KR200156833Y1 - The unnecessary radiation masking circuit due to degaussing coil - Google Patents

Abstract

The present invention relates to a CRT element circuit, and in particular, a flyback sub-pulse (-) is applied to the front of the CRT to satisfy the undesired radiant wave standard (TCO-92) in the degussing coil surrounding the CRT. The present invention relates to an unnecessary radiation blocking circuit using an element coil for blocking unwanted radiation.

In order to magnetize the CRT by a conventional device coil, the CRT has a surface resistance of 10 ³ Ω or less, so that unnecessary radiation is blocked, thereby disadvantageous in terms of price.

The present invention applies a flyback negative pulse to the element coil even when the element signal is not applied to the element coil, thereby attenuating and blocking unwanted radiation waves generated from the entire surface of the cathode ray tube. The resistance of 10 ³ Ω or less is enough to lower the price because it can expect the effect of blocking the unnecessary radiation of CRT even in 10 ⁹ Ω.

Description

THE CUTTING CIRCUIT OF UNWANTED RADIATIVE WAVE BY DEGAUSSING COIL

The present invention relates to a TV CRT device circuit, and more particularly, to an undesired radiation blocking circuit using a device coil to block unnecessary radiation by applying a flyback negative pulse to a device coil to which a device signal is not applied. .

Referring to the configuration of the electromagnetic wave preventing device of the conventional CRT with reference to FIG. 1, first, the AC power input unit (1) for supplying AC power, receiving the AC power supplied from the AC power input unit to limit the initial current The dummy diode TH1 for protecting the bridge diode BD1, the bridge diode BD1 for rectifying and converting the AC power input through the dummyster TH1 into a DC power source, and the bridge diode BD1. A DC output unit 2 for outputting a rectified output DC power, a control unit 3 for controlling AC power input to the dummyster TH1 and the element coil DL1, and control of the control unit 3 A relay RY1 for inputting AC power to the dummyster TH1 and the device coil DL1 by switching on and off, and receiving the power by the relay RY1 to limit the initial current to the device coil DL1. More output to The element TH1 and the element coil DL1 for receiving the AC power input through the dummyster TH1 and flowing the device current to element the CRT.

The control unit 3 includes a capacitor C1 for charging a voltage, a zener diode ZD1 for maintaining a constant voltage by the charging voltage of the capacitor C1 and outputting a bias voltage to the base of the transistor Q1. And a transistor Q1 for switching on by the bias voltage output from the zener diode ZD1 to output a voltage to the primary coil of the relay RY1 to control the relay RY1, and to switch in the transistor Q1. The transistor Q1 operates by discharging the voltage charged in the capacitor D1 which protects the relay RY1 by the voltage across the primary coil of the relay RY1 and the capacitor C1 when the power is turned off. And a switch SW1 for allowing the device coil DL1 to operate manually.

Reference numeral RW11 is a lead wire.

The device circuit for preventing the generation of electromagnetic waves, which is configured as described above, is applied to the dummy circuit TH1 when AC power is input from the AC power input unit 1, and the resistance value is initially increased and then the resistance value is lowered. By controlling the inrush current generated initially by limiting the initial current by the output AC power to the bridge diode (BD1), AC power applied through the dummy diode (TH1) from the bridge diode (BD1) To rectify and convert the DC power to the DC power and output the rectified DC power from the DC output unit 2 to the bridge diode BD1.

When the initial power input, the relay (RY1) switch 'A'-'B', 'D'-'E' terminals are connected, so the AC power supplied from the AC power input unit 1 is connected to the dummyster TH1. When applied, the dummyster TH1 restricts an initial current to flow in the element coil DL1 that is surrounded by the CRT, thereby magnetizing the CRT and causing the magnetization of the CRT.

At this time, the controller 3 receives a voltage to charge the capacitor C1, and because the charging voltage of the capacitor C1 is low, the zener diode ZD1 cannot operate, and thus the capacitor C1 of the capacitor C1 As the charge is completed and discharged, the zener diode ZD1 operates to apply a bias voltage to the base of the transistor Q1 to turn on the transistor Q1. When the transistor Q1 is turned on, 1 of the relay RY1 is turned on. The device coil DL1 is short-circuited by applying a voltage to the vehicle side coil, thereby stopping the device operation. In this case, the bridge diode BD1 operates normally.

In order to prevent unnecessary radiation appearing on the front of the CRT in conventional device circuits, it is necessary to apply a surface resistance value of 10 ³ Ω or less, so that unnecessary radiation can be blocked, which is a factor in the price increase and unnecessary radiation when the device signal is not applied. There is a problem that is difficult to attenuate.

In order to solve the conventional problems, the present invention applies unnecessary radiation waves appearing on the front side of the CRT by generating a flyback negative pulse to the element coil to block the unnecessary radiation, and to reduce the resistance of the CRT surface resistance. It is to lower the unit cost by blocking the unnecessary radiation even in 10 ⁹ Ω.

1 is a circuit diagram showing the configuration of a device circuit for preventing the generation of electromagnetic waves in the prior art

2 is a circuit diagram showing the configuration of the unwanted radiation wave blocking circuit by the device coil of the present invention

Referring to FIG. 2, a configuration of an unwanted radiation wave shielding device using the device coil of the present invention is as follows.

AC current input terminal AC for inputting AC current, transistor Q11 for switching output to the primary coil of relay RY11 by input of element signal DS, and ON by switching of transistor Q11. A relay RY11 for switching off and inputting an alternating current to the dummy coil TH12 and the device coil DL11; a dummy bus TH12 for limiting the input current to the device coil DL11; A device coil DL11 for magnetizing the CRT by flowing a device current through the switching of (RY11) and generating a pulse of a flyback negative (-) when the device signal DS is absent and applied to the device coil. It consists of a flyback negative pulse generator (11).

In addition, the flyback negative pulse generator 11 receives a driving signal HS and switches the transistor Q12 to a flyback transformer FBT and outputs the flyback by switching the transistor Q12. A flyback transformer (FBT) generating a back pulse, a comparator (IC1) for comparing the flyback pulses of the flyback transformer (FBT) and outputting them to a resistor (R14) and a capacitor (C12), and the comparator ( Charges and discharges by IC1) and receives a resistor R14 and a capacitor C12 that output a bias voltage to the base side of the transistor Q13, and a bias voltage input from the resistor R14 and the capacitor C12 to be switched. And a transistor Q13 for outputting the flyback negative pulse to the element coil DL11 through the relay RY11.

R11 to R14 are resistors, C11 to C14 are capacitors, D11 is diodes,

DY is a deflection yoke.

Referring to the operation of the unnecessary radiation blocking circuit by the device coil of the present invention configured as described above are as follows.

When the device signal DS is applied to the base of the transistor Q11 through the resistor R11, the transistor Q11 is turned on.

When the transistor Q11 is turned on, the secondary terminal 'b-c' e-f 'of the relay RY11 is connected to the terminal RY11 by flowing a current to the collector RY11 primary coil L11. It is connected by switching to ac and fd.

Through the connected terminals `ac` and` fd`, the alternating current AC is limited by the dummyster TH12, and a device current flows through the element coil DL11 surrounded by the CRT to magnetize the CRT. Will be demagnetized.

When the device signal DS is not applied, when the driving signal HS is applied to the base of the transistor Q12, the transistor Q12 is turned on and is switched by the transistor Q12 to be turned on. The flyback pulse is induced to the secondary side through the primary side of the former (FBT).

When the flyback pulse induced on the secondary side of the flyback transformer FBT is input to the `+` terminal of the comparator IC1, the comparator IC1 compares the flyback pulse to the resistor R14 and the capacitor ( C12).

In the resistor R14 and the capacitor C12, the applied signal is charged and discharged and applied as a bias voltage to the base of the transistor Q13, so that the transistor Q13 is turned on and the transistor Q13 is switched on. The flyback negative pulse as at point P in FIG. 2 is applied to the secondary terminal of the relay RY11.

Since the flyback negative pulse applied to the relay RY11 is connected to the secondary `ef`'b-c 'terminal of the relay RY11, a negative pulse is applied to the element coil DL11. Will be authorized.

The negative pulse flowing through the element coil DL11 attenuates the unnecessary radiation wave generated on the entire CRT.

Here, the surface resistance (Anti-Static Coating) value of the CRT is 10 ⁹ Ω to sufficiently block the unnecessary radiation.

The present invention blocks the unnecessary radiation by attenuating the unnecessary radiation generated on the front of the CRT by generating a pulse of the flyback negative (-) even when there is no device signal in order to remove the unnecessary radiation caused by the device coil. Even if the surface resistance of the CRT is less than 10 ³ Ω, it is possible to reduce the CRT cost by blocking the unnecessary radiation of the CRT even at about 10 ⁹ Ω.

Claims (1)

A transistor Q11 for switching on and off by the device signal DS and a relay for applying AC power to the dummyster TH12 and the device coil L11 by switching on and off by switching of the transistor Q11. In the element circuit composed of (RY11) and an element coil (L11) for magnetizing the CRT by flowing element current, Transistor Q12 that receives the driving signal HS, switches on and off, and outputs the primary coil of the flyback transformer FBT, and generates a flyback pulse by the transistor Q12 to generate a comparator IC1. The flyback transformer (FBT) applied to the '+' terminal of the comparator, the comparator (IC1) to compare and output by the flyback pulse of the flyback transformer (FBT) and the comparator (IC1) A resistor R14 and a capacitor C12 for charging and discharging a signal to be applied as a bias voltage of the transistor Q13, and a bias voltage is input by the resistor R14 and the capacitor C12 to receive a device through the relay RY11. It is composed of a transistor Q13 for switching and outputting a flyback negative pulse to the coil L1. When the device signal DS is not applied, unnecessary radiation generated on the entire CRT by applying a flyback negative pulse. Flyback Negative Pulse Attenuates Wave Biological father 11, the unnecessary radiation blocked by the element coils, characterized in that a circuit consisting of