KR920006056Y1 - Degaussing circuit - Google Patents

Abstract

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Description

Geomagnetic Field Circuit

Circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

5: power control unit 10: device control unit

15: delay unit Q1-Q4: transistor

RL1, RL2: Relay DS: Element coil

SW: selection switch

The present invention is a device circuit that prevents the earth magnetic field and shadow mask shadows in a TV using a CRT, and can drive the device coil only for a certain time when the power of the TV is 'on'. The present invention relates to a geomagnetic element circuit that allows a user to operate it arbitrarily.

In order to eliminate the magnetic field generated between the TV's shadow mask and the earth's magnetic field, the device coil was installed around the shadow mask of the CRT and the AC power was supplied to the device coil when the powder was 'on'.

However, conventionally, the AC power is applied to the device coil through a transistor, so when the power is 'on', the AC power flows through the device coil until the resistance value of the resistor rises, so the device operation is performed. Even after the device is turned on, as long as the AC power is supplied, a small current flows through the coil to the device coil, so the micro current at this time affects the screen deflection, which causes the screen to become unstable and causes power loss due to the small current. This was to be.

In addition, in large TVs, the device is operated only once when AC is input, and when the screen viewing occurs, the color purity decreases due to the influence of the earth's magnetic field, and the power cord has to be unplugged and then plugged in again.

In other words, since the device is operated through the position at the initial stage when the main AC power is cut off, the power cord must be unplugged and then plugged in again.

In consideration of this, the present invention allows the AC power to flow to the device coil only for a certain period of time when the power is 'on', and then completely cuts off the AC power applied to the device coil. In the TV of the remote control series which is driven by the power signal of the microcomputer and provided with a power control unit for controlling the set main power supply, and a relay for controlling AC power applied to the device coil, An element control unit is provided with a delay unit for delaying the power rectified by the flyback pulse of the flyback transformer for a predetermined time and operated by the delayed power supply and the power signal of the microcomputer to supply AC power to the device coil, and to control the driving device. It was made to connect.

At this time, the device control unit is provided with a selection switch that allows the user to arbitrarily select the device operation, and the time that AC power is supplied to the device coil is the delay time of the delay unit and the time of pressing the selection switch.

Thus, the present invention to drive the device coil for a certain time when the power 'on' while driving the device coil at the request of the user will be described in detail with reference to the accompanying drawings.

The present invention is provided with a power control unit (5) for controlling the operation of the main power supply relay (RL2) by the transistor (Q4) is selected as the power signal of the microcomputer and the AC power applied to the element coil (DS) In a TV of a remote controller series provided with a relay RL1 for controlling, a delay unit 15 is configured to delay a power supply rectified by a flyback pulse of a flyback transformer (FBT) for a predetermined time, and the delay unit 15 The device controller 10 is connected to the delayed power source and the microcomputer power signal to control the driving of the relay RL1.

In this case, the device controller 10 is supplied with a standby power source STB ⁺ and a transistor Q3 having a collector axis of the transistor Q4 connected to a base, and a collector and emitter side of the transistor Q3 connected to a delay unit ( The transistor Q2 to which the output power of 15 is applied to the base, the transistor Q1 connected to the collector and the base side of the transistor Q2, and the relay RL1 to the collector side, and the transistor Q2. The selector switch (SW) connected to the collector side and intermittent the standby power supply (STB ⁺ ) is connected.

The delay unit 15 is connected to the power supply rectified by the flyback pulse of the flyback transformer (FBT) to be charged to the capacitor (C2) through the variable resistor (VR1) and the charging voltage of the capacitor (C2) is Zener diode ( The anode side of the control diode ZD1 is connected to the cathode side of ZD1 and is connected to the base of the transistor Q2.

When the AC power flows to the device coil DS only for a certain time when the power is turned on, the present invention looks at the effect of the present invention, which allows the device to be operated simply by pressing the selector switch when desired. .

First, when AC power is supplied to the TV set, the standby power generation unit of the set (not shown) waits with the standby power (STB ⁺ ) supplied. If the power is not 'ON', the power signal of the microcomputer is low. Is output at the level to turn the transistor Q4 of the powder control part 5 'turn off', and the relay RL2 is not driven by the 'turn off' of the transistor Q4, so that the main power of the set is not turned on. .

In addition, since the collector side of the transistor Q4 is high level when the power is 'off', the base of the transistor Q3 of the element control unit 10 becomes high level, and the transistor Q3 is 'turned off' and thus the transistor Q2. ) Is 'turned off' and 'turns off' to transistor Ql by 'turning off' of transistor Q2, so that relay RL1 is not driven.

Therefore, when the AC power is turned on but the power is not in the 'on' state (when the power is 'off'), the relay RL1 is not driven so that the AC power is not supplied to the device coil DS, thereby preventing device operation.

When the power is turned on in this state, the power signal of the microcomputer is output at a high level, and the relay RL2 is turned on to supply the main power in the set by turning on the transistor Q4 of the power control unit 5. .

When the main power is supplied in the set, the flyback pulse is induced on the secondary side of the flyback transformer (FBT), rectified and smoothed by the diode (D6) and the capacitor (C4), and then supplied to another source (B ⁺ ). At the same time it is applied to the leading edge (15).

At the same time, since the base of transistor Q3 is turned low due to 'turn on' of transistor Q4, the emitter potential of transistor Q2 is raised, and the base of transistor Q2 is still low. It is a state.

(Because the power supply rectifying the flyback pulse of the flyback transformer FBT is delayed by the delay unit 15 and applied to the base of the transistor Q2, which will be described later.)

Accordingly, at the same time as the power 'on', the transistor Q2 is 'turned on' and the transistor Q1 is 'turned on' with the 'turn on' of the transistor Q2, so that the relay RL1 is 'on' and the relay RL1 is turned on. When turned on, AC power is applied to the device coil DS to perform device operation.

That is, the device operation starts with the power 'on' operation.

At this time, when the power is turned on, the main power is turned on to rectify the flyback pulse induced at the secondary side of the flyback transformer (FBT) through the diode D5 and then to the capacitor C2 through the variable resistor VR1. The charging time of the capacitor C2 is adjusted by varying the variable resistor VR1.

When the capacitor C2 gradually increases the charging voltage to increase the zener voltage of the zener diode ZD1, the zener diode ZD1 is turned on to apply a high level to the base of the transistor Q2, thereby turning on the transistor Q2. 'Turn off'.

When the transistor Q2 is 'turned off', the transistor Q1 is 'turned off' so that the relay RL1 is 'off' so that AC power is not supplied to the device coil DS, thereby completing the device operation.

That is, if the power signal of the microcomputer is output at the high level when the power is turned on, the device controller 10 drives the relay RL11 to supply AC power to the device coil DS, and the power signal of the microcomputer is output at the high level. Relay RL1 is operated by stopping the operation of the element controller 10 by applying a power source rectified by the secondary flyback pulse of the flyback transformer FBT to the element controller 10 after a predetermined time delay. Is 'off' to end the device operation.

As described above, the device operation of the device coil DFS starts with the power 'on', and the device operation is stopped after the delay time of the support unit 15 is performed after the device operation is performed for the delay time of the delay unit 15.

That is, the relay RL1 is turned on together with the power 'on' so that the device coil is maintained for a predetermined time until the voltage charged in the capacitor C2 of the delay unit 15 exceeds the zener voltage of the zener diode ZD1. When the AC power is applied to the DS and the delay time of the delay unit 15 has elapsed, the relay RL1 is turned off to cut off the AC power applied to the device coil DS so that the device operation is turned on. It is done only for a certain time.

When the user wants to perform the device operation again while viewing the screen, the user presses the selection switch SW.

When the selector switch SW is pressed, the standby power supply STB ⁺ is applied to the base of the transistor Q1, and the transistor Q1 is turned on to drive the C relay RL1. The power is turned on to perform device operation.

That is, the relay RL1 is driven while the selection switch SW is pressed to perform element operation.

As described above, the present invention operates the device coil driving relay during the delay time of the delay unit in the power-on 'on' operation so that the device can be operated. It is possible to perform the operation, eliminating the leakage current that flows unnecessarily to the device coil after the device operation, which can solve the instability of the screen and at the same time reduce the power consumption, and also can solve the inconvenience during the operation of the device again. will be.

Claims (3)

A relay for controlling the operation of the main power-supply relay RL2 is provided by the transistor Q4 whose drive is selected as the power signal of the microcomputer, and a relay for controlling AC power applied to the element coil DS. A remote control series TV equipped with (RL1), comprising a delay unit 15 for delaying a predetermined time for a power supply rectifying a flyback pulse of a flyback transformer (FBT), and An element magnetic circuit comprising: an element controller (10) which is operated by a power signal of a microcomputer and controls an operation of a relay (RL1). The device control unit 10 is a transistor Q3 is applied to the standby power supply (SRB ⁺ ) and the collector side of the transistor (Q4) is connected to the base, and the collector and emitter side of the transistor (Q3) A transistor Q2 connected to the output power of the delay unit 15 to the base, a transistor Q1 connected to a collector and a base of the transistor Q2, and a relay RL1 connected to a collector, and A geomagnetism device circuit comprising a selector switch (SW) connected to a collector side of a transistor (Q2) and configured to interrupt a standby power supply (STB ⁺ ) supply. 2. The delay unit 15 is characterized in that the power supply rectified by the flyback pulse of the flyback transformer (FBT) is charged voltage of the capacitor (C2) through the variable resistor (VR1) of the cathode side of the zener diode (ZD1) And the anode side of the zener diode (ZD1) is connected to a base of the transistor (Q2).