control unit 5.

In this state, the heater drive terminal when the microcomputer 1 ignites the combustion device. And low and high potentials are respectively output to the igniter driving terminal IG.

Then, heater drive terminal Since the transistor TR2 is turned on by the low potential output, the heater driving relay RY2 is driven, and the heater generates heat to heat the burner according to the driving of the relay RY2, and thus the igniter driving terminal IG. Since the transistor TR3 is turned on by the high potential output, the igniter driving relay RY1 is driven, and the igniter is driven in accordance with the driving of the relay RY1 to ignite the burner.

The microcomputer 1 outputs a high potential drive signal to the burner motor driving terminal BL, the fan motor driving terminal FN, and the electronic pump driving terminal PU while igniting the combustion device as described above.

Therefore, the burner motor driving photocoupler PC1 is operated by the high potential output to the burner motor driving terminal BL to drive the burner motor to supply combustion air to the burner, and to the fan motor driving terminal FN. At one high potential, the fan motor driving photocoupler (PC2) operates to drive the fan motor to exhaust the air heated by the burner, and the high potential output to the electromagnetic pump driving terminal (PU) allows the electronic pump driving photo. The coupler PC3 operates to drive the electronic pump to supply fuel for combustion to the burner.

In this state, when the ignition of the burner is completed and the fuel starts to burn, the microcomputer 1 is connected to the heater driving terminal. And the transistors TR2 and TR3 are turned off by outputting the high potential and the low potential to the igniter driving terminal IG, the driving of the relays RY2 and RY1 is stopped, and the operation of the heater and the igniter is stopped.

When the microcomputer 1 operates normally in this state, the pulse signal is output to the pulse signal output terminal PL as shown in FIG. 2C. The output pulse signal is a resistor R15 and a capacitor ( Through C5, it is rectified to DC voltage by diodes D4 and D5 and capacitor C6, divided by resistors R16 and R17, and applied to the base of transistor TR4.

Therefore, the transistor TR4 is turned on and the low potential is inputted to the input terminal IN of the microcomputer 1 so that the microcomputer 1 determines that it operates normally.

When the microcomputer 1 malfunctions and does not output a pulse signal to the pulse signal output terminal PL, as shown in FIG. 2C, the microcomputer 1 continuously outputs a high potential or outputs a low potential. One of the high potential or the low potential is interrupted by the capacitor C5, and the transistor TR4 is turned off because the low potential is continuously applied to the base of the transistor TR4, and the input terminal IN of the microcomputer 1 continues. The high potential is entered.

Then, the microcomputer 1 judges itself as malfunctioning, outputs a high potential to the output terminal ER as shown in FIG. 2d, and alarms the malfunction while lighting the light emitting diode LD. The reset operation is performed to stop the combustion operation of the combustion device.

3 is a signal flow diagram showing the operation of the microcomputer 1 by the malfunction detection circuit of the present invention.

The present invention is such that the microcomputer 1 performs the initialization operation in step 10, the reset terminal in step 11 When the low potential is inputted by determining whether the low potential is input, the initialization operation is performed in step 10.

And reset terminal If the low low potential is not input, the high potential is output to the igniter driving electron IG in step 12, and the heater driving terminal in step 13. Outputting the low potential to drive the relays RY1 and RY2, driving the igniter and the heater to ignite the combustion device, and then outputting the pulse signal to the pulse signal output terminal PL in step 14, step 15 Determine whether the high potential is input to the input terminal (IN) at.

At this time, when the high potential is not input to the input terminal IN, the microcomputer 1 determines that the normal operation is itself, and performs the normal combustion operation in step 16, that is, the burner motor driving terminal BL. ), A driving signal is output to the fan motor driving terminal FN and the electronic pump driving terminal PU to drive the burner motor, the fan motor, and the electronic pump to perform a combustion operation.

When the high potential is input to the input terminal IN, it is determined that the malfunction is performed, and in step 17, the high potential is output to the output terminal ER to light up the light emitting diode LD. The combustion operation is stopped by performing the reset operation at.

On the other hand, in the above described the malfunction detection circuit of the present invention by taking a combustion device as an example, in the implementation of the present invention, it is simply performed on various devices using a microcomputer, that is, a refrigerator and an air conditioner using a microcomputer, for example. can do.

As described in detail above, the present invention improves the reliability of a product using a microcomputer by detecting a hardware failure of the microcomputer and stops the operation of the microcomputer, and damages the product due to the malfunction of the microcomputer. There is an effect such that it can be prevented.

Claims (1)

In the apparatus provided with the microcomputer (1), the capacitor (C5) for passing the pulse signal output terminal (PL) for outputting the pulse signal in the normal operation of the microcomputer (1) only the pulse signal, and the diode (D4, D5) and a rectifier of capacitor C6 are connected to the base side of transistor TR4, and collector of transistor TR4 is connected to input terminal IN of microcomputer 1, and resistors R7, A microcomputer (1) is connected to a power supply (Vcc2) through R6), and the microcomputer (1) stops the control operation of the device when a high potential is input to the input terminal (IN).