KR100935451B1 - The rear projection screen - Google Patents

Abstract

PURPOSE: A rear projection screen is provided to secure the wide viewing angle by improving the brightness and uniformity of a screen and to improve the sharpness of a screen. CONSTITUTION: A rear projection screen(100) is composed of a diffusion film(10), a transparent net(20), a transparent adhesion layer(30), and a light absorption part(40). The diffusion film photo-diffuses the light by diffuse-reflecting the transmitted light. The transparent net is positioned on the rear of the diffusion film. The transparent adhesion layer is interposed between the diffusion film and the transparent net. The light absorption part is formed on the rear side of the transparent adhesion layer.

Description

Rear Projection Screen {The Rear Projection Screen}

The present invention relates to a rear projection screen, and more particularly, to reduce weight and provide ease of transportation and installation, and to improve the brightness and uniformity of the screen and to secure a viewing angle, and to improve the screen sharpness. It is about.

In the display apparatus, as the demand for large-screen high-definition images increases, the spread of projectors that enlarge and project a small image using a projection lens is spreading. Such projectors are classified into a front projection projector and a rear projection projector according to a projection method.

Front projection is a method of projecting an image in the same direction as a user views an image, and a front projection projector is generally used in a theater or a conference room. On the other hand, the rear projection is a method of projecting the image in a direction opposite to the user viewing the image. A rear projection projector is provided on the projection TV to generate an image. In addition, rear projection is more used than front projection because a bright screen can be seen even in a bright environment.

In particular, in the case of a screen used for a digital touch display device or an electronic blackboard among the rear projection screens, a computer screen is projected and displayed from the rear of the screen, and a finger or a similar object is placed within 15 mm of the screen surface through an infrared sensor or an infrared camera sensor. When it is approached, it is recognized as a touch, and in the case of an electronic blackboard which aims to write letters directly on the screen, the touch can be executed without writing the written letters only when the touch is recognized within 10 mm.

In the case of the rear projection screen for the copyboard, the size of the screen is larger than 70 inches, and most of the tempered glass screen using the transparent tempered glass is used to minimize the deformation of the screen due to the temperature and humidity of the use environment due to the enlargement. .

However, in the case of such tempered glass screen, it is difficult to remove the diffusion film from the transparent tempered glass after the diffusion film is adhered to the transparent tempered glass once, and fine dust or hair is stuck to the bonding surface of the tempered glass or the diffusion film. Bonding defects such as bubbles are frequently generated, and the weight is increased due to the enlargement of the tempered glass according to the large production, making it difficult to transport or install the site, and there is a fear of damage due to impact during transportation.

Accordingly, in Korean Utility Model Registration No. 20-0444192, as shown in FIG. 1, a touch sensor and a light weight mesh screen for an electronic blackboard of the method of attaching the diffusion film 130 to the transparent mesh 120 have been posted. The above design improves the adhesion defect of the diffusion film by attaching the diffusion film to the transparent mesh instead of the tempered glass, which is a conventional screen, but the effect of lightening the screen, but when the brightness is increased, the contrast (contrast) falls, large contrast There is a problem that the brightness is remarkably lowered when raising, and there is a problem that an uneven stain occurs on the white screen, and the light is interposed between the orthogonal pixel and the transparent mesh of the original screen projected by the transparent mesh formed by orthogonal transparent yarns. There is a problem that interference occurs.

Therefore, the present invention has been made to solve the above problems, and by reducing the weight of the screen to facilitate the transport and installation of the screen,

Enhances the contrast of the screen, enabling a large screen with clear image quality.

The present invention provides a rear projection screen that prevents spots from occurring even when the brightness of a white screen is increased, and also prevents interference of light.

In one embodiment of the present invention for solving the above-mentioned problems, the diffusion film 10 for diffusing the light transmitted through diffuse reflection; A transparent mesh 20 disposed on the back surface of the diffusion film 10 and formed by weaving transparent yarns at right angles; A transparent adhesive layer 30 interposed between the diffusion film 10 and the transparent mesh 20 to adhere thereto; And a black light absorbing part 40 provided on a rear surface of the transparent adhesive layer 30 and filled in a lattice space of the transparent mesh 20. The rear projection screen 100 comprising: to provide.

In the rear projection screen 100 according to the present invention, the transparent mesh 20 can reduce the thickness of the intersection to a predetermined thickness by thermally compressing the intersection where the transparent yarn is orthogonal.

In addition, the diffusion film 10 is a polystyrene, acrylic resin and glass having different refractive indices in a base film formed of any one material selected from transparent materials of PVC, acrylic, urethane, PE, PET, and glass It can be formed by coating a diffusing agent mixed with the base film,

Preferably, the black light absorbing portion 40 forms a black adhesive layer on the back of the transparent adhesive layer 30, and thermally compresses the transparent mesh 20 to the back of the black adhesive layer, The transparent mesh 20 may be formed to contact the rear surface of the transparent adhesive layer 30 through the black adhesive layer.

More preferably, the black fine powder 61 formed in the form of black beads mixed with black dye using glass or synthetic resin as a material is mixed with the UV resin 60 to form the back surface of the transparent mesh 20. It can be applied to the lattice space.

Further, the transparent mesh 20 formed by weaving transparent yarns at right angles may be twisted at a predetermined angle to form a lattice in a lozenge shape.

Rear projection screen according to the present invention, by attaching a transparent mesh configured to weave orthogonal transparent yarns instead of tempered glass, it is possible to reduce the weight of the screen to facilitate the transport and installation of the screen,

By forming a black light absorbing part in the lattice space of the transparent mesh, it is possible to implement a large screen of clear image quality by improving the contrast of the screen,

By reducing the thickness by thermocompression bonding the areas where the transparent yarns in the transparent mesh, even if the brightness on the screen of the white screen does not occur,

In addition, by forming the lattice into a rhombic shape by twisting the transparent mesh formed by weaving the transparent yarns orthogonal to a predetermined angle, it is possible to implement a clear image quality without light interference phenomenon. .

DETAILED DESCRIPTION Hereinafter, embodiments of the present invention in which the above object can be specifically realized are described with reference to the accompanying drawings. In describing the embodiments, the same names and symbols are used for the same components, and additional description thereof will be omitted below.

1 is a cross-sectional view showing a conventional lightweight mesh screen, Figure 2 is a front view showing a transparent mesh 20 in the rear projection screen 100 according to the present invention, Figure 3 is a rear projection screen 100 in accordance with the present invention 4 is a cross-sectional view illustrating thermal compression of the transparent mesh 20 using the compression roller 50, and FIG. 4 is a cross-sectional view showing an embodiment of the rear projection screen 100 according to the present invention. 5 is a cross-sectional view showing that the UV resin 60 mixed with black fine powder is applied to the rear surface of the black light absorbing portion 40 formed in the lattice space of the transparent mesh 20 of FIG. 4. 6A through 6C are cross-sectional views illustrating a process of forming the black light absorbing part 40 formed in the lattice space of the transparent mesh 20, and FIG. 7 is a transparent mesh (in the rear projection screen 100 according to the present invention). 20) is a perspective view showing that the lattice is formed into a rhombus shape by twisting at a predetermined angle, and then attached to the diffusion film 10.

As shown in FIGS. 2 and 4, the rear projection screen 100 according to the embodiment of the present invention is formed by weaving transparent yarns orthogonally, and has a transparent mesh disposed on the rear surface of the film. 20) serves to refract and scatter light projected from a light source located at the rear of the screen in a primary manner, and secondly scatters light scattered first by the transparent mesh 20 to diffuse reflection and to perform light diffusion. Diffusion film 10 having a, is provided between the transparent mesh 20 and the diffusion film 10, a transparent adhesive layer 30 for adhering the transparent mesh 20 and the diffusion film 10 is formed, It is provided on the back of the transparent pressure-sensitive adhesive layer, it is composed of a black light absorbing portion 40 filled in the empty lattice space of the transparent mesh 20.

The diffusion film 10 is located in front of the rear projection screen 100 according to the present invention, a transparent material of any one selected from PE (polyethylene), PET (polyethylene terephthalate), PVC, acrylic, urethane In the base film to be formed, a diffusing agent mixed with polystyrene, acrylic resin and glass having different refractive indices in a predetermined ratio may be formed by coating the base film. Preferably, the diffusion of a bead mixture having a different refractive index of about 20 to 30 micrometers to 100g of acrylic-based UV curable resin in a PET base film of 150 to 180 microns thick (about 3 to 10g) The coating on the PET base film may form a diffusion film 10 having an improved viewing angle. In this case, the bead mixture may be mixed with a polystyrene having a refractive index of 1.59, an acrylic resin having a refractive index of 1.49, and a glass having a refractive index of 1.52 in a ratio of 1: 2: 1, respectively, to form the bead mixture.

The transparent mesh 20 is drawn into a thin round plastic thread using a plastic material having transparency and tensile strength, such as polyester, polypropylene and nylon, and then the circular plastic thread is orthogonal to a carpenter of 50 to 300 necks. It is formed by weaving. As described above, in the case of forming a screen by weaving a circular plastic yarn orthogonal to the transparent mesh 20 formed on the diffusion film 10 while maintaining the thickness of the portion where the plastic yarn crosses each other as it is. The thickness of the intersection portion is almost twice the thickness of the single circular plastic seal constituting the transparent mesh 20, causing uneven light scattering during projection of a bright screen, resulting in uneven spots on a white full screen screen. Will cause. Thus, preferably, as shown in Figure 3, in the rear projection screen 100 according to the present invention after weaving the circular plastic seal orthogonally, a pair of compression rollers 50 heated to a constant temperature By passing the thickness between the areas where the plastic seal crosses each other by a certain thickness, the scattering of the light passing through the transparent mesh 20 can be made uniform, which may appear on the white full screen screen By preventing the occurrence of speckles, it is possible to implement a screen with a clear image quality.

In order to bond the transparent mesh 20 to the rear surface of the diffusion film 10, the back surface of the diffusion film 10 is coated with a transparent adhesive to form a transparent adhesive layer 30, preferably in the transparent adhesive By mixing the bead mixture and coating the back of the diffusion film 10, the viewing angle of the screen may be further improved.

The black light absorbing portion 40 formed in the lattice space of the transparent mesh 20 is first formed by forming a black adhesive layer on the back side of the transparent adhesive layer 30, and predetermined as a back side of the black adhesive layer. Thermally compressing the transparent mesh 20 heated to a temperature so that the heated transparent mesh 20 heat-flows the black adhesive layer to push the black adhesive layer into a lattice space that is an empty space of the transparent mesh 20. It penetrates through and heat-compresses to contact the transparent adhesive layer 30 provided on the front surface of the black adhesive layer.

In more detail, looking at the formation process of the black light absorbing portion 40, as shown in Figure 6a to 6c, the transparent adhesive layer 30 to the thickness of 10 to 30 micron meter on the back of the diffusion film 10 On the back side, the melting temperature of the transparent adhesive layer 30 and the transparent mesh 20 is formed of a material lower than the plastic yarn constituting the black, the black light absorbing portion layer mixed with black dye 5 to 10 Apply with a micron meter.

The black light absorbing layer coated on the back surface of the transparent adhesive layer 30 is heated to a predetermined temperature below the melting point of the material transparent yarn constituting the transparent mesh 20, and thermally pressurized to the black light absorbing layer, and the transparent mesh In the heat pressurization, the black light absorbing layer is heated in a viscous fluid state due to the heated transparent mesh 20, and the empty space of the transparent mesh 20 formed by orthogonal transparent yarns by pressing the plastic thread. By pushing toward the center of the phosphorus lattice to fill the empty space of the lattice, the transparent mesh 20 advances until it reaches the transparent adhesive layer 30 located in front of the black light absorbing layer while pushing the black light absorbing layer, the It is possible to form a black light absorbing portion 40 in the grid space of the transparent mesh 20.

The light is scattered and diffused while passing through the transparent mesh 20 to improve the wide viewing angle and brightness, and as described above, the light absorbing portion 40 is formed by filling the lattice space of the transparent mesh 20, thereby increasing brightness. Even if you increase the brightness (contrast) will not be lowered bright and clear picture on the screen can be realized.

Preferably, as shown in Figure 5, black fine powder 61 in the form of black beads formed by mixing a black dye in glass or synthetic resin mixed with a UV resin 60 of the transparent mesh 20 It is applied to the lattice space on the back, and the overall contrast of the screen can be adjusted by adjusting the application amount of the UV resin 60 mixed with the black bead-shaped fine powder.

In addition, although the image quality of the screen projected on the screen was not clear due to the interference of light generated between the rectangular orthogonal pixels projected from the light source and the transparent mesh 20 formed orthogonal to the conventional rectangular shape, the transparent yarn was At the time of bonding the transparent mesh 20 formed by weaving orthogonally to the diffusion film 10 through the transparent adhesive layer 30, the rectangular mesh lattice pattern formed at right angles to the vertical and horizontal lines is used. Rather than bonding 20 horizontally, preferably, as shown in FIG. 7, the transparent mesh 20 is slightly twisted to deform the lattice pattern into a rhombus shape and attached to the diffusion film 10. By suppressing the interference of light generated by the orthogonal pixel and transparent mesh 20 projected at, the screen of clearer and clearer image quality is displayed on the screen. It is possible hyeonhal.

Although some embodiments have been described above by way of example, it will be apparent to those skilled in the art that the present invention may be embodied in many other forms without departing from the spirit and scope thereof.

Accordingly, the above-described embodiments are to be considered as illustrative and not restrictive, and all embodiments within the scope of the appended claims and their equivalents are included within the scope of the present invention.

1 is a cross-sectional view showing a conventional lightweight mesh screen;

2 is a front view showing the transparent mesh 20 in the rear projection screen 100 according to the present invention;

3 is a cross-sectional view showing that the rear projection screen 100 according to the present invention thermally compresses the transparent mesh 20 using the pressing roller 50;

4 is a cross-sectional view showing one embodiment of a rear projection screen 100 according to the present invention;

FIG. 5 is a cross-sectional view showing that the UV resin 60 mixed with black fine powder is coated on the rear surface of the black light absorbing portion 40 formed in the lattice space of the transparent mesh 20 of FIG. 4;

6A to 6C are cross-sectional views illustrating a process of forming the black light absorbing part 40 formed by filling the lattice space of the transparent mesh 20; And

FIG. 7 is a perspective view of the rear projection screen 100 according to the present invention, in which a transparent mesh 20 is twisted at a predetermined angle to form a lattice in a rhombus shape, and then attached to the diffusion film 10.

Explanation of symbols on the main parts of the drawings

10: diffusion film 20: transparent mesh

30: transparent adhesive layer 40: light absorption part

41: black adhesive layer

50: compression roller 60: UV resin

61: black fine powder

100: rear projection screen

Claims (6)

Diffusion film 10 for diffusing the light transmitted through diffuse reflection; A transparent mesh 20 disposed on the back surface of the diffusion film 10 and formed by weaving transparent yarns at right angles; A transparent adhesive layer 30 interposed between the diffusion film 10 and the transparent mesh 20 to adhere thereto; And And a black light absorbing part (40) provided on the rear surface of the transparent adhesive layer (30) and filled in the lattice space of the transparent mesh (20). The method of claim 1, The transparent mesh 20, A rear projection screen (100), characterized in that the cross section of the transparent yarn is orthogonal thermal compression to reduce the thickness of the cross section to a predetermined thickness. The method of claim 1, The diffusion film 10, In the base film formed of any one material selected from PVC, acrylic, urethane, PE, PET of a transparent material, A diffusing agent in which polystyrene, acrylic resin and glass having different refractive indices are mixed and formed at a predetermined ratio, Rear projection screen 100, characterized in that formed by coating on the base film. The method of claim 3, wherein The black light absorbing portion 40, A black adhesive layer is formed on the back side of the transparent adhesive layer 30, and the transparent mesh 20 is thermally compressed to the back side of the black adhesive layer, so that the transparent mesh 20 penetrates the black adhesive layer to make the transparent. Rear projection screen 100, characterized in that formed in contact with the back of the adhesive layer (30). The method of claim 4, wherein Black fine powder (61) formed in the form of black beads mixed with black dye using glass or synthetic resin as a material, The rear projection screen (100), characterized in that it is mixed with the UV resin (60) and applied to the lattice space on the back of the transparent mesh (20). The method according to any one of claims 1 to 5, The transparent mesh 20 formed by weaving transparent yarns at right angles, Rear projection screen 100, characterized in that to form a grid in a rhombic shape by twisting at a predetermined angle.

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