KR930007542Y1 - Free voltage circuit - Google Patents

Abstract

No content.

Description

Automatic voltage switching device

1 is a block diagram of a conventional automatic voltage switching device.

2 is a circuit diagram of an automatic voltage switching device of the present invention.

3 is a flow chart of the microcomputer of the present invention.

* Explanation of symbols for main parts of the drawings

10: rectifier 20: constant voltage

30: reset unit 40: clock oscillation unit

50: waveform oscillation unit 60: switching unit

70: micom

The present invention relates to an automatic voltage switching device, which is particularly sensitive to the input voltage by the microcomputer when 220V is input while the parts of the product are connected to 100V, so that the parts of the product can match the input voltage so that the product can operate normally. It is suitable for that.

In the conventional automatic voltage switching device, as shown in FIG. 1, a rectifier 1 for converting an AC voltage into a DC voltage, a constant voltage device 2 for compensating voltage variation to obtain a constant voltage, and the rectifier device ( 1) and a voltage comparator 3 for discriminating the power supplied from the constant voltage device 2, and a switching device 4 operated by the voltage comparator 3.

The automatic voltage switching device having such a configuration rectifies the input voltage in the rectifier 1 and supplies it to the constant voltage device 2, and determines whether the voltage supplied from the constant voltage device 2 and the rectifier 1 is 100V or 220V. When the voltage comparing device 3 discriminates and supplies the necessary signal to the switching device 4, the switching device 4 switches to the driving power supplied from the rectifier 1 according to this signal, so that the product can operate normally. It will be possible.

The conventional automatic switching device described above has a problem that the voltage comparator 3 is composed of many electronic components such as a comparator, a resistor, a capacitor, and the like.

The present invention is devised to improve the above problems, which is to drive the voltage switching device by comparing the voltage by the time constant set in the microcomputer, so that each component can operate according to the input voltage.

This will be described in detail with reference to the accompanying drawings.

According to an embodiment of the present invention, as shown in FIG. 2, the rectifying unit 10 drops and rectifies the input voltage, and the constant voltage unit 20 and the constant voltage unit 20 convert the voltage applied from the rectifying unit 10 into a constant voltage. 20 generates a oscillation waveform and a clock generator 40 which is connected to the reset device 30 for resetting the microcomputer 70 to the voltage applied from the control unit 20 and the constant voltage unit 20 informing the operation time of the microcomputer 70. Waveform oscillator 50 for operating the microcomputer 70, and the voltage switching unit 60 for switching the input voltage by the output of the microcomputer 70.

In particular, the microcomputer 70 resets the power waveform supplied by the constant voltage unit 20 and the clock waveform supplied by the clock generator 40 and the oscillation waveform supplied by the waveform oscillator 50 and the microcomputer 70. The connection is configured to operate by the initialization of the reset device 30 for.

The action and effect of the present invention of such a configuration is by the bridge rectifier circuit (BD) for the input voltage is passed through the capacitor (C ₁ ) and the resistor (R ₁ ) of the rectifier 10, the voltage is dropped and then full-wave rectification The voltage converted to DC and rectified in the bridge rectifier circuit BD is applied to the constant voltage unit 20 through the smoothing capacitor C ₂ to reduce the ripple rate, and then converted to a constant voltage. 40 is applied to the reset unit 30 and the like.

At this time, the resistance value of the resistor R ₂ (R ₃ ) of the rectifier 10 is such that the split point b of the resistor R ₂ (R ₃ ) becomes 4V when the input voltage is 220V, and 2V becomes 110V. Set the resistance as much as possible.

Meanwhile, since the minimum power, clock waveform, and oscillation waveform are required for the microcomputer 70 to operate, the clock waveform unit 40 and the waveform oscillator 50 generate respective waveforms and supply the waveforms to the microcomputer 70. Let's go.

In this case, as shown in the flowchart of FIG. ₃ , the voltage of the split point b is determined by the resistors R ₂ and R ₃ of the rectifier 10, and thus the input terminal A of the microcomputer 70 is operated. Is applied to the microcomputer 70 is the input terminal (A) Voltage of V Read (step 21) the input terminal A ) Voltage (V ) Is greater than or equal to the constant voltage (Vcc) / 2 (step 22). ) To "low" (step 24), the output terminal G of the microcomputer 70 ) Stays current.

That is, since the normal state of the voltage switching unit 60 is switched to the load of 220V, the output terminal G of the microcomputer 70 ) Will not be converted.

In addition, the input stage (A ) Voltage (V ) Is less than the constant voltage (Vcc) / 2 output terminal (G) of the microcomputer 70 Is set to "high" (step 23), and the voltage switching unit 60 is switched to the opposite state.

That is, the terminal of the voltage switching unit 60 is switched to the 110V load so that the parts of each part operate properly to the 110V load.

Therefore, the present invention compares the voltage applied directly from the rectifying unit 10 by the microcomputer 70 to the constant voltage Vcc, and then determines the voltage switching unit 60 to drive the size much smaller than the conventional voltage and switching device. This makes the circuit simpler, especially cost-effective, and effective for all products used in areas with more than one input voltage.

Claims (1)

In the voltage switching device in which the stop value 1 is connected to the switching device 4 through the constant voltage device 2 and the voltage comparator 3, the voltage division is performed by the resistors R ₂ (R ₃ ) of the rectifier 10. Automatic voltage switching device, characterized in that consisting of a microcomputer 70 for operating the voltage switching unit 60 in response to the applied voltage compared to the constant voltage (Vcc).