KR960001567Y1 - Voltage automatic circuit - Google Patents

Abstract

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Description

Voltage automatic switching circuit

1 is a voltage automatic switching circuit diagram of the present invention.

2 is an output waveform diagram of each part of the present invention.

* Explanation of symbols for main parts of the drawings

10: zero crossing circuit 20: voltage sensing circuit

30: two-division circuit 40: relay switch

50: trance

The present invention relates to a voltage automatic switching circuit, and more particularly to a voltage automatic switching circuit that automatically generates a constant output voltage by sensing the input voltage of 100V or 220V.

In the conventional voltage switching circuit, a voltage selection control switch 40 (a-b: a'-c ') and a transformer 50 are connected to each other to form a power supply circuit for step-down or step-up.

When 220V power is applied to the input terminal of the step-down power circuit, the select switch terminal 40 is connected to the 100V output side (a-b ') so that the voltage stepped down to 10OV from the transformer is output and power of 10OV is applied. In this case, the select switch terminal 40 is connected to the opposite axis (a'-c ') so that the power of 100V is output to the output terminal.

In the boosting power supply circuit, the reverse operation was performed so that the 220V power was output when the 100V power supply was stepped up.

However, such a voltage switching circuit has the inconvenience of manually operating a separate switch according to the input voltage, and if the user inputs 220V in a state where it is fixed at 100V due to carelessness, the product may cause serious damage or severe cases. There are disadvantages that include the risk of fire.

Therefore, the present invention has been devised to solve the above-mentioned conventional problems, and an object of the present invention is to provide a voltage automatic switching circuit for keeping the output constant at all times regardless of whether the input voltage is 100V or 220V. have.

As a technical configuration for realizing the object of the present invention described above, the input power is sensed as a primary zener diode, the primary relay is driven at 100 V, and the input is sent as an output. When the input power is 220 V, the secondary side of the transformer is used. SCR also detects the signal and operates it as the clock of D-type flip-flop, and operates the phototriac every two cycles by using an end-gake that operates only when the output signal of the clock and the flip-flop are simultaneously "high." It is turned on so that 10OV comes out as an actual output.

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

1 is a voltage automatic switching circuit of the present invention, after rectifying an input power source, a voltage sensing circuit 20 for driving a relay RYl according to a sensing source of the rectified value by a zener diode ZDI, and the relay RYl. Relay switch 40 for switching the input power and the input power through the transformer 50 and the rectifier diode part BD2, which are controlled by A two-dividing circuit 30 for outputting the fill wave by the element T4, and a zero-crossing circuit 10 for dividing the input power by two pulse pulses output from the two-dividing circuit 30 and outputting only a half-period signal. It consists of.

Hereinafter, the operation and the effect of these will be explained. When a 100 V AC power is applied to the input power supply terminal, the zener diode is divided by the voltage resistor R1 (R2) through the bridge diode ZDI of the voltage sensing circuit 20. Contact when caught on cathode side of (ZDI) The voltage applied to is lower than the breakdown voltage of the zener diode ZDI, so the zener diode ZDI is turned off, so the triac T3 is turned on because there is no pulse applied to the gate of the triac T2. .

Accordingly, the relay RY1 is operated to be connected to the contact-on b of the relay switch 40 so that the input AC power does not pass through the triac Tl which is turned off and immediately appears at the output terminal OUTl.

On the other hand, when an AC power source of 220V is applied to the input power terminal, the voltage divided by the resistors R1 and R2 of the voltage sensing circuit 20 is greater than the voltage of the zener diode ZDI. Is conducted, so that a voltage is applied to the gate of the triac T2 so that the triac T2 is turned on.

When the triac T2 is turned on, no voltage is applied to the gate of the triac T3, so that the triac T3 is turned off.

Therefore, the relay switch 40 is connected to the connection terminal b 'as it is.

Here, the voltage passing through the transformer 50 through the connection terminal a-b ′ of the relay switch 40 is equal to the voltage of waveform 2 in FIG. 2 via another bridge diode BD2. It is applied to the frequency division circuit 30.

Then, the contact point of the two frequency divider circuit 30 In Fig. 2, a voltage similar to waveform (b) of FIG. 2 appears, and this voltage is converted into a square wave through the diode D6, the resistors R8, R9, and the zener diode ZD2, so that the D-type flip-flop 31 It acts as a clock signal to the clock stage CLK.

The flip-flop 31 receives the clock signal and outputs the output Q according to the clock signal as shown in the waveform D of FIG. 2, and the AND gate 32 when the click signal and the output Q signal coincide with each other. ) Is turned on and its output comes out as waveform E in FIG.

Since the prototriac T3 is turned on only when the output of the AND gate 32 is high, the SCR T1 of the zero crossing circuit 10 is turned on each time and actually contacts. In 2 input cycles, a two-divided signal is outputted every one cycle, so that 10OV of the same power can be supplied.

As described above, the present invention detects 100V or 220V by a zener diode to drive a relay, and at 100V, the input appears as it is, and at 220V, only one cycle is performed every two cycles through a zero crossing circuit and a two-division circuit. It is divided into two outputs and outputs the same power as 100V automatically, so there is an excellent effect of eliminating inconvenience and risk by manual operation.

Claims (1)

(Correction) a voltage sensing circuit which rectifies the input power and operates the relay according to the rectified value detected by the zener diode, A relay switch for switching an input power transmission path according to the operation of the relay; A two-dividing circuit for dividing the input power output from the relay switch by two and outputting a half-period pulse wave by the optical element; And a zero-crossing circuit for outputting a half-period waveform by dividing the input power by two by the pulse wave detection output from the optical element.