JP2009294675A - Plasma display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the weight of a device, and reduce halation. <P>SOLUTION: A front sheet to be pasted on the front surface of a plasma display panel has a mesh structure composed of a light shielding body whose surface on the front side is blackened and has a plane size larger than that of the screen of the display panel. A length Dm between diagonal lattice points of the mesh lattice is made shorter than longer one of each of cell pitches Pv and Ph in vertical and horizontal directions of the screen 50, and the arrangement direction of the mesh is inclined with respect to the arrangement direction of the cells in the screen 50. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a display panel device including a display panel and a front sheet attached thereto.

  Technological development of a plasma display panel (PDP), which is a self-luminous device, is progressing toward the enlargement of the screen with the aim of providing a more powerful display. An important issue in increasing the size is weight reduction.

  Generally, a display device including a plasma display panel includes a front plate filter that uses tempered glass as a support. The front plate filter is disposed in front of the plasma display panel and is separated from the plasma display panel. The front plate filter has various functions related to display operations such as optical adjustment of display color, antireflection of external light, shielding of electromagnetic waves, and shielding of near infrared rays, and also has a function of protecting the plasma display panel from mechanical shock. is doing. In addition, disposing the front plate filter in front of the plasma display panel is also effective for insulating the vibration sound of the plasma display panel.

  However, since the front plate filter has a large weight per se, it is not preferable for increasing the size of the plasma display panel. In order to reduce the weight of the display device, a structure in which a thin filter using a resin film as a support is directly attached to the front surface of the plasma display panel instead of assembling the front plate filter is suitable. Japanese Patent Application Laid-Open No. 2001-343898 describes a front filter comprising a transparent conductive film for EMI countermeasures and an antireflection film bonded to the front side thereof.

JP 2001-343898 A

    When a thick translucent sheet is attached to the front of the plasma display panel, the light from the screen is scattered on the sheet surface (interface with the air) far from the panel surface, and the outline of the bright part of the image appears blurred. There was a problem that “halation” became prominent. In addition, there is a problem that the reflected image of the external light is distorted by fine irregularities on the front surface of the sheet.

    An object of the present invention is to reduce halation while reducing the weight. Another object is to provide a light-weight display panel device that has impact resistance and a slight distortion of a reflection image of external light.

    In the present invention, the front sheet to be attached to the front surface of the display panel has a structure having a mesh having a larger plane size than the screen, which is made of a light-shielding body whose front surface is blackened. The mesh blocks reflection of light between the front and back interfaces of the front sheet and spreads in the surface direction, thereby reducing halation. Since the mesh eyes transmit visible light, there is no problem in display. The transmittance of the mesh is selected so that the halation is sufficiently reduced within a range where a predetermined luminance can be obtained. The relationship between the mesh pitch and the screen cell pitch is selected so that the light shields overlap in all cells.

    A thin film having a thickness of 30 μm or less is suitable as the mesh. The mesh pattern may be formed by a method of partially removing a uniform film or a method of forming a light shielding body by plating or deposition on a part of the formation surface. A mesh composed of a patterned film is desirable because it has better flatness and pattern uniformity than a mesh knitted fiber, and does not increase scattering that adversely affects halation. If the mesh is formed of a conductor, the mesh can be used for shielding electromagnetic waves. Further, by arranging the visible light transmittance adjusting layer on the front side of the mesh, it is possible to reduce reflected return light from the front sheet surface and improve halation.

    By placing a soft layer behind the mesh, the mesh can be protected against impact from the outside surface, and even if a hard scratch-resistant layer is placed in front of the mesh, it absorbs shock to the plasma display panel Function is obtained. In order to prevent damage to the mesh due to deformation of the soft layer, the thickness of the soft layer is preferably 1 mm or less. In order to prevent display distortion, it is desirable that the outer surface of the front sheet be a hard flat surface.

    According to the first to ninth aspects of the invention, it is possible to reduce the halation to the same extent as a panel without a front sheet while reducing the weight.

    According to the invention of claim 5, the front sheet can be used for shielding electromagnetic waves.

    According to the inventions of claims 6 to 8, a lightweight display panel device having impact resistance and a slight display distortion can be obtained.

It is a figure which shows the external appearance of the display apparatus which concerns on this invention. It is a figure which shows the structure of a display panel apparatus. It is a figure which shows the 1st example of a structure of a display apparatus. It is a figure which shows the structure of the principal part of a display apparatus. It is a figure which shows the outline | summary of fixation of a front sheet | seat. It is a figure which shows the layer structure of a front sheet. It is a figure which shows typically the conductor pattern of an electromagnetic wave shielding layer. It is a figure which shows the pitch of the mesh in an electromagnetic wave shielding layer. It is a figure which shows the other example of a mesh pitch. It is a figure which shows the 2nd example of a structure of a display apparatus. It is a figure which shows the outline | summary of the planar shape of a display panel apparatus. It is a figure which shows the 3rd example of a structure of a display apparatus.

  A plasma display panel useful as a color display device is a suitable application target of the present invention.

  FIG. 1 shows the appearance of a display device according to the present invention. The display device 100 is a flat type and has a screen 50 having a diagonal size of 32 inches. The screen 50 has a horizontal dimension of 0.72 m and a vertical dimension of 0.40 m. The decorative cover 101 that determines the planar size of the display device 100 has an opening larger than the screen 50, and the front surface of the display panel device 1 is partially exposed.

  FIG. 2 shows the configuration of the display panel device. The display panel device 1 includes a plasma display panel 2 that is a device constituting a screen, and a front sheet 3 as a filter member that is directly attached to the front surface of the plasma display panel 2 that serves as a display surface. The plasma display panel 2 is a self-luminous device that emits light by gas discharge, and includes a front plate 10 and a back plate 20. Both the front plate 10 and the back plate 20 are components using a glass plate having a thickness of about 3 mm as a support. Since there is no restriction on the configuration of the plasma display panel 2 in the embodiment of the present invention, description of the internal structure of the plasma display panel 2 is omitted here.

  FIG. 3 is a cross-sectional view taken along arrow 3-3 in FIG. 1 and shows a first example of the configuration of the display device. FIG. 4 is an enlarged view of a portion surrounded by a chain line in FIG. 3, and shows a structure of a main part of the display device. FIG. 5 shows an outline of fixing the front sheet.

  As shown in FIG. 3, in the display device 100, the display panel device 1 is arranged in a conductive housing 102 to which a decorative cover 101 is attached. The display panel device 1 is attached to an aluminum chassis 105 with a heat conductive adhesive tape 104, and the chassis 105 is fixed to the conductive housing 102 via spacers 106 and 107. A drive circuit 90 is disposed on the back side of the chassis 105. In FIG. 3, the power supply, the video signal processing circuit, and the audio circuit are omitted.

  The front sheet 3 is a flexible laminate in which a 0.2 mm-thick front side portion 3A having a resin film as a support and a 1.0 mm-thick back side portion 3B made of a resin layer overlap each other as will be described later. In particular, the thin front-side portion 3A, which is a functional film having a multilayer structure, is excellent in curvature. The plane size of the front sheet 3, strictly speaking, the plane size of the front side portion 3 A is larger than the plane size of the plasma display panel 2, and the peripheral portion of the front side portion 3 A is located outside the plasma display panel 2. The planar size of the back side portion 3B is smaller than that of the front side portion 3A and larger than that of the screen.

  The conductive housing 102 is a metal plate formed into a box shape having a square back surface, four side surfaces, and an annular front surface, and is a conductor that covers the side surface and the back surface of the plasma display panel 2 apart from them ( (See FIG. 5). The inner peripheral edge of the front surface of the conductive housing 102 is located outside the plasma display panel 2 when viewed from the front.

  In the display device 100, the front sheet 3 extends almost flat along the plasma display panel 2, and only the end thereof is in contact with the front surface of the conductive housing 102. An annular pressing member 103 is arranged on the front side of the front sheet 3, and the end of the front sheet 3 is fixed to the conductive housing 102 in such a manner that the front sheet 3 is sandwiched between the pressing member 103 and the front surface of the conductive housing 102. The In practice, however, the end of the front side portion 3A of the front sheet 3 is fixed to the conductive housing 102 as shown in FIG. Here, the front side portion 3A has an electromagnetic wave shielding layer 320 having an antihalation function. The electromagnetic wave shielding layer 320 is a back side layer in the front side portion 3A. The planar size of the front side portion 3A is equal to that of the front sheet 3 and is larger than that of the back side portion 3B. Therefore, the electromagnetic wave shielding layer 320 and the conductive housing 102 are connected by fixing the front sheet 3 to the conductive housing 102. The connection position is a position away from the plasma display panel 2.

  As well shown in FIG. 4, the plasma display panel 2 and the conductive housing 102 are connected to each other through the hollow support portion 3 </ b> Aa of the front sheet 3. Since the front sheet 3 has flexibility, even if the positional relationship between the plasma display panel 2 and the conductive housing 102 changes due to impact or heat, the stress applied to the plasma display panel 2 is relieved by the deformation of the portion 3Aa. . The influence on the connection between the front sheet 3 and the conductive housing 102 is also reduced. Deformation includes bending, shrinking, stretching, and twisting.

  As a method of fixing the end portion of the front sheet 3, a method of driving a plastic rivet 150 is suitable from the viewpoint of mass productivity and weight reduction. It is desirable that holes 3Ah, 102h, and 103h that fit the rivets 150 are provided in advance in the front sheet 3, the conductive housing 102, and the pressing member 103. A large number of holes can be collectively formed by punching. Although a protrusion corresponding to the thickness of the pressing member 103 is generated at the end portion of the front sheet 3, an increase in the thickness of the display device 100 due to this is only about 1 to 2 mm.

  FIG. 6 shows the layer structure of the front sheet. In the front sheet 3, an optical film layer 310 having a thickness of 0.1 mm, an electromagnetic wave shielding layer 320 having a thickness of 0.1 mm, a shock absorbing layer 351 having a thickness of 1.0 mm, and an adhesive layer 352 having a thickness of several μm are stacked in this order from the front side. The laminate is about 1.2 mm thick. The optical film layer 310 and the electromagnetic wave shielding layer 320 constitute the front side portion 3A, and the plane size is common in these layers. The visible light transmittance of the entire front sheet 3 is about 40% as a value corrected for visibility. The shock absorbing layer 351 and the adhesive layer 352 constitute the back side portion 3B. The weight of the front sheet 3 is about 500 g, and the front sheet 3 is significantly lighter than a conventional front plate filter (about 4.2 kg).

  The optical film layer 310 includes a film 311 made of PET (polyethylene terephthalate), an antireflection film 312 coated on the front side of the film 311, and a dye layer 313 formed on the back side of the film 311. The antireflection film 312 prevents reflection of external light. However, the function of the antireflection film 312 may be changed from AR (anti-reflection) to AG (anti-glare). The antireflection film 312 includes a hard coat that increases the scratch resistance of the sheet surface to a pencil hardness of 4H. The dye layer 313 is responsible for adjusting the visible light transmittance of red (R), green (G), and blue (B) for color display and shielding near infrared rays. The dye layer 313 includes an infrared light absorbing dye that absorbs light in the vicinity of a wavelength of 850 nm to 1100 nm, a neon light absorbing dye that absorbs light in the vicinity of a wavelength of 580 nm, and a dye for adjusting the visible light transmittance in the resin. It is. The external light reflectance of the optical film layer 310 is 3% with a visibility corrected value, and the visible light transmittance is 55% with a visibility corrected value. The infrared transmittance is 10% on average in the wavelength region.

  The electromagnetic wave shielding layer 320 includes a PET film 321 and a 10 μm-thick conductive layer 322 which is a copper foil having a mesh portion. In the conductive layer 322, the visible light transmittance of the region overlapping with the screen is 80%. Since the front surface of the conductive layer 322 is blackened, when the electromagnetic wave shielding layer 320 is viewed through the optical film layer 310, the electromagnetic wave shielding layer 320 appears almost black.

  The film 311 of the optical film layer 310 and the film 321 of the electromagnetic wave shielding layer 320 have a function of preventing glass scattering when an emergency situation occurs in which the glass plate of the plasma display panel 2 breaks. In order to obtain this function, it is desirable that the thickness of the film 311 and the film 321 is 50 μm or more.

  The shock absorbing layer 351 is made of an acrylic soft resin and has a visible light transmittance of 90%. The shock absorbing layer 351 is formed by applying a resin. At the time of application, the resin enters the mesh gap in the conductive layer 322 to flatten the conductive layer 322. Thus, light scattering due to the unevenness of the conductive layer 322 is prevented.

  The shock absorbing layer 351 made of a soft resin contributes to making the front sheet 3 thin. The display panel apparatus 1 was placed on a horizontal hard floor, and a test was performed in which about 500 g of iron balls were dropped toward the center of the screen. The impact force immediately before the plasma display panel 2 was cracked was about 0.73 J. The result of the similar test for the plasma display panel 2 without the front sheet 3 is about 0.13 J, and the result of the similar test for the display panel device in which only the optical film layer 310 is attached to the plasma display panel 2 is about. It was 15J. That is, the improvement in impact resistance by the front sheet 3 is about 0.6 J, and the impact absorbing layer 351 is responsible for the most improvement of about 0.58 J. The 1.0 mm thick shock absorbing layer 351 has practicality.

  In this embodiment, the rear surface layer portion of the resin layer constituting the shock absorbing layer 351 functions as the adhesive layer 352. The shock absorbing layer 351 adheres relatively firmly to the electromagnetic wave shielding layer 320 made of PET and copper. On the other hand, the adhesive layer 352 adheres loosely to the glass surface that is the front surface of the plasma display panel 2. Its adhesive strength is about 2 N / 25 mm. When the front sheet 3 is peeled off, the optical film layer 310 and the electromagnetic wave shielding layer 320 are not peeled off, and the front sheet 3 is normally peeled off from the plasma display panel 2. “Normal” means an aspect in which a uniform peeled surface having no peeling residue that can be visually observed is obtained.

  FIG. 7 schematically shows a conductor pattern of the electromagnetic wave shielding layer. The conductive layer 322 of the electromagnetic wave shielding layer is a layer in which a conductive mesh 322A that overlaps the screen 50 and an annular conductor 322B that surrounds the conductive mesh 322A are integrated. The planar size of the conductive mesh 322A as the metal mesh pattern film of the present invention is larger than that of the screen 50. The width of the upper, lower, left and right bands constituting the conductor 322B is about 30 mm. The back side portion 3B of the front sheet is disposed so that the peripheral edge thereof overlaps with the annular conductor 322B over the entire length. Thereby, since the periphery of the back side part 3B is hidden by the conductor 322B in the observation from the front, even if the outline of the back side part 3B is an indefinite shape, the orderly appearance is not impaired. In forming the back side portion 3B, it is necessary to expose the vicinity of the periphery of the conductor 322B, but high pattern accuracy is not necessary. An error of about 10 mm is allowed.

  In FIG. 7, the conductive mesh 322A is coarse, but the actual mesh pitch is about the same as the cell pitch of the screen 50 as described later. The alignment mark and the rivet hole can be formed in the conductor 322B without increasing the number of manufacturing steps of the conductive layer 322. The alignment mark facilitates the work of attaching the front sheet 3 to the plasma display panel 2.

  FIG. 8 shows the pitch of the mesh in the electromagnetic wave shielding layer. The grid of the conductive mesh 322 </ b> A is a square pattern, and the mesh array direction is inclined with respect to the cell 51 array direction on the screen 50. The inclination angle in this example is 55 °. The screen 50 is composed of a large number of cells 51 arranged in an orthogonal arrangement format, and the vertical cell pitch Pv is about 390 μm and the horizontal cell pitch Ph is about 300 μm. On the other hand, the mesh pitch Pm of the conductive mesh 322A is 280 μm. Here, the length Dm between the diagonal lattice points of the mesh is about 350 μm, which is shorter than the cell pitch Pv, which is the longer one of the vertical and horizontal cell pitches on the screen 50. A state in which all the cells 51 and a part of the mesh overlap is obtained by the magnitude relation of the pitch and the inclination in the arrangement direction. That is, a light shielding body is arranged in front of all the cells 51, and the halation preventing effect can be obtained almost uniformly over the entire screen 50.

  FIG. 9 shows another example of the mesh pitch. In FIG. 9, the length Dm ′ between the diagonal lattice points of the conductive mesh 322 </ b> A is equal to the cell pitch Pv in the vertical direction on the screen 50. Also in this case, all the cells 51 overlap with a part of the mesh. In order to make the overlap between each cell and the mesh more uniform, the mesh pitch may be reduced. However, considering the strength and conductivity, it is desirable to set the line width of the mesh to 10 μm or more, and attention should be paid to the fact that if the mesh pitch is reduced under the restriction, the visible light transmittance becomes excessively small.

  FIG. 10 shows a second example of the configuration of the display device. The basic configuration of the display device 200 is the same as that of the display device 100 described above. In FIG. 10 and the following drawings, the constituent elements having the same reference numerals as those in FIG. 3 are constituent elements common to the display apparatus 100.

  The display device 200 includes a display panel device 5 that is a screen module. The display panel device 5 includes a plasma display panel 2 and a front sheet 6, and the front sheet 6 includes a front side portion 6A and a back side portion 6B. The layer structure of the front sheet 6 is the same as in FIG. In the display device 200, the planar size of the front side portion 6A is larger than that in the above-described example, the four sides of the periphery of the front side portion 6A are bent substantially at right angles to the back side, and the end of the front side portion 6A is the conductive housing 202. It is fixed to. The fixed form is a form in which the front side portion 6A is sandwiched between the side surface of the conductive housing 202 and the annular pressing member 203. The fixing position is behind the front surface of the plasma display panel 2 and away from the plasma display panel 2. At the fixed position, the electromagnetic wave shielding layer of the front side portion 6A is in contact with the conductive housing 202, and both are conductively connected.

  By bending the front side portion 6A, the fixed position comes closer to the plasma display panel 2 than in the case where it is not bent, and the planar size of the conductive housing 202 can be reduced. Moreover, since the fixing position is behind the case where the front side portion 6A is not bent, the thickness (side dimension) of the conductive housing 202 can be reduced. The downsizing of the conductive housing 202 contributes to the weight reduction of the display device 200.

  In addition, when the factory (device maker) which manufactures the display panel apparatus 5 and the factory (set maker) which accommodates the display panel apparatus 5 in a housing and completes the display apparatus 200 differ, when the display panel apparatus 5 is transported It is necessary to prevent damage to the peripheral edge of the front side portion 6A. For example, when the display panel device 5 is transported in a state where it is attached to the aluminum chassis 205, the end of the front side portion 6A is fixed to the chassis 205 with an insulating material to reduce the packaging size. Can do.

  FIG. 11 shows an outline of a planar shape of the display panel device. In the front sheet 6 of the display panel device 5, cuts 61 that facilitate folding of the front side portion 6A are formed at the four corners of the front side portion 6A. A plurality of holes 6Ah used for fixing the front side portion 6A are formed along the periphery of the front side portion 6A.

  FIG. 12 shows a third example of the configuration of the display device. The configuration of the display device 300 is almost the same as that of the display device 200 described above. The display device 300 is characterized in that the inner peripheral edge of the front surface of the decorative cover 301 is brought close to the screen area, and the sound absorbing materials 351 and 352 are disposed between the decorative cover 301 and the front sheet 6. The sound absorbing materials 351 and 352 are bonded to the decorative cover 301 in advance, and the sound absorbing materials 351 and 352 are pressed against the front sheet 6 by placing the decorative cover 301 on the display panel device 5. Since the sound absorbing materials 351 and 352 are flexible sponges, no excessive force is applied to the plasma display panel 2. Since the audible noise (abnormal noise) due to the vibration of the plasma display panel 2 is large in the peripheral portion of the plasma display panel 2, the noise can be greatly reduced by the arrangement of the sound absorbing materials 351 and 352. In the conventional structure in which the front plate filter is disposed in front of the plasma display panel, although noise is blocked by the front plate filter, there is sound propagation reflected from the front plate filter and moving forward from the back. In contrast, the display device 300 absorbs the abnormal noise almost completely, so that a quiet display environment can be obtained. Since the sound emitted from the plasma display panel 2 is conducted through the back side portion 6B attached to the plasma display panel 2, it is desirable to arrange the sound absorbing materials 351 and 352 so as to overlap the back side portion 6B.

According to the above-mentioned Example 1, Example 2, and Example 3, halation can be reduced as compared with the case where the front sheets 3 and 6 are not attached. Specifically, the white pattern of about 10cm square was displayed at a luminance of 350 cd / m ^2, a length from the end of the white pattern to the end of the region where light emission appears to 1 cd / m ² or more luminance spread halation Measured as an indicator. By attaching the front sheets 3 and 6, the halation was reduced by 0.7 times. Note that. When the conventional plate filter was placed 1 cm away from the front of the panel in front of the plasma display panel, the halo was increased 2.5 times compared to the case where no plate filter was placed.

  According to the above-described Example 1, Example 2, and Example 3, in the conductive layer 322 of the electromagnetic wave shielding layer 320, the conductive mesh 322A that transmits light and the annular conductor 322B that surrounds the conductive mesh 322A are integrally formed. Therefore, the price of the display panel devices 1 and 5 can be reduced as compared with a structure in which a conductive tape is pasted around a mesh woven with conductive fibers.

  The above embodiment has the following modifications.

  The rearmost surfaces of the front sheets 3 and 6 can be an adsorption surface having a self-adsorption action. For example, after the shock absorbing layer 351 is formed, a film made of a silicone material is formed on the surface of the shock absorbing layer 351. Thereby, it becomes possible to repeat peeling and affixing between the front sheets 3 and 6 and the plasma display panel 2 any number of times. This contributes to maintenance at the stage after the display panel device is assembled, as well as to reduce loss during the manufacture of the display panel device. This is because the front sheet can be easily replaced when it is damaged. It is also conceivable to adsorb only the antireflection layer 312 to the remaining portions of the front sheets 3 and 6 as a sheet that self adsorbs. With respect to the strength of adsorption, it is desirable that separation is possible only with a pulling force in the vertical direction, and the adsorption force is desirably 4 N / 25 mm or less (when the separation speed is 50 mm / min).

  The same effect can be obtained by using an acrylic foam similar to the material of the shock absorbing layer 351 instead of the silicone material.

  In addition, when attaching the front sheets 3 and 6, if necessary, a cleaning process represented by spraying water or air is performed in advance, and the adsorbed surface is cleaned when the peeled front sheet is reused. Apply processing.

  The red phosphor (for example, (Y, Gd, Eu) PVO4) of the plasma display panel 2 and the discharge gas (for example, Ne—Xe gas of Xe 5% or more at a gas pressure of 500 Torr) are reduced so as to reduce the amount of orange light emission. It is useful to design properly. If an optical filter with a narrow absorption wavelength range that selectively absorbs orange light is not required, the front sheet 3 can be further reduced in price.

  In the above description, the plasma display panel is exemplified, but the device constituting the screen is not limited to the plasma display panel, and other display panels including EL (Electro Luminescence), FED (Field Emission Display), and liquid crystal constitute the screen. Even with the device, the anti-halation by the mesh can be applied.

  The present invention contributes to improvement in display quality and cost reduction of a light-weight display device having a large screen.

3,6 Front sheet (sheet)
2 Plasma display panel (display panel)
100, 200, 300 Display device 1, 5 Display panel device 320 Electromagnetic wave shielding layer 322A Conductive mesh (mesh made of light shielding body)
310 Optical film layer (transmittance adjusting layer)

Claims (9)

A display panel device comprising a plasma display panel and a translucent front sheet attached to the front surface of the plasma display panel,
The display panel device according to claim 1, wherein the front sheet has a mesh having a larger plane size than a screen of the plasma display panel, which is made of a light-shielding body whose front surface is blackened.   The mesh grid is a square pattern, the length between diagonal grid points in the mesh is shorter than the longer one of the vertical and horizontal cell pitches on the screen, and the mesh array direction is The display panel device according to claim 1, wherein the display panel device is inclined with respect to a cell arrangement direction on the screen.   The display panel device according to claim 1, wherein the visible light transmittance of the mesh is a value within a range of 60% to 90%.   The display panel device according to claim 1, wherein the front sheet includes a transmittance adjustment layer that attenuates visible light located on a front side of the mesh.   The display panel apparatus according to claim 1, wherein the mesh is a patterned metal film having a uniform thickness.   The display panel device according to claim 5, wherein the front sheet has an impact absorption layer made of a resin located on a rear side of the mesh.   The display panel device according to claim 6, wherein the shock absorbing layer is softer than the mesh.   The display panel device according to claim 6, wherein the shock absorbing layer has a function of protecting the mesh against a local shock of 0.2 Joule. In a display device in which a filter member having a predetermined optical filter function is arranged on the front surface of the plasma display panel to constitute the device surface,
A metal mesh having a uniform thickness between the optical filter member and the plasma display panel, which absorbs display light that is reflected on the plasma display panel side from the device surface made of the filter member and is recursed at least because the filter surface side is black. A display device comprising: a pattern film; and the metal mesh pattern film, the filter member, and the plasma display panel are integrally bonded to each other without an interface with air.

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