DE102019116373B3 - Armored composite glass pane - Google Patents

Abstract

Armored composite glass pane made of several float glass or borosilicate float glass and plastic panes (1; 3; 5; 7; 9; 11; 14; 16; 18; 23) connected to one another via plastic films, the inwardly directed pane (23) being a PC pane and at least the outwardly directed borosilicate float glass or float glass pane as a cover pane (1) with its side floating on a tin melt during its manufacture, the tin side (12), is oriented outward, characterized in that the armored composite glass pane is designed for STANAG, level 3 armored vehicles and consists of a borosilicate float glass pane functioning as a cover pane (1) made of 3.8 mm thick borosilicate float glass, which is followed by two 11 mm thick borosilicate float glass panes (3; 5) followed by two 5.5 mm thick borosilicate float glass panes (7; 9), which in turn are followed by an 11 mm thick, two 5.5 mm thick and one 11 mm borosilicate float glass pane (11; 14; 16; 18), followed by four PU foils (1 9-23) with a thickness of 0.64 mm and a PC disk (23) with a thickness of 2 mm follows.

Description

The invention relates to an armored composite glass pane made of several float glass or borosilicate float glass and plastic panes connected to one another via plastic films according to the preamble of the main claim.

Known glass structures of a bulletproof glass composite pane, DE 202008016395 U1 , from a number of different glass and plastic panes in different thicknesses are known, which due to the high proportion of glass always have a very high weight and to achieve the required safety, require a thick composite structure, so that an increased installation space is required in a vehicle. Furthermore, an improper combination of different float glass and plastic panes can lead to a short service life due to the edge dissolving of the composite.

Also known are a transparent glass-polymer composite, DE 10 2010 013 641 A1 , as well as a transparent bullet-resistant laminate, EP 2 705 951 A1 , with at least one tin side facing the impact side or also a composite safety disk, DE 20 2005 017 657 U1 , and a glass structure of an armored blown composite pane, DE 20 2008 016 395 U1 , as well as a bullet-resistant transparent composite pane, DE 10 2011 117 340 A1 , which have different arrangements of glass and plastic panes of different thicknesses in order to optimize the ballistic protection of a vehicle and the people sitting in it. On the other hand, a laminated glass pane with a composite layer and an edge sealing layer is known, DE 296 13 002 , U1, and a laminated safety glass and process for its production, DE 1010 12 859 A1 , as well as a method for the production of armored glass for a motor vehicle and armored glass, DE 195 39 607 A1 , as well as an armored car, DE 36 39 781 C1 , or a bullet-resistant transparent layer composite and protective arrangement with a bullet-resistant layer composite, DE 10 2008 028 318 A1 , and also an integrated transparent safety glass armor unit, U.S. 3,671,370 A , which each have beveled, stepped or ground edges in order to counteract delamination of the layers and thus a loss of security, but which ultimately still have a large overall thickness and a high specific weight depending on a required security class.

The object of the invention is to provide an armored composite glass pane which, compared to known glass structures, with the same or increased security, a security class for according to STANAG, Level 3 armored vehicles, a lower overall thickness and a lower specific weight per m ² .

The solution to this problem arises in connection with the features of the preamble according to the invention together with the technical features of the characterizing part of the first patent claim. The fact that at least the cover pane, which is directed outwards towards the firing side and consists of a borosilicate float glass pane or a simple float glass pane, with its side floating on a tin melt during its manufacture, the tin side, is directed outwards, results in a significant improvement in the bullet resistance of the glass structure equipped with it.

As is known, flat glass is mainly produced using a float glass process in which the still liquid, but also the already solidified glass melt, floats continuously on one side on a bath of liquid tin, this tin side always being slightly doped with tin from the tin melt. This doping is not visible to the naked eye, but this side fluoresces gray / blue under short-wave ultraviolet radiation, so that it is easy to detect and can be arranged facing outwards when the armored composite glass pane is folded.

This results in improved ballistic protection compared to known constructions of the same protection class.

With the inventive armored composite glass pane, which ensures security according to STANAG, level 3 is designed for armored vehicles, a standardization agreement of the NATO signatory states, a cover pane consists of 3.8 mm thick borosilicate float glass, which is followed by two 11 mm thick borosilicate float glass panes, followed by two 5.5 mm thick borosilicate float glass panes, which in turn is 11 mm thick and Two 5.5 mm thick and one 11 mm borosilicate float glass panes follow, followed by four PU films, each 0.64 mm thick, and a PC pane, 2 mm thick.

Further advantageous configurations of the subject matter of the invention result from and in combination with the technical features of the following subclaims.

According to a particularly preferred embodiment of the invention, all borosilicate float glass or float glass panes of the armored laminated glass pane are put together with their tin sides facing outwards and connected to one another, so that the advantages of this alignment of the complement individual float glass or borosilicate float glass panes perfectly.

All float glass or borosilicate float glass panes are preferably connected to one another by means of PVB or PU films, which have proven particularly useful in the manufacture of armored composite glass panes. However, this could also be other foils that are suitable for transparent bonding in a similar function.

It is also advantageous that the cover pane and the subsequent borosilicate float glass or float glass panes are connected with a PVB or PU film that is about twice as thick as the other float glass or borosilicate float glass panes, so that this first connecting layer can better absorb the stresses caused by thermal expansion that occur between the subsequent composite panes no longer occur as strongly. Furthermore, this first film layer is advantageously used to arrange a window heater embedded therein.

According to a further advantageous embodiment of the invention, the inward-facing PC pane and the first adjoining float glass or borosilicate float glass pane are connected to one another via several PU foils placed one on top of the other, so that here too the different material stresses caused by thermal expansion are optimally absorbed without the risk that the individual composite layers separate from each other.

In a particularly preferred embodiment of the armored laminated glass pane according to the invention, all panes are connected to one another by means of single-layer or multi-layer PU films of the same or different thickness.

In a further advantageous embodiment of the invention, the end faces of the float glass or borosilicate float glass panes are ground like a C-profile or trapezoidal profile, and the end faces of the PC glass pane are bevelled at 45 ° for a flat introduction of force.

According to a particularly preferred embodiment of the invention, the inventive armored laminated glass pane is produced in an autoclave in a predetermined autoclave cycle and tension-optimized in a subsequent tempering process, so that an increased service life of the inventive armored laminated glass pane is established. The inventive armored laminated glass pane can preferably be used safely in a temperature range from -32 ° C to + 49 ° C.

All float glass panes of this armored laminated glass pane consist of borosilicate float glass and are connected to each other with PVB foils, whereby the PC plastic glass pane and the innermost borosilicate float glass pane are connected to one another via four PU foils in order to counteract delamination tendencies caused by thermal stress.

For this purpose, the cover pane is connected to the subsequent borosilicate float glass pane with a 0.76 mm thick PVB film, i.e. more than three times the thickness of the remaining films, which in turn are connected to one another via subsequent 0.25 mm thick PVB films are.

In contrast to an armored composite glass pane of the prior art with a previous thickness of 86 mm and a weight of 200 kg / m ² , this inventive armored composite glass pane can be produced with a total thickness of only 78 mm and a weight of 166 kg / m ² inventive armored composite glass pane is not only lighter than the previous structure but also has a higher ballistic resistance due to the outwardly oriented tin side or the orientation of all tin sides to the outside.

The specially developed autoclave cycle with a subsequent tempering process optimizes the stress in the component and thus ensures a longer service life for the armored laminated glass pane treated in this way.

• 1 einen nicht maßstabgerechten schematischen Glasaufbau.

An exemplary embodiment of the invention is described in more detail below with reference to a drawing. It shows:

• 1 a schematic glass structure not to scale.

The inventive laminated glass pane consists exclusively of borosilicate float glass panes 1 ; 3 ; 5 ; 7th ; 9 ; 11 ; 14th ; 16 ; 18th and an inward facing PC disk 23 , being between the borosilicate glass panes 1 ; 3 ; 5 ; 7th ; 9 ; 11 ; 14th ; 16 ; 18th each PVB film 2 ; 4th ; 6th ; 8th ; 10 ; 13 ; 15th ; 17th are arranged and between the innermost borosilicate glass pane 18th and the PC plastic glass pane 23 four PU foils 19-22 are arranged one above the other.

The cover disk 1 and all subsequent borosilicate float glass panes 3 ; 5 ; 7th ; 9 ; 11 ; 14th ; 16 ; 18th are with their tin sides 12th oriented outwards, with between cover plate 1 and the first subsequent borosilicate glass pane 3 a 0.76 mm thick PVB film 2 is interposed and the remaining PVB films 4th ; 6th ; 8th ; 10 ; 13 ; 15th ; 17th each have a thickness of 0.25 mm.

The layer thicknesses of the borosilicate glass panes 1 ; 3 ; 5 ; 7th ; 9 ; 11 ; 14th ; 16 ; 18th are selected so that the top layer 1 begins with a thickness of 3.8 mm and the subsequent layers with thicknesses of 11 mm, 11 mm, 5.5 mm, 5.5 mm, 11 mm, 5.5 mm, 5.5 mm, 5.5 mm and 11 mm, the last layer of polycarbonate 23 has a thickness of 2 mm and the PU films 19-22 each have a thickness of 0.64 mm.

The PVB films 2 ; 4th ; 6th ; 8th ; 10 ; 13 ; 15th ; 17th or PU foils 19-22 can be replaced by foils which, in a similar function, are suitable for the transparent bonding of the glass or plastic panes.

The total thickness achieved by the inventive armored composite glass pane is 78 mm and its specific weight 166 kg / m ² compared to a previous armored composite glass pane with a thickness of 86 mm and a specific weight of 200 kg / m ² .

Overall, despite the reduced overall thickness and reduced specific weight, improved ballistic protection is achieved in comparison with known constructions of the same protection class.

Claims (12)

Armored composite glass pane made of several float glass or borosilicate float glass and plastic panes (1; 3; 5; 7; 9; 11; 14; 16; 18; 23) connected to one another via plastic films, the inwardly directed pane (23) being a PC pane and At least the outwardly directed borosilicate float glass or float glass pane as a cover pane (1) with its side floating on a tin melt during its manufacture, the tin side (12), is oriented outward, characterized in that the armored composite glass pane is designed for STANAG, level 3 armored vehicles and for this purpose consists of a borosilicate float glass pane functioning as a cover pane (1) made of 3.8 mm thick borosilicate float glass, which is followed by two 11 mm thick borosilicate float glass panes (3; 5) followed by two 5.5 mm thick borosilicate float glass panes (7; 9), which in turn are followed by an 11 mm thick, two 5.5 mm thick and one 11 mm borosilicate float glass pane (11; 14; 16; 18), followed by four PU foils ( 19-23) with a thickness of 0.64 mm and a PC disc (23) with a thickness of 2 mm follows. Reinforced composite glass pane after Claim 1 , characterized in that all borosilicate float glass or float glass panes (1; 3; 5; 7; 9; 11; 14; 16; 18) are put together with their tin sides (12) facing outwards. Armored composite glass pane according to one of the preceding claims, characterized in that all borosilicate float glass or float glass panes (1; 3; 5; 7; 9; 11; 14; 16; 18) by means of PVB or PU films (2; 4; 6, 8 ; 10; 13; 15; 17) are connected to each other. Reinforced composite glass pane after Claim 3 , characterized in that the borosilicate float glass pane functioning as a cover pane (1) and the borosilicate float glass or float glass pane (3) following it is connected with a PVB or PU film (2) that is at least twice as thick as the other float glass or borosilicate float glass panes ( 3; 5; 7; 9; 11; 14; 16; 18). Armored composite glass pane according to one of the preceding claims, characterized in that the inwardly directed PC pane (23) and the innermost float glass or borosilicate float glass pane (18) are connected to one another via several PU foils (19-22) placed one on top of the other. Armored laminated glass pane according to one of the preceding claims, characterized in that all panes (1; 3; 5; 7; 9; 11; 14; 16; 18; 23) are single or multi-layered with PU films (2; 4; 6; 8; 10; 13; 15; 17; 19; 20; 21; 22) are connected to one another. Armored composite glass pane according to one of the preceding claims, characterized in that the glass pane functioning as a cover pane (1) is designed as a borosilicate float glass pane. Armored composite glass pane according to one of the preceding claims, characterized in that the end faces of the float glass or borosilicate float glass panes (1; 3; 5; 7; 9; 11; 14; 16; 18) are ground like a C-profile or trapezoidal profile. Armored composite glass pane according to one of the preceding claims, characterized in that the end faces of the PC glass pane (23) are bevelled at 45 °. Armored laminated glass pane according to one of the preceding claims, characterized in that it is produced in an autoclave in a predetermined autoclave cycle and in a subsequent tempering process in a stress-optimized manner. Reinforced composite glass pane after Claim 10 , characterized in that the borosilicate float glass pane functioning as a cover pane (1) and the subsequent borosilicate float glass pane (3) with a 0.76 mm thick PVB film (2) and the remaining borosilicate float glass panes (3; 5; 7; 9; 11; 14; 16; 18) are connected to one another with 0.25 mm thick PVB films (4; 6, 8; 10; 13; 15; 17). Armored composite glass pane according to one of the preceding claims, characterized in that it has a total thickness of 78 mm and a specific weight of 166 kg / m ² .

Images