KR0171737B1 - Noise shielding equipment - Google Patents

Abstract

The present invention is to remove the VLMF noise generated during the return period of the cathode ray tube. The present invention effectively removes the VLMF noise generated during the retrace period by applying an inverse signal of the horizontal deflection signal to the shadow mask 5 of the cathode ray tube. The transformer T is connected to the collector side of the horizontal output transistor Q. The reverse signal of the horizontal deflection signal is generated, and the generated reverse signal is applied to the shadow mask 5 of the cathode ray tube, and the signal applying means is formed on the outer surface of the funnel portion 3 of the cathode ray tube such as copper or aluminum. Coating a conductive material to form an electrode 10, and the electrode 10 and the glass and graphite layers 9 of the funnel portion 3 form a condenser, thereby suppressing the inverse signal of the horizontal deflection signal (5). To apply.

Description

Noise canceller

1 is a schematic cross-sectional view showing the structure of a typical cathode ray tube.

2 is a view showing a conductive plate coated on the cathode ray tube by the noise removing device of the present invention.

3 is an equivalent circuit diagram of a cathode ray tube by the noise removing device of the present invention.

4 is a circuit diagram showing a noise removing device of the present invention.

* Explanation of symbols for main parts of the drawings

1 cathode ray tube body 3 funnel portion

3A: Glass 5: Shadow Mask

9 graphite layer 10 electrode

T: trance FBT: flyback trance

Q: horizontal output transistor

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a monitor and a television receiver employing a cathode ray tube such as a cathode ray tube (CRT), a color picture tube (CPT) or a color display tube (CDT), and a cathode ray tube during a blanking period. The present invention relates to a noise removing device for removing VLMF (Very Low Magnetic Field) noise. In general, devices employing a cathode ray tube generate an electron beam from an electron gun in the cathode ray tube, and the generated electron beam is vertically and horizontally deflected according to a magnetic field of a vertical deflection coil and a horizontal deflection coil installed in the neck of the cathode ray tube. While passing through the shadow mask on the front surface, it collides with the fluorescent surface to reproduce a predetermined image. In this case, the electron beam does not continuously collide with the fluorescent surface, and the electron beam is collided between the syringes with the image signal, and the electron beam is not collided during the return period without the image signal. Therefore, the beam current flows in the cathode ray tube between the syringes, and the beam current does not flow during the return period. VLMF noise is generated due to the difference in the beam current. The generated VLMF noise is very harmful to the human body and should not be radiated outward from the cathode ray tube. To this end, TCO is conventionally coated on the front side of the cathode ray tube to prevent VLMF noise from radiating to the front side of the cathode ray tube, but the technology of coating TCO is very difficult and increases the production cost of the cathode ray tube, which is economical for consumers. There is a burden. Accordingly, an object of the present invention is to provide a noise canceling device that effectively removes VLMF noise generated during the retrace period by applying an inverse signal of a horizontal deflection signal to a shadow mask of a cathode ray tube. In order to achieve the above object, the present invention connects a transformer to a collector side of a horizontal output transistor to generate a reverse signal of a horizontal deflection signal, and applies the generated reverse signal to a shadow mask of a cathode ray tube. The signal applying means is typically coated with a conductive material such as graphite on the inner tube wall of the cathode ray tube, and forms a capacitor by coating a conductive material such as copper or aluminum on the outside of the cathode ray tube, and then forms a shadow through the formed capacitor. The inverse signal of the horizontal deflection signal is applied to the mask. Hereinafter, with reference to the accompanying drawings will be described in detail the noise canceller of the present invention. 1 is a schematic cross-sectional view showing the structure of a typical cathode ray tube. Here, reference numeral 1 denotes a main body of the cathode ray tube, and the main body 1 includes a front panel part 2 and a rear funnel part 3. In addition, a fluorescent surface 4 is formed on the inner surface of the panel portion 2, and a shadow mask 5 is fixed and installed at the rear of the fluorescent surface 4, and in the neck portion 6 behind the funnel portion 3. The electron gun 7 is provided to emit an electron beam toward the shadow mask 5 in front of the electron gun 7. In addition, the funnel portion 3 is provided with an anode terminal 8 for applying a high pressure, and the inner tube wall of the funnel portion 3 has a graphite layer which is a conductive material for supplying a high pressure applied to the anode terminal 8 ( 9) is coated. In this cathode ray tube, the present invention forms a signal application means in the funnel portion 3, as shown in FIG. The signal applying means coated the conductive material such as copper or aluminum on the outer surface of the funnel portion 3 to form the electrode 10. Therefore, according to the present invention, as shown in FIG. 3, the electrode 10, the glass 3A of the funnel portion 3, and the graphite layer 9 form a capacitor to apply a predetermined signal to the electrode 10. In this case, the applied signal passes through the glass 3A and is applied to the graphite layer 9. 4 is a circuit diagram showing a noise canceling apparatus of the present invention. As shown in the figure, the primary side is connected between the collector of the horizontal output transistor Q and the flyback transformer FBT in which the horizontal deflection signal is applied to the base in the horizontal drive unit, thereby inverting the horizontal deflection signal to the secondary side. The transformer T to be detected was connected and connected such that an inverse signal of the horizontal deflection signal detected by the transformer T was applied to the electrode 10 through the resistor R. In FIG. 4, reference numeral D denotes a damper diode, C denotes a resonance capacitor, HDY denotes a horizontal deflection coil, and B ⁺ denotes a power source. According to the present invention configured as described above, the horizontal deflection signal output from the horizontal drive unit while the power source B ⁺ is applied is applied to the base of the horizontal output transistor Q, and amplified and output to the collector thereof. The horizontal deflection signal output to the collector of the horizontal output transistor Q is converted into a sawtooth signal by the damper diode D and the resonant capacitor C as in the normal horizontal output circuit, and is then applied to the horizontal deflection coil HDY. It is applied to horizontally deflect the electron beam. The horizontal deflection signal output to the collector of the horizontal output transistor Q flows to the primary side of the flyback transformer FBT, generates a high voltage to the secondary side, and is applied to the primary side of the transformer T to be guided to the secondary side. Here, the present invention is wound so that the polarity of the primary side and the secondary side of the transformer (T) are different from each other so that the reverse signal of the horizontal deflection signal is induced to the secondary side of the transformer (T). In this way, the reverse signal of the horizontal deflection signal induced to the secondary side of the transformer T is applied to the electrode 10 of the signal applying means through the resistor R. The reverse signal of the horizontal deflection signal applied to the electrode 10 is transmitted to the graphite layer 9 through the glass of the panel portion 3 constituting the condenser together with the electrode 10, and the horizontal signal transmitted to the graphite layer 9. The inverse signal of the deflection signal is applied to the shadow mask 5. That is, the present invention applies the inverse signal of the horizontal deflection signal to the shadow mask 5 during the return period, so that the VLMF noise generated because no beam current flows during the return period is generated. As described above, in the present invention, the inverse signal of the horizontal deflection signal is applied to the shadow mask during the return period so that VLMF noise is not generated so that noise emitted to the front surface of the cathode ray tube is not generated.

Claims (3)

The transformer T for detecting the reverse signal of the horizontal deflection signal and the reverse signal of the horizontal deflection signal detected by the transformer T are applied to the shadow mask 5 of the cathode ray tube during the return period so that noise is not generated. Noise canceling circuit comprising a signal applying means. 2. The transformer (T) according to claim 1, wherein the transformer (T) connects the primary side directly to the flyback transformer (FBT) on the collector of the horizontal output transistor (Q), and the secondary side is wound with a different polarity than that of the primary side. Noise canceller, characterized in that for detecting the reverse signal. The method according to claim 1, wherein the signal applying means forms an electrode 10 coated with a conductive material on the outer surface of the funnel portion 3 of the cathode ray and the main body 1, so that the glass of the electrode 10 and the funnel portion 3 is formed. 3A and the graphite layer 9 coated on the inner wall surface of the cathode ray tube form a condenser so that an inverse signal of the horizontal deflection signal applied to the electrode 10 is passed through the glass and graphite layers 9 of the funnel portion 3. Noise canceller, characterized in that applied to the shadow mask (5).