KR20210125198A - Double-glazed glass system for emergency escape and firefighter entry windows - Google Patents

Abstract

The present invention is to provide a double-glazed glass system for emergency escape and firefighter entry windows, which can be simply applied to double-glazed glass to collectively crush the double-glazed glass with one striking force. According to the present invention, the double-glazed glass system for emergency escape and firefighter entry windows comprises: a shredding bundle (10) which is installed between double-glazed glass (1), and in which a crushing blade (12) is formed on an outer surface corresponding to the double-glazed glass (1); a cross rod (20) formed between the double-glazed glass (1) so as to position the shredding bundle (10); and a marking member (30) installed on an outer surface of the double-glazed glass (1) corresponding to the shredding bundle (10) to indicate a striking point.

Description

{Double-glazed glass system for emergency escape and firefighter entry windows}

The present invention relates to a double glazing system for emergency evacuation and firefighter entry windows, and to a double glazing system for emergency evacuation and firefighter entry windows capable of collectively shredding the entire laminated glass with one blow.

In general, glass windows of buildings use tempered glass with higher strength than general glass so that there is no fear of being easily damaged by impact. Since such tempered glass does not break easily, it is difficult to escape in case of an emergency.

In other words, in case of emergency including fire or toxic gas leakage, it is necessary to destroy the glass window and quickly escape to the outside of the building, or a rescue team must enter quickly from the outside to reduce human casualties, but due to the nature of tempered glass, it cannot be easily destroyed. As a result, it leads to major casualties.

Accordingly, in Patent Publication No. 10-2010-0085601 disclosed in the prior art, a hollow fixing member having one surface fixed to the glass window, and a guide movable in the vertical direction to the fixing member, are installed to be movable, one end protruding through the fixing member The other end is a technology including a breaking member provided so as to be able to break the glass window by hitting, and a cap member that fixes one end of the breaking member with the inside and the inner circumferential surface is movably provided along the outer circumferential surface of the fixing member has been presented

In addition, in Utility Model Registration No. 20-0439195, which is another prior art, the glass breaking device for emergency escape can fix the fixing part to the glass surface by the fixing tape, and the breakage part is fixed by placing the insertion part fixing projection and the insertion part supporting projection of the fixing part. It can be fixed normally, and a pressing part is placed inside the circular fixing part and multiple broken parts are formed on the pressing part. In an emergency, if the pressing part is hit, the insertion part supporting projection is damaged, the 4 steel projections of the damaged part break the glass door. has been registered

However, the prior art is a technique for escaping by breaking the glass with a simple operation such as a blow, but as most of the glass windows constructed in recent years are formed of at least two or more double-glazed windows to secure a high degree of thermal insulation, any one glass window In order to destroy the remaining windows, a separate striking tool such as a hammer is absolutely necessary to destroy the remaining windows, and in the event of a fire, rescue teams from outside the building must destroy the double-glazed windows step by step and enter, thus delaying rescue activities. there was.

Accordingly, the present invention was conceived to solve the above problems, and by a simple assembly structure of arranging a crushing bundle and a cross rod between the multilayer glass, the manufacturing process is simplified and the existing multilayer glass production line can be produced without change, In particular, it is a task of the present invention to provide a double-glazed glass system for emergency evacuation and firefighter entry windows, in which double-glazed glass is collectively shredded with one strike force, which greatly shortens the time for emergency evacuation and rescue team entry in case of an emergency.

In order to achieve this object, a feature of the present invention is a crushing bundle 10 which is installed between the multilayer glass 1, and the crushing blade 12 is formed on the outer surface corresponding to the multilayer glass 1; a cross rod 20 formed between the double-glazed glass 1 to position the crushing bundle 10; and a marking member 30 which is installed on the outer surface of the double-layer glass 1 corresponding to the crushing bundle 10 and is formed to indicate the striking point.

And, the marking member 30 is characterized in that the multi-layer glass (1) to hit the outer surface of the shredding blade (12') is formed a multi-shredding bundle (10') is further installed.

In addition, it is characterized in that the desiccant 40 is provided between the crushing bundle 10 and the liver rod 20 to absorb moisture.

In addition, the interbar 20 has an isolation partition 22 formed therein to accommodate the crushing bundle 10, or insert molding the crushing bundle 10 inside the interstitial rod 20, and the crushing blade 12 is external. It is formed to be exposed as, or insert-molding the crushing bundle 10 inside the rod 20, and the crushing blade 12 is covered by the heat insulating layer 24 to be non-exposed.

In addition, a plurality of crushing bundles 10 are insert-molded in the longitudinal direction of the inter-bar 20, and one or a plurality of crushing bundles 10 are integrally formed according to the cutting length of the inter-bar 20. .

In addition, the interstitial rod 20 is characterized in that it consists of a sine wave-shaped support plate (20a) and an airtight block (20b) formed on one or both sides of the support plate (20a) and attached to the double-layer glass (1).

In addition, the crushing bundle 10 is formed in a spherical, cylindrical or polyhedron, characterized in that at least one or a plurality of crushing blades 12 are formed on the outer surface corresponding to the multi-layer glass (1).

In addition, when the crushing bundle 10 is installed in two or more layers, the crushing blades 12 formed in the crushing bundles 10 adjacent to each other are arranged so as to be inconsistent on a straight line, so that the crushing blade 12 strikes the point is characterized in that they are formed to be shifted from each other.

According to the above configuration and action, the present invention can be produced without changing the existing double-layer glass manufacturing line as well as the simplification of the manufacturing process by a simple assembling structure of arranging a crushing bundle and a cross rod between the multi-layer glass, and in particular, a multi-layer glass with a single striking force. The glass is shredded in batches, which greatly shortens the time for emergency evacuation and entry of rescue teams in case of an emergency.

1 is a front view showing a preferred embodiment of the double-glazed system for emergency evacuation and firefighter entry windows provided by the present invention.
Figure 2 is a block diagram showing the assembly structure of the crushing bundle and the interstitial bar of the double-glazed glass system for emergency escape and firefighter entry windows.
3 is a configuration diagram showing various types of crushing bundles of the double-glazed glass system for emergency escape and firefighter entry windows.
Figure 4 is a configuration diagram showing various forms of the crushing bundle and the inter-bar coupling structure of the double-glazed glass system for emergency escape and firefighter entry windows.
Figure 5 is a block diagram showing the shredding bundle and the inter-bar integrated structure of the double-glazed glass system for emergency evacuation and firefighter entry windows.
Figure 6 is a configuration diagram showing various forms of the double glazing system for emergency evacuation and firefighter entry windows.
7 is a configuration diagram showing a state in which two crushing bundles are applied to the triple glass of the double-glazed glass system for emergency escape and firefighter entry windows.
8 is a configuration diagram showing a state in which a multi-shredding bundle is applied to the marking member of the double-glazed glass system for emergency escape and firefighter entry windows.
9 is a block diagram showing a desiccant of a double-glazed glass system for emergency escape and firefighter entry windows.

Hereinafter, the present invention will be described in detail based on the accompanying illustrative drawings. 1 is a front view showing a preferred embodiment of the double-glazed glass system for emergency evacuation and firefighter entry windows provided by the present invention, and FIG. 2 is a configuration showing the crushing bundle and interstitial assembly structure of the double-glazed glass system for emergency evacuation and firefighter entry windows It is also

Referring to the drawings, the configuration of the present invention is largely composed of a crushing bundle 10 disposed between tempered glass, a rod 20 surrounding the crushing bundle, and a marking member 30 attached to the glass surface exposed to the outside. .

According to the present invention, the crushing bundle 10 is installed between the multilayer glass 1, and the crushing blade 12 is formed on the outer surface corresponding to the multilayer glass 1 .

The crushing blade 12 refers to a configuration for directly hitting the glass plate when the crushing bundle 10 is in point contact or line contact with the glass plate and an external shock is transmitted.

The crushing bundle 10 is formed of a metal body having high hardness, or a block in which the area corresponding to the crushing blade 12 is formed as a metal layer locally. At this time, the crushing bundle 10 is disposed adjacent to any one corner of the multilayer glass 1 as shown in FIG. 1 so as not to obstruct the view through the multilayer glass 1 .

At this time, the crushing bundle 10 shows a state in which one is installed between the double-layered glass 2 of the double structure as shown in FIG. It shows the state in which the two crushing bundles 10 are installed. The crushing bundles 10 should be installed between all the glass and the glass, and at the same time, the crushing bundles 10 should be arranged on the same line for effective transmission of striking force.

The crushing bundle 10 is formed in a spherical, cylindrical or polyhedron, and at least one or a plurality of crushing blades 12 are formed on the outer surface corresponding to the multilayer glass 1 . As an example, Fig. 3 (a) shows a configuration in which the crushing bundle 10 is formed in a spherical shape, and an arcuate crushing blade 12 is formed so as to be able to strike the multilayer glass 1 on the outer circumferential surface, Fig. 3 (b) To (c) shows a configuration in which the crushing bundle 10 is formed in a polyhedron, and at least two vertices form the crushing blade 12, and FIGS. 3 (d) to (f) are the crushing bundles 10 are cylindrical or It shows a state in which one or a plurality of wedge-shaped crushing blades 12 striking the double-layer glass 1 on both side surfaces opposite to each other are formed in a quadrangle and protrude.

On the other hand, the formation of the crushing bundle 10 is not limited to Figs. 3 (a) to (f), and can be deformed into any shape as long as it has a structure that can be supported by a rod 20 to be described later.

In a configuration for fixing the position of the crushing bundle 10 , an interstitial rod 20 is formed between the multilayer glass 1 . The interstitial rod 20 has an isolation compartment 22 formed therein as shown in FIG. 4 (a) to accommodate the crushing bundle 10, or as shown in FIG. 4 (b), a crushing bundle ( 10) is insert-molded and the crushing blade 12 is exposed to the outside, or the crushing bundle 10 is insert-molded inside the interbar 20 as shown in FIG. ) and may be formed in an unexposed state.

As shown in FIGS. 4 (b) to (c), in insert-molding the crushing bundle 10 inside the inter-bar 20, a plurality of crushing pieces are crushed in the longitudinal direction of the inter-bar 20, as shown in FIG. The bundle 10 is insert-molded, and one or a plurality of crushed bundles 10 are integrally formed according to the cutting length of the inter rod 20 .

In this way, when the interstitial rod 20 is manufactured by molding into which the crushing bundle 10 is inserted, the mass production of the crushing bundle 10 and the interstitial rod 20 integral structure is possible and, if necessary, one or more crushing bundles 10 ) when applied between the multilayer glass 1, the integrity is maintained, so that the assembly can be improved.

And, the interstitial rod 20 is composed of a sinusoidal support plate 20a and an airtight block 20b formed on one or both surfaces of the support plate 20a and attached to the double-layer glass 1 .

As an embodiment, Figure 6 (a) is a sine wave-shaped support plate (20a) airtight block (20b) is formed on one surface, the sine-wave-shaped support plate (20a) is molded to form an inner peripheral surface to the inside of the crushing bundle (10) shows a state that is accommodated, Figure 6 (b) is a sine wave-shaped support plate (20a) airtight block (20b) is formed on one surface, the sine wave-shaped support plate (20a) is molded to form an outer peripheral surface, crushing bundles inside (10) represents a state that is accommodated, Figure 6 (c) is a sine wave type support plate (20a) on both sides of the airtight block (20b) is formed, the sinusoidal support plate (20a) is located inside the airtight block (20b) It is molded so as to show a state in which the crushing bundle 10 is accommodated therein.

At this time, the airtight block 20b is formed of a material having a soft adhesive property so that it is closely adhered to the glass 1 and airtightly attached, and the support plate 20a is made of a metal material to stably support the weight of the crushing bundle. and prevent deformation of the shape of the gwanbong even after long-term use.

In the case of installing two or more crushing bundles 10 in multiple layers, such as a triple window, the crushing blades 12 formed in the crushing bundles 10 adjacent to each other are arranged so as to be inconsistent on a straight line. . As an embodiment thereof, Figure 7 shows a state in which two crushing bundles 10 are installed in multiple layers between triple glass, at this time, one crushing blade 12 is formed on either side of the crushing bundle 10, Two crushing blades 12 are formed in other crushing bundles 10 adjacent to each other, and the crushing blades 12 formed in each crushing bundle 10 are formed to be inconsistent with each other on a straight line.

Accordingly, when a striking force is applied through one side of the crushing bundle 10, the striking points by the crushing blades 12 of the crushing bundles 10 adjacent to each other are shifted from each other, and this causes the glass 1 to be bent to the side and an external force is applied. There is an advantage in that the glass (1) destruction efficiency is improved even with a weak striking force.

In addition, the marking member 30 according to the present invention is installed on the outer surface of the multi-layer glass 1 corresponding to the crushing bundle 10 to indicate the striking point. The marking member 30 is formed of a reflective sheet, a reflective material (sheets such as silver foil paper, banshi sheet, etc.) that is easy to identify day and night including a reflective sheet and a metal sheet, and a design (design (hammer, arrow, etc.), and a crushing bundle (10). ), it is also possible to form an overlapping insulation sheet in order to secure thermal insulation properties.

At this time, as shown in FIG. 8 , a multi-shredding bundle 10 ′ in which a crushing blade 12 ′ is formed so as to strike the outer surface of the double-layer glass 1 may be further formed on the marking member 30 . That is, the marking member 30 is formed of a multi-shredding bundle 10' having a crushing blade 12' formed on one surface, and the multi-shredding bundle 10' is a sheet-shaped cap or a self-adhesive adhesive member. It is installed on the outer surface of the double-glazed glass (1).

Here, the multi crushing bundle 10 ′ can be applied in the same manner as in various embodiments of the crushing bundle 10 , but is configured in a form in which the crushing blade 12 is applied to one surface of the crushing bundle 10 .

When an emergency situation occurs, when the marking member 30 is struck indoors or outdoors, the striking force is primarily applied from the outside of the double-layer glass by the multi-shredding bundle 10 'and at the same time, the crushing bundle (10) installed between the double-layered glass Since the crushing blade 12 strikes another multi-layer glass while the impact is transmitted to the furnace, the multi-layer glass is collectively crushed by a single striking force.

In FIG. 9 , a desiccant 40 is provided between the crushing bundle 10 and the interstitial rod 20 to absorb moisture. The desiccant 40 is installed on the inner circumferential surface of the interstitial rod 20 in the form of a sheet, or is installed embedded in the interstitial rod 20 .

In this configuration, when dew condensation is generated in the inner space of the interstitial rod 20 or the isolation compartment 22 by the interstitial rod 20 that closes and encloses the periphery of the crushing bundle 10, it absorbs contamination between the double-glazed glass. In addition to the prevention, it is possible to prevent damage to the crushed bundle 10 and the liver rod 20 due to moisture.

The present invention configured as described above simplifies the manufacturing process by a simple assembling structure of arranging the crushing bundle 10 and the interstitial rod 20 between the multi-layer glass 1, and it can be produced without changing the existing multi-layer glass manufacturing line. , in particular, the double-glazed glass is collectively shredded with one blow by the shredding bundle 10, which has the advantage of greatly shortening the time for emergency evacuation of evacuees and entry to the rescue team in case of an emergency.

As described above, the present invention has been described with specific examples, but the present invention is not particularly limited by the examples disclosed in this specification and the accompanying drawings, and within the scope that does not depart from the technical spirit of the present invention It will be apparent that various modifications and variations can be made by those skilled in the art.

1: double-glazed glass 10: crushed bundle
10': multi-shredding bundle 12, 12': shredding blade
20: interstitial rod 20a: support plate
20b: airtight block 22: containment section
24: insulation layer 30: marking member
40: desiccant

Claims (6)

It is installed between the multi-layer glass (1), the crushing bundle 10 in which the crushing blade 12 is formed on the outer surface corresponding to the multi-layer glass (1);
a cross rod 20 formed between the double-glazed glass 1 to position the crushing bundle 10; and
The double-glazed glass system for emergency evacuation and firefighter entry windows, characterized in that it comprises;
The method of claim 1,
The multi-layer glass system for emergency escape and firefighter entry windows, characterized in that the marking member 30 is further formed with a multi-shredding bundle 10 ′ having a crushing blade 12 ′ formed to strike the outer surface of the double-layer glass 1 . .
The method of claim 1,
A double-glazed glass system for emergency escape and firefighter entry windows, characterized in that a desiccant (40) is installed between the crushing bundle (10) and the inter rod (20) to absorb moisture. The method of claim 1,
The interstitial rod 20 has an isolation compartment 22 formed therein so that the crushing bundle 10 is accommodated, or the crushing bundle 10 is insert-molded in the interstitial 20, and the crushing blade 12 is exposed to the outside. Double-glazed glass system for emergency escape and firefighter entry windows, characterized in that the shredding bundle 10 is insert-molded inside the bar 20, and the shredding blade 12 is coated with a heat insulating layer 24 and is not exposed. .
The method of claim 1,
The interbar 20 is formed of a support plate 20a formed of a metal material to have a sinusoidal shape, and an airtight block 20b formed on one or both sides of the support plate 20a and attached to the double-layer glass 1, characterized in that Double glazing system for emergency evacuation and firefighter entry windows.
The method of claim 1,
When the crushing bundle 10 is installed in two or more layers, the crushing blades 12 formed in the crushing bundles 10 adjacent to each other are arranged to be inconsistent on a straight line, so that the striking points by the crushing blades 12 are mutually exclusive. Double-glazed glass system for emergency escape and firefighter entry windows, characterized in that they are misaligned.

Images