KR880001150B1 - Power circuit - Google Patents

Abstract

The AC power supplying circuit includes a relay control (3) connected between AC power input plut (1) and AC output plug (2). Connected between the plug (1) and the control (3) are transistor (4), battery charger (5), battery charge control (6), battery (7), inverter (8), transformer (9), low voltage cut-off switch (10), and inverter drive circuit (11). With a detection of power failure, the DC power converted from AC and charged at a voltage in battery (7) is converted back into AC by inverter (8) and is supplied through transformer (9) and relay control (3) to AC output (2).

Description

Ac power supply circuit

1 is an overall block diagram illustrating the present invention.

2 is a circuit diagram showing a first embodiment of the present invention.

3 is a circuit diagram showing a second embodiment of the present invention.

In the present invention, when the power supply is cut off due to a power failure when using a computer, a communication device, and other home appliances in operation, DC power is charged to the battery during energization so that AC power of the rated voltage can be continuously supplied regardless of the power failure. The present invention relates to an AC power supply circuit invented so that power can be output by a sensor.

Conventionally, there was a circuit for power supply in case of power failure, but in general, AC power is rectified and reduced to DC power and configured to draw out DC power charged in a battery. There was a problem that the supply circuit cannot be used. The present invention solves the conventional problems as described above with reference to the accompanying drawings in detail the configuration and operation effects as follows.

1 is a block diagram illustrating the overall configuration of the present invention. The relay control unit 3 is connected between a line connecting the AC power input plug 1 and the AC power output plug 2, and the AC power input plug ( 1) between the relay control unit 3 and the transformer 4, the battery charging unit 3, the battery charging control unit 6, the battery (7), D / A (DC / AC) converter (8), transformer (9) ), The low voltage interrupter 10 and the converter driver circuit 11 are connected to each other.

When the power is supplied, the power supplied to the AC power input flag 1 is transferred to the AC power output plug 2 as it is by the operation of the relay controller 3, and at the same time, AC power is supplied to the transformer 4 to charge the battery part 5. The AC power input to) is full-wave rectified and converted into the DC voltage of the rated voltage and input to the battery charge control unit 6, and the battery charge control unit 6 can be supplied to the DC power battery 7 having a constant voltage. At the time of power failure, the relay of the relay control unit 3 is positioned as an opposite contact point at the time of charging so that the charged DC power of the battery 7 is converted from the D / C converter 8 to the AC power source to convert the transformer 9. The AC power is supplied to the AC power output plug 2 through the relay switch of the relay controller 3.

Here, the low voltage cut-off part 10 indicated by the dotted line is to cut off the power supply of the battery 7 by the operation of the relay when the battery 7 floats below the regular voltage, and is detachable as necessary. The furnace 11 is a circuit for driving the D / C converter 8 only for high output.

FIG. 2 is a circuit diagram showing the first embodiment of the present invention. When power is supplied to the AC power input plug 1 during energization, the switches SW.1 and SW.2 are operated by the operation of the relay K2. AC power is output from the positions of the contacts (a, c) to the positions of the contacts (b, d), and AC power is output to the output plug (2), and is simultaneously transmitted to the transformer (T2) to the secondary side of the transformer (T2). In the bridge rectifier circuit composed of diodes D1, D2, D3, and D4, the coil is full-wave rectified and transferred to the Darlington connected transistors Q3 and Q4. Here, the zener diode Z1 and the variable resistor R5 are for matching the reference voltage to the base of the transistor Q4. When the voltage of the battery is lower than the rated voltage, a large amount of current flows to the emitter of the transistor Q3, and as the battery gradually charges, the voltage applied to the transistors Q3 and Q4 decreases to a low point, thereby decreasing the transistor Q4. ) Is gradually turned off, and the transistor Q3 is supplied with a current enough to keep the relay K1 in an operating state (the switch SW.3 is positioned from the contact e to the contact f). The diodes D5 and D6 protect the battery 7 and the battery charger 5 and prevent the reverse current from the relay K1.

Since the relays K1 and K2 do not operate during a power failure, the switches SW.1, SW.2, and SW3 are connected at the positions of the contacts b, d, and f. It returns to a), (c) and (e). Accordingly, the DC power charged in the battery 7 is input to the bases of the transistors Q1 and Q2 through the primary coil of the transformer T1. At this time, the transistors Q1 and Q2 have an oscillation frequency signal oscillated by the time constant values of the resistors R1, R2, and R3 and the capacitor C1, which alternately triggers the base to operate the secondary side of the transformer T1. The square wave is generated in the power supply so that AC power is supplied through the AC power output plug 2 through the switches SW.1 and SW.2.

3 is a circuit diagram showing a second embodiment of the present invention, which is a high output AC power supply circuit. When power is supplied to the AC power input plug (1) during energization, the relay (K11) operates to switch (SW.4) and (SW.5) to the contacts (h, j) at the positions of the contacts (g) and (i). Switch (SW.8) and (SW.9) of relays K12 and K13 move away from the positions of contacts o and p and switch SW. 6), (SW.7) is in the position of the contact (km).

Therefore, the AC power is transmitted to the terminals L1 and L2 of the transformer T12, and the voltage is stepped down at the secondary side of the transformer T12 to be full-wave rectified and rectified through the diodes D17 and D18. The cathode end of the thyristor SCR is caught. When the voltage of the battery 7 is lower than the rated voltage, the transistor Q17 causes a current to flow in the collector to drive the gate of the thyristor SCR. At the same time, a portion of the voltage of the battery 7 is applied to the base of the transistor Q18 so that the resistor R26 is varied so that the transistor Q18 is turned on when the battery 7 is fully charged.

That is, as the transistor Q18 is conducted when fully charged, the transistor Q17 is turned off. The thyristor SCR conducted by the transistor Q17 is turned on for half a period and then turned off again, but supplies some current to the battery 7 through the resistor R29.

During power failure, the relay K11 stops operating, and the switches SW.4 and SW.5 switch to the positions of the contacts g and i, and the coils of the relays K12, K13 and K14 Current flows from the battery (7), and the switches (SW.8) and (SW.9) of the relays (K12) and (K13) are connected to the positions of the contacts (o) and (p) and the switches of the relay (K14). (SW.6) and (SW.7) switch from the position of the contact (k, m) to the position of the contact (i, n).

Here, the diodes D11, D12, and D19 are for blocking the reverse current generated from the relay.

The constant voltage regulator RG outputs a constant voltage to the output terminal, and inputs it through pin7 so that the timer IC1 operates according to the time constants of the resistors R11, R12, R13 and the capacitor C14. Outputs a 60Hz square wave and inputs it to an unstable multivibrator composed of transistors (Q11), (Q12), resistors (R16), (R17), (R18), (R19), capacitors (C17), and (C18). The transistors Q11 and Q12 are alternately turned on and off to drive the transistors Q13 and Q14 of the Darlington connection connected to the resistors R22 and R23 to alternately turn on and off the transistors Q11 and Q12. INVERTER) Transistors Q15 and Q16 are switched.

Therefore, the square wave is generated through the transformer T12 to supply AC power to the AC power output plug 2 through the switches SW.6 and SW.7.

If the voltage falls below the specified voltage while the charging voltage of the battery 7 is discharged, an error occurs in the battery 7. Therefore, when the voltage of the battery 7 goes down, the battery 7 and the D / A converter 8 The relay (K15) connected between) operates so that the switch SW.10 switches from the position of the contact r to the position of the contact q to cut off the power supply below the specified voltage from the battery 7. .

The operation process when the battery 7 falls below the specified voltage will be described.

When the voltage of the battery 7 falls below the specified voltage, the base voltage of the transistor Q19 adjusted by the variable resistor R32 is dropped and the transistor Q10 is turned off.

At this time, the transistor Q20 is turned on to operate the relay K15 so that the switch SW.10 is positioned at the contact q, and when the AC power is applied, the resistor R34 and the diode D21 are turned on. Current flows to turn on the transistor Q19, which in turn turns off the transistor Q20, so that the switch SW.10 of the relay K15 is located at the contact point r, and is brought into a short circuit state.

As described above, the present invention has been invented so that it does not interfere with the work at all by supplying rated AC power to household appliances of electric and electronic devices even during a power failure.

Claims (1)

As described in the text and shown in the drawings, a relay control unit 3 is connected between a line connecting the AC power input plug 1 and the AC power plug 2, and a line connected to the AC power input plug 1. To the transformer (4), the battery charging unit (5) to the transformer (4), the battery charging control unit (6) connected to the output terminal of the battery charging unit (5), the battery charging control unit (6) to the output terminal Connect the battery (7) and connect the D / A converter (8) to the battery (7) output, but connect the power source of the battery (7) between the battery (7) output and the D / A converter (8). It is possible to connect the low voltage cut-off part 10 in case the voltage falls below the rated voltage, and connect the AC power converted by the D / A converter 8 to be output through the transformer 9, If necessary, the converter driver circuit 11 is connected to the D / A converter 8 so as to drive the D / A converter 8, and The output terminal of the beamer 9 is connected to the relay control unit 3 so that the AC power can be continuously supplied from the AC power output plug 2 by the operation of the relay control unit 3 during power failure and when energizing. AC power supply circuit.

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