KR900002160Y1 - Solenoid driving circuit of electronic range - Google Patents

Abstract

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Description

Solenoid drive control circuit of multifunctional microwave oven

1 is a conventional circuit diagram.

2 is an explanatory diagram showing the voltage variation according to the solenoid driving.

3 is a solenoid drive control circuit diagram of the present invention.

4 is an explanatory diagram showing a voltage variation according to solenoid driving.

* Explanation of symbols for main parts of the drawings

1: stop 2: micom

TR ₁ , TR ₁₀ : Transistor S: Solenoid

R ₁₂ : load resistance R ₁ , R ₂ , R ₁₀ , R ₁₁ : resistance

In the present invention, the solenoid drive control of the multi-functional microwave oven, in which the operating voltage applied to the solenoid, is lowered to a constant voltage at the initial stage of operation to maintain a low voltage necessary for maintaining the solenoid, thereby minimizing the voltage fluctuation rate. It is about a circuit.

In the conventional solenoid driving circuit, as shown in FIG. 1, the AC power source AC is connected to the primary side T ₁₁ of the low voltage transformer T ₁ , and the secondary side T _{12 thereof is} connected to the diode D ₁ . (D ₂ ) and via the condenser (C ₁ ) to the current device (1), the output side of the stop value (1) is connected to the operating power supply terminal (V _CC ) (V _SS ) of the microcomputer (2) to its control signal output terminal resistor (R ₂₎ and a transistor diode connected to the base of (TR ₁₎ and, connected in parallel to its collector (D ₃₎ and a solenoid (S) to (CS) via a resistor (R ₁₎ It is connected and configured.

In the conventional circuit, when the AC power source AC is applied, the AC power source AC is applied to the primary side T ₁₁ of the low voltage transformer T ₁ , and a constant voltage is applied to the secondary side T _{12 thereof} . After being induced, the full-wave rectified operating voltage V ₀ is output to the diode D ₁ (D ₂ ) through the capacitor C ₁ , and the full-wave rectified operating voltage V ₀ is set to the stop value 1. It is applied to the operating power supply terminal V _CC (V _SS ) of the microcomputer 2, and at the initial stage of the power supply terminal, the microcomputer 2 outputs a low potential signal to its control signal output terminal CS ₁ and the potential signal is resisted. It is applied to the base of the transistor TR ₁ via (R ₁ ) so that it is off and the solenoid S is not driven.

In this state, when the high potential signal is output from the control signal output terminal CS ₁ of the microcomputer 2, the transistor TR ₁ is turned on so that the operating voltage V ₀ is applied to the solenoid S and the transistor TR ₁ . Since the ground through the solenoid (S) is driven.

At this time, the full-wave rectified operating voltage (V ₀ ) is greatly reduced (V ₁ ) as shown in FIG. 2 so that the solenoid (S) is not driven to maintain the operating voltage (V ₀ ) at the rated voltage. Since the initial operating voltage (V ₀ ) must be maintained at a voltage higher than the rated voltage, when a voltage higher than the rated voltage is input to the stop value (1), not only the component elements of the stop value (1) are damaged. The voltage fluctuation rate caused by the solenoid driving is severe, and when the transformer with a large capacity is used to minimize the voltage fluctuation rate, there are many defects of cost increase and power loss.

The present invention is designed to reduce the voltage fluctuation rate by reducing the voltage applied to the solenoid initially to the load resistance and applying a low voltage necessary for maintaining the solenoid drive after a certain time in view of such a conventional defect. Referring to the drawings in detail as follows.

3 is a solenoid drive control circuit diagram of the present invention, and as shown therein, a low voltage transformer (T ₁ ), a diode (D ₁ -D ₃ ), a capacitor (C ₁ ), a resistor (R ₁ , R ₂ ), and a stop value. (1), in a solenoid driving circuit composed of a transistor (TR ₁ ), a solenoid (S), and a microcomputer (2), the collector of the transistor (TR ₁ ) is connected to a resistor (R ₁₁ ) and a transistor through a resistor (R ₁₀ ). It is configured by connecting to the base of TR ₁₀ and connecting the load resistor R ₁₂ to the collector of transistor TR ₁₀ .

Referring to the effect of the present invention configured in this way in detail as follows.

After the power is applied to the AC power source AC, the applied power source is applied to the primary side T ₁₁ of the low voltage transformer T ₁ , and a constant voltage is induced to its secondary side T ₁₂ . After (D ₁ , D ₂ ) and the condenser (C ₁ ), the electronically rectified operating voltage (V ₀ ) is the operating power terminal (V _CC ) (V _SS ) of the microcomputer 2 via the stop value (1). Is applied to.

In this state, when the low potential signal is output from the control signal output terminal CS ₁ of the microcomputer ₁ , the low potential signal is applied to the base of the transistor TR ₁ through the resistor R ₁ , so that it is turned off. Therefore, the operating voltage V ₀ is applied as a bias voltage to the base of the transistor TR ₁₀ through the solenoid S and the resistors R ₁₀ and R ₁₁ , and at this time, the bias applied to the base of the transistor TR ₁₀ . When the voltage is set low so that the solenoid S is not driven, the solenoid S is not driven, and the transistor TR ₁₀ is turned on so that the operating voltage V ₀ becomes the resistor R ₁₂ and the transistor TR ₁₀ . since the ground through the operating voltage (V ₀₎ is a voltage drop occurs in the load resistor (R ₁₂₎ a fourth diagram is reduced (V ₁₎ from the initial operating voltage (V ₀₎ as shown in Fig.

When a high potential signal is output from the control signal output terminal CS ₂ of the microcomputer 2 after a predetermined time in the state where the solenoid S is stopped in the initial state of power supply, the transistor ( TR ₁ ) is turned on, and accordingly, the operating voltage V ₀ is grounded through the solenoid S and the transistor TR ₁ , so that the transistor TR ₁₀ is turned off and the operating voltage V ₀ is driven to the solenoid S. Since the voltage is applied and flows, the voltage across the solenoid S is reduced (V ₂ ) rather than the initial voltage (V ₁ ).

Thus, the solenoid (S) has the role of a voltage drop along the non-drive state by the voltage (V ₁₎ is stronger than the operating voltage (V ₀₎ by a load resistor (R ₁₂₎ after a period of time the driving of the solenoid (S) By maintaining the operating voltage (V ₀ ) is always kept below a certain voltage.

As described above, the present invention reduces the voltage applied to the solenoid initially to the load resistance and, after a certain time, applies the low voltage necessary for maintaining the solenoid, thereby minimizing the voltage fluctuation rate during the solenoid driving. The low pressure transformer can be used, and the cost reduction effect can be expected.

Claims (1)

Low voltage transformer (T ₁ ), diode (D ₁ -D ₃ ), capacitor (C ₁ ), resistor (R ₁ , R ₂ ), stop value (1), transistor (TR ₁ ), solenoid (S) and micom ( In the solenoid driving circuit of 2), the collector of the transistor TR ₁ is connected to the base of the resistor R ₁₁ and the transistor TR ₁₀ through a resistor R ₁₀ and connected to the collector of the transistor TR ₁₀ . by connecting a load resistance (R ₁₂₎ characterized in that the solenoid (S) that lowers the if not drive the load resistor operating voltage (V ₀₎ with (R ₁₂₎ controlled by the voltage required by the solenoid (S) and sustain drive Solenoid drive control circuit of multifunctional microwave oven.