KR19990040839U - Field removal device of display device - Google Patents

Abstract

The present invention relates to an electric field removing device of a display device, and more particularly, in order to block electromagnetic waves generated by a clock oscillation, the display device outputs a reverse phase inverse pulse of the same frequency band as a horizontal output pulse and shield wire. The present invention relates to an electric field removal device capable of blocking harmful waves caused by an electric field generated from a CRT by transmitting to a reverse pulse sensor installed in a CRT front part and a CRT rear part through the front and rear of the CRT.

Description

Field removal device of display device

The present invention relates to a display device, and more particularly, to a display device having an electric field removing device for blocking a harmful wave component generated from the display device.

In recent years, there has been a growing interest in harmful electromagnetic waves generated from electronic products, and internationally, electromagnetic wave restriction standards have been set to produce products suitable for this.

In particular, in display devices using cathode ray tubes (CRTs), the electric fields and magnetic fields generated by CRTs have a harmful effect on the human body, and various regulatory agencies around the world are working to regulate them. Doing.

The TCO, established in Sweden, is the leading European Agency for Testing and Hazardous Radio Regulations, regulated with limits as shown in Table 1.

Parameter Frequency band Limit value Remarks Field effect (field length) ELF (5 ㎐-2 ㎑) 10 V / M ELF: Extremery Low Frequency VLF: Very Low Frequency VLF (2 400 to 400 ㎑) 1 V / M Magnetic field effects ELF (5 ㎐-2 ㎑) 200 nT VLF (2 400 to 400 ㎑) 25 nT

As shown in the above table, the limit value in the ELF region has a certain large value, so that the TCO regulation value may be satisfied when using a general CRT.

However, in the case of the VLF region, since the regulation value requires a relatively small value, the general CRT except for the high quality CRT is somewhat difficult to satisfy the regulation value.

As described above, the magnetic field and the electric field, which are tightening regulations, are caused by the voltage applied to the deflection coil, and the electric field is caused by the voltage applied to the anode.

In this case, in the above two fields, the magnetic field can be easily shielded by using a separate canceling coil on the correction coil and the deflection coil attached to the electron gun of the CRT, whereas the electric field generated by the voltage applied to the anode is shielded. Is not easy to have.

The most common method of shielding electric fields is by attaching a separate filter to the front of the CRT. The reason is that the shielding of the electric and magnetic fields generated from the monitor is possible by using a case on the side and the rear, but the front is glass. Since the shield is not shielded, the shield plate is attached to the front surface for shielding the electric field.

As another method, a method of minimizing electromagnetic harmful waves by lowering the coating resistance value of the CRT as much as possible was used. The CRT coating resistance used at this time should have a value of about 10 ³ or less to have a blocking effect.

However, in the case of employing a special filter in the configuration method for blocking the electromagnetic harmful waves as described above, the difficulty of attaching a separate shield plate mechanically to the front of the display device and the complexity of the process resulting therefrom There is a problem that productivity is lowered.

In addition, since the price of the filter is expensive, it is inferior in price competitiveness, and even when mass production is applied, it may cause problems in mounting and packing and transporting the product.

In addition, the use of specially coated CRTs uses expensive special coating liquids for the coating process of 10 ³ or less, and when applied to mass production, the yield is not only low, but also may cause technical difficulties, causing a price increase. do.

Therefore, the above two electromagnetic wave blocking methods are problematic in mass production, and even if applied in practice, they are inferior in price competitiveness.

The recent method proposed to solve the above problems is to cancel the voltage applied to the anode of the CRT, the high voltage of the inverted phase with respect to the anode voltage at the position symmetrical with the anode by the axis of the connection linear axis of the electron gun and the CRT It is a way to walk.

The method is described in detail in US Pat. No. 5,198,729 and thus further description is omitted.

This method has a burden of not being able to use the existing CRT production line due to the need to newly design the CRT itself due to the configuration of the symmetrical part of the anode, and moreover, the coating of the insulation coating film applied to the outer wall of CRT vacuum tube As the coating work is followed, there is a problem that the manufacturing difficulties follow.

In addition, since the electric field generated by the anode voltage has to be shielded with the voltage signal inverted phase at the anode symmetrical position, it is pointed out that the limitation that it is applicable to only a small size CRT.

An object of the present invention is to provide a field removing device of a display device for blocking an electric field generated due to a high voltage applied to an anode in a display device using a CRT.

Another object of the present invention is to provide an electric field removing device of a display device capable of blocking an electric field so as to satisfy a limit value in the VLF band among the TCO regulation limit values even using a general CRT.

Still another object of the present invention is to provide an electric field removal device capable of suppressing electromagnetic waves generated in front and rear of a CRT without forming a separate shield inside the display device.

Another object of the present invention is to provide a reverse pulse sensor between the top of the funnel and the anode of the CRT to spread the reverse pulse in front of the CRT, and to install a reverse pulse sensor in the video shield to reverse the rear of the CRT. It is to provide an electric field removing device of a display device that spreads pulses.

Another object of the present invention is to output a pulse of the inverse phase of the same frequency as the anode stage and to detect it through the shield wire to spread the front and rear of the CRT.

The electric field removing device of the display device according to the present invention for achieving the above object is a reverse pulse generator connected to the horizontal deflection output circuit of the display device to generate a reverse phase pulse of the same frequency as the horizontal deflection output pulse, and reverse pulse First and second reverse pulse sensors for diffusing the reverse pulses provided from the generator into the front and rear portions of the CRT, respectively; and first and second detectors for detecting the reverse pulses output from the reverse pulse generator and transmitting the reverse pulses to the reverse pulse sensors. It is characterized by comprising a second connecting means.

A detailed feature of the present invention is that the first reverse pulse sensor is installed between the upper portion of the funnel of the CRT and the anode terminal, and the second reverse pulse sensor is installed in the video shield surrounding the video PCB. Is in point.

Another detailed feature of the present invention is that each connecting means is composed of shielded wire.

1 is a side view of a CRT configuration showing an electric field removing device of a display device according to the present invention;

2 is a circuit diagram showing in detail the configuration of the reverse pulse generator of FIG.

3 is a rear view of the CRT showing the attachment state of each reverse pulse sensor shown in FIG. 1;

Figure 4 is a perspective view showing the configuration of the electric field removing device according to the present invention.

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

1 is a block diagram of an electric field removing device of a display device according to a preferred embodiment of the present invention.

As shown, the reverse pulse generator 10 outputs the reverse pulse, and is disposed between the upper portion of the funnel 2 of the CRT 1 and the end of the anode 3, so that the CRT 1 is forward. The first reverse pulse sensor 11 of a conductive material for diffusing the reverse pulse to the part, and the first connecting means 12 for detecting the reverse pulse from the reverse pulse generator 10 and transmits the reverse pulse to the first reverse pulse sensor 11 ) And a second reverse pulse sensor 21 mounted on the video shield 5 for blocking an electric field output from the video PCB 4 and diffusing the reverse pulse behind the CRT, and the first connecting means 12. The second connection means 22 receives the reverse pulse output from the reverse pulse generating unit and transmits the reverse pulse to the second reverse pulse sensor 21.

As shown in FIG. 2, the reverse pulse generator 10 has a primary coil connected to the collector terminal of the horizontal output transistor Q1 and transmits a horizontal flyback pulse waveform H-FLB to the secondary coil. It consists of the receiving transformer T1, and generates the reverse pulse which has a reverse phase with respect to the voltage pulse applied to the primary coil. The reverse pulse generated in the secondary coil of the transformer T1 is configured to be induced in the coil starting from the ground of the secondary coil. Between the transformer T1 and the first connecting means 12, a resistor R1 is configured so that a load is applied when the first reverse pulse sensor 11 is shorted to ground, so that no abnormality occurs in the operation of the product. do.

In the embodiment of the present invention as shown in Figure 3, each reverse pulse sensor (11, 21) is using a copper (copper) tape of the conductive material, if the material is conductive, such as slabs, metal can have the same effect have. In addition, the size is 280 mm long and 15 mm long or 50 mm long and 25 mm wide, but the shape and size thereof are not limited to the shape of a square or the like. However, since the second reverse pulse sensor 21 is installed in the video shield 4, the second reverse pulse sensor 21 has a smaller size than the first reverse pulse sensor 11. In addition, each reverse pulse sensor (11, 21) is attached using an insulating tape to insulate the peripheral device.

One end of the first connecting means 12 is connected to the secondary coil of the reverse pulse generator 10 detects the reverse pulse and transfers the reverse pulse to the first reverse pulse sensor 11 connected to the other end. Each connecting means 12, 22 is configured to be grounded using a shielded wire, which grounds an unnecessary electric field component which may have adverse effects by combining with harmful electric waves through each connecting means 12, 22. This is to block through.

The reverse pulse generator 10 outputs a reverse phase pulse of the same frequency as the pulse generated in the horizontal deflection output circuit. This reverse pulse is detected through the first connecting means 12 and transmitted to the first reverse pulse sensor 11.

In order to cancel harmful field waves, a reverse pulse having an approximately 240 V peak must be diffused from the reverse pulse sensors 11 and 21 to perform its role, and each reverse pulse sensor 11 and 21 must be insulated from the surrounding ground components. .

The second connecting means 22 receives one end connected to the first connecting means 12 to receive the reverse pulse output from the reverse pulse generator 10 and transmits it to the second reverse pulse sensor 21 connected to the other end. .

At this time, since the pulse diffused from the first reverse pulse sensor 11 to the surrounding has a reverse phase with the pulse supplied to the anode end 3 of the CRT 1, the two pulses cancel each other out to the front of the display device. The appearing electric field is cut off. According to the same operation effect, harmful waves are generated behind the CRT 1 by the reverse pulse diffused from the second reverse pulse sensor 21 installed in the video shield 5.

Figure 4 is a perspective view showing an easy to understand the mounting state of the display device according to the present invention. The reverse pulse generator 10 is a circuit configured in the horizontal output terminal as shown in FIG. 2, but it is represented as having a shape for the sake of understanding in the drawing. However, the reverse pulse generator 10 generates a reverse pulse from the secondary coil of the transformer.

Here, look at the effect of the electric field blocking according to the implementation of the present invention with reference to [Table 2] below.

[Table 2] shows the electric field limit values of the TCO, a European harmful radio regulatory agency, compared to the electric field values measured in general CRT without the present invention and the electric field measured values according to the applied state of the present invention.

Frequency band comparison target ELF area VLF area TCO regulated field limit 10.0 V / M 1.0 V / M General CRT 5.7 V / M 2.7 V / M CRT applied to this invention 1.3 V / M 0.4 V / M

More detailed experimental results according to the implementation of the present invention are shown in [Table 3]. This is an experimental result value applied to CRT model number M36LGE211XXC1 of Toshiba Japan Co., Ltd., and shows electric field values appearing with the change of resolution and the change of measurement position. Where 0 ° means the front of the monitor, 90 ° and 270 ° are measured from the side of the monitor and 180 ° from the back of the monitor. The measurement distance was measured at a distance of 30 cm from the front, and at a distance of 50 cm from the side and the back.

division ELF band VLF band Horizontal frequency Vertical frequency resolution 0 ° 0 ° 90 ° 180 ° 270 ° 31.5 60 640 × 480 1.36 V / M 0.355 V / M 0.449 V / M 0.287 V / M 0.391 V / M 54 85 800 × 600 1.26 V / M 0.439 V / M 0.541 V / M 0.284 V / M 0.480 V / M 78 60 1024 × 768 1.30 V / M 0.361 V / M 0.452 V / M 0.303 V / M 0.535 V / M

As shown in the above table, the present invention cuts the electric field to satisfy the TCO regulation limit in blocking the electromagnetic radiation emitted from the CRT, and in particular, to satisfy the electric field cutoff of the VLF band where the limit tolerance is very difficult. It can be seen.

As described above, the present invention does not require the use of a special filter to block an electric field generated from the CRT. It can be used to block the harmful electric field, the price is not only competitive, but also has the effect of fully satisfying the needs of users who require an ergonomic product.

Claims (7)

A reverse pulse generator connected to the horizontal deflection output circuit of the display device to generate an antiphase pulse having the same frequency as the horizontal deflection output pulse; A first reverse pulse sensor for diffusing the reverse pulse provided from the reverse pulse generator into a front surface of the CRT; A second reverse pulse sensor for diffusing the reverse pulse provided from the reverse pulse generator into a CRT rear surface; First connecting means for detecting a reverse pulse output from the reverse pulse generator and transferring the reverse pulse to the first reverse pulse sensor; And a second connection means for detecting a reverse pulse output from the reverse pulse generator and transferring the reverse pulse to the second reverse pulse sensor. The method of claim 1; The first reverse pulse sensor is installed between the upper portion of the funnel of the CRT and the anode terminal, The second reverse pulse sensor is a field removal device of the display device, characterized in that installed in the video shield (Video Shield). The method of claim 1; The first connection means and the second connection means is a field removal device of the display device, characterized in that composed of a shielded wire (Shieded Wire). The method of claim 1; And the reverse pulse generator comprises a transformer connected to the horizontal output circuit to generate a reverse phase of a signal applied to the primary coil to the secondary coil. The method according to any one of claims 1 to 4; And the second connecting means has one end connected to the second reverse pulse sensor and the other end connected to the first connecting means. The method of claim 1, And the first reverse pulse sensor and the second reverse pulse sensor are made of copper tape. The method of claim 6; And removing the copper tape from the peripheral apparatus using an insulating tape.