KR19990013891U - Monitor electromagnetic wave shield - Google Patents

Abstract

The present invention relates to a circuit for blocking low frequency harmful electromagnetic waves generated from the front side of the monitor. In the past, a method for blocking high frequency electromagnetic waves (EMI) emitted from the monitor tube has been studied in recent years. With the publication of the TCO standard, the need for low frequency electromagnetic shielding is urgent.

Accordingly, the present invention is a loop-type conductor wire installed along the outer edge of the water pipe at the front edge of the water pipe (CRT), and the conductor wire is wound and inserted into the screen line of the water pipe to screen current on the screen line When is passed, it consists of a ferrite core that provides the conductor wire with a low frequency of the same frequency and opposite polarity as the electromagnetic wave generated from the front surface of the water pipe.

The present invention as described above can pass the TCO standard for regulating low frequency electromagnetic waves, and also has the effect of protecting the human body from low frequency electromagnetic waves.

Description

Apparatus for shielding electromagnetic wave in a monitor

The present invention relates to a circuit for blocking low frequency harmful electromagnetic waves generated in front of the monitor.

In general, a color display device (CRT) used in a monitor focuses and accelerates hot electrons emitted from R, G, and B guns and collides with R, G, and B fluorescent surfaces through a point on a shadow mask to form pixels. The sawtooth current flows through the vertical and horizontal deflection coils to form a two-dimensional screen.

In order to operate the color display device (CRT), a heater voltage of about 6.3V is applied to the heater, a focus grid voltage, a screen grid voltage, etc. are required for focusing the emitted hot electrons, and an anode is used to accelerate the hot electrons. The high pressure of about 25KV will be applied.

As shown in FIG. 1, the power supply circuit of the monitor providing the voltage necessary for the CRT as described above may include a power supply 110, a PWM generator 120, and a B + voltage generator 130. , The oscillator 150, the horizontal driver 160, and the horizontal output unit 170.

Referring to FIG. 1, the DC voltage output from the power supply 110 is converted into a predetermined B + voltage by the PWM generator 120 and the B + voltage generator 130 and applied to the primary winding of the FBT 140. The B + voltage of the primary winding is switched by the horizontal output unit 170 according to the horizontal drive signal (H.drive) to generate a high voltage (HV) on the secondary winding side of the FBT 140.

At this time, the high voltage (HV) generated in the secondary winding of the FBT 140 is applied to the anode of the CRT, divided by the resistors, and then applied to the focus grid FOCUS and the screen grid SCREEN of the CRT, respectively. have.

That is, as the B + voltage applied to the primary winding of the FBT 140 is switched by the horizontal drive signal, the high voltage is induced to the secondary side, and the high voltage remains as an AC noise because a ripple signal of the same frequency as the horizontal drive signal remains. Will work. In addition, low-frequency electromagnetic waves are emitted from the front of the monitor by the high pressure including the AC noise.

The low frequency electromagnetic waves do not cause serious harm to the human body compared to the high frequency electromagnetic waves (EMI). However, since the TCO standard was published in Sweden in 1991, the TCO standard, also known as MPR III, is a low frequency electromagnetic wave emitted from a monitor. The specification for.

In the TCO standard, a standard for an alternating electric field and a standard for an alternating magnetic field are separately provided, which can be summarized as Table 1 and Table 2 below.

Specification for alternating electric field MPR 2 TCO (MPR 3) Frequency range ELF (5 ㎐ to 2 ㎑) VLF (2㎑ to 400㎑) ELF (5 ㎐ to 2 ㎑) VLF (2㎑ to 400㎑) Limit 25 V / m 2.5 V / m 10 V / m 1 V / m Measuring distance 50 cm 50 cm Front 30 cm Front 30 cm, 50 cm

Specification for alternating magnetic fields MPR 2 TCO (MPR 3) Frequency range ELF (5 ㎐ to 2 ㎑) VLF (2㎑ to 400㎑) ELF (5 ㎐ to 2 ㎑) VLF (2㎑ to 400㎑) Limit 250 nT 25 nT 200 nT 25 nT Measuring distance 50 cm 50 cm Front 30 cm, 50 cm 50 cm

However, there is a problem in that the conventional monitor is unable to cope with the above-described TCO standard because the device for blocking the low frequency electromagnetic waves is not configured.

Accordingly, an object of the present invention is to provide an electromagnetic wave shielding device of a monitor for blocking an electromagnetic wave of low frequency radiated from a power supply system of a monitor, which is devised to solve the problems of the prior art as described above.

The electromagnetic wave shielding device of the monitor according to the present invention for achieving the above object, the loop-type conductor wire which is installed along the outer edge of the water pipe at the front edge of the water pipe (CRT); And

The conductor wire is wound and inserted into the screen line of the water pipe, and when a screen current flows through the screen line, the conductor wire provides a low frequency wave having the same frequency and opposite polarity to the electromagnetic wave generated from the front surface of the water pipe. It is characterized by consisting of a ferrite core.

1 is a configuration diagram showing a power supply circuit of a general monitor,

2 is a configuration diagram showing a power supply device for a monitor including an electromagnetic wave shield according to the present invention,

Figure 2a is a front configuration diagram of the electromagnetic wave shield,

2b is a detailed structural diagram of a ferrite core;

3A is a waveform diagram of low frequency electromagnetic waves radiated from the surface of a picture tube,

3B is a waveform diagram of a pulse signal output from the conductor wire.

* Explanation of symbols for main parts of the drawings

110: power supply 120: PWM generator

130: B + voltage generator 140: FBT

150: oscillation unit 160: horizontal driving unit

170: horizontal output unit 210: water pipe

220: conductor wire 230: ferrite core

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

2 is a power supply circuit of the monitor equipped with an electromagnetic wave blocking device according to the present invention, which is a power supply 110, PWM generator 120, B + voltage generator 130, FBT 140, Oscillator 150, horizontal drive unit 160, horizontal output unit 170, the loop-shaped conductor wire 220 is installed along the outer edge of the water pipe 210 on the front edge of the water pipe 210, and the conductor When the wire 220 is wound and inserted into a screen line of the water pipe 210 and a screen current flows through the screen wire, the polarity is the same frequency as that generated from the front surface of the water pipe 210. It consists of a ferrite core 230 that provides the opposite low frequency to the conductor wire 220.

The operation of the present invention configured as described above is as follows.

The AC power flowing from the outside is applied to the primary side of the FBT 140 by the B + voltage through the SMPS 110, the PWM generator 120 and the B + voltage generator 130, the B + voltage of the FBT 140 The high pressure is induced to the secondary side of the FBT 140 while being switched by the horizontal driving signal applied to the other primary side.

The high pressure of the FBT 140 is connected to the anode cap of the water pipe 210 is applied to the surface of the water pipe 210. At this time, the high pressure includes the low frequency ripple, that is, the noise, and the low frequency noise causes the low frequency electromagnetic waves of the positive component as shown in FIG. 3A from the surface of the water pipe 210 by the low frequency noise. .

Meanwhile, the screen current of the FBT 140 is applied to the screen line of the water pipe 210 while the screen current flows to the screen line of the water pipe 210 while a voltage proportional to the high voltage (HV) is applied to the screen line of the FBT 140. Magnetism is induced to the ferrite core 230 and a voltage of a predetermined level is applied to the conductor wire 220 by the magnetism.

At this time, the polarity of the voltage applied to the conductor wire 220 is determined according to the direction of the conductor wire 220 wound on the ferrite core 230, as shown in Figure 2b the conductor wire 220 is ferrite When the core 230 is wound in a counterclockwise direction, a voltage whose polarity is opposite to the voltage applied to the screen line is applied to the conductor wire 220.

That is, when a low frequency electromagnetic wave of a positive component is generated on the surface of the water tube 210 by a high pressure, a negative component is applied to the conductor wire 220, and the two electromagnetic waves cancel each other, and thus radiate from the surface of the water tube 210. Low frequency electromagnetic waves are removed.

As described above, the present invention is a TCO that regulates low-frequency electromagnetic waves by winding a conductor wire around the front edge of the receiving tube and applying a negative pulse signal to cancel the low-frequency electromagnetic waves of the positive component radiating from the front of the receiving tube. It can pass the standard, and also has the effect of protecting the human body from low frequency electromagnetic waves.

Claims (1)

A loop-shaped conductor wire installed along the outer edge of the water pipe at the front edge of the water pipe (CRT); And When the conductor wire is wound and inserted into the screen line of the water pipe, and a screen current flows through the screen line, ferrite is provided to the conductor wire with a low frequency having the same frequency and opposite polarity as the electromagnetic wave generated from the front surface of the water pipe. Electromagnetic shielding device of the monitor, characterized in that consisting of a core.