KR0139550Y1 - Electric field elimination apparatus of display - 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 due to clock oscillation in a display device using a CRT, an antiphase canceling pulse of the same frequency band as a horizontal output pulse, 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 diffusing through a canceling pulse wire provided at an outer edge of the CRT and a rear end of the CRT.

Description

Field removal device of display device

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

2 is an embodiment of the present invention.

3 is a partial detail of FIG. 2.

The present invention relates to an electric field removing device of a display device. More specifically, in order to block electromagnetic waves generated due to clock oscillation in a display device using a CRT, an anti-phase canceling pulse of the same frequency band as a horizontal output pulse is used. The present invention relates to an electric field removing device of a display device that can block harmful waves caused by an electric field generated from a CRT by diffusing to surroundings.

In recent years, as users become more interested in harmful electromagnetic waves generated from electronic products (e.g., TVs, computers, etc.), products that meet the Electro Magnetic Interference (EMI) standards internationally or in each country producing electronic products EMI testing for the production of

In particular, in the display device using the CRT, the electric field and the magnetic field generated by the CRT has a harmful effect on the human body, and various regulatory agencies are working around the world for its regulation.

Beginning with MPR I in Sweden in 1987 and tightened and enforced in 1990, the MPR II regulation regulates the strength of the electric and magnetic fields to minimize the user's health damage from VDT syndrome. Table 1 is as follows.

As shown in Table 1 above, the limit value in the ELF region has a certain large value, so that the MPR II regulation value (25 V / m) 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 (2.5V / m), the general CRT except for the high quality CRT has some difficulties.

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.

At this time, in the above two fields, the magnetic field can be easily shielded by using a correction of the deflection coil attached to the electron gun of the CRT, whereas the electric field generated by the voltage applied to the anode has a characteristic of not being easily shielded. 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 to shield the electric field.

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

However, in the construction method for blocking the electromagnetic harmful waves as described above, when a special filter is employed,

There is a problem that productivity is lowered due to the difficulty of attaching a separate shield plate mechanically to the front of the display device and the complexity of the process.

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, how to use specially coated CRT 10 In the following coating treatment method, expensive special coating liquid is used, and when it is applied to mass production, the yield is not only low, but also may be technically difficult, causing a price increase.

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.

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

The present invention for achieving the above object is connected to a horizontal deflection output circuit of the CRT, the voltage generating means for generating an antiphase canceling pulse of the same frequency band as the horizontal output pulse,

It is installed in parallel with the degaussing coil surrounding the front edge of the CRT, and an extension line is installed so as to surround the deflection yoke at the rear end of the CRT to detect the canceling pulse from the voltage generating means and spread the canceling pulse around the CRT. It is characterized by including a wire.

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 the display device according to a preferred embodiment of the present invention.

As shown, the configuration of the present invention is largely divided into a voltage generating means 100 for outputting a canceling pulse so as to meet the object of the present invention, and detecting the canceling pulse from the voltage generating means 100 and surrounding the CRT. It consists of a canceling pulse wire 110 to diffuse in.

Here, the voltage generating means 100 has a primary coil connected to the collector end of the horizontal output transistor 10 and the horizontal size control circuit 20, respectively, and receives a horizontal flyback waveform from the secondary coil and applies it to the primary coil. It consists of a transformer that generates the reverse phase of the received signal to the secondary coil. Therefore, the following transformer refers to the voltage generating means and uses the same sign.

2 is a diagram illustrating an embodiment of the present invention, wherein the canceling pulse wire 110 is installed to surround the front outer portion of the CRT, and the extension line is installed to surround the deflection yoke H_DY at the rear end of the CRT.

(A) and (b) of FIG. 3 are detailed views of part A of FIG. 2, (a) is an enlarged perspective view, and (b) is one side cross-sectional view of (a).

As shown in FIG. 3 (a), the canceling pulse wire 110 is provided in the latching hole 131 in parallel with the gauging coil 120.

In addition, in FIG. 3 (b), the latch 131 is coupled to the EAR 132 configured at four corners of the CRT to connect the CRT to the rib 130 of the front case.

The reason why the degaussing coil 120 and the canceling pulse sensor 110 are installed side by side here is that the degaussing coil is canceled separately by using the circumference surrounding the EAR 132 installed at each corner of the CRT. This is to avoid using the pulse wire attachment tool.

The operation and effects of the present invention configured as described above will be described.

The output line is drawn by winding the coil at 18 revolutions starting from the ground of the secondary coil of the transformer 100 receiving the horizontal flyback (H_FLB) waveform at the collector terminal of the horizontal output transistor Q1. Since winding at 18 revolutions is an example of the present invention, it will not be necessary to describe that the magnitude of the canceling pulse varies according to the number of windings.

In this case, the canceling pulse generated at the secondary side of the transformer 100 is detected through the canceling pulse wire 110. When spreading the canceling pulse transmitted to the canceling pulse wire 110 around the CRT, it is efficient to spread at the outermost portion of the CRT. Therefore, the position where the canceling pulse wire 110 is fixed to the CRT is installed so as to surround the front outer portion of the CRT as shown in FIG. 2, and the extension line surrounds the deflection yoke H_DY at the rear end of the CRT.

In this case, the canceling pulse wire 110 installed at the front outer portion cancels harmful electromagnetic waves by spreading the antiphase canceling pulse of the same frequency band to the front portion of the CRT with respect to the electromagnetic waves radiated to the front surface of the CRT.

In addition, the extension line of the canceling pulse wire 110 provided around the deflection yoke of the rear end of the CRT is to cancel the electromagnetic wave radiated around the deflection yoke.

The end of the canceling pulse wire 110 is fixed at an arbitrary position and must be insulated. This is because the canceling pulse generated from the transformer 100 is applied to the canceling pulse wire 110 with a peak value of approximately 210V. Table below shows the measured value of the VLF (Very Low Frequency) band of the measured value of the electric field according to the implementation of the present invention.

Where 0 ° means monitor front, 90 ° and 270 ° monitor left and right, and 180 ° from the back of the monitor.

As shown in Table 2, the present invention cuts the electric field to satisfy the MPR II regulation limit (2.5 V / m) in blocking the electromagnetic radiation emitted from the CRT, and particularly the electric field in the VLF band where the limit tolerance is very difficult. It can be seen that it works to satisfy the blocking.

As shown in the figure, when the electromagnetic wave of the positive pulse is radiated in the deflection yoke, it is possible to effectively block the electromagnetic wave radiated from the CRT by diffusing and radiating the negative phase pulse thereof on the front and rear ends of the CRT.

The present invention constructed and operated as described above does not require the use of a special filter to block an electric field generated from the CRT. By using a general multi-layer coating of the CRT can block the harmful electric field, it is not only cost competitive, but also satisfies the needs of users who require ergonomic products.

Claims (3)

It is connected to the horizontal deflection output circuit of the CRT, and is installed in parallel with the voltage generating means for generating an antiphase canceling pulse of the same frequency band as the horizontal output pulse, and the degaussing coil surrounding the front edge of the CRT. And a canceling pulse wire arranged to surround the deflection yoke of the deflection yoke to detect the canceling pulse from the voltage generating means and to diffuse the canceling pulse around the CRT. According to claim 1, wherein the voltage generating means, the primary coil is connected to the collector stage and the horizontal size control circuit of the horizontal output transistor, respectively, the horizontal flyback waveform of the secondary side coil receives the signal applied to the primary coil An electric field removing device of a display device, characterized by comprising a transformer for generating an antiphase to the secondary coil. The electric field removing apparatus of claim 1, wherein an end of the canceling pulse wire is insulated and attached at an arbitrary position.