JPH01105491A - Induction-heated cooking utensil - Google Patents

Abstract

PURPOSE:To prevent the occurrence of the unsafe action of an equipment by providing a fail-safe means which detects an abnormality of the scan output signal of a microcomputer and outputs the oscillation stop signal to an inverter driving circuit. CONSTITUTION:The scan signal of the output port P11 of a microcomputer 4 is inputted to the + input side of a comparator 12 in a fail-safe circuit 11, a serial circuit of a resistor R and an electrolytic capacitor C is connected to the output side of the comparator 12 via an input current limiting resistor 15. The cathode of a Zener diode 16 with the Zener voltage V2D is connected to the side of the electrolytic capacitor C, and the base of a transistor 17 with the base-emitter voltage VBE is connected to the other anode side. When the microcomputer 4 runs away, the output of the comparator 12 is kept in an opened state, the transistor 17 is turned on, the oscillation stop signal is inputted to an inverter driving circuit 6, and the heating of an object to be heated is stopped. The unsafe action of an equipment can be thereby prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to an induction heating cooker that uses a microcomputer to cook a pot or the like.

Conventional technology 2 Beano Conventionally, the control circuit for this type of induction heating cooker used only a discrete circuit containing multiple custom and general-purpose ICs when controlling various temperature control functions such as input adjustment function and oil cooking. It was configured. However, in recent years, there has been a demand for the addition of more precise temperature control functions such as water boiling detection, and on the other hand, control circuits have been required to be lower in cost and more densely integrated. Therefore, in order to realize the above-mentioned demands, attempts have been made to simplify the control circuit and diversify the functions of the induction heating cooker by installing a microcomputer.

Problems to be Solved by the Invention However, when a microcomputer is installed and provided with the various functions described above, the microcomputer may run out of control due to external factors such as static electricity, and the runaway detection function of the microcomputer itself may be affected. If an abnormality occurs, there may be problems such as unsafe operation of the equipment, such as the equipment continuing to oscillate without receiving the input on/off key, or the temperature control function not working and causing oil ignition. there were.

3. In view of the above problems, the present invention aims to detect an abnormality in at least one output signal of a microcomputer, stop the oscillation of the device, and prevent the occurrence of unsafe operation of the device.

Means for Solving the Problems In order to achieve the above object, the induction heating cooker of the present invention c.
Detects an abnormality in the scan output signal of the microcomputer and outputs a signal to stop oscillation to the inverter drive circuit.
This configuration includes fail-safe means that stops the oscillation of the device.

Effect: With the above configuration, if the microcomputer goes out of control due to an external factor such as static electricity, an abnormality in the scan signal is detected and the oscillation of the device is immediately stopped, and the input on/off key is not pressed. It is possible to prevent unsafe operations such as continuous heating of equipment and oil ignition.

EXAMPLE Hereinafter, the structure of an induction heating cooker according to an example of the present invention will be explained with reference to FIGS. 1 and 2.

In Fig. 1, 1/(2f) is connected by the SNS input circuit section 2 from one input line of the f Hz AC power supply 1 of the equipment.
The input signal converted into a rectangular wave is input to the SNS input port of a microcomputer 4, which is a so-called one-chip microcomputer, and has a CPU, ROM, RAM, and an input/output section in the inverter oscillation control section 3. Then, in synchronization with this SN8 human power, 1/(
The scan signal which has risen to Hi level (+Vo.) by 6f) is output from the microcomputer 4 (Pl 1).
, Pl 2° is constantly output from Pl3. (P
The circuits after the output stage of 12 and Pl3 are omitted. ) When the user turns on the input switch 5i of the device, the output signal from the Pll is input to the input capo P2, and when the Hi-Lo repeat cycle is counted six times in the microcomputer 4, the output signal is input from the output capo P3. An oscillation signal is input to the inverter drive circuit 6. When the inverter drive circuit 6 receives the oscillation signal, it drives the switching transistor 8 in the inverter circuit section 7, the inverter circuit 7 oscillates, and the heating coil 9 is supplied with a high frequency current of 5.\-7. The object to be heated 1o is heated.

Next, while the microcomputer 4 is outputting the inverter oscillation ON signal from the output port P3, the user turns on the switch 6 again for a period of 6 x 17 (2f) or more (if continued, the input capacitor of the microcomputer 4) Hi-L on P2
o The repetition period is counted six times, and an oscillation stop signal is output from the output capacitor P3 to the inverter drive circuit 6, the oscillation of the inverter circuit 7 is stopped, and the heating of the object to be heated 10 is stopped.

Unfortunately, when the microcomputer 4 is outputting an oscillation ON signal from the output port P3 to the inverter drive circuit 6, the microcomputer 4 goes out of control due to some external factor such as static electricity, and the output port P11 remains at Hi level. In this state, even if the user operates the switch 6 to stop the oscillation of the device, the normal scan signal is not transmitted to the input capacitor P2 of the microcomputer 4, and the output capacitor P3 continues to oscillate. An unsafe operation of the device occurs in that the ON signal is issued and the power remains on at 6, and the heated object 1o continues to be heated.

Therefore, the microcomputer fail-safe circuit 11 shown in FIG. 1 detects an abnormality in the output port P11 of the microcomputer 4 as described above, and forcibly inputs an oscillation stop signal to the inverter drive circuit 6 from the hardware side. This is intended to stop the oscillation of the inverter circuit section 7.

Here, the configuration of the microcomputer fail-safe circuit 11 will be explained with reference to FIG.

First, the scan signal of the microcomputer 4 output port P11 is sent to the comparator 1 in the fail-safe circuit 11.
The divided voltage V, (
-=10V0°/2) is input. Comparator 1
A series circuit of a resistor R and an electrolytic capacitor C is connected to the output side of the capacitor 2 via an input current limiting resistor 16, and a cathode of a Zener diode 160 with a Zener voltage of vZD is connected to the + side of the electrolytic capacitor C. 7 on the side
・\-7 Transistor 17 with base-emitter voltage of VBK
0 base is connected, and when this transistor is turned on, an oscillation stop signal is input to the inverter drive circuit.

Next, the operation of the microcontroller fail-safe circuit is shown in Figures 1 and 2.
This will be explained using figures.

First, region I in FIG. 2 is a case where the microcomputer 4 is outputting a normal scan signal from the output port P11. The output of comparator 12 is v,1. >vB,
During the period of 1/(6f), the voltage is turned off, and the + side voltage V□ of the electrolytic capacitor C increases due to the time constant of OR.

When vPH<vB, that is, 2/(6f), the output of the comparator 12 falls to OV, and the capacitor C is discharged through the entire resistor 16. In this case, resistor R and capacitor C
The value of is ((vZD +vax) / Voo)
The value satisfies RXC<1/(6f), and the resistance is 15
The resistance value of the resistor R needs to be sufficiently smaller than the resistance value of the resistor R.

If the thumbnail microcomputer 4 outputs a normal scan signal from the output port P11, KV, <(
V2. +VBg), the transistor 17 is not turned on, and no oscillation stop signal is output from the failsafe circuit 11 to the inverter drive circuit 6.

However, if the microcomputer 4 goes out of control due to some external factor (area in Figure 2...), the comparator 12
The output of continues to be open, and V is ((VZD +V
Bz) /Tea)xRxC time vZD 1VE
X, the transistor 17 turns on, and an oscillation stop signal is input to the inverter drive circuit 6, the inverter circuit 7 stops oscillating, no high frequency current is supplied to the heating coil 9, and the heating of the heated object 10 stops. do.

According to the configuration of the above embodiment, even if the microcomputer 4 goes out of control during the heating operation of the device and the heating stop switch 5 is operated, the microcomputer 4 does not respond and the oscillation is turned on from the microcomputer 4 to the inverter drive circuit 6. Even if the signal continues to be output, by detecting an abnormal signal at the output port P11 of the microcomputer 4, the fail-safe circuit 11 immediately outputs the oscillation stop signal 9I\-/ to the inverter drive circuit 6, and the inverter oscillation is stopped. This can stop the heating of the equipment and prevent unsafe operation of the equipment.

Effects of the Invention As is clear from the above embodiments, according to the present invention, even if the microcomputer goes out of control while the induction heating cooker is heating a pot etc. and the on/off switch of the device does not work, the microcomputer is fail-safe. By immediately stopping the heating of the equipment, it is possible to prevent unsafe operation of the equipment, such as empty cooking of a pot or oil ignition.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram of a main part of an induction heating cooker according to an embodiment of the present invention, and FIG. 2 is a timing chart of various voltage waveforms for explaining the principle of operation. 3... Inverter oscillation control section, 4...
Microcomputer, 6...Input on/off switch, 6...Inverter drive circuit section, 7...
... Inverter circuit section, 9 ... Heating coil,
10... Heated object, 11... Microcomputer fail-safe circuit section.

Claims (1)

[Claims] A heating coil that inductively heats an object to be heated, an inverter device that supplies high-frequency current to this heating coil, an inverter drive circuit that drives oscillation of this inverter device, and a microcomputer that controls this inverter drive circuit.
an inverter oscillation control section consisting of peripheral circuits thereof and an input switch of the device, and an induction heating system comprising a fail-safe means for detecting an abnormality in the scan output signal from the microcomputer and stopping the oscillation of the inverter circuit. Cooking device.