KR20070080351A - Emi shielding film and optical filter having the same - Google Patents

Abstract

An EMI shielding film and an optical filter having the same are provided to enhance a contrast ratio of a display panel under a bright external light by reducing an amount of the external light incident to the EMI shielding film. An EMI(ElectroMagnetic Interference) shielding film includes a base layer and an EMI shielding layer. The EMI shielding layer is formed on the base layer and includes a conductive pattern(24) and a ground portion(25). The conductive pattern includes plural horizontal and vertical conductive lines which cross each other. The conductive pattern is grounded via the ground portion. A spacing between horizontal conductive lines is smaller than a spacing between vertical conductive lines. A ratio of a height of the respective horizontal conductive lines with respect to the spacing between horizontal conductive lines is between 1:100 and 10:1.

Description

Electromagnetic shielding film and optical filter including the same {EMI SHIELDING FILM AND OPTICAL FILTER HAVING THE SAME}

1 is a plan view of a conductive pattern portion and a ground portion of the electromagnetic shielding film according to the present invention;

Figure 2 is a side cross-sectional view of the electromagnetic shielding film according to the present invention from the left or right side, based on the state shown in Figure 1,

3 is a side cross-sectional view showing a state in which a transparent layer is formed on a base layer of an electromagnetic shielding film according to the present invention;

4 is a plan view of a conventional electromagnetic shielding film,

5 is a side cross-sectional view of a conventional electromagnetic shielding film viewed from the left or the right with respect to the state shown in FIG. 4.

* Description of the symbols for the main parts of the drawings *

10: base layer 21: horizontal conductive wire

22: longitudinal conductive wire 23: groove

24 conductive pattern portion 25 grounding portion

30: transparent layer

The present invention relates to an electromagnetic shielding film which has a conductive pattern portion and a ground portion and shields electromagnetic waves in front of the display panel of the display device.

In general, a display device is a general term for a TV or a computer monitor, and includes a display module having a display panel for forming an image and a casing for supporting the display module.

An example of a display device, a display module of a flat panel display device includes a plasma display panel, a driving circuit board for driving the plasma display panel, and an optical filter disposed in front of the plasma display panel.

The optical filter may include an anti-reflection film that prevents external light incident from the outside from being reflected back to the outside, a near-infrared shielding film that shields near-infrared rays generated from the display panel to prevent malfunction of electronic devices such as a remote controller, and color control dyes. And a color correction film for increasing color purity by adjusting color tone, and an electromagnetic shielding film for shielding electromagnetic waves generated from the display panel when the display apparatus is driven.

Wherein the electromagnetic shielding film is shown in Figures 4 and 5, the base layer 110; A conductive pattern portion 124 provided on the base layer 110 and having horizontal and vertical conductive lines 121 and 122 forming a square groove 123, and a ground portion surrounding the circumference of the conductive pattern portion 124 ( And an electromagnetic shielding layer (124, 125) having a (125).

In the display device having such a configuration, the plasma display panel has an advantage of excellent contrast ratio in a dark environment, but has a disadvantage that the contrast ratio is lowered due to surface reflection of the plasma display panel under bright external lighting (bright conditions).

Thus, in the related art, a black stripe is provided inside the plasma display panel to reduce reflection of external light of the plasma display panel, thereby improving contrast ratio. However, in addition to the electrodes formed on the front panel of the plasma display panel, a separate black matrix film is used. Since it must be prepared, there is a problem that the number of steps is increased, the structure is complicated.

Accordingly, an object of the present invention is to provide an electromagnetic shielding film and an optical filter including the same, which can improve the contrast ratio of a display panel under bright external lighting conditions by improving the structure of the conductive pattern portion.

In order to achieve the above object, one embodiment of the present invention comprises a base layer; And an electromagnetic shielding layer provided on the base layer, the conductive pattern portion having a plurality of transverse and vertical conductive lines crossing each other, and an earth shielding portion for grounding the conductive pattern portion, wherein the spacing between the horizontal conductive lines is It provides an electromagnetic shielding film, characterized in that less than the spacing interval between the longitudinal conductive lines.

The ratio of the separation interval between the heights of the horizontal conductive lines and the horizontal conductive lines is 1: 100 to 10: 1.

Here, the height of each of the horizontal conductive lines is 1 ~ 100㎛, it is preferable that the spacing interval between the horizontal conductive lines is 10 ~ 1000㎛.

In addition, the ratio of the intervals between the thicknesses of the horizontal conductive lines and the horizontal conductive lines is 1: 100 to 3: 1.

Here, the thickness of each of the transverse conductors is 1 ~ 100㎛, it is preferable that the spacing interval between the transverse conductors is 10 ~ 1000㎛.

On the other hand, the inclination angle formed by a connecting line connecting the lower end of the one horizontal conductive line and the upper end of the other horizontal conductive line in a straight line on the basis of any one of the horizontal conductive line, the It is preferable that the inclination angle formed by the connecting line connecting the lower end of one longitudinal conductor and the upper end of the other longitudinal conductor in a straight line is smaller.

Preferably, the conductive pattern portion is disposed to be twisted with respect to the upper surface of the base layer in one of left and right directions along the plate surface direction of the base layer.

Here, the conductive pattern portion may be formed on the base layer by a photolithography method, and after the process according to the photolithography method, the outer surface may be blackened with an oxidizing solution to prepare the conductive pattern portion.

The conductive pattern portion may be formed by printing a conductive paste on the base layer.

The conductive paste may further include any one selected from carbon nanotubes and carbon black, and may be printed on the base layer by any one of an offset printing method, an ink jet printing method, and a screen printing method.

On the other hand, a transparent layer formed by coating a transparent resin on the base layer to cover the plurality of horizontal and vertical conductive lines and the grooves of the rectangular cross-sectional shape continuously formed by the plurality of horizontal and vertical conductive lines Can be prepared.

In addition, one or more selected from near-infrared absorbing dyes and color control dyes may be added to the transparent resin.

In order to achieve the above object, another embodiment of the present invention provides an optical filter comprising the electromagnetic shielding film.

The optical filter may include an anti-reflection film that prevents external light incident from the outside from being reflected back to the outside; A color correction film for enhancing color purity by adjusting color tones including color control dyes; It may further include a near infrared shielding film for shielding the near infrared.

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

Electromagnetic shielding film according to an embodiment of the present invention, as shown in Figure 1 and 2, the base layer 10; It includes an electromagnetic shielding layer (24, 25) provided on the base layer (10).

The base layer 10 is made of at least one selected from polyacrylic, polyurethane, polyester, polyepoxy, polyolefin, polycarbonate, and cellulose based materials having excellent adhesion and light transmittance. In this embodiment, the base layer is made of transparent polyethylene terephthalate (PET).

The electromagnetic shielding layers 24 and 25 include a conductive pattern portion 24 having a mesh shape and a ground portion 25 surrounding the circumference of the conductive pattern portion. Accordingly, the conductive pattern part 24 shields electromagnetic waves and guides them to the grounded ground part 25 and emits them to the outside. Here, the conductive pattern portion 24 and the ground portion 25 is not limited to the form shown in the figure may be provided in various forms.

The conductive pattern portion 24 is formed by forming a metal thin film such as copper, aluminum, iron, and nickel by a photolithography method, and then blackening the outer surface through a blackening treatment step with an oxidizing solution in a later step. In this embodiment, a photolithography method is used, but an offset printing method, an inkjet printing method, and a screen printing method may also be used. When the conductive paste is formed by a printing method, the surface may be blackened by oxidizing with an oxidizing solution after printing, or the blackening process may be omitted by adding carbon nanotubes or carbon black to the conductive paste. .

The conductive pattern part 24 is formed to be twisted with respect to the upper surface of the base layer 10 in the left direction along the plate surface direction of the base layer 10 to prevent the moiré phenomenon from occurring. In the present embodiment, the conductive pattern portion 24 is formed to be twisted in the left direction, but may be formed to be twisted in the right direction.

The conductive pattern portion 24 is continuous by a plurality of horizontal and vertical conductive lines 21 and 22 protruding from the upper surface of the base layer 10 and intersecting with each other, and a plurality of horizontal and vertical conductive lines 21 and 22. It consists of the groove part 25 of rectangular cross-sectional shape formed by the.

The spaced interval A ₁ between the horizontal conductive lines 21 is provided to be smaller than the spaced interval between the vertical conductive lines 22, the height and thickness of the vertical conductive line 22, and the spaced interval between the vertical conductive lines 22. May be provided in the same manner as in the prior art.

Accordingly, the inclination angle θ ₁ of the connecting line connecting the upper end of the other horizontal conductive line 21 at the lower end of the one side plate surface of one of the horizontal conductive lines 21 with the one side surface of the one horizontal conductive line 21. ) Is the angle of inclination (not shown) formed by the connecting line connecting the upper end of the other one of the longitudinal conductors 22 at the lower end of one of the longitudinal conductors (22) with one side of the one of the longitudinal conductors (22) Is less than

Since the grooves 25 of the rectangular cross-sectional shape are formed while the plurality of horizontal and vertical conductive lines 21 and 22 cross each other, they are regularly arranged to match the longitudinal column and the horizontal column.

Hereinafter, the horizontal conductive line 21 of the electromagnetic shielding film according to the present invention shown in FIG. 2 will be described in comparison with the horizontal conductive line 121 of the conventional electromagnetic shielding film shown in FIG. 5.

The thickness of the thickness (C ₁₎ and the conventional respective horizontal FIG wire 121 in the electromagnetic wave shielding film of an electromagnetic wave shielding film of each width also wires (21) in accordance with the present invention (C ₂₎ are mutually identical, and each horizontal FIG wire the height of the height (B ₁₎ and each transverse wire is also 121 (21), (B ₂₎ are the same as each other.

The separation distance A ₂ between any one horizontal conductive line 121 and the other horizontal conductive line 121 is a separation interval between any one horizontal conductive line 21 and the other horizontal conductive line 21 according to the present invention. As greater than (A ₁ ), the connecting line connecting the upper end of the other horizontal conductive line 121 at the lower end of one side plate surface of one of the horizontal conductive lines 121 and the one side of the horizontal conductive line 121 forming inclination angle (θ ₂₎ is any one of the horizontal Figure wires 21 in the lower end of one side of the printing plate other horizontal block diagram horizontally Fig which the connection line connecting the upper end of the wire 21 forming the side surfaces of the wires 21 of the It is larger than the inclination angle θ ₁ .

In addition, the ratio of the spaced interval A ₁ between the height B ₁ of each of the transverse conductive lines 21 and the transverse conductive lines 21 constitutes 1: 100 to 10: 1, preferably 1:10 to 5 : 1, most preferably 1: 5 to 2: 1. Here, the contrast ratio is determined by the ratio of the separation interval A ₁ between the height B ₁ of the horizontal conductive line 21 and the horizontal conductive line 21.

The height B ₁ of each of the horizontal conductive lines 21 is provided at 1 to 100 μm, and the spacing A ₁ between the horizontal conductive lines 21 is provided at 10 to 1000 μm.

In addition, the ratio of the distance (A ₁ ) between the thickness (C ₁ ) of each of the transverse conductive line 21 and the transverse conductive line 21 is 1: 100 to 3: 1, preferably 1:50 to 2 : 1, Most preferably, it is 1: 30-1: 2. Here, the transmittance is determined by the ratio of the spaced interval A ₁ between the thickness C ₁ of each transverse conductive line 21 and the transverse conductive line 21. In addition, the thickness of each transverse conductive line 21 is provided to 1 ~ 100㎛.

In the electromagnetic shielding film having such a configuration, as shown in FIG. 3, the transparent layer 30 covering the electromagnetic shielding layers 24 and 25 may be further provided on the base layer 10.

When the transparent layer 30 is bonded to another functional film (eg antireflection film, near infrared shielding film, color correction film) on the conductive pattern portion 24 of the electromagnetic shielding layers 24 and 25, the transparent layer 30 is not completely adhered to each other due to the mesh shape. However, an air layer is formed in the groove 23 of the conductive pattern portion 24 to prevent light scattering by the air layer, thereby filling the step caused by the conductive pattern portion 24 to prevent the electromagnetic shielding layers 24 and 25. It serves to cover the upper side is flat.

The transparent layer 30 is provided by coating a transparent resin such as a crosslinkable resin, a curable resin, and a UV curable resin on the electromagnetic shielding layers 24 and 25 so as to cover the electromagnetic shielding layers 24 and 25. In addition, functions such as near infrared absorption and color correction may be added to the transparent layer 30. That is, a dye and / or a color control dye absorbing near infrared rays may be added to the above-mentioned transparent resin for forming the transparent layer 30.

Electromagnetic shielding film according to the present invention having such a configuration can be applied to the optical filter disposed in front of the display panel of the display device.

An optical filter is disposed in front of the display panel and includes a color correction film for enhancing color purity by adjusting color tone including a color adjusting dye; A near-infrared shield for shielding near-infrared to prevent malfunction of an electronic device such as a remote controller; An electromagnetic shielding film (10, 24, 45) according to the present invention for shielding electromagnetic waves; It is composed of an antireflection film that prevents external light incident from the outside from being reflected back to the outside.

As such, when the optical filter to which the electromagnetic shielding films 10, 24, and 25 according to the present invention are applied is disposed in front of the display panel, the spacing A ₂ between the horizontal conductive lines 121 is large, that is, the outside Since the range (θ ₂ ) where external light can be incident from the illumination is large, and the amount of external light incident from the external illumination is large, the contrast ratio is lowered due to the reflection of the display panel surface under bright external lighting (bright conditions). Since the separation distance A ₁ between the horizontal conductive lines 21 is small, the ratio of the height B ₁ of the horizontal conductive line 21 to the separation interval A ₁ between the horizontal conductive lines 21 is increased, and the outside As the range θ ₁ through which the external light can be incident from the illumination is reduced, the amount of the external light that can be incident is reduced, so that the contrast ratio of the display panel can be improved under the clear condition.

As described above, according to the present invention, the amount of external light incident on the electromagnetic shielding film can be reduced, so that the contrast ratio of the display panel can be improved under bright external lighting conditions.

Claims (16)

A base layer; And an electromagnetic shielding layer provided on the base layer, the conductive pattern portion having a plurality of horizontal and vertical conductive wires crossing each other, and a grounding portion for grounding the conductive pattern portion. The spaced interval between the transverse conductive lines is less than the spacing interval between the longitudinal conductive line electromagnetic shielding film. The method of claim 1, The ratio of the separation interval between the height of each of the horizontal conductive line and the horizontal conductive line is 1: 100 ~ 10: electromagnetic shielding film, characterized in that. The method of claim 2, The height of each horizontal conductive line is 1 ~ 100㎛, Electromagnetic shielding film, characterized in that the spacing interval between the horizontal conductive line is 10 ~ 1000㎛. The method of claim 1, Electromagnetic shielding film, characterized in that the ratio of the thickness of each horizontal conductive line and the separation interval between the horizontal conductive line is 1: 100 ~ 3: 1. The method of claim 4, wherein The thickness of each horizontal conductive line is 1 ~ 100㎛, Electromagnetic shielding film, characterized in that the spacing interval between the horizontal conductive line is 10 ~ 1000㎛. The method of claim 1, The angle of inclination of the connection line connecting the lower end of the one horizontal conductive line and the upper end of the other horizontal conductive line in a straight line with respect to the one horizontal conductive line is the one with respect to the one vertical conductive line. Electromagnetic shielding film, characterized in that less than the inclination angle formed by the connecting line connecting the lower end of the longitudinal conductor and the upper end of the other longitudinal conductor in a straight line. The method of claim 1, The conductive pattern part is an electromagnetic shielding film, characterized in that disposed in the direction of the upper surface of the base layer in any one of the left and right direction along the plate surface direction of the base layer. The method of claim 1, The conductive pattern portion is formed on the base layer by a photolithography method, the electromagnetic shielding film. According to claim 8, After the process according to the photolithography method, the outer surface is blackened with an oxidizing solution to provide the conductive pattern portion, characterized in that the electromagnetic shielding film. The method of claim 1, The conductive pattern portion is formed by printing a conductive paste on the base layer, the electromagnetic shielding film. The method of claim 10, The conductive paste further comprises any one selected from carbon nanotubes and carbon black. The method of claim 10, The conductive metal paste is printed on the base layer by any one of an offset printing method, an ink jet printing method, a screen printing method. The method of claim 1, The transparent layer is formed on the base layer by coating a transparent resin so as to cover the plurality of horizontal and vertical conductive lines and a groove having a rectangular cross-sectional shape continuously formed by the plurality of horizontal and vertical conductive lines. Electromagnetic shielding film, characterized in that. The method of claim 13, Electromagnetic shielding film, characterized in that for adding the at least one selected from near-infrared absorbing dye and color control dye to the transparent resin. An optical filter comprising an electromagnetic shielding film according to any one of claims 1 to 14. The method of claim 15, An anti-reflection film for preventing external light incident from the outside from being reflected back to the outside; A color correction film for enhancing color purity by adjusting color tones including color control dyes; The optical filter further comprises a near infrared shielding film for shielding near infrared.

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