KR101255376B1 - High-definition sound absorption screen - Google Patents

Abstract

According to the present invention, the screen surface is composed of a flexible surface having an elongation of 50% or more, but having an excellent transmittance, and an image surface on which the image of the projector can be imaged. Selective composition, the image surface is formed on the screen itself or combined with a rigid thin film structure, and the diaphragm structure is formed outside the image surface, the incident image is transmitted and reflected without interfering with external light by contrast It is a high-definition sound absorption screen which can obtain 2 ~ 5 times the brightness and external sound is scattered and formed on the elastic surface of the screen and the sound energy is dissipated by the diaphragm.

Elastic permeable surface. Elastic surface, soft. tympanum. frame. Wire

Description

High-definition sound absorption screen {omitted}

1 is a diagram illustrating the sound absorption and reflection of the present invention

2 is an explanatory diagram of the sound absorption and transmission of the present invention.

3 is an explanatory diagram of a configuration of the present invention in a frame;

4 is an explanatory view of the acoustic vibration and simultaneous vibration action of FIG.

4A is an explanatory diagram illustrating a structure in which a spring is connected to the configuration of FIG. 3.

5 is an explanatory view of an embodiment of a sound absorbing roll screen of the present invention.

6 is an explanatory view of an embodiment of applying a combined structure of a wire line and a diaphragm structure to a roll screen;

7 is an explanatory diagram when using a combination structure of wire wire and diaphragm structure installation

8 is an illustrative example of an embodiment of an elastic surface of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

100; Screen a. Incident image b. Reflective image

c. Transmission image 1. Elastic permeation surface 1a. Elastic surface

2. Image plane 2a. Reflective plane 2b. Film reflector

2c.Transmission surface. 2d. Film Transmissive Surface 3. Frame

4. Fixed pin 5. Vibration plate. 6. rotating rod

7. Bottom stand 8. Support 9. Top rod

10.Rotating rod 11.Rotating motor 12.Wire wire

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a projection screen, and more particularly, to a high definition sound absorbing screen in which a sound absorbing function for sound, a high reflecting function of an incident image, and a high definition transmission function can act simultaneously.

In general, screen images are often used as background images in churches and concert halls.

In particular, recently, the worship service through hymns, recitals of singers, orchestra concerts, and speeches are often screened on the back of the stage, making the video background.

Image and sound have the same physical action characteristics such as reflection and diffusion

Therefore, a bright image requires the use of a screen with high reflectivity, and a screen with high reflectivity also reflects a large amount of sound in proportion to the noise, which is caused by acoustic radiation.

To prevent the reflection of this sound, it is possible to use a screen with a low reflectance, but the brightness of the image is so low that the image is blurred.

That is, the reflection of the sound and the brightness of the image are proportional.

Sound is air energy and light in the projected image is a wave.

By using the difference between the sound and the projected image, the sound s on one screen is reduced by the sound absorbing effect, and the projected image is transmitted and reflected to obtain a high-definition image.

It also enhances sound absorption while maintaining flatness, which is the basic function of the screen.

According to the sound, the screen itself vibrates by the diaphragm to double the sound absorption effect.

The purpose of the present invention is to provide a method for constructing a screen that simultaneously obtains efficient sound absorption and high definition image functions.

An elastic transparent surface 1 is formed on the surface of the screen 100 as shown in FIG. 1.

Elastic permeable surface (1) is formed of a material having a soft surface with elasticity and at the same time a transmission function of the image light.

In addition, in order to give elasticity to the surface of the screen 100, the elongation must be 50% or more to have elasticity such as rubber, and the material itself must be transparent and have excellent transmittance to enable high-transparent transparency and reflection.

Materials to meet these conditions include transparent rubber or silicone rubber. Or urethane material is possible

The material may have an elongation of 50% up to 600%, and may be soft and have a low surface hardness and may transmit and reflect an image of an image projector because the material itself is transparent.

The back surface of the screen 100 is composed of an image surface 2 for forming a projected image. The incident image a projected from the back surface is imaged on the image surface 2 and the screen 100 is transmitted as a transmission image c. On the surface,

However, if the image surface (2) material itself is high in permeability, the permeability can be adjusted by adding an appropriate amount of diffusion material to the inside of the elastic permeation surface (1) itself, and by adding dyes or pigments of dark color system The sharpness can be increased by enhancing the contrast effect.

As shown in FIG. 1, in the present invention, the sound S generated outside the screen 100 and incident on the screen 100 is applied to the elasticity of the elastic surface a, which is the surface of the elastic transparent surface 1, which is the surface of the screen 100. It is destroyed by a considerable amount.

At the same time, the brightness of the transmitted image of the projector that is projected to the back side and transmitted to the surface of the projector is transmitted to the surface of the screen 100 without the interference of external light. The brightness of 2-5 times the brightness of 1 gain of general transmission screen can be obtained at the same time as the sound absorbing effect.

In FIG. 1, the image plane 2 may be formed of a transmissive surface 100 by applying a diffusion material to the film transparent surface 2d of a thin film structure or the screen 100 itself, or by embossing. Can

The reflective screen constitutes a reflective surface 2a on which a reflective material such as aluminum is deposited on the elastic transparent surface 1 as shown in FIG. 2.

In this case, the incident image transmitted through the elastic transparent surface 1 is transmitted through the elastic transparent surface 1, reflected by the reflective surface 2a, and then transmitted back to the elastic transparent surface 1 to be viewed by the viewer.

The reflective surface 2a may be formed by attaching the reflective film 2a on which the reflective surface is deposited on the film structure of the thin film, or forming the reflective surface 2a by depositing aluminum on the back surface of the screen 100 material itself. It is possible

In the present invention, the sound S is extinguished by the elasticity of the elastic surface 1a, which is the surface of the elastic transparent surface 1, and the brightness of the reflected image d depends on the reflectance of the reflective surface 2a. In the case of flat screens, up to 5 gains can be achieved, while the sound absorption effect can be obtained at the same time as the brightness of 5 times the brightness of the normal screen.

The film transmissive surface 2d of FIG. 1 and the film reflecting surface 2c of FIG. 2 described above are made of a thin film having no elongation, but are made of hard, but the thickness is not limited. It is rolled up like a roll.

The film transmissive surface 2d may contain an appropriate amount of diffusion material so that the amount of image transmission can be adjusted.

In the reflective screen structure of FIG. 2, the image surface 2 on the back side is made of a hard material having no elongation as the film reflection surface 2c, but has a thickness of 2 μm to 1000 μm, which can be rolled like a roll.

As described above, the elongation of the elastically transparent surface 1 of FIGS. 1 and 2 is made of 50% or more of material, and the elongation is very high, and the elongation of the film transparent surface 2d or the film reflective surface 2a of the back surface is high. It is composed of hardly any hard and has mutually heterogeneous characteristics.

This heterogeneous configuration is that the elastically transparent surface 1 of the surface absorbs the sound S by softness, and the material of the film reflective surface 2a and the film transparent surface 2d of the hard back surface is the flatness of the screen 100 itself. There is a characteristic to keep sex.

The screen 100 of FIGS. 1 and 2 may be used as a flat screen by connecting with a rigid frame 3 such as metal or wood as shown in FIGS. 3 and 4.

Form the fixed pin 4 at regular intervals around the inside of the frame 3, and form the diaphragm 5 structure by forming the elastic permeable surface 1 wider to the left, right, and outside of the image surface 2 before and after. And associated with the frame (3).

In addition, as shown in FIG. 4, a plurality of small springs 5a may be formed between the diaphragm 5 structure between the frame 3 and the screen 100 structure and the frame 3 at a necessary interval.

The action of this configuration is that the structure of the diaphragm 5 and the structure of the spring 100 on the basis of the frame 93 vibrates due to the elasticity (S) of the spring (5a) so that the sound can be absorbed.

At this time, the elongation of the elastic permeable surface 1 has elasticity of 50% or more, so that the vibration plate 5 also has elasticity at the same elongation and is supported by the frame 3 so that the screen 100 itself is flat and firm in all directions. Pull to support it.

In particular, the structure of the vibrating plate 5 associated with the frame 3 causes the entire screen 100 to vibrate together by the vibration of the external sound S, thereby dissipating the sound S energy.

Therefore, the elastic permeable surface 1 dissipates the sound S by the softness of the surface itself, and at the same time, the diaphragm 5 dissipates the energy of the sound S by simultaneous vibration by the sound S.

Such an operation may be configured in the transmission image structure of FIG. 1 or the reflection image structure of FIG. 2.

As shown in FIG. 5, the rotating rod 6 is formed inside the lower stand 7, which is a movable screen structure, and the structure of the screen 100 of FIGS. 1 and 2 is rolled up like a roll, and the support 8 and the rotating rod 6 are formed. Phase by structure. It relates to a structure that can be used by opening and closing the bottom.

FIG. 5 shows the screen 100 by vibrating the sound S in association with the structure of the upper plate 9 of the vibration plate 5 structure on the back fixing pin 4 formed on the upper stand 9 of the screen 100. Configure it to vibrate like this.

FIG. 6 is a sound absorbing screen structure in which the rotating rod 6 is formed inside the upper bar 9 of the roll screen structure and the screen 100 is connected to the motor 11.

6 is a cross-sectional view of the wire line 12 coupled to the inside of the diaphragm 5 structure.

This configuration constitutes a wire wire 12 in the diaphragm 5, and the screen 100 vibrates together by the energy of the sound by the diaphragm 5 structure with the wire wire 12 as a base. s) to exhaust energy

In addition, the wire wire 12 and the diaphragm (s) structure can be opened and closed in the form of a roll to move up and down in accordance with the vertical opening and closing of the screen 100.

FIG. 7 extends the elastic transmission surface 1 to form a diaphragm 5 structure as shown in FIG. 6, and embeds a wire line 12 inside the diaphragm 5 structure, and the wire line 12 extends to the outside. Is a drawing installed in the space

In the structure of FIG. 7, when the wire wire 12 is pulled and installed in a required space, the screen 100 is flattened, and the elongation of the diaphragm 5 is oriented along the wire wire 12 in accordance with the acoustic (s) vibration energy. As the screen 100 vibrates, sound energy is absorbed and dissipated.

As shown in FIG. 8, the surface of the elastic transparent surface 1 is embossed, but in order to increase the sound absorbing effect, a fine triangular surface as shown in FIG. 8A, or FIGS. 8B and 8C, and As described above, it may be configured as a fine lateral curved surface or an embossed surface such as an irregular surface as shown in FIG.

The embossed surface is to enlarge the surface area of the elastic transparent surface 1 in relation to the plane has the effect of enlarging the contact surface of the sound (S) and thus can be expanded the sound absorbing effect.

The present invention removes the film transmissive surface 2d of FIG. 1 or the film reflective surface 2c of FIG. 2 and the image plane 2 as the transmissive surface 2c or the reflective surface 2a on the elastic transparent surface 1 itself. Can be configured

In such a configuration, one screen 100 functions at the same time as the elastic transmission surface 1 function, the image surface 2 function, and the diaphragm 5 function.

In this case, maintaining the flatness of the screen 100 is configured to upwardly stretch the elastic permeable surface 1 to 200% or more of high elasticity, so that the diaphragm 5 structure is pulled from the top, bottom, left and right, as well as maintaining the flatness. It can be more sensitive to acoustic vibrations.

The method of linking the diaphragm 5 structure and the frame 3 structure is not particularly limited, and the fixing pin 4 may also be formed in various forms to facilitate screen assembly.

As described above, according to the present invention

The surface of the screen 100 is made of a material having elasticity and good permeability to constitute an elastic permeable surface 1

By constructing the image surface (2) of the transmissive or reflective function on the back side, by combining the film of the thin film structure that can be rolled like a roll, or on the back surface itself

The external sound S is absorbed and diffused by the surface of the elastic transparent surface 1, and the transmitted or reflected image is scattered and formed at the back surface to display with 2-5 times of brightness to have sound absorption function and at the same time high brightness. It can also have a video function.

In addition, the present invention

The soft permeable surface of the elastic permeable surface 1 is composed of a soft soft material having an elongation of 50% or more up to 600%, and the film reflective surface 2c or the film transmissive surface 2d is formed on the back surface of the soft transparent material without elongation. The surface of the sound absorbing function, the hard surface of the image to form the image and the screen 100 itself to maintain the flatness can be obtained at the same time.

When each of the above screen 100 material is combined with the frame (3) or the existing roll screen structure by combining the diaphragm (5) structure to double the sound absorption function.

In addition, according to the present invention, by configuring the reflective surface or the image surface 2 having a transmissive function on one screen surface, the elastic surface 1a and the diaphragm 5 structure simultaneously absorb sound in one screen 100 structure. Under (100), high-definition images can be imaged and reflected or transmitted.

Therefore, the structure of the present invention is a high-definition image action of a high brightness of 2-5 times compared to the conventional structure in one screen 100

It is very useful as background screens for concerts, auditoriums, stage backgrounds, and conference hall background screens by allowing sound absorption to absorb and dissipate the energy of energy at the same time.

Claims (10)

An elastic surface (1a) composed of a material having a calculation rate of 50% or more of the elastically transparent surface (1) in order to reduce the sound (s) by surface elasticity due to soft surface elasticity in the sound absorbing screen; An elastic transmission surface (1) comprising the elastic surface (1a) and made of a transparent material capable of simultaneously transmitting an image; A reflecting surface (2a) made of a reflecting material capable of reflecting the transmitted image on the back of the elastic transparent surface (1) with a high definition of 2-5 gains; High-definition sound absorption screen, characterized in that the sound absorption function and high-definition image function at the same time in one screen 100 material delete The method of claim 1 High-definition sound absorption screen characterized by embossing on the surface itself of the screen 100 having the elastically transparent surface 1 The method of claim 1 High-definition sound-absorbing screen characterized by the composition of the image surface (2) having a scattering function consisting of a thin film of the reflective surface (2a) The method of claim 1 High-definition sound absorption screen characterized by the configuration of the image plane as a thin film transparent surface (2d) The method of claim 1 High-definition sound absorption screen characterized in that the structure of claim 1 configured by combining with the frame (3) The method of claim 1 High-definition sound absorption screen, characterized in that the structure of the screen 100 of claim 1 is configured to be rolled up and wound The high-definition sound absorption screen according to claim 1, wherein the diaphragm 5 is formed outside the image plane 2 so that the image plane 2 vibrates in accordance with the sound s. The high-definition sound absorption screen according to claim 8, characterized in that the wire wire 12 is coupled to the inside of the diaphragm 5. High-definition sound absorption screen according to claim 6, characterized in that the spring (5a) is coupled between the frame (3) structure and the diaphragm (5) structure.

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