KR100450344B1 - Light projected screen board and its manufacturing method - Google Patents

Abstract

The present invention relates to a projector light transmissive screen and a method of manufacturing the same, and an object thereof is to improve the transmissive projector screen in terms of brightness and clarity, helping to activate the market, and to implement a projector function outdoors. The present invention provides a transmissive screen and a method of manufacturing the same, which extends the projector market, which has been mainly used indoors (indoors, offices, meeting rooms through blackouts, etc.) to the outdoors, by improving performance.

According to an aspect of the present invention, there is provided a transmissive screen configured to transmit light of a projector to form an image, comprising: an embossed film layer that first refracts light of the projector, a polycarbonate layer having the film layer attached to one side, and the poly It consists of a matte transparent paint layer added with an adhesive bonded to the other side of the carbonate, a glass bead layer sprayed on the transparent paint layer so as not to overlap and refracted by light, and a solvent layer coating the surface of the glass bead layer. A transmissive screen and a method for producing the same are provided.

Description

Projector light transmissive screen and its manufacturing method

The present invention relates to a projector light transmissive screen and a method of manufacturing the same, which will be described in more detail by maximizing the amount of transmitted light and minimizing the loss of the image on the screen to maintain the most optimized image quality. The present invention relates to a transmissive screen and a method of manufacturing the same, which extends the function of a projector that has been used only indoors to enjoy a wide screen of a projector through a transparent screen having bright light and vivid image quality even outdoors.

Conventional transmissive screens have been largely covered with white silk (white mat) and embossed glass or acrylic plates, with a light coating on them.

Therefore, if the amount of light from the projector lamp is set to 100 (GAIN: the brightness of the light reflected on the mirror is generally called 100 gain, 1 gain is the brightness of the light reflected on white paper), the brightness of the image on the actual screen is The maximum has been less than 20 (GAIN) (20 gains appear to be the maximum brightness even for reflective screens).

In addition, if the light transmission amount is increased, the loss of the image increases with the light so that the light becomes bright but the image is not properly formed.

In particular, the transmissive screen made of white cloth is used only indoors where blackouts are installed because of the clarity and brightness of the light.

Moreover, such screens are very likely to be damaged when exposed outdoors due to the nature of the material as well as the brightness or image quality, as well as being exposed to strong weather or strong direct sunlight. Has been used.

As a result, most of the conventional transmissive screens have been suppressed in places where blackouts are not installed due to the low brightness of 20 gain or less, the sharpness behind the reflective screen, and the color reproduction ability of about 30%. We are trying to develop technology to overcome these problems.

The purpose of the present invention to solve the above problems has been raised only the need for technical development, but the actual development of the technology is not made in the transmission projector screen, which is insignificant in terms of brightness and clarity, and dramatically improved it in terms of brightness and sharpness to activate the market In addition to improving the screen performance to enable the implementation of the projector outdoors, the transmissive screen expands the projector market, which has been mainly used indoors (indoors and offices, meeting rooms through blackouts, etc.) to the outdoors. And to provide a method for producing the same.

The purpose of the present invention as described above is to maintain the amount of light emitted from the lamp of the projector as it is, the condensation of the projected image on the screen without loss of only 1%, so that the image is transmitted with light and high luminance on one side of the screen It is expressed in the resolution and resolution, and it has more than 3 times the brightness of the existing screen even at the viewing angle of 60 degrees or more, which is much higher than the conventional viewing angle of 40 degrees, and it is strong and tough so that it can be used outdoors in terms of materials. It is achieved by providing a curved and planar transmissive screen and a method of manufacturing the same, for example, by adding polycarbonate (hereinafter referred to as PC).

1 is a schematic view showing the components of the transmissive screen of the present invention;

Figure 2 is a block diagram showing the transmission state of light of the conventional transmissive screen,

Figure 3 is a block diagram showing a transmission state of the transmissive screen of the present invention,

4 is a flowchart illustrating a method of manufacturing a transmissive screen of the present invention;

5 is a comparison table of the luminance difference between the present invention and the existing product,

6 is an enlarged view of a surface treatment state of a transmissive screen of the present invention;

Figure 7 is a cross-sectional view showing the edge coupling portion of the transmissive screen of the present invention,

Figure 8 is an embodiment showing a rooftop advertising board using the present invention.

<Description of the symbols for the main parts of the drawings>

(1): film layer (2): polycarbonate layer

(3): matt transparent paint layer (4): glass bead layer

(5): solvent layer (6): air layer

(7): Polycarbonate layer for screen protection (8): Silicone packing material

9: stainless frame 10: bolt

The configuration of the present invention to achieve the object as described above and to solve the conventional drawbacks is to fix the polycarbonate layer constituting the base screen, the glass bead layer for refracting incident light and each component constituting the screen And an adhesive or solvent layer for support, wherein the transmissive screen allows light to pass through the projector to form an image, comprising: an embossed film layer (1) for first refracting light of the projector, and the embossed film layer The polycarbonate layer 2 attached to one side, the matte transparent paint layer 3 to which the adhesive agent adhere | attached on the other side of this polycarbonate, and 1/3 of diameter are buried so that it may be sprayed on this transparent paint layer and does not overlap. The glass bead layer (4) for secondary refraction, the solvent layer (5) for coating the surface of the glass bead layer, and the glass bead layer (4) of the transmissive screen. After attaching the packing material 8 to space a predetermined interval, the screen protection polycarbonate layer 7 installed therein, and the air layer 6 formed in the spaced spaces spaced therein further comprises a sequence comprising: The circumference of each layer constituting the entire screen is wrapped with a stainless frame 9 and then fixed by fastening means such as a bolt 10. The thickness of the embossed film layer is 0.1 mm to 1 mm, the polycarbonate layer has a thickness of 3 mm to 10 mm, a thickness of the matte transparent paint layer to which the adhesive is added, and a thickness of 0.1 to 1 mm, and the size of the solvent coated glass beads is 75-105 μm. .

In addition, the thickness of the polycarbonate layer for screen protection is 3mm ~ 10mm, the thickness of the air layer is 3mm ~ 10mm.

The form of the screen also consists of a flat plate and a round shape.

The method of manufacturing a transmissive screen of the present invention as described above is as follows. Adhesive for fixing and supporting each component constituting the screen and the polycarbonate layer constituting the base screen, the glass bead layer for refracting incident light or In the method of manufacturing a transmissive screen composed of a solvent layer to allow light from the projector to form an image, the method of attaching an embossed film of 0.1 mm to 1 mm thickness on one side of polycarbonate having a thickness of 3 mm to 10 mm A first step of spraying a matte transparent paint with an adhesive added on the opposite polycarbonate surface to which the embossed film is attached after the above process to have a thickness of 0.1 to 1 mm, and a matte to which the adhesive is added after the process A third step of depositing by spraying a glass bead having a diameter of 75-105㎛ so that 1/3 of the glass bead is buried on the transparent paint, and the glass bead after the above process In the fourth step of surface coating with a solvent (diluted paint) and after the above process, a polycarbonate for screen protection having a thickness of 3㎜ ~ 10㎜ is additionally attached to the glass beads surface coated with a solvent (diluted paint). , And further comprising a fifth step of treating the air layer having a gap of 3 mm to 10 mm therebetween.

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

Figure 1 shows a schematic view showing the components of the transmissive screen of the present invention, the configuration of the transmissive screen (MP board) of the present invention is composed of the surface receiving the light and the image coming from the projector.

One side is configured to transmit light and the other side is configured to receive the light and reproduce the image.

As the base material forming the projection plate, a plate or round polycarbonate (PC) having high transparency, high impact resistance, heat resistance, and cold resistance is used, and a thickness of about 3 to 10 mm is used to withstand the outdoors. (Strength: 100 times more than acrylic)

One side of the planar polycarbonate (the side through which light passes) is bonded to an embossed film that maintains a constant angle of diffuse reflection, and the film primarily blocks light irrelevant to the projected image.

The projected image transmitted through the film undergoes a first-order refraction at a much wider angle than the angle of light from the projector, and the refracted projected image reaches the opposite polycarbonate plane with at least 30-50 gains of light.

The projected image reaching the surface where the polycarbonate image is formed forms an image by drawing the refractive reflection angle up to 80 degrees through the glass beads of 75 ~ 105㎛ (MESH) of the surface particles past the matte transparent paint added with the adhesive. .

The glass beads are seated on the polycarbonate surface by a matte transparent paint added with an adhesive that transmits light as it is, and the glass beads that are seated out of the paint serve to enhance the viewing angle of the projection.

The uniformly deposited glass beads form a projected image with no loss of light, and the light from the lamp is displayed with a projection image of at least 30 gains while maintaining 100% color.

This function of glass beads comes from transparent round particles, and when light hits a surface of the particle, the angle of light is refracted and spread like a buccal to the surface of the round particle.

In the above constituent layers, the outer protective polycarbonate layer (PC layer) is 3 mm to 10 mm, the air layer is 3 mm to 10 mm, the solvent-coated glass bead layer is 75-105 μm, and the transparent adhesive coating layer is 0.1 to 1 mm, the screen polycarbonate layer has a thickness of 3 mm-10 mm, and the embossed film layer has a thickness of 0.1 mm-1 mm.

In this section, the effect of the present invention is well represented.

Figure 2 is a block diagram showing the transmission state of the light of the conventional transmissive screen, Figure 3 is a block diagram showing the transmission state of the transmissive screen of the present invention, as shown in Figure 2 is a conventional screen is a projection image of the light blocking Due to the large loss of the refraction reflecting angle is transmitted from the angle of the lamp of the projector as it is difficult to see the angle of view actually exceeds 60 degrees, but the transmissive screen (MP board) of the present invention as shown in Figure 3 When passing through, it separates the unnecessary light and image and transmits it to polycarbonate, and when it reaches the second glass bead, the projected image with large refraction reaches the second glass bead again. At least 30 gains of light and at least 30 times more than the white matte screen.

4 is a flowchart illustrating a method of manufacturing a transmissive screen according to the present invention. First, a finely embossed film is attached to one side of a flat or round polycarbonate, and then sprayed onto the other side of the matte transparent paint with an adhesive added. .

Before the paint is hardened, spray the glass beads so that they do not overlap the entire surface of the polycarbonate so that they are about 1/3 of the paint.

When the glass beads are settled and the paint is hardened, a very thin and transparent transparent solvent (thin paint) is sprayed on the surface of the glass beads to coat the coating.

Once this is done, the screen is finished. To protect the screen surface for outdoor installation, a sheet of 3-10 mm thick polycarbonate is attached to the surface where glass beads are deposited with a thickness of about 3-10 mm, which reduces heat transfer. In order to increase the strength, the 3 ~ 10㎜ space is treated in the air layer state.

That is, in the manufacturing method of the present invention, the first step is a process of attaching the embossed film to the polycarbonate, the second step is a process of spraying a matte transparent paint with an adhesive added to the opposite side of the polycarbonate to which the embossed film is attached; In the third step, glass beads are deposited on the matte transparent paint with adhesive, and the fourth step is surface coating with a solvent (diluted paint) on the glass beads, and the fifth step is for surface protection for outdoor installation. All of these processes are manufactured in five stages.

Figure 5 is a comparison table of the luminance difference between the present invention and the existing product, basically the conventional method of blocking the light to form a projection image on the screen and through the light as it is to maximize the light and image at the same time by the film and glass beads It differs greatly from the MP board in terms of brightness.

The transmissive screen made of white cloth has brightness of 1 gain to 3 gain like the white mat type reflective screen, but the MP board has brightness of at least 30 gain, so it can be used indoors and outdoors.

FIG. 6 is an enlarged view of the surface treatment state of the transmissive screen of the present invention, and FIG. 7 is a cross-sectional view showing the edge coupling portion of the transmissive screen of the present invention. The space of about 3-10 mm was treated with the air layer, and the surface was again protected by polycarbonate about 3-10 mm on it. In detail, after attaching the silicon packing material to the periphery of the glass bead layer of the transmissive screen to space a predetermined interval, the screen protection polycarbonate layer installed therein, and the air layer formed in the spaced space is further configured In addition, the circumference of each layer constituting the entire screen is wrapped in a stainless frame, and then fixed by fastening means such as bolts, which prevents strong weather and direct sunlight in the open air and improves heat resistance, so that it can be used as a display board of a rooftop. It has a function.

In particular, the glass beads in the air layer adds the function of emitting light by the projector lamp and emits light. Therefore, the larger the screen (more than 200 inches), the brighter the brightness is.

Figure 8 is an embodiment showing a rooftop advertising board using the present invention, according to the building form is configured in a flat or round shape screen after the installation on the rooftop to project the image from the screen rear projector.

Therefore, the transmissive screen (MP board) of the present invention can be installed intensively in the outdoor where the transmissive screen could not be used due to the above-described improved functions, and has a technical advantage that can be used as an ultra-large video screen of a rooftop, In terms of surface size, it is only 1/10 to 20 compared to the same size board, and it will be used as an outdoor screen for advertisement.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As described above, the present invention has achieved dramatic improvements in terms of brightness, resolution, and viewing angle compared to conventional transmissive screens. In particular, the present invention manufactures a new method from the material itself so that it can be used outdoors.

Therefore, the biggest effect is to escape from the conventional idea that all projectors are mainly used indoors, and can enjoy the image of the projector with a transmissive screen in the outdoors, so the market is expected to be activated first.

In addition, through glass walls, it can satisfy the desire to express the image from the inside out.

Accordingly, as shown in FIG. 9, it can be used as a substitute advertising board of a commercial company that has installed and operated a signboard of a rooftop at an enormous amount, and the mass production and mass distribution are possible due to the convenience of facilities and operations. If so, profitability is likely to be very high.

In particular, when the projector with the lamp brightness of 4,000 ANSI is applied to the present invention, the overall market of the projector is expected to be achieved in that the projector image can be enjoyed as much as the indirect light instead of the direct light even in the open daylight. do.

Claims (8)

delete Transmissive screen consisting of a polycarbonate layer that forms the base screen, a glass bead layer that refracts incident light, and an adhesive or solvent layer for fixing and supporting each component that forms the screen to allow light from the projector to form an image To An embossed film layer (1) for primary refraction of the projector's light, a polycarbonate layer (2) having the embossed film layer attached to one side, and a matte transparent with an adhesive bonded to the other side of the polycarbonate Coating layer 3, a glass bead layer 4 for refracting light secondary by 1/3 of its diameter so as not to overlap and sprayed on the transparent coating layer, and a solvent layer 5 for coating the surface of the glass bead layer. ) And a silicon packing material 8 attached to the front circumference of the glass bead layer 4 of the transmissive screen to space a predetermined interval, and then the screen protection polycarbonate layer 7 installed thereon and the space The air layer 6 formed in the space portion is configured in order to further include, Projector light transmissive screen, characterized in that the periphery of each layer constituting the entire screen consisting of the above sequence wrapped with a stainless frame (9) and fixed by fastening means such as bolts (10). delete The method of claim 2, The thickness of the embossed film layer is 0.1mm ~ 1mm, the thickness of the polycarbonate layer is 3mm ~ 10mm, the thickness of the matte transparent coating layer to which the adhesive is added is 0.1 ~ 1mm, the solvent Projector light transmitting screen, characterized in that the size of the coated glass beads are 75-105㎛. The method of claim 2, The thickness of the polycarbonate layer for screen protection is 3mm ~ 10mm, the thickness of the air layer is a projector light transmitting screen, characterized in that 3mm ~ 10mm. The method of claim 2, The screen of the projector is a light transmission type screen, characterized in that configured in one selected from the flat plate and round shape. delete Transmissive screen consisting of a polycarbonate layer that forms the base screen, a glass bead layer that refracts incident light, and an adhesive or solvent layer for fixing and supporting each component that forms the screen to allow light from the projector to form an image In the manufacturing method of A first step of attaching an embossed film having a thickness of 0.1 mm to 1 mm to one side of a polycarbonate having a thickness of 3 mm to 10 mm, A second step of spraying a matte transparent paint with an adhesive added on the opposite polycarbonate surface to which the embossed film is attached after the process to have a thickness of 0.1 to 1 mm; A third step of spraying and depositing a glass bead having a diameter of 75-105 μm so that 1/3 of the glass bead is buried on the matte transparent paint to which the adhesive is added; A fourth step of surface coating with a solvent (thin coal paint) on the glass beads after the above process, A fifth step of attaching a screen protection polycarbonate having a thickness of 3 mm to 10 mm to the glass beads surface-coated with a solvent (thin coal paint) after the above process, and treating the air layer having a gap of 3 mm to 10 mm therebetween. Method for manufacturing a projector light transmitting screen, characterized in that further comprising the step.