KR960008170Y1 - T.v. relay-off circuit - Google Patents

Abstract

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Description

Relay off-circuit when the TV's main non-plus voltage rises

1 is a general television power supply circuit.

2 is a relay off circuit diagram of the television bifurcation (B +) main voltage of the present invention.

* Explanation of symbols for main parts of the drawings

R1-R5: resistor D1-D2: diode

Q1-Q3: Transistor Ry: Relay

T1-T2: S.M.P.S Trans ZD1: Constant Voltage Zener Diode

BD1-BD2: bridge rectifier circuit 10: flyback transformer (F.B.T)

20: Micom 30: abnormal voltage detection unit

40: relay control unit 50: relay switch off holding unit

The present invention relates to a relay off-circuit when the main B + voltage of the television rises. In particular, a flyback transformer (FBT) in which the rise of the voltage supplies power to the peripheral parts and the CRT inside the television when the main B + voltage (+132 V) is exceeded. The present invention relates to a relay-off circuit when the main B + voltage of a television is increased to prevent damage to a component that may be applied as it is.

1 is a general television power supply circuit diagram, in which power applied from the outside through the plug F is full-wave rectified by the bridge rectifying circuit BD1 and then transformed on the secondary side after being applied on the primary side of the SMPS transformer T1. The main B + voltage (ie: + 132V) is input to the flyback transformer (hereafter: FBT).

Since the FBT (10) is configured to convert the power supply to the power supply (B +) and CRT required for each of the television bar, in the conventional case, the main B + voltage output after transformation on the secondary side of the SMPS transformer (T1) ( That is, when + 132V) rises, the high voltage output to each power supply terminal of the television and the CRT rises, and an abnormality occurs, which may seriously damage the peripheral components and the CRT inside the television.

Therefore, the present invention has been made to solve the conventional problems, the relay by the abnormal voltage detection means, the false abnormal voltage detection means for monitoring the presence or absence of the main B + voltage output after the transformation on the secondary side of the SMPS transformer (T1) Relay control means for switching off the relay by controlling the switching pulse voltage for driving the main B + voltage supplied to the FBT to the relay switch off holding means for continually initiating the off state of the relay by the relay control means (ie: +132 V) It provides a relay off circuit when the main B + voltage rises in the TV, which can protect the peripheral parts and the CRT inside the TV by blocking the power applied from the outside through the plug (F) at the same time. The purpose is.

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

2 is a circuit diagram according to the present invention, a bridge rectifying circuit (BD2) for full-wave rectifying the AC power applied from the outside, SMPS transformer (T2) for transforming the power output from the bridge rectifying circuit (BD2) and FBT (10) receiving the main B + power supplied from the SMPS transformer (T2) through the point A and outputting the power supply terminal and the CRT of each TV, and whether the main B + power applied through the A point The abnormal voltage detection unit 30 that detects the abnormal voltage detected by the abnormal voltage detection unit 30 controls the switching pulse voltage output from the microcomputer 10 that was driving the relay Ry. The relay control unit 40 for turning off Ry and the relay control unit 40 for maintaining the off state of the relay Ry by the relay control unit 40 are continuously configured.

Effects of the present invention according to the above configuration will be described in detail with reference to the drawings.

1 shows that AC power (220 / 110V) applied from the outside, like a general television power supply circuit, is full-wave rectified by the bridge rectifier circuit BD1 and then applied on the primary side of the SMPS transformer T1 on the secondary side. The transformed main B + voltage (ie: + 132V) is configured to be input to the flyback transformer (hereinafter FBT) 10.

FIG. 2 is a circuit diagram illustrating a relay-off circuit when the television B + main voltage rises according to the present invention.

The AC power applied from the first plug F is full-wave rectified by the bridge rectifying circuit BD2, and is applied to the primary side of the transformer T2 and then transformed to the secondary side.

At this time, a part of the main B + voltage (ie: + 132V) applied to the secondary side is input to the R.B.T (10) for supplying the necessary power to each supply power terminal and C.R.T.

In addition, when the main B + voltage applied to the secondary side is normal + 132V, this potential is input from the point A to the abnormal voltage sensing unit 30 composed of the voltage divider R1-R2 and the constant voltage zener diode ZD1.

That is, the voltage applied to the abnormal voltage sensing unit 30 is applied to the cathode of the constant voltage zener diode ZD1 after voltage dividing by the voltage divider R1-R2.

On the other hand, due to the characteristics of the constant voltage zener diode ZD1 (for example: The transistor Q1 of the relay controller 40 is turned on and off since only the anode potential is applied.

Therefore, the switching pulse voltage (high potential) output from the microcomputer 10 is applied to the base terminal of the transistor Q2 of the relay control unit 40 to thereby conduct the transistor Q2.

That is, the standby by 12V rectifying the AC input flows from the collector side of the conducting transistor Q2 to the emitter side through the relay coil 3 of the relay Ry, and thus the relay coil 3 of the relay Ry. The exciter generated at turns on the relay switch 4 of the relay Ry.

As a result, the AC (220V / 110V) current input from the plug F is applied to the bridge rectifier circuit BD2.

On the contrary, when the main B + voltage applied to the secondary side is +132 V which is abnormally increased, the potential is abnormally increased from the point A, and the main B + is composed of a voltage divider (R1-R2) and a constant voltage zener diode (ZD1). It is input to the abnormal voltage detector 30.

That is, the abnormal voltage applied to the abnormal voltage detecting unit 30 is applied to the cathode of the constant voltage zener diode ZD1 after the voltage dividing by the voltage divider R1-R2, and at the same time, the base of the transistor Q1 of the relay controller 40 is divided. The transistor Q1 is turned on after being applied to the stage.

Accordingly, the switching pulse voltage (high potential) output from the microcomputer 10 which kept the relay driving transistor Q2 in the turn-on state is a reverse current prevention diode through point c in accordance with the conduction of the transistor Q1. Some current passing through (D2) passes from the collector side of the switching transistor Q1 to the emitter side through point d. The relay driving transistor Q2 is kept in the turn-off state.

Here, the B + voltage rises and repeats, and the transistor Q1 is repeatedly turned on and off. As a result, the on / off action of the relay switch 4 is repeated.

Therefore, when the voltage of B + rises momentarily, the relay switch off composed of the resistor R3-R5 and the transistor Q3 keeps the relay switch 4 of the relay Ry off before damaging the component and the CRT. The holding unit 50 is operated.

That is, some potentials which have passed through the reverse current prevention diode D2 through point c are divided by the divided voltages R3-R4 through point d and then applied to the base terminal of the switching transistor Q3.

At this time, the applied potential conducts the switching transistor Q3. The standby power supply B1 + passes through the collector terminal of the transistor Q3 through the voltage drop resistor R5 on the emitter side of the transistor Q3. Is continuously applied to the base end of the transistor Q1.

Therefore, when the B + voltage is unstable, the shaking (on / off repetition) of the relay switch 3 can be eliminated, and the bridge rectification is turned off by turning off the relay Ry connected to the AC power input input from the plug F. Do not apply to the circuit BD2.

As described above, the present invention is useful when the high pressure of the TV increases and at the same time the high pressure is applied to the FBT as it is to be applied to the FBT as it is to prevent significant damage to the surrounding components and CRT inside the TV. to be.

Claims (1)

A television comprising a bridge rectifier circuit BD2 for full-wave rectification, an SMPS transformer T2 for transforming a power supply, and an FBT 10 for outputting to each supply power supply terminal B + and a CRT, from the transformer T2. The abnormal voltage detection unit 30 that detects the abnormality of the main B + power supply, and the abnormal voltage detected by the abnormal voltage detection unit 30 may output the output switching pulse voltage of the microcomputer 20 driving the relay Ry. Television comprising a relay control unit 40 for controlling and turning off the relay Ry, and a relay switch off holding unit 50 for continuously maintaining the off state of the relay Ry by the relay control unit 40. Relay off circuit when main B + voltage rises.