KR100347102B1 - Power Supply Circuit For Microwave Oven - Google Patents

Abstract

The present invention relates to a microwave oven, and more particularly, a power supply circuit of a microwave oven that can implement a circuit while reducing manufacturing costs by integrating each power supply unit for supplying power to a microprocessor and a light emitting diode of a microwave oven. It is about. The present invention is configured to integrate a microprocessor power supply unit and a light emitting diode power supply unit into one, and to supply power to the microprocessor and the light emitting diode in the integrated power supply circuit. Therefore, the present invention makes it possible to simply configure the power supply unit and to reduce the number of elements.

Description

Microwave Oven {Power Supply Circuit For Microwave Oven}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microwave oven, and more particularly, to a power supply circuit of a microwave oven in which integrated power circuits are integrated by integrating respective power supply circuits for supplying power to a microprocessor and a light emitting diode of a microwave oven.

A microwave oven is a cooking device that cooks food, and refers to a cooking device that heats and cooks food using microwaves of several GHz bands.

Microwaves at several GHz generated in the microwave vibrate the molecules of the food to be cooked, and the temperature of the food is increased by the frictional heat between the molecules to enable cooking.

Microwave ovens include a device that requires a high voltage, such as a magnetron to generate microwaves, and a power supply for driving a device that requires low voltage, such as a microprocessor to control the operation of the magnetron or a light emitting diode that displays the operating state of the microwave.

Next, a microwave power supply circuit according to the prior art will be described.

The microwave power supply circuit according to the prior art is configured as shown in FIG.

1A is a microprocessor power supply unit for supplying power to the microprocessor, and B is a light emitting diode power supply unit for supplying power to the light emitting diode.

Part A of FIG. 1 is a full-wave rectification circuit composed of two diodes D10 and D20 and a capacitor C10, and resets a DC voltage output to the capacitor C30 through the constant voltage circuit P10 and the reset circuit RS10. Supply to the microprocessor (M10).

Part B of FIG. 1 is a half-wave rectifier circuit composed of a diode D30 and a capacitor C20, and a DC voltage output to the capacitor C40 through the constant voltage circuit P20 is used as a driving voltage of the light emitting diode L10. do.

As shown in FIG. 1, the two power supply units commonly include diodes D10, D20, and D30, capacitors C10, C20, and C30, and constant voltage circuits P10 and P20.

Next, an operation process of the microwave power supply circuit according to the related art will be described with reference to FIG. 1.

When the AC voltage is supplied to the microwave oven, the voltage is applied through the primary side of the transformer PT10 and the AC voltage decompressed through the secondary terminal is output.

Since the voltage of the secondary terminal of the transformer PT10 is an AC voltage which cannot drive the microprocessor M10, it should be converted into a DC voltage.

The diodes D10 and D20 and the capacitor C10 are connected to the secondary terminal of the transformer PT10 to output the reduced AC voltage to configure a circuit as shown in A.

The reduced AC voltage supplied through the secondary terminal of the transformer PT10 has a rectifying process of changing into a DC voltage while passing through the two diodes D10 and D20.

And while passing through the capacitor (C10) to obtain the improved DC voltage by removing the pulsation included in the DC power.

The DC voltage is insufficient as a driving power source because the voltage value is not constant and unstable to be used as a driving voltage of a precise and sophisticated device such as the microprocessor M10.

Therefore, the unstable DC voltage outputted is applied to the constant voltage circuit P10 to supply the improved DC power.

The DC voltage output from the constant voltage circuit P10 is connected to a terminal 28, which is a power terminal of the microprocessor M10, via a reset circuit RS10, and a negative voltage is connected to a terminal 14 to a negative voltage. The microprocessor M10 is driven.

Part B of FIG. 1 is a light emitting diode power supply unit for supplying DC power to the light emitting diode L10.

The secondary terminal of the transformer PT10 supplied to the light emitting diode power supply B and the secondary terminal of the transformer PT10 for supplying power to the microprocessor power supply A are different terminals.

That is, the transformer PT10 has a secondary terminal for supplying power to the microprocessor power supply unit A and another secondary terminal for supplying power to the light emitting diode power supply unit B.

The light emitting diode driver B forms a half-wave rectifier circuit by connecting one diode D30 and one capacitor C20 to the secondary terminal of the transformer.

Since the precise DC voltage is not required for the LED driver B like the microprocessor M10, the DC driver supplies the DC voltage using a half-wave rectifier circuit.

In order to improve the DC voltage to a driveable DC voltage, the DC voltage is supplied to the constant voltage circuit P2 to supply a stable DC voltage through the capacitor C40.

The DC voltage is supplied as driving power to the anode terminal of the light emitting diode L10 which is connected to the resistor R10 of the transistor Q10 and constitutes a circuit.

Next, an operation process of the light emitting diode L10 will be described.

When a driving signal is generated in the microprocessor M10 and a signal is input to the base terminal of the transistor Q10, the transistor Q10 is turned on to conduct the collector and the emitter.

Therefore, the power supplied from the capacitor C40 and the light emitting diode L10 form a closed circuit, and the light emitting diode L10 emits light by the DC power.

As described above, the microprocessor power supply A and the light emitting diode power supply B receive a voltage from different secondary terminals of the transformer PT10, but the ground terminal of the reset circuit RS10 and the light emitting diode driver B By connecting the ground terminal of), make the same ground power supply to prevent potential difference.

In the conventional microwave power supply circuit which operates as described above, voltage circuits for generating driving voltages of the microprocessor M1 and the light emitting diode L10 are provided.

Therefore, since two independent power supply circuits are configured, the number of devices included is increased, the circuit becomes complicated, and the manufacturing cost increases when the circuit is configured.

In addition, in the power circuit in which each power circuit is dualized as in the prior art, the secondary side of the transformer PT10 is supplied to supply the voltage output through the secondary side of the transformer PT10 to each of the power supplies A and B. The number of terminals must also increase. Therefore, the transformer according to the prior art has a problem of reducing the efficiency of the transformer caused by the additional use of the transformer secondary terminal.

Accordingly, an object of the present invention is to provide a microwave power supply circuit that can reduce the manufacturing cost and improve the efficiency of the transformer by configuring a power supply circuit in which the microprocessor power supply unit and the light emitting diode power supply unit are integrated.

1 is a power supply circuit of a microwave oven according to the prior art

2 is a power supply circuit of a microwave oven according to the present invention.

Explanation of symbols on the main parts of the drawings

A: microprocessor power supply section M10, M20: microprocessor

B: light emitting diode power supply PT10, PT20: transformer

P10, P20: constant voltage circuit

A microwave power supply circuit according to the present invention for achieving the above object comprises a microprocessor for controlling the cooking operation of the microwave; A light emitting diode under the control of the microprocessor and displaying an operating state of the microwave oven; A transformer for generating first and second voltages having heterogeneous magnitudes; A half-wave rectifier connected to a secondary side of the transformer and configured to half-wave rectify a first voltage; A full-wave rectifier connected to the secondary side of the transformer and full-wave rectified by a second voltage; A capacitor group connecting a first capacitor between an output terminal of the half-wave rectifying unit and an output terminal of the full-wave rectifying unit, and a second capacitor connected between the output terminal of the full-wave rectifying unit and the ground terminal; And a constant voltage circuit configured to generate a driving voltage of the microprocessor and the light emitting diode as an output voltage of the full wave rectifying part passing through the second capacitor.

Hereinafter, a power supply circuit of a microwave oven according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram of a power supply circuit of a microwave oven according to the present invention.

Like the power supply circuit according to the prior art, the power supply circuit according to the present invention also includes a transformer PT20, diodes D15, D25, and D35, capacitors C15, C25, and C35, and a constant voltage circuit P30. .

However, in the present invention, unlike the prior art, the number of elements in the power supply circuit is reduced, so that the circuit configuration is simplified and the number of terminals of the transformer secondary side is reduced.

In the present invention, since the ground terminal is used in common while integrating the two power supply units A and B, the remaining unnecessary terminals are removed.

Therefore, the number of secondary terminals of the transformer PT20 is reduced, so that an improvement in the efficiency of the transformer PT20 can be expected.

Next, a connection relationship between the microwave power supply circuit according to the present invention will be described with reference to FIG. 2.

In the present invention, the diode D15, D25, and D35 anode terminals are connected to the secondary terminal of the transformer PT20, and the output voltage is supplied through the capacitors C15 and C25. The voltages output from the two capacitors C25 and C15 are input to the constant voltage circuit P30.

An output terminal of the constant voltage circuit P30 is connected to the capacitor C35 and a voltage is supplied to the reset circuit RS20 by connecting the capacitor C35 and an input terminal of the reset circuit RS20.

The terminal of the capacitor C35 is connected to supply a positive voltage to terminal 28 of the microprocessor and a negative voltage to terminal 14 of the microprocessor.

Unlike the related art, the DC voltage output using only one constant voltage circuit P30 is supplied to the reset circuit RS20 and the microprocessor M20 and used as a driving voltage of the light emitting diode L15.

Next, an operation process of the power supply circuit of the microwave oven according to the present invention will be described with reference to FIG. 2.

When the power is supplied to the microwave oven and the power is applied to the primary side of the transformer PT20, the AC voltage decompressed to the secondary side of the transformer PT20 is output.

In order to rectify the decompressed AC voltage supplied through the secondary transformer PT20 terminal, diodes D15, D25, and D35 and capacitors C15 and C25 are converted into DC power.

Through the two diodes D25 and D35, a full-wave rectified DC voltage is output to the capacitor C25, and a half-wave rectified DC voltage is output to the capacitor C15 through the diode D15.

The voltages output from the two capacitors C15 and C25 are used as a power source for a relay unit (not shown), and the voltage of the capacitor C25 to which the full-wave rectified voltage is output is input to the constant voltage circuit P30.

The DC voltage improved through the constant voltage circuit P30 is output to the capacitor C35, and the DC power is supplied to the reset circuit RS20 and the power terminal of the microprocessor M20 to drive the same.

In addition, the DC voltage output through the capacitor C35 is used as an input power source for driving the light emitting diode L15.

The light emitting diode L15 is connected to a resistor R15 connected to the collector terminal of the transistor Q20 to form a circuit with the DC power supply.

When the microprocessor M20 commands the driving of the light emitting diode L15, a command signal is input to the base terminal of the transistor Q20 connected to the output terminal of the microprocessor M20.

When a signal is input to the base terminal of the transistor Q20, the transistor Q20 is turned on and the collector and emitter are in a conductive state, and the light emitting diode L15 and the DC power supply form a closed circuit.

The light emitting diode L15 starts to be driven by the DC power supply, and if the microprocessor M20 stops the signal, the transistor Q20 is turned off and the power supply is cut off so that the light emitting diode L15 is turned off. Will stop running.

Therefore, it can be seen that the present invention enables the microprocessor and the light emitting diode to be driven through one power supply circuit.

As described above, the power supply circuit of the microwave oven according to the present invention comprises a power supply unit by integrating a microprocessor power supply unit and a light emitting diode power supply unit.

Therefore, the present invention can be simply configured in terms of circuit configuration or design, and it is possible to reduce material costs by reducing the number of unnecessary elements, and to enable economic circuit configuration.

In addition, since the power supply unit is integrated, there is an advantage that can improve the efficiency of the transformer.

Claims (1)

A microprocessor for controlling cooking operation of a microwave oven; A light emitting diode under the control of the microprocessor and displaying an operating state of the microwave oven; A transformer for generating first and second voltages having heterogeneous magnitudes; A half-wave rectifier connected to a secondary side of the transformer and configured to half-wave rectify a first voltage; A full-wave rectifier connected to the secondary side of the transformer and full-wave rectified by a second voltage; A capacitor group connecting a first capacitor between an output terminal of the half-wave rectifying unit and an output terminal of the full-wave rectifying unit, and a second capacitor connected between the output terminal of the full-wave rectifying unit and the ground terminal; And a constant voltage circuit configured to generate a driving voltage of the microprocessor and the light emitting diode with an output voltage of the full wave rectifying portion passing through the second capacitor.