JP7107611B1 - double glazing - Google Patents

Abstract

An object of the present invention is to provide a double glazing that can be made lighter while maintaining safety against impact by using heat-strengthened glass. A multi-layer glass 1 having a space 1h formed between a first glass 10 arranged on the outdoor side and a second glass 20 arranged on the indoor side, wherein the multi-layer glass 1 has a thickness of is 9 to 44 mm, the first glass 10 is glass with a glass portion thickness of 3 to 12 mm, and the thickness of the glass portion is 3 to 12 mm. It is a laminated glass made by laminating two sheets of tempered glass with a thickness of 2.5 to 6 mm. [Selection drawing] Fig. 1

Description

The present invention relates to double glazing. More particularly, it relates to double glazing in which dry air, argon gas, or the like is enclosed between a plurality of sheet glasses.

In recent years, the size of typhoons has increased significantly, and the damage inside buildings has become more serious due to the damage to the glass installed in the windows and openings facing the outside due to the impact of the typhoon, and the flying objects have broken the glass. There have been cases where people have been injured by penetrating.
On the other hand, in buildings, the size and weight of glass are increasing, and as the size of glass increases, the glass becomes more susceptible to damage. is becoming important to

Float glass and heat-treated glass (tempered glass, tempered glass) are used for the glass installed in windows and openings facing the outdoors.

When increasing the wind pressure resistance of float glass, it is generally dealt with by increasing the thickness of the glass. However, in a large window such as a sweep window, depending on the design conditions, the plate thickness may become too thick and the glass may not fit in the glass groove of the standard sash. In addition, even if the glass can be accommodated in the glass groove of a standard sash, the weight of the glass increases, making it difficult for elderly people and children, who are residents, to easily operate the sweep window. There may be cases where it is not possible to

If heat-treated glass (tempered glass, double-strength glass) is used instead of float glass, the strength of the glass itself can be increased even if the thickness is the same. For the same thickness, tempered glass is approximately twice as strong as float glass, and tempered glass is three to five times as strong as float glass. Therefore, if heat-strengthened glass or tempered glass is used instead of float glass, the thickness of the glass can be reduced even if the strength is the same as that of float glass, so that the weight of the glass can be reduced.

By the way, double-strength glass and tempered glass are common in that the strength of the glass itself is higher than that of float glass. Heat-strengthened glass has a breakage pattern in which large pieces and small pieces similar to float glass are mixed, whereas tempered glass has a breakage pattern in which all pieces are granular with a size of about 5 to 10 mm when broken. occurs. Tempered glass is used for automatic doors and other parts that people may come into contact with because it can prevent secondary disasters such as injuries caused by large fragments when broken.

On the other hand, when the tempered glass is broken, the broken pieces become granules with a size of about 5 to 10 mm as described above. For this reason, when tempered glass is used for windows and openings facing the outside, if the glass is damaged by a typhoon, etc., a large hole will be formed in the damaged part, and the damage inside the building will become serious from that opening. .

Such a problem can be prevented by using a tempered laminated glass in which two or more tempered glasses are laminated with a film or the like. However, even when the tempered laminated glass is used, if all of the tempered glass forming the tempered laminated glass is broken, the toughness of the tempered laminated glass is lost. If the toughness of the tempered laminated glass is lost, even if the broken pieces do not fall and the glass exists in the broken portion, the wind pressure resistance and impact resistance safety of the glass against flying objects cannot be ensured. For this reason, even if the weight of the glass can be reduced by using the tempered laminated glass, it is not desirable in terms of ensuring the impact resistance safety of the glass. Therefore, in order to reduce the weight of glass used for windows and openings while ensuring impact resistance safety, it is conceivable to use tempered glass instead of tempered glass.

By the way, Patent Document 1 discloses a technique related to multi-layer glass using heat-strengthened glass, and discloses the use of laminated glass obtained by combining heat-strengthened glass and float glass as outdoor glass. there is Further, it is disclosed that the glass on the indoor side is a laminated glass obtained by combining the same or different types of tempered glass, float glass, and tempered glass.

Japanese Patent Application Laid-Open No. 2002-226237

However, Patent Document 1 is a technique for the purpose of not generating streaks or mottled striped patterns in the reflected image of the glass, and from the viewpoint of the generation of striped patterns, the use of double-strength glass for double glazing is proposed. negative about
Moreover, Patent Document 1 does not disclose any effect of the use of double-strength glass on the impact resistance safety of double glazing. No confirmed cases.

SUMMARY OF THE INVENTION In view of the above circumstances, an object of the present invention is to provide a multi-layered glass that can be made lighter while maintaining safety against impact by using heat-strengthened glass.

The double glazing of the first invention is a double glazing in which a space is formed between the first glass arranged on the outdoor side and the second glass arranged on the indoor side, the double glazing comprising: JIS R3109 test: It has impact resistance that passes the C class impact test in 2018, the double glazing has a thickness of 25.76 to 44 mm, and the first glass has a thickness of 25.76 to 44 mm. The glass is made of strong glass and has a thickness of 5 to 12 mm at the glass portion. It is characterized by being a laminated glass made by laminating two sheets of tempered glass with a thickness of 4 to 6 mm (excluding those having an intermediate shielding plate in the space between the first glass and the second glass) .
The double glazing of the second invention is a double glazing in which a space is formed between the first glass arranged on the outdoor side and the second glass arranged on the indoor side, the double glazing comprising: JIS R3109 test: It has impact resistance that passes the 2018 class D impact test, the double glazing has a thickness of 27.28 to 44 mm, and the first glass has a thickness of 27.28 to 44 mm. It is glass with a thickness of 5 to 12 mm at the glass portion using strong glass, and the second glass is a polyvinyl butyral film, ethylene vinyl acetate film, or ionomer resin film with a thickness of 2.28 to 3 mm. It is characterized by being a laminated glass made by laminating two sheets of tempered glass with a thickness of 4 to 6 mm (excluding those having an intermediate shielding plate in the space between the first glass and the second glass) .
The double glazing of the third invention is a double glazing in which a space is formed between the first glass arranged on the outdoor side and the second glass arranged on the indoor side, the double glazing comprising: JIS R3109 test: It has impact resistance that passes the 2018 grade E impact impact test, the double glazing has a thickness of 31.04 to 44 mm, and the first glass has a thickness of 1 Laminated glass in which two tempered glass sheets having a thickness of 4 to 6 mm are laminated via a polyvinyl butyral film, an ethylene vinyl acetate film, or an ionomer resin film having a thickness of 52 to 3 mm, and the second glass has a thickness of 1.52. It is characterized by being a laminated glass in which two sheets of tempered glass with a thickness of 4 to 6 mm are laminated via a polyvinyl butyral film, ethylene vinyl acetate film, or ionomer resin film with a thickness of ~ 3 mm (however, the first glass and excluding those with an intermediate shielding plate in the space between the second glass) .
The double glazing of the fourth invention is a double glazing in which a space is formed between the first glass arranged on the outdoor side and the second glass arranged on the indoor side, the double glazing comprising: It has impact resistance that passes the ISO 16932 E class test (E _ISO class test), and the double glazing has a thickness of 25.76 to 44 mm and a polyvinyl butyral film of 1.52 to 3 mm. Laminated glass in which two tempered glass sheets having a thickness of 4 to 6 mm are laminated via an ethylene vinyl acetate film or an ionomer resin film, and the second glass is a polyvinyl butyral film having a thickness of 2.28 to 3 mm, ethylene vinyl It is characterized by being a laminated glass in which two sheets of tempered glass with a thickness of 4 to 6 mm are laminated via an acetate film or an ionomer resin film (however, in the space between the first glass and the second glass (except those with intermediate blocking plates) .

According to the first to fourth inventions , it is possible to reduce the weight while maintaining impact resistance safety. Moreover, it can also be used for existing sashes.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic explanatory drawing of the sash frame S which installed the double glazing 1 of this embodiment, Comprising: (A) is a front view, (B) is a side view. (A) is a partially enlarged view of the multi-layer glass 1 of the present embodiment in which the first glass 10 is laminated glass, and (B) is the multi-layer glass of the present embodiment in which the first glass 10 is single-layer glass. 1 is a partially enlarged view of FIG.

The multi-layer glass of this embodiment is glass installed in windows or openings facing the outdoors, and is characterized by enhanced impact resistance safety.

The location and member where the double glazing of the present embodiment is installed are not particularly limited. For example, the multi-layer glass of the present embodiment can be used for windows such as sweep windows and large-opening FIX windows of general houses, and openings such as roof lighting windows (skylights: top lights).

Also, the size of the multi-layer glass of the present embodiment is not particularly limited. The surface area of the exposed part is, for example, 0.1 to 18 m ² or 0.1 to 3 m ² when installed in the sweep window, the sash frame of the opening, the FIX window, or the roof lighting window. It can be used for glass with a thickness of 1 to 3 m ² . In particular, if it is used for the multi-layered glass of this embodiment used for a sweep window with an exposed portion having a surface area of 1 to 18 m ² , the weight of the glass can be reduced even if the glass is large, so it can be used for a sweep window. easier to operate.

A state in which the double glazing of the present embodiment is installed in a sash frame of a sweep window will be described below as a representative, but the members and structures for installing the double glazing of the present embodiment are not limited to the following structures.

<Sash frame in which double glazing 1 of the present embodiment is installed>
In FIG. 1, symbol S indicates the sash frame of the sweep window in which the double glazing 1 of the present embodiment is installed. As shown in FIG. 1, the sash frame S has a pair of vertical frames S1, S2 and a pair of horizontal frames S3, S4. A groove g is provided. The width of this groove g is, for example, 9 to 44 mm in the case of a sash frame used for a general sweep window, but there is also a width of about 53 mm. The double glazing 1 of this embodiment can be used for the sash frame S having the groove g with the groove width in this range. That is, by arranging the sides 1a to 1d of the double glazing 1 of the present embodiment in the grooves g formed in the respective frames S1 to S4 of the sash frame S, the double glazing 1 of the present embodiment is formed into the sash frame. It is installed in S.

<Multilayer glass 1 of the present embodiment>
As shown in FIG. 1, the double glazing 1 of the present embodiment (hereinafter sometimes simply referred to as double glazing 1) has a gap (space 1h) between a first glass 10 and a second glass 20. It is set in an empty space. The first glass 10 is arranged so as to be positioned on the outdoor side when the sash frame S on which the multi-layer glass 1 is installed is installed in a building or the like. Further, the second glass 20 is arranged so as to be positioned on the indoor side when the sash frame S on which the multi-layer glass 1 is installed is installed in a building or the like.

As shown in FIG. 1, between the first glass 10 and the second glass 20, that is, a surface 10f of the first glass 10 facing the second glass 20 (hereinafter sometimes simply referred to as the surface 10f of the first glass 10) ) and a surface 20f of the second glass 20 facing the first glass 10 (hereinafter sometimes simply referred to as the surface 20f of the second glass 20), a spacer 1k is provided. The spacer 1k is, for example, an aluminum rectangular bar having a predetermined dimension and a substantially rectangular cross section, and is formed so that its width is the same as the interval of the space 1h. This spacer 1k is installed on each side 1a to 1d of the multi-layer glass 1, respectively. Specifically, the spacers 1k are installed on the sides 1a to 1d of the multi-layer glass 1 so that the space 1hs surrounded by the spacers 1k is isolated from the outside. A desiccant may be provided in the spacer 1k to keep the space 1hs surrounded by the spacer 1k dry.

As shown in FIG. 1, a sealing material 1s is provided around the spacer 1k to airtightly isolate the inside of the space surrounded by the spacer 1k from the outside. This sealing material 1s is, for example,
It is made of a material such as polysulfide or silicon, and is provided so as to fill the space between the first glass 10 and the second glass 20 outside the spacer 1k. Specifically, the space between the surface 10f of the first glass 10 and the surface 20f of the second glass 20 and between the edges of the sides 1a to 1d of the double glazing 1 and the outer surface of the spacer 1k A sealing material 1s is provided so as to fill the portion. Since the space 1h (specifically, the space 1hs) is isolated from the outside by providing the sealing material 1s, the multi-layer glass 1 can maintain the state of the space 1h (specifically, the space 1hs) for a long period of time. , the double glazing 1 can be maintained in a state close to that at the time of manufacture.

The space 1h of the multi-layer glass 1 is filled with dry air, argon gas, helium gas, krypton gas, or other gas, or is kept in a vacuum state without being filled with gas.

With such a structure, the double glazing 1 can reduce the thermal conductivity between the first glass 10 and the second glass 20, and can improve the heat insulation performance.

In the multi-layer glass 1 of the present embodiment, the metal film Lf may be formed on both or one of the surface 10f of the first glass 10 and the surface 20f of the second glass 20 . By forming such a metal film Lf, it is possible to enhance the heat insulation and heat shielding properties of the double glazing 1 of the present embodiment. The metal film Lf employed for the double glazing 1 of this embodiment is not particularly limited. For example, a low-emissivity film (Low-E film) containing tin oxide or silver, a heat ray reflecting film, or the like can be used as the metal film Lf.

<First Glass 10 and Second Glass 20>
As shown in FIGS. 1 and 2, the double glazing 1 of the present embodiment has the above structure, and both the first glass 10 and the second glass 20, or the second glass 20 is made of tempered glass. As a result, the weight is reduced while maintaining a certain level of impact resistance and safety.

<First glass 10>
As shown in FIG. 1, the first glass 10 is glass arranged so as to be positioned on the outdoor side when the sash frame S with the double glazing 1 is installed in a building or the like, as described above. For the first glass 10, heat-strengthened glass or tempered glass is used. Double-strengthened glass and tempered glass are heat-strengthened glasses made by heat-treating ordinary float glass. The compressive stress on the glass surface of general float glass is 17.7 MPa or less, but it is 20 to 60 MPa for tempered glass and greater than 60 MPa for tempered glass. The thickness of the first glass 10 is 3-12 mm, preferably 3-10 mm, more preferably 4-8 mm. The thickness of the first glass 10 is suitable for the conditions of the building in which the sash frame S with the double glazing 1 is installed.

It should be noted that the thickness of the first glass 10 may have an allowable error (for example, about ±0.3 to ±0.5 mm) in normal products. For example, if the allowable error is ±0.3 mm, the thickness of the first glass 10 is 3±0.3 mm to 12±0.3 mm, 3±0.3 mm to 10±0.3 mm, 4±0.3 mm It may be from 0.3 mm to 8±0.3 mm.

<When the first glass 10 is laminated glass>
In addition, as shown in FIG. 2A, as the first glass 10, glass (laminated glass) in which two single-layer glasses 11 and 12 are laminated with a film 13 may be used. In this case, both of the two single-layer glasses 11 and 12 may be made of double-strength glass, or both of them may be made of tempered glass. Of course, one sheet may be double-strengthened glass and one sheet may be tempered glass. When double-strength glass and tempered glass are laminated together, it is desirable to use double-strength glass for the single-layer glass 11 on the outdoor side.

Moreover, when the first glass 10 is laminated glass, the thickness of the single-layer glasses 11 and 12 is not particularly limited. For example, when double-strength glass is used for both or one of the single-layer glasses 11 and 12, the thickness is preferably 2.5 to 6 mm, more preferably 3 to 5 mm, even more preferably 4 to 5 mm. When tempered glass is used for both or one of the single-layer glasses 11 and 12, the thickness is preferably 3 to 6 mm, more preferably 3 to 5 mm, even more preferably 4 to 5 mm. Also in this case, the thickness of the double-strengthened glass or tempered glass used for the single-layer glasses 11 and 12 may have an error (for example, about ±0.3 to ±0.5 mm) that is permissible in normal products. .

When both the single-layer glasses 11 and 12 are made of double-strengthened glass, or when both of the single-layer glasses 11 and 12 are made of tempered glass, glass having the same thickness and the same compressive stress on the glass surface should be used. Alternatively, the single-layer glass 11 and the single-layer glass 12 may have different thicknesses and different compressive stresses on the glass surface. However, when the same type of single-layer glass is used as the single-layer glasses 11 and 12, it is better to use glass having the same thickness and compressive stress on the surface of the glass so that the warp width of the single-layer glasses 11 and 12 after heat treatment is unified. It is preferable in that the quality control of the final product (the product in which the single-layer glasses 11 and 12 are bonded together) can be easily performed.

In addition, as the film 13 for bonding two single-layer glasses together, a film used in general laminated glass can be used. For example, polyvinyl butyral (PVB), ethylene vinyl acetate (EVA), polyurethane (PU), a film (film) obtained by pouring acrylic resin between the single-layer glasses 11 and 12 and curing, and ionomer resin to the single-layer glasses 11 and 12 As the film 13, a film (a film) (SG intermediate film) or the like which is cured by flowing between them can be used. Also, the thickness of the film 13 is not particularly limited, and can be, for example, about 0.1 to 3 mm.

<Second glass 20>
As shown in FIGS. 1 and 2B, the second glass 20 is arranged so as to be positioned on the indoor side when the sash frame S with the double glazing 1 installed is installed in a building or the like, as described above. It is a glass that is As the second glass 20, glass (laminated glass) is used in which two single-layer heat-strengthened glasses 21 and 22 are laminated together. The thickness of the tempered glasses 21 and 22 forming the second glass 20 is preferably 2.5 to 6 mm, more preferably 3 to 5 mm, even more preferably 4 to 5 mm.

The thickness of the double-strength glasses 21 and 22 used for the second glass 20 may have an error (for example, about ±0.3 to ±0.5 mm) that is permissible in normal products. For example, if the allowable error is ±0.3 mm, the thickness of the tempered glass 21, 22 is 2.5±0.3 mm to 6±0.3 mm, or 3±0.3 mm to 5±0.3 mm. It may be 3 mm, 4±0.3 mm to 5±0.3 mm.

Further, for the single-layer heat-strengthened glasses 21 and 22, glass having the same thickness and the same compressive stress on the glass surface may be used, and the heat-strengthened glass 21 and the heat-strengthened glass 22 may have the thickness and the compression of the glass surface. Different stresses may be used. However, if the single-layer heat-strengthened glasses 21 and 22 have the same thickness and the same compressive stress on the surface of the glass, it is easier to unify the warp width of the heat-treated heat-treated glasses 21 and 22, and the final product (heat-strengthened This is preferable in terms of ease of quality control of the product (product in which the glasses 21 and 22 are bonded together).

As the film 23 for laminating the two single-layer heat-strengthened glasses 21 and 22 together, a film used in general laminated glass can be used. For example, polyvinyl butyral (PVB), ethylene vinyl acetate (EVA), polyurethane (PU), a film (film) obtained by pouring acrylic resin between the single-layer glasses 11 and 12 and curing, and ionomer resin are applied to the double-strength glasses 21 and 22. As the film 13, a film (a film) (SG intermediate film) or the like which is cured by flowing between them can be used. Also, the thickness of the film 13 is not particularly limited, and can be, for example, about 0.1 to 3 mm.

<Impact resistance>
The multi-layered glass 1 of the present embodiment has the following configuration, so that it can be tested in accordance with JIS R 3109:2018 "Method for testing against flying objects during storms for architectural glass" (test conditions: strong wind area category 4 (basic wind speed 45m/s≤V≤48m/s, maximum pressure difference 3640Pa)) and has impact resistance to pass a repeated pressure loading test.

<C class test>
For example, the double glazing 1 has a size of W900 mm×H1100 mm and a thickness t of 25.76 mm (see FIG. 1). Further, the first glass 10 is a 5 mm-thick single-layer heat-strengthened glass (the target value of the compressive stress on the glass surface in glass manufacturing is 51 MPa), and the heat-strengthened glasses 21 and 22 of the second glass 20 are a 4-mm-thick single layer. A laminated strength glass (the target value of compressive stress on the glass surface in glass production is 51 MPa) is used, and the film 23 is a polyvinyl butyral film having a thickness of 0.78 mm. It is also assumed that the distance between the surface 10f of the first glass 10 and the surface 20f of the second glass 20 is 12 mm, and that the space 1hs is filled with dry air. Then, the multi-layer glass 1 passed the JIS R3109 test: 2018 Class C impact object collision test, which was performed according to the JIS R 3109: 2018 "Method for collision test of flying objects in windstorms for architectural glass" test. It can have impact resistance to be used. In addition, in the JIS R3109 test: Class C of 2018, wood with a cross section of 20 mm × 40 mm and a mass of 2.05 kg is used as the impacting body, and the impact speed between the impacting body and the double glazing 1 is 12 .2 m/s.

<D class test>
For example, the double glazing 1 has a size of W900 mm×H1100 mm and a thickness t of 27.28 mm (see FIG. 1). Further, the first glass 10 is a 5 mm-thick single-layer heat-strengthened glass (the target value of the compressive stress on the glass surface in glass manufacturing is 51 MPa), and the heat-strengthened glasses 21 and 22 of the second glass 20 are a 4-mm-thick single layer. A laminated strength glass (the target value of the compressive stress on the glass surface in glass manufacturing is 51 MPa) is used, and the film 23 is a polyvinyl butyral film having a thickness of 2.28 mm. It is also assumed that the distance between the surface 10f of the first glass 10 and the surface 20f of the second glass 20 is 12 mm, and that the space 1hs is filled with dry air. Then, JIS R3109 test: JIS R3109 test: 2018 class D impact impact test conducted according to JIS R 3109: 2018 “Method for collision test of architectural glass during storm”. can be In addition, in the JIS R3109 test: Class D of 2018, the impact body uses wood with a cross section of 20 mm × 40 mm and a mass of 4.1 kg, and the collision speed between the impact body and the double glazing 1 is 15. .3 m/s.

<E class test>
For example, the double glazing 1 has a size of W900 mm×H1100 mm (see FIG. 1) and a thickness t of 31.04 mm (see FIG. 2(B)). The first glass 10 is a laminated glass of single-layer tempered glass with a thickness of 4 mm (the target value of the compressive stress on the glass surface in glass manufacturing is 51 MPa), and the film 13 has a thickness of 1. .52 mm polyvinyl butyral film. The heat strengthened glass 21 and 22 of the second glass 20 is a single layer heat strengthened glass with a thickness of 4 mm (the target value of the compressive stress on the glass surface in glass production is 51 MPa), and the film 23 is a polyvinyl butyral film with a thickness of 1.52 mm. do. It is also assumed that the distance between the surface 10f of the first glass 10 and the surface 20f of the second glass 20 is 12 mm, and that the space 1hs is filled with dry air. Then, the JIS R3109 test: 2018, which was conducted according to the JIS R 3109: 2018 "Flying object collision test method during stormy winds for architectural glass" test, has impact resistance that passes the 2018 class E impact test. can be In addition, in the JIS R3109 test: 2018 E class, the impacting body is made of wood with a cross section of 20 mm × 40 mm and a mass of 4.1 kg, and the impact speed between the impacting body and the double glazing 1 is 24.4 m. /s.

<E _ISO grade test>
In addition, this double glazing 1 has an impact resistance that passes the impactor collision test of the _ISO 16932 class E test (E _ISO class test) as a shocker collision test. can be

For example, the double glazing 1 has a size of W900 mm×H1100 mm (see FIG. 1) and a thickness t of 25.76 mm (see FIG. 2(B)). The first glass 10 is a laminated glass of single-layer tempered glass with a thickness of 4 mm (the target value of the compressive stress on the glass surface in glass manufacturing is 51 MPa), and the film 13 has a thickness of 1. .52 mm polyvinyl butyral film. The heat strengthened glasses 21 and 22 of the second glass 20 are single-layer heat strengthened glass with a thickness of 4 mm (the target value of the compressive stress on the glass surface in glass production is 51 MPa), and the film 23 is a polyvinyl butyral film with a thickness of 2.28 mm. do. It is also assumed that the distance between the surface 10f of the first glass 10 and the surface 20f of the second glass 20 is 12 mm, and that the space 1hs is filled with dry air. When an E class test (E _ISO class test) of ISO 16932 was conducted as a bomber collision test, it was possible to have impact resistance that passed the bomber collision test of the E _ISO class test. In the E _ISO class test, a piece of wood with a cross section of 20 mm x 40 mm and a mass of 6.8 kg was used as the impacting body, and the collision speed between the impacting body and the double glazing 1 was 24.4 m/s. be.

The double glazing of the present invention is suitable for windows and openings facing the outdoors.

REFERENCE SIGNS LIST 1 multi-layer glass 1k spacer 1s sealing material 1h space 1hs space 10 first glass 11 single-layer glass 12 single-layer glass 13 film 20 second glass 21 double-strength glass 22 double-strength glass 23 film Lf metal film S sash frame g groove

Claims (4)

A multi-layer glass in which a space is formed between a first glass arranged on the outdoor side and a second glass arranged on the indoor side,
The double glazing is
JIS R3109 test: It has impact resistance that passes the 2018 class C impact impact test,
The double glazing is
a thickness of 25.76 to 44 mm;
The first glass is
It is glass with a thickness of 5 to 12 mm at the glass part using heat-strengthened glass ,
The second glass is
Double glazing characterized by being a laminated glass in which two sheets of tempered glass with a thickness of 4 to 6 mm are laminated via a polyvinyl butyral film, ethylene vinyl acetate film, or ionomer resin film with a thickness of 0.78 to 3 mm ( (excluding those having a plate member in the space between the first glass and the second glass) . A multi-layer glass in which a space is formed between a first glass arranged on the outdoor side and a second glass arranged on the indoor side,
The double glazing is
JIS R3109 test: It has impact resistance that passes the 2018 class D impact impact test,
The double glazing is
The thickness is 27.28 to 44 mm,
The first glass is
It is a glass with a thickness of 5 to 12 mm at the glass part using double-strength glass,
The second glass is
2. Laminated glass in which two tempered glass sheets with a thickness of 4 to 6 mm are laminated via a polyvinyl butyral film, ethylene vinyl acetate film, or ionomer resin film with a thickness of 28 to 3 mm.
Double glazing (excluding those having a plate member in the space between the first glass and the second glass) characterized by: A multi-layer glass in which a space is formed between a first glass arranged on the outdoor side and a second glass arranged on the indoor side,
The double glazing is
JIS R3109 test: It has impact resistance that passes the 2018 class E impact impact test,
The double glazing is
The thickness is 31.04 to 44 mm,
The first glass is
A laminated glass in which two sheets of tempered glass with a thickness of 4 to 6 mm are laminated via a polyvinyl butyral film, an ethylene vinyl acetate film, or an ionomer resin film with a thickness of 1.52 to 3 mm,
The second glass is
Laminated glass made by laminating two tempered glasses with a thickness of 4 to 6 mm via a polyvinyl butyral film, ethylene vinyl acetate film, or ionomer resin film with a thickness of 1.52 to 3 mm.
Double glazing (excluding those having a plate member in the space between the first glass and the second glass) characterized by: A multi-layer glass in which a space is formed between a first glass arranged on the outdoor side and a second glass arranged on the indoor side,
The double glazing is
ISO16932 Class E test (E _ISO class test) and has impact resistance that passes
The double glazing is
a thickness of 25.76 to 44 mm;
The first glass is
A laminated glass in which two sheets of tempered glass with a thickness of 4 to 6 mm are laminated via a polyvinyl butyral film, an ethylene vinyl acetate film, or an ionomer resin film with a thickness of 1.52 to 3 mm,
The second glass is
2. Laminated glass in which two tempered glass sheets with a thickness of 4 to 6 mm are laminated via a polyvinyl butyral film, ethylene vinyl acetate film, or ionomer resin film with a thickness of 28 to 3 mm.
Double glazing (excluding those having a plate member in the space between the first glass and the second glass) characterized by:

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