KR920004819Y1 - Control circuit of detecting different voltage in x-ray and the source of electron - Google Patents

Abstract

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Description

Abnormal voltage detection control circuit of X-ray and power supply

1 is a circuit diagram of a conventional design.

2 is a circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

10: Regulator 20: SMPS Power Stage

30: abnormal voltage detection control unit 40: abnormal voltage detection unit

R1-R12: Resistor BD1, BD2: Bridge Diode

C1-C7: capacitor D1-D6: diode

T1: transformer ZD1: Zener diode

FBT: flyback transformer Q1-Q3: transistor

RY: Relay SW1: Relay drive switch

Lo: Drive coil B ⁺ : Main power

B1 ⁺ : Standby power source B2 ⁺ : Flyback transformer secondary side power source

The present invention detects the high-voltage rise of the flyback transformer and the abnormal voltage of the switching mode power supply (SMPS) power stage in the power supply circuit of the TV, and the X-ray and the power stage to cut off the AC input. It relates to an abnormal voltage detection control circuit.

Conventionally, as illustrated in FIG. 1, an AC input input to the bridge diode BD is applied to the relay RY as a standby power supply through the transformer T1 and the standby power supply stage 5.

At this time, when the power key of the remote controller (not shown) is pressed, the microcomputer outputs the 'high' level, which is the power 'on' signal, to drive the transistor Q1, and thus the standby power output from the standby power stage 5 is connected to the relay RY. The relay driving switch SW1 is 'on' by flowing to the ground through the driving coil Lo and the transistor Q1.

Therefore, the input AC input is rectified and smoothed through the bridge diode BD and the condenser C5 via the relay drive switch SW1 of the relay RY, and then applied to the SMPS power stage 20. Accordingly, the SMPS power stage The switching pulse generated at 20 is rectified smoothly through the diode D6 and the capacitor C7, and then the main power source B ⁺ is applied to the primary side of the flyback transformer (not shown).

At this time, when the main power supply (B ⁺ ) through the SMPS power stage 20 rises due to the load abnormality, a separate abnormal voltage detection circuit is not configured so that an abnormal voltage is caused on the secondary side of the flyback transformer. There was a defect that caused a very large adverse effect.

In other words, when the main power supply (B ⁺ ) rises due to abnormal load, the horizontal oscillation can be stopped by the X-ray cut-off circuit built in the horizontal drive stage. Since the main power source B ⁺ outputted from the power supply stage 20 is continuously applied to the primary side of the flyback transformer, an abnormal voltage is generated on the secondary side of the flyback transformer, which causes a very large adverse effect on the entire system.

Therefore, the purpose of the present invention is to detect the high voltage rise of the flyback transformer that generates X-rays and the abnormal voltage generation of the SMPS power supply to block the AC input to protect the entire system. Detection means for detecting an abnormal voltage generated at the high voltage rise and the SMPS power supply terminal and switching means for controlling the AC input by switching to the output of the detection means.

The present invention is described in detail by the accompanying drawings as follows.

FIG. 2 is a circuit diagram according to the present invention, which rectifies and smoothes an AC input applied through a transformer T1 to apply a standby diode B1 ⁺ to a relay RY through a regulator 10 to a relay RY and a capacitor. (C4), the relay RY for controlling the input of the AC input by driving the transistor Q1 whose operation is selected as the power output of the microcomputer, and rectifying and smoothing the AC input input by the driving of the relay RY. The flyback transformer FBT by outputting the main power supply B ⁺ to the bridge diode BD2 and the capacitor C5 and the output of the bridge diode BD2 and the capacitor C5 to be applied to the SMPS power supply terminal 20. In the remote control type power supply circuit composed of the SMPS power supply terminal 20 to be applied to the primary side of the circuit, the main power supply B ⁺ and the resistor R10 of the SMPS power supply terminal 10 through the resistors R11 and R12 are connected. a flyback transformer secondary side power source (B2 ⁺⁾ of voltage from the foot through The abnormal voltage detection unit 40 configured to generate the Zener diode ZD1 for detecting the voltage and the abnormal voltage detection control unit driving the abnormal voltage detection output of the abnormal voltage detection unit 40 to cut off the power 'on' signal output of the microcomputer ( 30).

Here, the abnormal voltage detection control unit 30 configures the transistors Q2 and Q3 to be continuously driven by the abnormal voltage detection output of the abnormal voltage detection unit 40, and when the transistor Q2 is driven, It is configured to block the power 'on' output signal.

Hereinafter will be described the effect of the present invention.

Turn on the power switch (not shown) to turn on the AC input. Since the AC input is applied to the primary side of the transformer T1, the power generated from the secondary side of the transformer T1 turns on the bridge diode BD1 and the capacitor C4. After rectifying and smoothing, the regulator 10 is applied to the relay RY and the abnormal voltage detection controller 30 with a constant standby power supply B1 ⁺ .

At this time, when the power 'on' output signal is output from the microcomputer by key input of a remote controller (not shown), the output power 'on' output signal 'turns on' the transistor Q1 through the diode D5 and the resistor R2 to relay the power. The standby power supply B1 ⁺ applied to the (RY) flows to the ground through the transistor Q1, and the relay driving switch SW1 constituting the relay RY is 'on', while the microcomputer is operated by the key input of the remote controller. When the power 'off' output signal is output, the output power 'off' output signal 'turns off' the transistor Q1 through the diode D5 and the resistor R2 to apply the standby power supply B1 applied to the relay RY. ⁺ ) Is cut off so that the relay drive switch SW1 constituting the relay RY is 'off'.

The power output of the microcomputer, which is not shown here, is output at the 'high' level when the power is' on 'to' turn on 'the transistor Q1, and at the' off 'level when the power is' off' so that the transistor Q1 is' Turn off.

That is, when the power output of the microcomputer driving the relay RY is output as a power 'on' output signal, the input AC input is rectified smoothed through the bridge diode BD2 and the capacitor C5 via the relay RY, and then SMPS. The switching pulse applied to the power supply terminal 20 and generated in the SMPS power supply terminal 20 is rectified and smoothed through the diode D6 and the capacitor C3 to the desired power, and then output to the main power supply B ⁺ . It is applied to the primary side of the fly back transformer (FBT) through the line.

In addition, when the power output of the microcomputer driving the relay RY is output as a power 'off' output signal, the input AC input is cut off from the relay RY, and the work of the flyback transformer FBT is transmitted through the SMPS power stage 20. The main power source B ⁺ applied to the vehicle side is not supplied.

As described above, the main circuit is applied to the SMPS power stage 20 that outputs the main power source B ⁺ in the remote control power circuit that controls the supply of the main power source B ⁺ as the power 'on' output signal of the microcomputer. When the abnormal voltage is generated from the flyback transformer (FBT) which outputs the flyback transformer (B2 ⁺ ) from the secondary side to the power supply (B ⁺ ), it stops the operation of the system and at the same time the flyback transformer (FBT) It is to cut off the AC input input to the SMPS power stage 20 for supplying the main power (B ⁺ ) to the primary side.

That is the main power source (B ⁺⁾ of the over-voltage resulting from the SMPS power supply terminal 20 for outputting a main power supply (B ⁺⁾ to the anomalies of the system or SMPS power stage 20 is applied to the primary side ply at the secondary side When the X-ray is generated by the abnormal voltage generation from the flyback transformer FBT generating the back transformer secondary side power source B2 ⁺ , the abnormal voltage detection control unit 30 detects the X-ray. ) To cut off the power 'on' output signal of the microcomputer and the relay (RY) is driven to 'off' state to cut off the AC input.

The SMPS power stage 20 is divided into the case where an abnormal voltage is generated in the SMPS power stage 20 that outputs the main power source B ⁺ and when X-ray occurs due to an abnormal voltage generation on the secondary side of the flyback transformer FBT. And when the normal voltage is output from the flyback transformer FBT, the zener diode ZD1 of the abnormal voltage detector 40 maintains the blocking state, but the main power source B ⁺ of the SMPS power terminal 20 is higher than normal. The Zener diode ZD1 is in a conductive state, so that the flyback transformer generated on the secondary side of the flyback transformer FBT to which the base of the transistor Q2 is applied at the 'high' level and the main power source B ⁺ is applied. Even when the secondary power supply B2 ⁺ is higher than the normal state, the zener diode ZD1 is in a conductive state, and a 'high' level is applied to the base of the transistor Q2.

Accordingly, the transistor Q2 is 'turned on' due to the abnormal voltage of the SMPS power stage 20 and the flyback transformer FBT through the zener diode ZD1, and the base side of the transistor Q3 is driven by driving the transistor Q2. Low level, transistor Q3 is also turned "on"

Therefore, the power 'on' output signal of the microcomputer that applied the AC input to the SMPS power supply terminal 20 through the bridge diode BD2 by driving the transistor Q1 to turn on the relay RY is the diode D2 and Since the transistor Q2 flows to the ground, the transistor Q1 is 'turned off' and the relay RY is 'off' to cut off the AC input through the relay RY.

This is because the system cuts off the AC input input to the SMPS power stage 20 by cutting off the power output of the microcomputer when an abnormal voltage occurs in the SMPS power stage 20 or an abnormal voltage occurs on the secondary side of the flyback transformer (FBT). You can protect the whole.

As described above, the present invention detects this by using a Zener diode when an abnormal voltage occurs in the SMPS power terminal or an abnormal voltage occurs in the secondary side of the flyback transformer, and then blocks the AC input by blocking the power 'on' output signal of the microcomputer. Therefore, there is an effect that can protect the system safely in case of abnormal voltage.

Claims (2)

The main power supplied through the bridge diode BD2 and the SMPS power stage 20 is driven by driving the relay RY to which the standby power B1 ⁺ is applied via the bridge diode BD1 and the regulator 10 to the power output of the microcomputer. in the remote control system power supply circuit for controlling the power (B ^+), a resistance (R11) a flyback transformer secondary side through the main power supply (B ⁺⁾ and a resistance (R10) of the SMPS power stage 20 with (R12) The power supply 'ON' of the microcomputer is driven by the abnormal voltage detection unit 40 including the zener diode ZD1 for detecting the occurrence of the abnormal voltage from the power supply B2 ⁺ and the abnormal voltage detection output of the abnormal voltage detection unit 40. The abnormal voltage detection control circuit of the X-ray and power supply stage which comprised the abnormal voltage detection control part 30 which interrupts a signal output. The abnormal voltage detection controller 30 is configured such that the transistors Q2 and Q3 are continuously driven by the abnormal voltage detection output of the abnormal voltage detection unit 40, and the diode D2 is driven when the transistor Q2 is driven. The abnormal voltage detection control circuit of X-ray and power stage configured to block the power 'on' output signal of the microcomputer.