JPH06310895A - Electromagnetic wave shielding window - Google Patents

Abstract

PURPOSE:To ensure electromagnetic wave shielding performance, by mounting conductive material for electric connection, between a unit frame and an electromagnetic shielding glass plate, and between adjacent electromagnetic wave shielding glass plates. CONSTITUTION:Structure sealing material 4, back-up material 6 and conductive back-up material 2 are arranged between the conducting surface of an electromagnetic wave shielding film 13 of an electromagnetic wave shielding glass plate 1 and a unit frame 7. The electromagnetic wave shielding glass plate 1 is bonded and fixed to the unit frame 7 by using the structure sealing material 4, which are electrically connected by the conductive back-up material 2. Between the conductive back-up material 2 arranged on both sides of the connection end portions of adjacent electromagnetic wave shielding glass plates 1, the similar conductive back-up material 2 is arranged. Hence the conducting surfaces of the electromagnetic shielding films 13 of the electromagnetic shielding glass plates turn to an electrically continuous body, and electromagnetic shielding performance is improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of an electromagnetic wave shielding window.

[0002]

2. Description of the Related Art In a modern office building, which is an intelligent building, information communication facilities such as a complex electronic exchange and a computer are shared to perform information communication with the inside and outside of the building. In addition to diversifying and individualizing information needs, providing prompt and accurate information is one of the major issues in large-scale buildings. As an answer to such a problem in an intelligent building, an information network using a data highway method using an optical fiber cable or a coaxial cable has been studied and proposed.

However, in the data highway system using an optical fiber cable or a coaxial cable, the optical fiber or the coaxial cable must be spread all over the interior of the intelligent building. It will take extra.

Further, if radio waves are used for information communication in a building, it is not necessary to lay cables, but in this case, on the other hand, noise radio waves are emitted to the outside. Will be subject to regulations. On the other hand, there arises a problem that the system malfunctions due to external radio waves, internal TV intermediate frequency, radio microphone radio waves, and the like.

Wireless communication, which is expected to grow in demand in the future, does not emit electromagnetic noise because it does not interfere with other buildings in order to prevent mutual interference in the building. On the contrary, it does not emit electromagnetic waves because it does not affect other buildings. Is required. In addition, there is a need for technology that does not emit radio waves and does not allow radio waves to be transmitted even in computer centers, hospitals, and AV conference rooms that handle precision electronic equipment. In particular, recently, it has been found that electromagnetic wave noise radiated from a computer or a display can be easily caught by a relatively simple device, so that eavesdropping on radio waves leaking from electronic devices handling information such as computers has become a problem. .

As described above, noise caused by electromagnetic waves has become a major social problem in recent years. Society needs a technology that does not emit radio waves and does not allow radio waves to enter, and the development of EMI (Electro Magnetic Interference) technology that does not emit radio waves is under way.

Further, in terms of immunity in which radio waves cannot enter (devices are hindered by external electromagnetic noise), techniques for preventing external electromagnetic waves from entering buildings are being advanced. As an external noise source, a building (electromagnetic wave shielding building) that does not allow these electromagnetic waves is required in a place where the electromagnetic environment is bad, such as near a train or a high voltage line.

An invention relating to an electromagnetic wave shielding glass window in which a building and an opening such as a window and a doorway are formed by using an electromagnetic wave shielding member and the entire building has an electromagnetic wave shielding structure to enable communication inside the building by radio waves, A patent application has already been filed. Buildings using such electromagnetic wave shielding glass windows are often intelligent buildings, and the number of cases in which the entire building is shielded from electromagnetic waves is increasing. On the other hand, in an intelligent building, a structural silicone sealant is used to bond a glass plate to a unit frame connected to the vertical part of the building to form the outer wall surface of the glass plate. The structure is widely adopted. However, at present, almost no SSG construction method having electromagnetic wave shielding performance has been developed. Among them, as one of the conventional examples of the SSG construction method, an example in which conductivity is added to the structural sealing material to secure the electromagnetic wave shielding performance of the window (JP-A-3-26027).
No. 8) will be described below.

FIG. 5 is a diagram for explaining a conventional example of an SSG construction method having an electromagnetic wave shielding performance. The electromagnetic wave shielding window by the SSG construction method includes two electromagnetic wave shielding glass plates 1 adjacent to each other. A conductive film (hereinafter referred to as an electromagnetic wave shielding film) 13 having an electromagnetic wave shielding performance is formed on the indoor side surface of the electromagnetic wave shielding glass plate 1. The electromagnetic wave shielding glass plate 1 is supported at the end thereof by a backup member 6 and a connecting frame 7 on a vertical portion 8 of the building, and is fixed to the vertical portion 8 and the electromagnetic wave shielding glass plate 1. Structural sealant 1 between the ends of
2 is filled and sealed and fixed. Further, a waterproof sealing material 5 is filled and sealed between the connection ends of two adjacent electromagnetic wave shielding window glasses 1.

As the structural sealing material 12, a high modulus conductive sealant material containing a conductive material is used. And these structural sealing 12 are the electromagnetic wave shielding coating films 1 of the electromagnetic wave shielding window glass 1.
3 and the metal sash of the cubic portion 8 are used to electrically connect and are grounded.

[0011]

This type of conventional S
The electromagnetic wave shielding window by the SG construction method covers the periphery of the window with a conductive material, uses a conductive material for the window member, adds conductivity to the structural sealing material, and enables electrical connection between the electromagnetic wave shielding glass plate and the building. There is. In this case, the conductive structural sealing material between the electromagnetic wave shielding glass plate and the vertical portion, because it has added conductivity, compared to the normal structural sealing material,
Performance is deteriorated in terms of elasticity and durability, which are the original functions of the sealing material, and it is insufficient as a structural sealing material.

[0012] The present invention is to solve the above-mentioned problems, and by using the same sealing material having the structure of the ordinary SSG construction method as the structural sealing material, various performances as a window of the ordinary SSG construction method can be obtained. (EN) Provided is an SSG construction method having an electromagnetic wave shielding performance that does not impair the shielding performance of a single electromagnetic wave shielding glass plate without hindering it.

[0013]

That is, according to the present invention, a plurality of electromagnetic wave shielding glass plates are arranged on the outer wall surface of a projectile of a building, and the end portions of the adjacent electromagnetic wave shielding glass plates are backup materials and The unit frame is held by a structural sealing material, and the unit frame is supported by a vertical portion of the outer wall of the body electrically grounded and a gasket, and between the unit frame and the joint end of the electromagnetic wave shielding window glass plate. In an electromagnetic wave shielding window by the SSG construction method in which is sealed by a waterproof sealing, a conductive material electrically connected between the unit frame and the electromagnetic wave shielding glass plates and between the adjacent electromagnetic wave shielding glass plates is mounted. The electromagnetic wave shielding window has improved electromagnetic wave shielding performance.

Further, the electromagnetic wave shielding window according to the SSG construction method of the present invention is provided between the electromagnetic wave shielding glass plates adjacent to each other between the electromagnetic wave shielding glass plate and the unit frame, and between the unit frame and the building upright. By mounting a conductive material, it is possible to electrically connect the electromagnetic wave shielding glass plate, the unit frame, and the vertical portion.

In the present invention, since the structural sealant material that maintains the performance as the window of the SSG construction method is the same as the structural sealant material used in the general SSG construction method, there is a problem in terms of elasticity and durability. There is no.

[0016]

In the electromagnetic wave shielding window according to the SSG construction method of the present invention,
By placing a conductive material made of a good electric conductor between the electromagnetic wave shielding glass plate and the unit frame, and between the unit frame and the vertical portion, the electromagnetic wave shielding glass plate, the unit frame and the building vertical portion are electrically integrated. The electromagnetic wave shielding performance around the window can be improved.

As the conductive material, a material at least the surface of which is made of a conductor is used. For example, a conductive backup material, a conductive gasket, and the like can be given as examples. Since the surface of the conductive backup material is generally covered with a metal mesh, the electrical performance is very high and the electrical connection with the unit frame is easy.
Further, in general, the conductive gasket has a smaller elongation than the conductive sealing material and may have a higher hardness, so that it becomes possible to include a large amount of the raw material for adding conductivity in the main raw material, and thus the conductive gasket The volume resistance can be greatly reduced as compared with the sealing material, and the conductivity can be improved.

[0018]

Embodiments Embodiments will be described below with reference to the drawings. FIG. 1 is a diagram showing an example of an electromagnetic wave shielding window by the SSG construction method having an electromagnetic wave shielding performance of the present invention, where 1 is an electromagnetic wave shielding glass plate having a conductive electromagnetic wave shielding coating formed thereon, and 2 is a conductive material. Conductive backup material as one, 3 is also a conductive gasket as a conductive material,
Reference numeral 4 is a structural sealing material, 5 is a waterproof sealing material, 6 is a backup material, 7 is a unit frame, and 8 is a vertical portion of the building.

In the example shown in FIG. 1, the structural sealing material 4, the backup material 6 and the conductive backup material 2 are arranged between the conductive surface of the electromagnetic wave shielding coating 13 of the electromagnetic wave shielding glass plate 1 and the unit frame 7. The electromagnetic wave shielding glass plate 1 and the unit frame 7 are bonded and fixed by the structural sealing material 4 and electrically connected by the conductive backup material 2. Further, by disposing similar conductive backup materials 2 between the conductive backup materials 2 arranged on both sides of the joining end portions of the adjacent electromagnetic wave shielding glass plates 1, the electromagnetic wave shielding of the electromagnetic wave shielding glass plate 1 is performed. The conductive surface of the coating is electrically continuous.

Further, by disposing the conductive gasket 3 between the unit frame 7 and the vertical portion 8, the electromagnetic wave shielding glass plate 1 is electrically connected to the grounded vertical portion 7, and the electromagnetic wave shielding glass plate 1 is shielded from electromagnetic waves. Performance can be expressed more reliably.

FIG. 2 is a diagram showing an embodiment in which conductivity is added to a conventional backup material, 1 is an electromagnetic wave shielding glass plate, 22 is a conductive backup material as one of the conductive materials, and 3 is the same. A conductive gasket as one of the conductive materials, 4 is a structural sealing material, 5 is a waterproof sealing material, 7 is a unit frame, and 8 is a cubic portion.

In the example shown in FIG. 2, the structural sealing material 4 and the conductive backup material 22 are arranged between the conductive surface of the electromagnetic wave shielding film of the electromagnetic wave shielding glass plate 1 and the unit frame 7 to form the electromagnetic wave shielding glass plate. 1 and the unit frame 7 are adhesively fixed by the structural sealing material 4 and electrically connected by the conductive backup material 22. Further, by disposing the similar conductive backup material 2 between the conductive backup materials 2 arranged on both sides of the joining ends of the electromagnetic wave shielding glass plates 1, the electromagnetic wave shielding glass plate 1
The conductive surface of is electrically continuous.

Further, by disposing the conductive gasket 3 between the unit frame 7 and the vertical portion 8, the electromagnetic shielding glass plate 1 is electrically connected to the grounded vertical portion 8, and the electromagnetic shielding performance of the electromagnetic shielding glass 1 is improved. It can be expressed more reliably.

3 (a) to 3 (f) are views showing examples of various types of cross sections of the conductive backup material 2 as a conductive material used in the present invention, and 14 is neoprene, chloroprene, silicone. Foam made of,
Reference numeral 15 is a conductive metal made of a conductor such as copper, stainless steel or aluminum, 16 is a metal wire made of tin-plated copper wire or copper weld wire, and 17 is a rubber body such as neoprene rubber, chloroprene rubber or silicone rubber. As shown in the figure, the conductive backup material is a foam 14 or a rubber body 1 such that at least the surface is made of a conductor.
The periphery of 7 is covered with a film of conductive metal 15, a tubular foil, or a film, or is covered with metal wire 16.

FIGS. 4A to 4F are views showing an example 15 of cross sections of various types of the conductive gasket 3 as a conductive material used in the present invention, which is made of conductive rubber. There is.

[0026] In the present invention, electromagnetic wave shielding as a glass plate, flat glass, or plastic plate or the like organic glass plate transparent plate surface to the conductive SnO ₂ film of the electrically conductive In ₂
A transparent conductive film such as an O ₃ film, a conductive ZnO film or an Ag film, or a conductive glass frit paste or a conductive coating material containing a conductive metal such as silver, copper or aluminum on the surface of the transparent plate. Is printed on a line or a film by printing, flexographic printing or other printing method,
Then, it may be baked or cured to form an electromagnetic wave shielding filament or an electromagnetic wave shielding film, or may be formed by superposing both of them. In addition,
In this case, both are formed so as to be electrically conductive.

By the way, the surface of a transparent plate made of, for example, a plate glass or a plastic plate has various shades and reflection colors depending on the type, thickness and treatment method of metal or metal oxide, or a laminate of these. The transparency, light transmittance, and reflectance of the transparent plate are different. When used as a window in a building in such a state, the function as an electromagnetic wave shielding building is maintained, but the living environment inside the room may be deteriorated and the original design intention of the building may not be met. In such a case, it is possible to give the color tone, the transmission / reflection performance, and the pattern pattern that match the planning intention of the building.

[0028]

[Effect of the Invention] When constructing an electromagnetic wave shielding building, the window is the most vulnerable part in securing the electromagnetic wave shielding performance. For example, in a building called a shielded room, which requires a high level of electromagnetic wave shielding performance, sufficient electromagnetic wave shielding cannot be ensured in the window, so the building has no window. However, as is clear from the above description, according to the present invention, the electromagnetic wave shielding glass plate and the unit frame are connected by the conductive material, and the unit frame and the grounded cubic portion are connected to each other to electrically connect to the building. Therefore, an electromagnetic wave shielding window that does not impair the electromagnetic wave shielding performance of the electromagnetic wave shielding glass plate itself can be constructed, which is suitable for intelligent buildings and the like.

Since a conductive material is also applied between the window frame and the electromagnetic wave shielding glass plate, the durability and weather resistance are equivalent to those of the conventional window as compared with the case where the conductive structural sealing material is used. In addition, the work of constructing the electromagnetic wave shielding glass plate can be performed as easily as the conventional one.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of the basic configuration of an electromagnetic wave shielding window according to the present invention.

FIG. 2 is a cross-sectional view of the basic configuration of the electromagnetic wave shielding window according to the SSG construction method of the present invention.

FIG. 3 is a cross-sectional view of a conductive backup material used in the electromagnetic wave shielding window of the present invention.

FIG. 4 is a cross-sectional view of a conductive gasket used in the electromagnetic wave shielding window of the present invention.

FIG. 5 is a cross-sectional view of the basic configuration of an electromagnetic wave shielding window by the conventional SSG construction method.

[Explanation of symbols]

 1: Electromagnetic wave shielding glass plate 2: Conductive backup material 3: Conductive gasket 4: Structural sealing material 5: Waterproof sealing material 6: Backup material 7: Unit frame 8: Cubic part 13: Electromagnetic wave shielding film 14: Foam 15: Conductive Metal 16: Metal wire 17: Rubber body

Claims (1)

[Claims] 1. A plurality of electromagnetic wave shielding glass plates are arranged on the outer wall surface of a projectile of a building, and adjacent ends of the electromagnetic wave shielding glass plates are connected to a unit frame via a backup material and a structural sealing material. The unit frame is supported and supported by a vertical portion of the outer wall of the body that is electrically grounded and a gasket, and the unit frame and the joint end of the electromagnetic wave shielding window glass plate are sealed by a waterproof sealing. In the electromagnetic wave shielding window by the SSG construction method, an electromagnetic wave having improved electromagnetic wave shielding performance, characterized in that a conductive material electrically connected between the unit frame and the electromagnetic wave shielding glass plate and between adjacent electromagnetic wave shielding glass plates is mounted. Shield window.