KR101090351B1 - blast resistance window system - Google Patents

Abstract

An object of the present invention is to install the wire across the wire inside the explosion-proof glass that can withstand the explosion and blast caused by the explosion to support the explosion-proof glass pushed by the explosion and a predetermined interval along the entire circumference of the explosion-proof window By providing a shock absorbing device to achieve the purpose of providing explosion-proof windows to protect human life and promote safety.

The present invention is a window body consisting of a main frame and a sub-frame that can be fixed to the explosion-proof glass and the edge of the explosion-proof glass and the explosion-proof glass to the wall of the building to withstand the explosion and blast caused by the explosion; The first frame for shock absorption is formed along the entire circumference of the sub-frame so as to absorb the direct shock due to the lateral pressure transmitted to the window body, and is installed in the main frame to be engaged with the first protrusion. An impact absorber having a second protrusion for shock absorption that is broken together with the first protrusion by an impact caused by the blast pressure; And forming an installation groove along the entire circumference of the main frame to fix the shock absorber at a predetermined interval to the entire circumference of the main frame, and fit into the installation groove to fit the shock absorber. It includes a fastener that can be fixed at any position of the installation groove.

Explosion Proof Windows, Explosion Proof Glass, Pressure, Shock Absorption

Description

Explosion-proof window

The present invention relates to an explosion-proof door, and more particularly, to support the explosion-proof glass pushed by the explosion by installing a wire across the inside of the explosion-proof glass that can withstand the explosion and gusts caused by the explosion, and further (To) Explosion-proof windows that can protect the life and safety by absorbing the impact of the explosion by providing a shock absorbing device at a predetermined interval around the whole.

In general, the windows installed in the building are for the purpose of daylight and ventilation, and these windows are responsible for the important aesthetic function of the building and natural light. On the other hand, the window is broken glass due to natural disasters such as typhoons, explosions, etc. When the glass is broken, a lot of lives are damaged by the fragments of glass scattered.

Here, the explosion accident may be caused by various causes, for example

(1) explosives caused by terrorism and explosives caused by high bombs such as TNT;

(2) The flammable gas, such as natural gas, leaks to form a vapor cloud and then ignited to cause a vapor cloud explosion,

(3) Most explosion accidents in which the container storing the high pressure gas bursts explosively and explode.

In such an explosion, a very rapid expansion of the air causes a high-pressure explosion, which propagates from the explosion source.

In particular, a lot of physical damage is expected because of the strong explosions in the area close to the explosion source. In other words, glass is easily broken in windows installed in buildings near the explosion source.

In order to prevent this, conventionally, windows and windows are installed with glass laminated with multilayer laminated glass or a protective polyester film, but such windows and windows have problems in thickness and specific gravity of glass. For example, in order to withstand the pressure, it must be able to absorb the energy to promote safety, the glass installed in the existing windows and doors did not satisfy this, there was a disadvantage that can not protect the facility and personnel.

An object of the present invention is to support the explosion-proof glass to be pushed by the explosion by installing the wire across the inside of the explosion-proof glass that can withstand the explosion and blast caused by the explosion, and to impact at a predetermined interval along the entire circumference of the explosion-proof window By installing an absorber, it is designed to provide explosion-proof windows that can absorb the impact of explosion and protect human life and promote safety.

The present invention for achieving the above object is the main frame and the sub-frame which can be fixed to the wall of the explosion-proof glass and the explosion-proof glass and the explosion-proof glass to the wall of the building which can withstand the explosion and blast caused by the explosion Window body consisting of; The first frame for shock absorption is formed along the entire circumference of the sub-frame so as to absorb the direct shock due to the lateral pressure transmitted to the window body, and is installed in the main frame to be engaged with the first protrusion. An impact absorber having a second protrusion for shock absorption that is broken together with the first protrusion by an impact caused by the blast pressure; And forming an installation groove along the entire circumference of the main frame to fix the shock absorber at a predetermined interval to the entire circumference of the main frame, and fit into the installation groove to fit the shock absorber. It includes a fastener that can be fixed at any position of the installation groove.

The cover may be further installed so that the shock absorber is not exposed to the outside.

In addition, the explosion-proof glass is laminated between at least two sheets of glass plates and at least two sheets between the glass plates and the polycarbonate plate (POLYCARBONATE) to be able to reinforce the glass plates and installed between each plate And are fixed to any one of the adhesive layers and the adhesive layers which are bonded together to be integrally bonded while melting by heat in a lamination process, and both ends are protruded outwards across the glass plates, and protrude outward. Both ends are fixed to any one of the main frame and the sub-frame, characterized in that made of a wire to support the explosion-proof glass pushed by the explosion.

The wires may be arranged to be arranged in at least two rows at predetermined intervals.

The present invention supports the explosion-proof glass to be pushed by the explosion by installing the wire across the inside of the explosion-proof glass that can resist the explosion, and by installing a shock absorbing device to form a predetermined interval along the edge of the explosion-proof window, explosion pressure and gusts It is possible to absorb the shock transmitted from the explosion-proof windows from the effect of protecting people and promoting safety.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the explosion-proof window according to the present invention, Figure 2 is a cross-sectional view of the line II of Figure 1, Figure 3 is an enlarged view "A" of Figure 2, Figure 4 is an explosion-proof window according to the present invention Figure 5 is an exploded perspective view showing the separation state of the shock absorber is installed in, Figure 5 is a view showing a state in which the shock absorber is destroyed to absorb the shock in the explosion-proof window according to the invention, Figure 6 is a "B" of FIG. Wealth enlarged view.

As shown in the drawings, the explosion-proof window according to the present invention is provided with a window body 100. The window body 100 is installed along the edge of the explosion-proof glass 110 and the explosion-proof glass 110 that can withstand the explosion and blast caused by the explosion, the sub-frame 104 for fixing the explosion-proof glass 110 And a main frame 102 which is fixed to the wall of the building by defects on the outside of the sub-frame 104.

The explosion-proof glass 110 is formed by adhering the polycarbonate (POLYCARBONATE) plate and the polyvinyl butyral (POLYVINYLBUTYRAL) in close contact between at least two or more glass plates. That is, a polycarbonate plate is provided between two glass plates. Then, an adhesive film made of a resin bonded by heat is inserted between the glass plate and the polycarbonate plate, and when heat is applied in a laminating process, the glass plate and the polycarbonate plate are bonded to each other while the surface of the adhesive film is melted. . Here, the polycarbonate constituting the polycarbonate plate is a kind of resin material that is resistant to impact and heat and transparent, and can be remarkably lighter and thinner than glass, having the advantages of glass and, on the contrary, complementing the disadvantages of glass. Can be. Therefore, by providing a polycarbonate plate between the glass plates, it is possible to significantly improve impact resistance while being relatively light and thin.

In addition, the adhesive film is made of polyvinyl butyral (POLYVINYLBUTYRAL), the polyvinyl butyral is a kind of resin material to bond the glass plate and the polycarbonate plate by a lamination process, and the impact absorption is excellent, such as an adhesive Play a role. The polyvinyl butyral is bonded to the surface of the glass plate has an effect of preventing the glass plate is scattered when the breakage does not leave sharp fragments. That is, by joining at least two or more glass plates with a flexible polyvinyl butyral to a plastic series polycarbonate plate, even if breakage occurs due to the blast energy, the glass plate does not scatter, so that it can withstand the blast energy. You can keep safe. Such explosion-proof glass 110 will be described in more detail later with reference to FIGS. 7 to 10.

In order to install such explosion-proof glass 110 between the said main frame 102 and the subframe 104, it installs integrally using the flexible silicone sealant. That is, the silicone sealant is installed in a structure having a sufficient bonding surface around the perimeter of the explosion-proof glass 110 provided between the main frame 102 and the sub-frame 104 to prevent explosion in a condition having elasticity to the resistance of the explosion. The detachment of the glass 110 may be prevented.

The silicone sealant has a function of absorbing the impact between the explosion-proof glass 110 and the frames 102 and 104 by the characteristics (strong durability and flexibility). In particular, by effectively fixing the edge of the explosion-proof glass 110 to the frame (102,104) by the silicone sealant, even if the explosion-proof glass 110 is damaged by the explosion pressure can hold the edge of the explosion-proof glass 110 and glass fragments. It can distribute the energy of the pressure to the window frame.

As shown in the drawings, the explosion-proof window according to the present invention includes a shock absorber 120. The shock absorber 120 is installed between the main frame 102 and the sub-frame 104 in order to be able to absorb the direct shock transmitted to the window body 100 by the explosion. That is, the shock absorber 120 forms a shock absorbing first protrusion 122 along the entire circumference of the sub-frame 104 and engages with the first protrusion 122 to absorb the second shock absorbing second. The protrusions 124 are installed at predetermined intervals along the circumference of the main frame 102 to absorb the shocks while the first and second protrusions 122 and 124 are destroyed by the impact of the pressure.

As shown in the drawings, the explosion-proof door according to the present invention is provided with a fastener 130. The fastener 130 is for fixing the shock absorber 120 to the main frame 102 at a predetermined interval, and the fastener 130 is a bolt for fixing the shock absorber 120 ( 132 and nuts 134. The fastener 130 as described above may be installed to penetrate the bolt 132 through the shock absorber 120 and the main frame 102 may be fixed by inserting the head of the bolt 132 into the main frame 102. The installation grooves 126 are formed along the entire circumference of the 102. That is, the head of the bolt 132 is fixed to the mounting groove 126 and then fixed to the bolt 132 by tightening the shock absorber 120 as a nut 134 (see FIG. 4).

By the fastener 130, the shock absorber 120 may be fixed at an arbitrary position at predetermined intervals along the entire circumference of the main frame 102. That is, the head of the bolt 132 is inserted into the installation groove 126 formed in the main frame 102 so as to slide the bolt 132 can be positioned at any position around the main frame 102 The shock absorber 120 may be fixed by moving anywhere around the main frame 102 to a desired position (a site that receives the most impact).

The shock absorber 120 fixed to the main frame 102 by the fastener 130 is fixed at predetermined intervals along the entire circumference of the main frame 102 and is transmitted to the window body 100. It can absorb the direct impact of the blast pressure. That is, the shock absorbing second protrusion 124 provided in the shock absorber 120 and the shock absorbing first protrusion 122 provided in the sub-frame 104 by the width pressure transmitted to the window body 100. Is broken together to absorb the shock (see FIGS. 5 and 6). To this end, in the present invention, the first and second protrusions 122 and 124 for absorbing shock absorb a shock rather than being destroyed when subjected to impact, and thus have a weaker strength than that of metal, for example, iron, which is deformed while being deformed. It is good to manufacture with aluminum which has ductile property with good water absorption.

In addition, the explosion-proof window according to the present invention may be further provided with a cover 140 so that the shock absorber 120 is not exposed to the outside. By the cover 140, the shock absorber 120 is not visible to the outside, thereby improving the appearance of the explosion-proof window. The cover 140 is formed in a bar shape having a “a” shape so as to couple the main frame 102 and the sub frame 104 to each other so that the shock absorber 120 is not visible to the outside.

According to the present invention, the explosion-proof glass 110 is fixed to the main frame 102 and the sub frame 104, and the shock absorber 120 is disposed between the main frame 102 and the sub frame 104. To distribute the detonation energy. That is, the shock absorbing first and second protrusions 122 and 124 installed at predetermined intervals along the entire circumference of the frames 102 and 104 may be dispersed and absorbed while being destroyed by the impact of the explosion.

Figure 7 is an exploded perspective view for explaining the structure of the explosion-proof glass provided in the explosion-proof window according to the present invention, Figure 8 is a cross-sectional view showing a structure for the explosion-proof glass of FIG.

As shown in the drawings, the explosion-proof glass 110 provided in the explosion-proof window according to the present invention is a glass plate (112a, 112b) and the glass plate (laminated in at least two sheets to be resisted from the explosion and blast caused by explosion) Laminating process is installed between the polycarbonate (POLYCARBONATE) plate 114a and each of the plates (112a, 112b, 114a) that is laminated between the 112a, 112b to strengthen the glass plates (112a, 112b) It is composed of adhesive layers (116a, 116b) to be adhered to each plate to be integrally bonded while melting by heat. The adhesive layers 116a and 116b are not shown in the separated perspective view of FIG. 7, but the adhesive layers are illustrated in FIG. 8.

In order to manufacture the explosion-proof glass 110, a polycarbonate plate 114a is provided between two glass plates 112a and 112b. Then, after inserting an adhesive film made of a resin that is bonded by heat between the glass plates 112a and 112b and the polycarbonate plate 114a, respectively, and applying heat in a laminating process, the surface of the adhesive film melts and The base glass plates 112a and 112b and the polycarbonate plate 114a are bonded to each other by the adhesive layers 116a and 116b.

Here, the polycarbonate constituting the polycarbonate plate (114a) is a kind of resin material that is strong and transparent to impact and heat, it is tough and remarkably lighter than glass and can be thinner, and has the advantages of glass and conversely the disadvantages of glass. Can complement. Therefore, by installing the polycarbonate plate 114a between the glass plates 112a and 112b, the impact resistance can be greatly improved while being relatively light and thin.

In addition, the adhesive film is preferably made of polyvinyl butyral (POLYVINYLBUTYRAL), the polyvinyl butyral is a kind of resin material to the glass plate and the polycarbonate plate mutually bonded by the lamination process, and excellent impact absorption ability to the adhesive and Play the same role.

Such polynibyl butyral is bonded to the surface of the glass plate is effective to prevent the glass plate is scattered when it is broken to leave sharp fragments. That is, by bonding at least two or more glass plates with a flexible polyvinyl butyral to a plastic series polycarbonate plate, even if breakage occurs due to blasting energy, the glass plate does not scatter and can withstand the blasting energy. By making it possible to maintain safety, explosion-proof glass can be manufactured to resist explosion pressure and gusts.

In addition, the explosion-proof glass 110 is installed so that the wire 118 is embedded to support the explosion-proof glass 110 that is pushed by the explosion to absorb the shock. The wire 118 is fixed to the adhesive layer 116b constituting the explosion-proof glass 110, so that both ends of the wire 118 protrude outward of the explosion-proof glass 110. That is, the diameter of the wire 118 is formed to form a diameter corresponding to the thickness of the adhesive layer 116b for adhering the glass plate 112b and the polycarbonate plate 114a to be located in the adhesive layer 116b to the adhesive layer By being fixed as 116b, the wire 118 can be firmly embedded in the explosion-proof glass 110. In particular, when the diameter of the wire 118 is larger than the thickness of the adhesive layer 116b, the wire 118 presses the polycarbonate plate 114a while laminating the plates 112a, 112b, and 114a. To be bonded.

The wire 118 is installed in this way is built in the explosion-proof glass 110 is installed across the explosion-proof glass 110, it can support the explosion-proof glass 110 pushed by the explosion. That is, in order to support the explosion-proof glass 110 pushed by the wire 118 to the explosion, both ends of the wire 118 protruding outward of the explosion-proof glass 110 to one of the fixed frame or the sub-frame. You can fix it.

Figure 9 is an exploded perspective view showing another embodiment of the explosion-proof glass provided in the explosion-proof window according to the present invention.

As shown in the drawings, the other embodiment of the explosion-proof glass is different only in the configuration in which the wires 118a and 118b are arranged in two rows at a predetermined interval in the explosion-proof glass described above, and the other configurations are the same. . This alternative embodiment can more reliably support the explosion-proof glass (110a) is pushed by the explosion by the wires (118a, 118b) are arranged in two rows at a predetermined interval on the explosion-proof glass (110a).

10 is an exploded perspective view showing another embodiment of the explosion-proof glass provided in the explosion-proof window according to the present invention.

As shown in the drawing, another embodiment of the explosion-proof glass may be different only in the configuration in which at least two or more polycarbonate plates 114a and 114b are provided between the glass plates 112a and 112b in the explosion-proof glass described above. In addition, the other structure is the same. That is, the explosion-proof glass shown in FIG. 10 has at least two or more polycarbonate plates 114a and 114b integrated between adhesive layers between the glass plates 112a and 112b laminated at least two or more. The wire 118c is provided between the polycarbonate plates 114a and 114b. The explosion-proof glass according to the third embodiment can strengthen the glass plates 112a and 112b more firmly by installing at least two of the polycarbonate plates 114a and 114b.

In various embodiments of the explosion-proof glass of the present invention, the glass plate for forming the explosion-proof glass is described by showing only the configuration in which two sheets are laminated, the glass plate and the polycarbonate plate is three or four or more Multiple layers can be installed.

According to the present invention, since the explosion pressure energy (shock due to the explosion) exerts the most pressure on the center of the explosion-proof glass, the explosion-proof glass is bent by absorbing the pressure. At this time, both ends of the wire is fixed to any one of the fixed frame or the sub-frame, it is possible to support the explosion-proof glass bent by the pressure energy. In particular, the present invention provides a safeguarding function by preventing the fragments from flying or falling off by the adhesive layers 116a and 116b during the storm, even if the laminated glass plates 112a and 112b are broken. Have

1 is a view showing the explosion-proof window according to the present invention,

2 is a cross-sectional view taken along the line I-I of FIG.

3 is an enlarged view of a portion “A” of FIG. 2;

Figure 4 is an exploded perspective view showing a separation state of the shock absorber installed in the explosion-proof window according to the present invention,

5 is a view showing a state in which the shock absorber is destroyed to absorb the shock in the explosion-proof window according to the present invention,

FIG. 6 is an enlarged view of a portion “B” of FIG. 6;

7 is an exploded perspective view for explaining the structure of the explosion-proof glass provided in the explosion-proof window according to the invention,

8 is a cross-sectional view showing the structure of the explosion-proof glass shown in FIG.

9 is an exploded perspective view showing another embodiment of the explosion-proof glass shown in FIG.

10 is an exploded perspective view showing still another embodiment of the explosion-proof glass shown in FIG.

Explanation of symbols on the main parts of the drawings

100-Window Body 102-Main Frame

104-Subframe 110,110a, 110b-Explosion Proof Glass

112a, 112b-glass plate 114a, 114b-polycarbonate plate

116a, 116b-adhesive layer 118,118a, 118b, 118c-wire

120-shock absorber 122,124-first and second protrusions for shock absorption

126-Mounting groove 130-Fastener

132-Bolt 134-Nut

Claims (4)

delete delete Window body consisting of a main frame and a sub-frame that can be fixed to the explosion-proof glass and the edge of the explosion-proof glass to resist from the explosion and blast caused by the explosion; The first frame for shock absorption is formed along the entire circumference of the sub-frame so as to absorb the direct shock due to the lateral pressure transmitted to the window body, and is installed in the main frame to be engaged with the first protrusion. An impact absorber having a second protrusion for shock absorption that is broken together with the first protrusion by an impact caused by the blast pressure; And An installation groove is formed along the entire circumference of the main frame to fix the shock absorber at a predetermined interval to the entire circumference of the main frame, and is fitted into the installation groove to install the shock absorber. A fastener configured to be secured at any position of the groove, The explosion-proof glass is laminated between at least two sheets of glass plates and at least two sheets of polycarbonate plates (POLYCARBONATE) which are laminated between the glass plates and reinforce the glass plates. It is fixed to any one of the adhesive layer and the adhesive layer to be bonded by bonding each plate integrally while melting by the heat in the process, and both ends protruding outward across the glass plate, both ends protruding to the outside Explosion-proof window characterized in that made of a wire to support the explosion-proof glass pushed by the explosion by being fixed to any one of the main frame and the sub-frame. The explosion-proof door according to claim 3, wherein the wires are arranged to be arranged in at least two rows at predetermined intervals.

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