KR200427287Y1 - Fire retardant projection screen - Google Patents

Abstract

The present invention relates to a projection screen having a flame retardant function in case of fire. The composition of the screen is composed of a thin film surface film and a substrate of the back layer, but the surface layer is a film material having a scattering surface and a reflecting surface having a transmissive function. Maintaining more than 2 times of clarity, flame-proof screen is formed by mixing flame-proof materials such as chlorine and antimony, which are flame-retardant materials, on the film material. In order to eliminate the bubbles in the process of matching the surface film and the back substrate, air channels and grooves are formed on the flame-retardant surface film or the back substrate to maintain the uniform surface and flame-proof function and the brightness and clarity that are unique to the screen at the same time. This relates to a flame retardant projection screen characterized by this feature.

, Flame retardant material, surface film, back substrate, bubble phenomenon, air conduction and groove

Description

Fire Retardant Projection Screen {omitted}

1 is a schematic cross-sectional view of the subject innovation

2 is an explanatory diagram of the screen surface with bubble phenomenon

3 is an air view and a groove explanatory diagram of the flame retardant surface film of the present invention

4 is an explanatory view of the air and groove formed on the surface of the back substrate of the present invention

5 is an explanatory diagram of an embodiment of an air diagram and a groove

6 shows an example of an application in combination with a flexible back substrate.

Brief description of the symbols in the drawings

100. Screen 1. Flame retardant film 1a. Spawn cotton

2. Back substrate 2a. Air groove and groove 3. Adhesive side

3a. Adhesive side 4. Reflective side 5. Bubble

6, net

The present invention relates to a projection screen, and a projection screen that is designed so that the projection screen itself has a flame retardant performance and at the same time have a function of displaying a high-quality image and devoid of bubbles on the surface.

In general, the image screen is made of a material such as vinyl chloride has a strong ignition factor and there are risk factors such as asphyxiation due to the generation of smoke in the fire has been a problem in the use of multiple phosphorus.

In addition, when the flame retardant treatment is performed on the screen surface, there are problems such as deterioration of the quality of the image due to the material properties of the flame retardant and generation of bubbles on the image surface by chemical action.

In case of using the screen as a conventional non-combustible metal material only, there is a limitation in the process to obtain the uniformity of the surface, the processing process has to be harmful chemical processing, the process is difficult, the production is difficult and the manufacturing cost is too much.

The standards for flame retardant performance in the world are as follows.

The flame burning on the surface of the flameproof product must be stopped within 20 seconds after the burner is removed.

The burnout time must be within 30 seconds after the burner has been removed from the surface without burning.

The carbonized area of the surface should be 50 square meters and the carbonized length should be within 20cm by the above method.

Contact number of the flame should not be completely melted more than 3 times until the material is completely melted.

The soot generation density generated at this time should be 400 or less.

The object of the present invention is to propose a configuration of a flame retardant screen that satisfies the condition by applying the first condition of the flame retardant function to the screen.

In addition, to prevent the degradation of the image quality due to the addition of flame retardant to propose the composition of the flame retardant screen to obtain the function of the flame retardant function and the screen at the same time.

Another object of the present invention is to propose a configuration that eliminates the bubble phenomenon of the screen surface generated in the process of separately manufacturing and matching the surface and the back of the screen in order to satisfy the flame retardant function and the image sharpening function.

By the present invention for achieving this purpose

As shown in Fig. 1, the overall configuration of the screen 100 is composed of the flame retardant surface film 1 and the back substrate 2 in a dual configuration.

The preferred thickness of the flame retardant surface film 1 is composed of a thin film having a thickness of 5 μm to 500 μm, but is a transparent material through which light is transmitted, and the diffusion material is formed on the surface of the flame retardant surface film 1 or the material itself of the flame retardant surface film 1. Or by forming an embossed surface on the surface or by applying a diffusion material to form an image to project and transmit it.

Examples of the flame retardant composition in the flame retardant surface film 1 material itself are as follows.

Nitrogen, phosphorus to halogen elements such as bromine and chlorine. Antimony, or phosphorus and halogen should be used in combination. Select flame retardant according to the thickness and material of the surface film and mix it by adding or subtracting the amount considering the flame retardant grade.

When the present invention is to be used as a reflection screen, a reflection surface 4 is formed on one surface of the flame-proof surface film 1 having a flame-retardant function.

When the back substrate 2 is made of plastic, it is appropriate to add an appropriate amount of flame retardant such as bromine, chlorine, nitrogen, and antimony as described above to have a flame retardant function.

It is composed of non-combustible materials such as steel, non-metal materials such as aluminum sheets, or materials such as glass, which are not burned.

Such a screen 100 requires an adhesive treatment for the uniform surface of the screen 100 on the bottom surface of the flame resistant surface film 1 when the flame resistant surface film 1 and the back substrate 2 are configured as described above. The flame retardant is required for the adhesive face 3, so the flame retardant must be mixed.

The present invention is often attached to the local window glass window or in the case of a large screen in the field to combine the flame-resistant surface film (1) and the back substrate (2).

In this case, as shown in the photograph of FIG. 3, the surface of the screen 100 is generated by bubbles or air caused by the adhesive surface 3 or the chemical composition of the flame retardant, and the bubbles continue to increase as the internal chemical component is vaporized. Is generated.

Therefore, as a means to remove it, the air gap and the grooves 2a are formed in the adhesive layer 3 itself on the back surface of the flame resistant surface film 1.

The formation of the air and grooves 2a is such that a thin mesh like net 6 having a thickness within the thickness of the adhesive surface 3 is laid on the back surface of the flame-proof surface film 1 as shown in FIG. After the coating is carried out, the net 6 is peeled off, whereby air pits and grooves 2a are formed by the marks of the net 6.

As shown in FIG. 4D, the release paper 1c may be attached to the bottom of the adhesive layer 3 to protect the air level and the grooves 2a of the adhesive layer 3.

As shown in FIG. 4 (d), the release paper 1c and the net 6 may be separated from the flame resistant surface film 1 at the same time, and then attached to the back substrate 2 of the site.

As shown in FIG. 4, the air diagram and the groove 2a are formed on the surface of the back substrate 2 as shown in FIG.

However, it is more effective to form the air depth and groove 2a deeper than the surface area size.

That is, when the air gap and the width of the groove 2a are wider than the adhesive surface 3a of the adhesive layer 3, the flame resistant surface film 1 is easily removed from the back substrate 2 because the entire adhesive surface 3a is narrow. Since there is a disadvantage of detachment, the surface area of the adhesive surface 3a is more than twice as large as that of air and the width of the groove 2a.

The air and grooves 2a may be formed in a curved shape as shown in Fig. 5 (a) or in a hexagonal shape as in Fig. 5 (b) or in a net shape as shown in Fig. 4, but any condition is important. It is important that the air drawing and the grooves 2a be configured to penetrate the ends of the flame retardant surface film 1 and the screen 100 in mutual connection with the air drawing and the grooves 2a.

This is because when bubbles are generated, they can be released from the outer surface to release air and gas from the outside of the screen 100 structure.

In addition, as shown in FIG. 6, the screen 100 is composed of the flame retardant surface film 1 and the back substrate 2 as described above. The flame retardant surface film 1 has a scattering surface 1a and a reflective surface 4. It is formed of a thin film and composed of a flame retardant material containing a flame retardant such as antimony in the flame retardant surface film (1) itself,

The back substrate 2 may be composed of a flexible flame retardant material such as glass fiber and a flame retardant nonwoven fabric or flame retardant film, and may be rolled up like a roll.

This invention like this

By separating and controlling the flameproof surface film 1 and the back substrate 2 in a binary manner, the flameproof surface film 1 can be formed into a thin film and the film surface can be uniformed by printing.

This is because the flame retardant surface film 1 itself can be flameproofed by containing a flame retardant and can be combined with the back substrate 2 formed of flame retardant or nonflammable material such as glass or metal.

The surface of the flame retardant surface film (1) when the image is formed on the scattering surface (1a) when used as a transmission screen, the flame retardant surface film (1) itself is glass. As it is a transparent material such as plastic with a flame retardant, it is visible to viewers by transmitting the image formed by scattering directly.

The configuration of the present invention

The flame retardant surface film 1 is formed of a thin film between 5 μm and 500 μm, and has a flame retardant function as described above, and at the same time, the back substrate 2 is made of a material such as metal or glass.

The actual flame test showed that the flames of the burner were removed from the burner on the surface of the present invention in less than 20 seconds.

In the present invention, when the flame of the burner is removed from the surface, it is extinguished within 30 seconds without raising the flame.

The carbonized area of the surface of the present invention was less than 50 m 2 and the carbonized length was less than 20 cm 2.

This action is possible because the flame retardant surface film 1 itself has a flame retardant function and its thickness is less than 500 μm.

In addition, even if the contact number of the flame contacting the surface of the present invention three or more times, only the film surface of the flame-resistant surface film 1 is damaged, the substrate 2 is a glass or metal material, so there was no deformation.

In the measurement of soot generation, smoke generation was minimal until the thickness of the flame retardant surface film 1 was 50 μm, and the soot generation density up to 500 μm was also 400 or less.

Therefore, the present invention satisfies all of the above flame retardant functions while having a screen function.

In more detail, when the structure of the present invention is composed of only the flame-retardant surface film (1) cross section without dualizing the structure of the present invention into the flame-retardant surface film (1) and the back substrate (2), the thickness of the screen is 500 µm or more. Should be

The thickness of the flame-retardant surface film (1) exceeds the regulation that is less than 20 seconds when testing the state of burning the flame from the time of removing the flame of the burner even if the flame retardant function is flame retardant by the flame retardant during the flame retardant performance test. Burned out for more than 30 seconds

When the flame on the burner was removed from the surface, the test had to be turned off within 30 seconds without raising the flame and did not turn off for more than 40 seconds.

At this time, the carbonized area of the surface was over 50㎡, especially the soot generation density was over 800.

Therefore, the present invention is composed of the flame retardant surface film (1) and the back substrate (2) is the reason that the flame retardant surface film (1) as possible by film or thin film to ensure the flame-proof performance and the back substrate (2) flame-proof performance It is intended to consist of solid glass and metal

In addition, the surface film structure of such a thin film structure is to form a scattering surface (1a) by embossing on the surface of the flame-resistant surface film (1) for the purpose of use as a screen for watching the transmission image, and the transparent substrate such as glass back substrate (2) As a result, the transmission loss was caused by the flame retardant, but since the transmission part was thinned, the effect of minimizing the transmission loss was generated.

As a result of forming the reflective surface 4 on the back surface of the flame resistant surface film 1, the image scattered and formed by the flame resistant surface film 1 is directly transmitted to reflect back from the reflective surface 4, thereby causing the loss of reflection by the flame retardant. Although the surface of the film is thin and the reflecting effect of the reflective surface is more than twice the brightness than the conventional screen.

In addition, as shown in Figure 3, if the flame-resistant surface film (1) to form an air flow and grooves (2a) by the net (6) such as mesh in the adhesive layer (3)

As a result of attaching the window surface of the installation place, such as a show window, as the back substrate 2, as a result, it adheres to the outside of the screen 100 by discharging internal air and gas to the outside of the screen 100 through the air drawing and the groove 2a during the adhesion process. It was possible to attach the screen 100.

In general, in the case of a fixed-size large screen indoors, it was impossible to pass through the door due to the limited size of the door.

As shown in Fig. 4, the back substrate 2 is formed on the surface of the back substrate 2, that is, the metal surface, as shown in Figs. 4 and 5 (a) and 5 (b). It was possible to install the large screen 100 easily because it was possible to divide the material into sizes that can be transported, assemble it in the field, and attach the film of the flame resistant surface film 1 thereon.

In particular, since air and gas inside the screen 100 can be discharged to the outside of the screen 100 by using the air drawing and the groove 2a without special mechanical equipment, it is possible to install a flame-retardant projection screen having a uniform surface without bubbles.

In addition, as shown in FIG. 6, when the back substrate 2 is composed of a flexible flame retardant material such as glass fiber and flame retardant nonwoven fabric or flame retardant film, it can be rolled and moved.

Therefore, this invention

The flame retardant film (1) and the back substrate (2) are produced separately and merged into one to form a thin film on the surface of the screen that can improve the quality of the image.

The back substrate 2 is made of non-combustible material such as metal, thereby improving flame retardant performance and greatly reducing smoke generation.

The surface of the screen 100 is composed of a flame-retardant surface film (1) having a separate thin film structure, which enables easy and uniform fabrication of the surface, so that the flame retardant performance, transmission clarity 2 times, brightness and clarity 2 times or more are possible. .

In addition, by forming an air channel and a groove 2a on one side of the flame retardant surface film 1 and the back substrate 2, the phenomenon of bubbles 5 on the surface of the screen 100 due to the generation of air or gas during bonding or field bonding after moving is also eliminated. Since it can be used on the back surface (2) of the site flame retardant material, such as glass windows and gypsum board of the installation site, its use range and practicality is very large.

Therefore, the present invention is a flame retardant projection screen having high practicality in spaces and advertisement devices used by various multi-persons such as conventions, academies, conference rooms, and the like.

Claims (5)

1. For projection screens The screen 100 is composed of a flame retardant surface film 1 and a back substrate 2 On the flame-resistant surface film 1 to form a scattering surface (1a) but to form a thin film The flame retardant surface film 1 itself is composed of a flame retardant material containing a flame retardant such as antimony and bromine. The back substrate 2 is made of a flameproof material such as metal or glass, and then Flameproof projection screen characterized in that the combination of the flame-resistant surface film (1) and the back substrate (2) The method of claim 1 Flameproof projection screen characterized in that the reflective surface 1b is formed on the flameproof surface film 1 In projection screen The screen 100 is composed of a flame retardant surface film 1 and a back substrate 2 The flame-resistant surface film (1) to form a scattering surface (1a) but consisting of a thin film The flame retardant surface film 1 itself is composed of a flame retardant material containing a flame retardant such as bromine and antimony. The back substrate 2 is made of a flame retardant material such as metal, glass, After forming the air channel and the groove (2a) on the surface of the back substrate (2) Flame retardant projection screen characterized in that the flame-retardant surface film (1) is combined to the surface of the back substrate (2) In projection screen The surface of the screen 100 is composed of a flame retardant surface film (1), but a film thin film containing a flame retardant such as antimony or bromine. If the flame-resistant surface film (1), the flame retardant projection screen characterized in that the air drawing and groove (2a) is formed in the adhesive layer (3) In projection screen The screen 100 is composed of a flame retardant surface film 1 and a back substrate 2 The flame retardant material containing flame retardants such as bromine and antimony in the flame retardant surface film 1 itself On the flame resistant surface film 1, a scattering surface 1a is formed, but a reflective surface 4 is formed on one surface to form a thin film. Fire-retardant projection screen characterized in that the back substrate (2) is composed of a flexible flame-retardant material such as glass fiber, non-woven fabric to roll like a roll

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