KR880000407Y1 - Supply voltage automatic switching circuit - Google Patents

Abstract

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Description

Supply voltage automatic switching circuit

Figure is a power supply voltage automatic switching circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

3: rectifier 4,12: voltage divider

17 Zener diodes 6,7 first and second comparators

21, 22, 23: first, second, third triac 28: single winding transformer

The present invention relates to a power supply voltage automatic switching circuit of electrical equipment and equipment, and more particularly to a power supply voltage automatic switching circuit designed to generate a predetermined desired voltage on the load side irrespective of the selection of the input voltage.

Most of the conventional electric equipment is equipped with a 100V / 220V switching switch, the inconvenience of having to manually switch the switch to select the voltage of the electric device with respect to the power supply voltage by the human hand and often inadvertent voltage to the electric device Incorrect selection of components has often caused damage to components and malfunction of electrical equipment.

Conventionally, there has been an automatic switching circuit of an electric device with respect to the power supply voltage to compensate for this disadvantage, but in the configuration, the circuit is complicated and when the relay is used, the operation of the relay is uncertain due to the change of the input voltage and the power consumed by the relay. In case of using a large lottery transformer, there are various problems such as a slight increase in the capacity of the transformer.

The present invention solves the above drawbacks, and converts AC into a stable output voltage of direct current using a bridge rectifier, and then applies these voltages to the first and second comparators and selectively applies the triac according to the output of the comparator. The conductive voltage is applied to the single winding transformer so as to generate a predetermined voltage on the load side, or directly to the load side to generate a predetermined voltage at all times. To this end, the present invention converts the supply voltage into a DC voltage of an AC constant voltage through a rectifier transformer and a bridge type rectifier, and applies the voltage divided resistor and the zener diode to the inverting terminal and the non-inverting terminal of the two comparators. These comparators have a low logic output and a high logic output, which in turn allow the comparator gates to perform bidirectional voltage control of AC connected to the output terminals of each comparator. It is designed to generate a predetermined voltage on the load side or to apply a power supply voltage directly to the load side by applying a triac selectively and conducting triac to conduct the triac. As a power supply voltage automatic switching circuit, a liver using a semiconductor Since it is made in a simple configuration, the reliability is increased, and the capacity of the transformer is smaller than in the case of using a lottery transformer.

The present invention will be described in detail based on the accompanying drawings.

In the figure, the bridge-type rectifier 3 is configured such that alternating current generates a predetermined stable voltage on the power supply side of the alternating current. This rectifier 3 is of general construction and is shown schematically in the drawing. Therefore, the power supply side voltage is applied to the primary side of the rectifying transformer 2 by the plug 1, and the secondary side voltage of the rectifying transformer 2 is converted from AC to DC by the bridge type rectifier 3 to be predetermined. It is generated with DC voltage of.

The predetermined DC voltage on the + side from the bridge rectifier 3 is simultaneously connected to the inverting input terminal of the first comparator 6 and the non-inverting input terminal of the second comparator 7 via the resistor 4. It is applied to the non-inverting input terminal of the first comparator 6 and the inverting input terminal of the second comparator 7 via the resistor 5.

Also, a predetermined voltage on the + side of the rectifier is individually connected to the first and second comparators 6 and 7 via the resistors 9 and 10. On the other hand, the -side terminal of the bridge type rectifier 3 is connected to the + side terminal of the rectifier by jumping the first and second comparators 6 and 7. At the connection point 11 between the resistor 4 and the connection point 14 of the inverting terminal of the first comparator 6, a resistor 12 is provided between the -side connection point 13 of the bridge-type rectifier 3, A Zener diode 17 has its anode side connected to the junction 16 between the resistor 5 and the junction 15 of the non-inverting terminal of the first comparator 6 and the cathode at its junction 18 on the rectifier side. The side is to be connected.

The output of the first comparator 6 is applied to the gate of the third triac 23 via a resistor 19, and the output of the second comparator 7 is transmitted through the resistor 20. 21, the gate of the second triac 22 is connected to the midpoint 24 of the resistor 19 and the third triac 23 to output the output from the first comparator 6 It is supplied simultaneously with the gate of the third triac. The first anode of the first triac 21 is directly connected to the plug 1 terminal of the input side of the power supply voltage, and the plug (1) terminal and the first anode midpoint of the first triac 21 ( 25 is connected to the first anode of the second triac 22.

In addition, the second anode of the first triac 21 is connected to the output terminal A on the load side, and at the same time, the second anode of the third triac 23 is the intermediate point 26 on the output terminal A side. ) Is connected. The first anode of the third triac 23 is connected to one side of the single winding transformer 28, and the second anode of the second triac 22 is connected to the lap portion T in the middle of the single winding transformer 28. Connected.

On the other hand, the other side of the single winding transformer 28 is connected to an intermediate point 27 in the middle of the output terminal B on the load side and the other terminal of the input side plug 1 of the power supply voltage to receive the power supply voltage directly.

According to the present invention configured as described above, when an AC voltage of 100 volts is applied to the input side plug 1 of the power supply voltage, the AC voltage is converted into a DC voltage V _D by the transformer 2 and the bridge rectifier 3. At this time, the voltage V _D is determined by the resistor 12 via the resistor 4, and the divided voltage (Equation 1) equals the ratio between the inverting terminal of the first comparator 6 and the second comparator 7. It is simultaneously applied to the inverting terminal.

… … … … … … … … … … Formula (1)

The voltage passing through the resistor 5 is simultaneously applied to the non-inverting terminal of the first comparator 6 and the inverting terminal of the second comparator 7 by the set voltage V _Z by the zener diode 17.

However, set voltage (V _Z ) is

Have a relationship with

Accordingly, the output of the first comparator 6 becomes a high logic output and the output of the second comparator 7 becomes a low logic so that a voltage V _D is applied to the output side of the first comparator 6. Is applied to the gates of the second and third triacs 22 and 23 via a resistor 19, the second and third triacs 22 and 23 are triggered and the first triac 21 is Since the output of the second comparator 7 is low logic, it is in a blocking state. Therefore, the 100 volt voltage applied to the input side plug 1 side of the power supply voltage conducts the first and second anodes of the second triac 22 via the midpoint 25 and then the single winding transformer 28. Is applied to the wrap part of the power supply and at the same time, the other end of the input side plug (1) of the power supply voltage is connected to the single-circuit transformer 28 via the intermediate point 27, so that the single-side transformer 28 is connected to the output terminals A and B on the load side. A voltage of 220 volts on the load side is applied by the step-up action of. On the contrary, if 220 volts of power is applied to the plug 1 on the input side of the power supply voltage, the DC voltage (V _D ) at the time of applying the 100 volts voltage becomes 2.2 times the DC voltage (2.2 V _D ) and the zener diode 17 is applied. Setting voltage (V _Z ) by Make the voltage bigger. Accordingly, since the voltage applied to the non-inverting terminal of the first comparator 6 is greater than the voltage applied to the inverting input terminal, the output of the first comparator 6 becomes low logic and the non-inverting terminal of the second comparator 7 Since the voltage input to is smaller than the voltage applied to the inverting input terminal, the output becomes high logic.

Therefore, the second and third triacs 22 and 23 are in a blocked state, and the first triac 21 is in a conductive state, so that a power supply voltage of 220 volts does not go through the single winding transformer 28 and directly loads a terminal ( Is applied to A) and (B).

As such, the present invention allows a predetermined voltage to be generated at the output terminal of the load side regardless of the input power supply voltage.

Claims (1)

In the automatic voltage supply switching circuit of an electric machine, a voltage of the voltage divider resistors 4 and 12 and a rectifier that divides the voltage to a predetermined voltage by a bridge-type rectifier 3 that converts alternating current into direct current is set to a predetermined voltage. A circuit composed of a zener diode (17) which is set to be equal to the voltage generated by the voltage dividers (4) and (12), and the inverting input terminal of the first comparator (6) and the non-inverting of the second comparator (7). An input terminal, a voltage of the zener diode 17 is connected to a non-inverting input terminal of the first comparator 6 and an inverting pressure terminal of the second comparator 7, and an output terminal of the first comparator 6 The ruler is simultaneously connected to the gates of the second and third triacs 22 and 23, and the output terminal of the second comparator 7 is connected to the gate of the first triac 21. Voltage automatic switching circuit.