JPH03173091A - Power level adjustment of electronic cooker and circuit therefor - Google Patents

Abstract

PURPOSE: To easily control low output, and eliminate an operationally fluctuating phenomenon by adjusting a power level by outputting a pulse signal from a microcomputer by a pulse width modulation control method when a preset power level is not less than 5 and by a time duty ratio control method when the power level is less than 5. CONSTITUTION: This method and a circuit are composed of a driving part 11 to turn on and off a power transistor TRI by an output signal of a pulse width control part 10 including a microcomputer 4 to output a pulse signal by a time duty ratio control method by a power level set by a user and a pulse signal by a pulse width modulation control method. When assuming that a maximum power level is 10, the power transistor TRI is turned on and off by a time duty ratio control method on a power level 1 to 4, and is turned on and off by a pulse width modulation control method on a power level 5 to 10. Therefore, low output is easily controlled, and an operationally fluctuating phenomenon can be removed.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention changes the direction of the current flowing to the working coil by turning on and off the power transistor of the inverter section, and changing the direction of the current flowing to the working coil. In an electronic cooking device that heats and cooks food using the magnetic field generated by a working coil as the temperature changes, is the time duty ratio controlled by the power level set by the user? The present invention relates to a power level adjustment method and circuit for an electronic cooking device that uses both the I11 method and the pulse width modulation control method to turn on and off a power transistor.

<Prior art> A conventional method for adjusting the power level in an electronic cooking device is to turn on and off a power transistor within a certain period of time set to a power level that allows the electronic cooking device to output maximum output. A time duty ratio control method that varies the power level by adjusting the time duty ratio, and a pulse width modulation control method that adjusts the power level by adjusting the time that the power transistor is turned on according to the width of the pulse signal within a certain time. There was a way.

<Problems to be Solved by the Invention> However, with the time duty ratio control method described above, a low output can be output, and the power level can be easily adjusted even with a low output. And since the frequency at which the power transistor is turned on and off is constant, there are many working coils. The wire-type electronic cooking device also has the advantage of not generating beat noise due to frequency differences. On the other hand, when the power transistor is turned on and off, the fluctuation rate of the power supply voltage is large and the load current fluctuates, resulting in flickering in operation. Furthermore, there is a drawback in that transient phenomena occur and stable operation of the electronic cooking appliance cannot be expected.

On the other hand, the pulse width modulation control method has the advantage of being able to continuously output power and maintain a constant power level.

When the power level is low, such as about 200 W or less, it is difficult to control the low output power level because the load current is small and the input current is difficult to sense. In the case of the electric cooking appliances, there is a problem in that when the power levels are set to be different from each other, beat noise is generated due to the frequency difference.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method for combining a time duty ratio control method and a pulse width modulation control method according to a power level set by a user, and a circuit therefor, in order to overcome such conventional deficiencies. It is. To give a concrete example of this method, assuming that the maximum power level is IO, power transistors are turned on and off using the time duty ratio control method at power levels 1 to 4, and pulse pulses are turned on and off at power levels 5 to 10. It is turned on and off using a width modulation control method.

Example The present invention will be explained in detail with reference to the accompanying drawings.

FIG. 1 is a circuit diagram of an electronic cooking device according to the adjustment method of the present invention. As shown in the figure, when the power transistor (TR1) of the inverter section (2) is turned on and off, the working coil (WC) is connected through the rectifier (1).
), which detects the current flowing to the current transformer (CT), and pulse signal and pulse width modulation control using a time duty ratio control method based on the power level set by the user. A microcomputer (4) that outputs a pulse signal according to the method, a digital/analog converter (5) that converts the output pulse signal of the microcomputer (4) into an analog signal, and an output voltage of the input current sensor (3). , the output voltage and power supply terminal (Vcc) of the digital/analog converter (5) are connected to resistors (R1, R2).
comparators (6) and (7), which are respectively compared with the reference voltage (Vref) divided by ), a tableware sensing signal output unit (9) that outputs a tableware sensing signal based on the output signal of the comparator (7),
An inverter (■1) that inverts the output signal of the microcomputer (4), the comparator (7) and the inverter (11)
) AND gate (AND1) that converts the output signal of
and a pulse width control section (10) that is enabled by the output signal of the AND gate (AND1) and then outputs a pulse signal according to the output signals of the integrator (8) and the tableware sensing signal generation section (9); Pulse width control section (10)
The output signal of the above power transistor (TR1)
It is composed of a drive section (11) that turns on and off.

The adjustment method of the present invention having such a configuration will be described in detail with reference to the signal flow diagram of FIG. 2 and the waveform diagram of FIG. 3.

In the initial state before the user operates the electronic cooking device, the power transistor (TR1) is turned off and there is no input current, so the input current sensing section (3) outputs a low voltage, so the comparator (7) A high voltage is output based on the reference voltage (Vref) applied to the non-inverting input terminal (+). This high voltage is applied to the enable terminal (EN1) of the integrator (8), and at the same time the integrator (8) is disabled.
A high voltage is applied to the tableware sensing signal generator (9) to generate a tableware sensing signal. Mycom (4) outputs low voltage,
After that low voltage is inverted to a high voltage through the inverter (It), it is input to the AND gate 1- (AND1) along with the high voltage output from the comparator (7), so the AND gate (AND1) converts the high voltage. Output and pulse width control section (
10) is applied to the in-apple terminal (EN2). As a result, the pulse width control section (lO) is disabled and outputs a low voltage regardless of the output signals of the integrator (8) and the tableware detection signal generation section (9), so that the drive section (11)
will not turn on the power transistor (TR1).

In this state, the user operates the electronic cooker and
As shown in the figure, when the power-on key signal is input to the microcomputer (4) at step (101) and the power level key signal is input at step (102), the microcomputer (4)
sets the power level (N) according to the power level key signal input in step (1α3), and outputs the tableware detection signal in step (104), that is, outputs a 5Qmsec pulse signal at a 2 second cycle.

If the microcomputer (4) outputs a pulse signal in this way,
The output pulse signal is inverted to a low voltage through the inverter (11) and applied to the AND gate (AND1), so the AND gate (AND1) outputs a low voltage and enables the pulse width controller (10). . As a result, the pulse width controller (10) outputs the tableware sensing signal generator (9). A pulse signal is output based on the tableware detection signal. This pulse signal is input to the drive section (11), so the drive section (11) is powered by a power transistor (TR).
1) is turned on to allow current to flow through the working coil (WC). The current transformer (CT) detects the current flowing to the working coil <WC), and the input current sensing section (3) outputs a sensing voltage of the input current. When the input current is at an appropriate level, the comparator (7) outputs a low voltage to pull the integrator (8) in, and at the same time continuously enables the pulse width controller (10).

Then, the microcomputer (4) determines whether or not the tableware is normal at step (105), and if the tableware is not normal, the microcomputer (4) judges at step (105).
Step 104) is continuously and repeatedly performed to determine whether the tableware is normal. If the tableware is normal, it is determined at step 106 whether the power level (N) is 5 or higher.

At this time, assuming that the power level (N) is 10, the microcomputer (4) calculates the time of step (107) 't' variable (K) multiplied by the power level (N), that is, K x 10
A pulse signal is output with a time width of m5ec. The output pulse signal is converted into an analog signal by the digital/analog converter (5) and then input to the comparator (6), so the comparator (6) outputs a high voltage. The output high voltage is integrated by an integrator (8) and then a pulse width controller (1)
0), the driver (11) turns on and off the power transistor (TR1) according to the power level (N) 10, and the current flows to the working coil (WC). The direction of ti is changed.

Then, the microcomputer (4) determines whether a power-off key signal is input in step (108).

When the power-off key signal is input, a reset pulse signal of 4 m5ec is output in step (109) to stop the operation of the electronic cooker, and if the power-off key signal is not input, step (110) is performed. It is determined whether the power level key signal is inputted or not, and if the power level key signal is not inputted, the direction of the current flowing to the working coil (WC) is changed by repeatedly performing step (105). , if a power level key signal is input, step (103) is repeatedly performed. At this time, if the power level (N) is between 9 and 5, the microcomputer (4) outputs K The working coil (W
C) change the direction of the current flowing to C).

On the other hand, if the power level (N) is 4 or less, in step (111) the variable (N) is multiplied by the power level (N) to calculate the number of pulse signals to be output (P), and in step (111)
12) to count the time (1). In step (113), it is determined whether 2 seconds have elapsed or not, and if 2 seconds have not elapsed, the number of pulse signals (P) is subtracted in step (114), and the remaining pulse signal is subtracted in step (115). The number of pulse signals (P
) is 0 or not, and if it is not 0, step (
(K x
A pulse signal with a width of 5+5 secO is output at a period of 150 tasec. In step (118), it is determined whether or not a power level key signal is input, and if the power level key signal is input, the process is repeated from step (103), and if not, the process is performed repeatedly from step (112). K X 5 n+
The direction of the current flowing to the working coil (WC) is changed by repeatedly outputting a pulse signal of sec at a period of 150 m5 ec.

In this state, a pulse signal was output according to the set power level (N), and when the number of remaining pulse signals (P) reached O in step (115), a reset pulse signal of 4 m5ec was output. The process is repeated from the post-step (112), and when 2 seconds have elapsed in the step (113), the step (12) is repeated.
0), it is determined whether a power-off key signal is input. When the power off key signal is input, it stops operating,
If the power-off key signal is not input, step (12)
In step 1), it is determined whether or not the power level key signal is input, and if the power level key signal is input, step (103) is performed.
), and if the power level key signal is not input, the direction of the current flowing to the working coil (WC) is changed from step (104) onwards.

<Effects of the Invention> As explained in detail above, the present invention turns the power transistor on and off using the pulse width modulation control method when the power level set by the user is low, so that it is possible to control the low output. It is easy to do this, and the phenomenon of flickering can be eliminated.

Furthermore, not only can the generation of beat noise due to frequency differences be reduced, but also transient phenomena will not occur.
It has the effect of making the movement smoother.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram of an electronic cooking device according to the adjustment method of the present invention, FIG. 2 is a signal flow diagram of a microcomputer according to the adjustment method of the present invention, and FIGS. FIG. 3 is a waveform diagram showing a pulse signal output according to a set power level. ■... Rectifier, 2... Inverter section, 3... Input current sensing section, 4... Microcomputer, 5 Digital/analog converter, 6.7... Comparator, 8... Integrator , 9
... tableware sensing signal generation section, 10 ... pulse width control section, 11 ... drive section, CT ... current transformer, TRI ...
Power transistor, WC...working coil,
11... Inverter, R1, R2... Resistor. Figure 2 Procedural Amendment (1) The title of the invention is corrected to "Method and circuit for adjusting power level of an electromagnetic cooker." (2. The scope of claims is amended as shown in the attached sheet. (3) “Electronic cooker” in the following part of the specification is corrected to “electromagnetic cooker”. 4. Proprietary name: Kinsei Co., Ltd. Embedded in 5) , date of amendment order Claims (1) The power transistor (TR1,) is turned on and off by the pulse signal output by the microcomputer (4) according to the set power level (N), and the working coil (
In the power level adjustment method for an electromagnetic cooker that changes the direction of the current flowing through the WC), when the set power level (N) is 5 or more,
The microcomputer (4) outputs a pulse signal using a pulse width modulation control method that repeatedly outputs a pulse signal with a time width equal to the time width of the variable (K) multiplied by the power level (N) at a constant cycle, and the power level (N) is 5. If it is less than, output a number of pulse signals equal to the variable (M> multiplied by the power level (N)) for a certain period of time, and output the pulse signals at a fixed period with a width equal to the variable (K) multiplied by a certain period of time. A power level adjustment method for an electromagnetic cooker, characterized in that the microcomputer (4) outputs a pulse signal to adjust the power level using the time duty control method. (2) Pulse width control! (10) Color pulse In the power level adjustment circuit of the electromagnetic cooker, the power transistor (TR1) of the inverter section (2) is controlled on/off by the output signal of the drive section (11) controlled by the signal. 2), an input terminal sensing section (3) that senses the current flowing through the working coil (WC), and a pulse signal using the time duty control method and a pulse signal using the pulse width modulation control iB method according to the power level set by the user. Microcontroller to output (
4), a digital/analog converter (5) that converts the output pulse signal of the microcomputer (4) into an analog signal, and a digital/analog converter (5) that converts the output voltage of the input terminal sensing section (3) to the digital/analog converter (5). output voltage and reference voltage (V
The output signal of the comparator (6) is integrated based on the output signal of the comparator (7), and is output to the pulse width control 1 (10). an integrator (8), a tableware sensing signal output section (9) that outputs a tableware sensing signal to the pulse width control section (10) based on the output signal of the comparator (7), and an output signal of the microcomputer (4). and an AND gate (AND1) that converts the output signals of the comparator (7) and the inverter (11) into AND gates and outputs an enable control signal to the pulse width control section (10). A power level adjustment circuit for an electromagnetic cooker, characterized by:

Claims (1)

[Claims] (1) The microcomputer (
4) outputs a pulse signal from the power transistor (T
R1) on and off, working coil (WC)
In a power level adjustment method for an electronic cooking device that changes the direction of current flowing through the device, when the set power level (N) is 5 or more,
The microcomputer (4) outputs a pulse signal using a pulse width modulation control method that repeatedly outputs a pulse signal with a time width equal to the time width of the variable (K) multiplied by the power level (N) at a constant cycle, and the power level (N) is 5. If the value is less than 1, output a number of pulse signals equal to the variable (M) multiplied by the power level (N) for a certain period of time, and output the pulse signals at a fixed period with a width equal to the variable (K) multiplied by a certain time. A method for adjusting a power level of an electronic cooking device, characterized in that a microcomputer (4) outputs a pulse signal to adjust the power level using a time duty control method. (2) Power level of an electronic cooking device in which the power transistor (TR1) of the inverter section (2) is controlled on/off by the output signal of the drive section (11) which is controlled by the pulse signal from the pulse width control section (10). The adjustment circuit includes an input current sensing part (3) that senses the current flowing through the rectifier (1) to the working coil (WC) of the inverter part (2), and a time duty ratio control method according to the power level set by the user. A microcomputer (4) that outputs a pulse signal based on a pulse signal and pulse width modulation control method, a digital/analog converter (5) that converts the output pulse signal of the microcomputer (4) into an analog signal, and the input current sensing section. A comparator (
6) (7) and an integrator (8) that integrates the output signal of the comparator (6) using the output signal of the comparator (7) and outputs it to the pulse width control section (10); Vessel (7)
The tableware detection signal is output from the pulse width control section (
a tableware sensing signal output section (9) that outputs to the microcomputer (4), an inverter (11) that inverts the output signal of the microcomputer (4), the comparator (7) and the inverter (11).
) is converted into an AND signal and the pulse control section (10)
AND gate (AND) that outputs an enable control signal to
1) A power level adjustment circuit for an electronic cooking device, comprising: