KR930005790Y1 - Inverter output control circuit for electronic range - Google Patents

Abstract

No content.

Description

Inverter output control circuit of microwave oven

1 is a block diagram of the control circuit of the present invention.

2 is an output logic diagram of a decoder according to the present invention.

* Explanation of symbols for main parts of the drawings

1: magnetron 10: current detection transformer

11: drive transformer 20: control unit

30: decoder 41 ~ 43: photo coupler

The present invention relates to an inverter output control circuit of a microwave oven, and more particularly, to an output control circuit for controlling an inverter output by an output of a microcomputer control device as a connection circuit between a microwave power supply device and a microcomputer control device. will be.

The microwave drive requires a high voltage (for example, a fixed voltage of a KV order) and a high power, and the current-voltage characteristic indicates a constant voltage characteristic, and moreover, the current-voltage characteristic changes with the temperature of the magnetron.

The relationship between the anode current of the magnetron and the anode-cathode voltage is a parameter of the temperature of the magnetron, which causes abnormal oscillation when the current value increases beyond the threshold.

As described above, it is very difficult to stably drive the magnetron, and conventionally, a type of power source that boosts an AC power source of an applied frequency to a transformer has been used.

In such a conventional microwave power supply device, for example, as described in Electronic Technology Publication No. 20, No. 3 (1978) P34 to P45, after boosting the commercial power supply, the rectifier is rectified by a half-wave voltage rectifier circuit and magnetron. The control of the output power was made by controlling the normal phase of the bidirectional control switch element connected in series with the transformer primary winding.

On the other hand, in recent years, a small light weight switching power supply has been developed, but when they are used as a magnetron driving power supply such as a microwave power supply, the following problems occur.

That is, in the case of light load or no load, part of the emitted microwave is reflected by the magnetron by reflection and heats the magnetron. As a result, the temperature of the magnetron is raised, and in the worst case, the glass or ceramic of the microwave output part is broken. There is a risk of becoming. As a power supply that boosts the applied frequency power to a transformer, the output of the magnetron is relatively small at light loads, so the overheating of the magnetron is relatively small.However, when a switching power supply is used, the output is set even at light loads. Overheating of the magnetron is a more important problem.

In the microwave oven, the current-voltage characteristic changes with temperature, and in the case of a temperature rise, the operating power drops and the current value increases with respect to the same applied voltage, and at a certain value, for example, about 1A in the microwave power supply. Exceeding the above causes an abnormal oscillation. Therefore, it is necessary to control the input of the magnetron according to the temperature.

As indicated in the above document, the magnetron has a constant voltage characteristic and the magnetron applied voltage has a large pulsation even though the magnetron has a constant voltage characteristic and there is an upper limit on the allowable instantaneous power of the input, so that the control range of the output power is narrow. In case of overheating, there is a problem that the operation of the microwave oven should be stopped by opening the power supply circuit by the thermostat.

Moreover, in the power source of the prior art, since the transformer of the magnetron power source of the microwave is operated at a use frequency, the transformer is not only a large mass, but also requires a separate design using commercial frequencies of 50 Hz and 60 Hz. Furthermore, the magnetron of the load shows the constant voltage characteristics, and when the applied voltage between the anode and the cathode exceeds the cut-off voltage, the anode current starts to flow and the anode current increases linearly with the increase of the applied voltage, so that the microwave output can be obtained. As mentioned above, when the anode current reaches the threshold, the magnetron causes an abnormal oscillation and thus the microwave output cannot be obtained. This abnormal oscillation significantly shortens the life of the magnetron.

Furthermore, the cut-off voltage of the magnetron is, for example, about 4 KV, and this value is changed by the temperature of the magnetron, and fluctuates several 100 V in normal operation. However, in the power supply of the prior art, since the power supply voltage and the cut-off voltage of the magnetron are not considered, the anode current exceeds the threshold value when the power supply voltage rises or the cut-off voltage drops, causing a haircut oscillation. Alternatively, there is a problem in that the applied voltage of the magnetron does not become higher than the cutoff voltage and the microwave output is hardly obtained when the power supply voltage falls or the cutoff voltage rises.

Due to the conduction of the transistor Q1, the feedback output voltage FB1 of the current sensing transformer 10 is divided by the resistors R1 and R2 connected to the emitter of the transistor Q1, through the diode D1. The final feedback voltage FB2 to the controller 20 is obtained.

Then, the control unit 20 receives the feedback voltage FB1 and operates the switching transistor Q10 that controls the magnetron 1 driving transformer 11 according to the voltage.

If the three outputs of the microcomputer are (0,0,1), only one of the three photo couplers 41-43 operates, and only the a3 input is applied to the inputs a1-a3 of the decoder 30 to output the output (X2). ) Only becomes high, and if the three outputs of the microcomputer are (0,11), two of the three photocouplers 41-43 operate, and only a2 and a3 inputs to the inputs a1-a3 of the decoder 30 are high signals. Is applied so that only the output X4 goes high.

In this logic operation, when all three output signals of the microcomputer are high, the three photo couplers 41 to 43 operate and are input to the decoder 30.

In order to solve this problem, the transformer turns ratio is such that the magnetron applied voltage is higher than the expected cutoff voltage even when the power supply voltage becomes the lowest value, and when the power supply voltage rises, the anode current is detected to reach the threshold value. Previously, a method of preventing abnormal oscillation by considering turning off the bidirectional control switch is considered, but in this case, a means for detecting an anode current is required, resulting in a complicated control circuit of the bidirectional control switch.

As a switching power supply of the prior art for a microwave oven, there exist some which were disclosed by Unexamined-Japanese-Patent No. 58-4121, for example. In this switching power supply, the input frequency applied to the high voltage transformer is changed by a frequency converter to change the oscillation output of the magnetron.

As described above, this switching power supply does not take into account changes in temperature of the magnetron's current-voltage characteristics, and therefore, proper driving of the magnetron was impossible.

Moreover, in this switching power supply, no consideration has been given to the switching loss point when a switching element is used in the frequency converter.

In order to reduce the switching loss, the method of turning on at the point where the switching element voltage is minimized is common as a method of operating a resonant converter.

However, in these conventional resonant converters, a resonant circuit is newly set at the input side of the transformer, or a resonance voltage is generated by using the operation at the transformer output side. Therefore, the operating range is narrow, for example, the input power is not smoothed. It cannot be used for voltage waveforms. On the other hand, as a switching power supply for a load requiring a large power such as a microwave oven, since the input current is large, when the input voltage is smoothed, a large-capacity capacitor is required and it is not practical.

In addition, the existing microwave oven to control the output on / off switching the inverter with a microcomputer.

That is, the magnetron generates a high output when the on-width is large, and generates a low output when the on-width is small.

This technique has a problem that the output of the magnetron is not continuous, but intermittent output, unsuitable for food cooking.

The present invention has been made to solve the above-mentioned conventional problems, an object of the present invention is to control the output of the inverter by the control of the microcomputer when connecting the power supply of the inverter for microwave oven and the microcomputer control itself. An inverter output control circuit for controlling a microwave oven is provided.

Technical configuration for achieving the above object of the present invention, three photo couplers operated by three output signals of the microcomputer, a decoder for receiving three input signals of the three port coupler and generates eight output signals, and The transistor operates according to the eight output signals of the decoder, the voltage divider and diode for dividing the first feedback voltage of the current detection transformer according to the operation of the eight transistors, and the magnetron driving transformer by the second feedback voltage through the diode. The controller is configured to control the switching transistor for controlling the switching characterized in that to continuously adjust the output of the microwave.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a circuit diagram of the present invention, in which eight transistors Q1-Q8 collectors are connected to a current sensing transformer 10 for controlling the high pressure of the magnetron 1 of a microwave oven, and an operating voltage width of the current transformer 10 is shown in FIG. The emitters of the transistors Q1-Q8 are connected to the control unit 20 for controlling the transistors through the resistors R1-R16 and diodes D1-D8, and 3x is provided at the base of the transistors Q1-Q8. 8 Decoder 30 is connected.

The three inputs a1-a3 of the decoder 30 are connected to the photo transistor emitters of the photo couplers 41-43, and the photodiodes of the photo couplers 41-43 are output terminals of a microcomputer (not shown). Is connected to.

Here, the output control of the microcomputer is set to adjust the voltage applied to the magnetron 1 by controlling the feedback current of the current sensing transformer 10.

If all three output signals of the microcomputer are zero, there is no voltage applied to the photodiode of the photocoupler 41-43. Therefore, the photo coupler 41-43 does not operate. Therefore, as shown in FIG. No signal is applied to the input terminals a1-a3 of the decoder 30.

Then, only the output terminal X1 signal of the decoder 30 goes high.

Only the transistor a1 is turned on by the high signal of the output terminal X1, and the feedback output voltage FB1 of the current sense transformer 10 is applied to the emitter of the transistor Q1 by the conduction of the transistor Q1. The voltage is divided by the connected resistors R1 and R2 to become the final feedback voltage FB2 through the diode D1 to the controller 20.

Then, the control unit 20 receives the feedback voltage FB1 and operates the switching transistor Q10 that controls the magnetron 1 driving transformer 11 according to the voltage.

If the three outputs of the microcomputer are (0,0,1), only one of the three photo couplers 41-43 operates, and only the a3 input is applied to the inputs a1-a3 of the decoder 30 to output the output (X2). ) Only becomes high, and if the three outputs of the microcomputer are (0,11), two of the three photo couplers 41-43 operate, and only a2 and a3 inputs to the inputs a1-a3 of the decoder 30 are high signals. Is applied so that only the output X4 goes high.

In this logic operation, if all three output signals of the microcomputer are high, the three photo couplers 41-43 operate and all of the inputs a1-a3 of the decoder 30 are applied with the high signal, so only the output X8 is output. Goes high.

The transistors Q1-Q8 operate according to the outputs X1-X8 of the decoder 30, and the feedback output voltage FB1 of the current sense transformer 10 is operated by the operations of the transistors Q1-Q8. The voltage is divided by the resistors R1-R16 connected to the emitters of the transistors Q1-Q8 to become the final feedback voltage FB2 through the diodes D1-D8 to the control unit 20.

Then, the controller 20 controls the output of the inverter by changing the operating voltage of the switching transistor Q10 according to the feedback voltage FB2.

The inverter means an output of the switching transistor Q10, and the induction heating transformer 11 is driven by this output value to generate a high frequency magnetic field, and the magnetron 1 is operated by the high frequency to cook food. It is.

As described in detail above, the present invention improves the cooking performance of the food by continuously adjusting the output of the microwave, there is an excellent effect that can implement a high value-added microwave.

Claims (1)

In the control circuit for controlling the output of the microwave, photo output couplers 41 to 43 operated by three output signals of the microcomputer and input signals a1-a3 of the three port couplers receive eight output signals X1. A decoder 30 generating -X8, transistors Q1 to Q8 operating according to the eight output signals of the decoder, and a feedback voltage FB1 of the current detection transformer 10 according to the operation of the eight transistors. A switching transistor Q10 for switching and controlling the magnetron 1 driving transformer 11 by a voltage divider R1-R16 and a diode D1-D8 for dividing the voltage and the feedback voltage FB2 through the eight diodes. Inverter output control circuit of the microwave oven, characterized in that the control unit 20 is configured to control the output of the microwave continuously.