DE202018105920U1 - Shelling-resistant glazing - Google Patents

Abstract

Bombardment-resistant glazing (100) comprising a ballistic block (10) comprising at least two transparent panes (11, 12, 13, 14) which are interconnected via an intermediate layer (19) and at least one further transparent pane (16, 17) parallel to and spaced apart from the discs (11, 12, 13, 14) of the ballistic block (10) and connected by a circumferential spacer (21) to the ballistic block (10) between the ballistic block (10). 10) and the at least one further disc (16, 17) a cavity (20) is formed, wherein the bullet-resistant glazing (100) and in particular the ballistic block (10) of the bullet-resistant glazing (100) without an energy-absorbing layer or film of polycarbonate is executed.

Description

The invention relates to a bullet-resistant glazing. In particular, the invention relates to a transparent, shatterproof and bullet-resistant glazing and their use.

It is known wall formations, such as building facades, in safety-prone objects, bullet-resistant train. If such facade or wall constructions are to be made transparent, bullet-resistant glass elements are arranged. In view of the high demands on thermal insulation bullet-resistant insulating glass elements are generally used.

For example, from the document DE 2 901 951 A1 Such a bullet-resistant insulating glass element known. In this case, the insulating glass plane is formed by two individual disks spaced apart by a spacer. The resulting air gap provides for the desired improved thermal insulation.

The bullet-resistant glass plane is formed by arranged on the individual discs, glued together further single discs. This results in so-called laminated glass packages, which are composed of several, successively arranged individual discs, which are connected to each other at their mutually contacting surfaces by films or cast resin.

For manufacturing, transport technology and architectural reasons, however, the dimensions of bullet-resistant insulating glass elements are limited. In facade or wall constructions, therefore, a plurality of individual bullet-resistant insulating glass elements are required, which must be arranged at a distance to each other in order to arrange the elements that ultimately form the frame can, and then to allow a retaining clamping of the edges per individual insulating glass elements.

However, this approach has several disadvantages. If, for example, in the edge region of the bullet-resistant insulating glass elements an oblique bombardment takes place, in which the bullet path in the bullet-resistant insulating glass element, i. to the main plane, obliquely, the projectiles can emerge in the edge region of the insulating glass elements. After that, the projectiles only have to penetrate the designated elements of the facade construction in order to reach the area to be protected.

The elements of the façade which hold the bullet-retarding insulating glass elements are generally composite profile arrangements, in particular in the form of hollow-chamber profiles made of aluminum, which do not have a sufficient bullet-resistant effect. Since the projectiles only have to penetrate part of the individual panes of the laminated glass package during oblique bombardment, this represents a danger to the area to be protected. The bombardment of the bullet-proof insulating glass elements can be extremely pronounced in the case of oblique bombardment in individual cases.

To avoid this disadvantage, it is known to provide steel inserts on the elements of the facade in the region between adjacent insulating glass elements. In individual cases, several such steel inserts must be provided, which may be arranged for example in cavities corresponding hollow chamber profiles.

However, the arrangement of such steel inserts is extremely laborious, since a number of additional steps in the production of appropriate facade structures is required. For example, the steel inserts have to be deflected according to the length of the elements of the facade construction to be protected and introduced, secured and fastened to places that are generally difficult to access. Occasionally additional steel corner pieces in the area of corner joints are to be taken into consideration, which is intended to protect the facade construction against bombardment even in its corner areas.

Another problem of such steel inserts is the interruption of the desired poor heat transfer in the corresponding areas of the facade. It may therefore be necessary to arrange additional insulating inserts, which in turn cause additional costs by manufacturing and especially by assembly.

Instead of using steel inserts, it would be possible - at least theoretically - to increase the dimensions of the bullet-resistant insulating glass elements. However, as already indicated, the dimensions are limited in particular for manufacturing reasons. In particular, for technical reasons currently no bulletproof or bulletproof glazing with dimensions greater than 7 m (length) x 2 m (width) can be realized, since this is the critical size of the bulletproof glass usually on a surface opposite the bombardment direction applied polycarbonate plate or a shatter protection film is. Larger formats are therefore not feasible, in particular, because then the static requirements are no longer feasible. This is due in particular to the fact that laminate films for polycarbonate load transmission from a size of about 14 m ² can no longer afford.

In addition, although the proportion of polycarbonate in the bullet-resistant or bullet-resistant glazing would have a positive effect on the bullet resistance, however, there are negative consequences on the fire behavior when the plastic content or the polycarbonate content reaches a certain mass.

Based on this problem, the invention is therefore based on the object of specifying a bullet-resistant glazing, with which dimensions can be realized, which are well above the currently realizable dimensions of about 7 mx 2 m, at the same time a splitter outlet are effectively prevented upon firing of the glazing Furthermore, and where the bullet - resistant glazing in the Standard EN 1063 (Conditions of the standard: filing date) specified conditions for the classification BR1-NS to BR7-NS met.

According to the invention this object is achieved by the subject matter of independent claim 1, wherein advantageous developments of the bullet-resistant glazing mentioned in the independent claim 1 are specified in the dependent claims.

Accordingly, the present invention relates in particular to bullet-resistant glazing with a ballistic block of at least two transparent panes, which are connected to one another via an intermediate layer. The bullet-resistant glazing has in addition to the ballistic block at least one further transparent disc which is parallel to the slices of the ballistic block and spaced therefrom and connected via a circumferential spacer with the ballistic block that between the ballistic block and the at least one another disc is formed a cavity.

According to the invention, provision is made in particular for the bullet-resistant glazing and in particular the ballistic block of the bullet-resistant glazing to be implemented without an energy-absorbing layer or foil made of polycarbonate.

According to embodiments of the bullet-resistant glazing, it is further provided that the intermediate layer between the at least two transparent panes of the ballistic block is formed from a material which is highly resistant to polycarbonate. Of course, this aspect is not to be considered as limiting.

In particular, it is provided in the bullet-resistant glazing that the intermediate layer, via which the at least two transparent panes of the ballistic block are connected to each other, comprises a transparent and in particular polycarbonate-free and / or polymethyl methacrylate-free intermediate layer, which has a disc compared to a polycarbonate material high strength bonds together.

The achievable with the inventive solution advantages are obvious. Due to the fact that the bullet-resistant glazing has a ballistic block and at least one further transparent pane which is arranged at a distance from the ballistic block, there is a bullet-resistant double-glazed insulating glazing, which due to the air gap between the ballistic block on the one hand and the at least one further transparent pane on the other hand provides a good thermal insulation.

On the other hand, the selected multi-layer glazing proves to be very effective in terms of their bullet-proof or bullet-resistant property. The arranged on the bombardment ballistic block substantially prevents a shoot through, while at least one spaced apart from the ballistic block on the side facing away from the firing side arranged further disc has the task, which on the back of the ballistic block in case of shelling peeling off splitter intercept.

Because the ballistic block of the glazing according to the invention has a multiplicity of transparent panes which are connected to one another via an intermediate layer, the ballistic block itself assuming the function of energy absorption, it is possible to apply it to any energy-absorbing foils or plates, in particular one particular one to dispense with potential bombardment direction opposite surface of the slices of the ballistic block.

Moreover, this approach makes it possible to connect the slices of the ballistic block with the aid of an intermediate layer, so that the ballistic block at the same time forms a load-bearing, load-bearing structure, in particular also in sizes over 15 m ² . The intermediate layer is in particular transparent and, above all, formed from a polycarbonate-free and / or polymethyl methacrylate-free material.

With this measure, the production size limited by conventional splinter protection films known from the prior art is eliminated. Insofar, in particular sizes for the bullet-resistant glazing in the range of, for example, 20 mx 3.5 m (or larger) are conceivable. In particular, an overall bullet-resistant effect can be achieved without splinter outlet without the bullet-resistant glazing and in particular the ballistic block of the bullet-resistant glazing having an energy-absorbing layer or film of polycarbonate.

It is particularly preferred in this context that the intermediate layer or intermediate layers of the ballistic block is at least partially or partially formed of an ionoplast polymer or a material with similar material properties, such as high-strength polyvinyl butyral (PVB).

In this context, in particular, a two-component and in particular clear silicone as material for the intermediate layer or intermediate layers of the ballistic block offers. Such a two-component silicone material is particularly advantageous in terms of fire behavior, since it is difficult or impossible to ignite. According to embodiments of this aspect, in particular a reactive and preferably crystal-clear silicone material is used, which reacts at a critical temperature which can be predetermined beforehand. Such a silicone material may then be in the cooled state, i. in a state below the critical curing temperature, poured into a space between two discs of the ballistic block or introduced differently.

Compared to conventional PVB films or PVB sheets or conventional polycarbonate sheets, which are applied as an energy absorbing structure on an outer surface of the discs, liners made of high-strength polyvinyl butyral or a two-component silicone material or an ionoplast interlayer are much tougher and stiffer, so that Ballistic block is not unstable even with a larger weight (ie larger dimensions), but remains static self-supporting stable overall.

In addition, it has been found that a bullet-resistant laminated glass using a polycarbonate film as a ductile, energy-absorbing plastic outer layer can form cracks in the layer due to the properties of the polycarbonate layer, depending on temperature, which adversely affect the overall appearance and the safety of composite safety glass.

According to the invention, instead of a polycarbonate outer panel, an intermediate layer formed in the ballistic block of the glazing according to the invention is used, even in the case of high temperature fluctuations in outdoor use, even in the long term, no cracks in the ionoplast interlayer, because they are much stiffer and stronger than polycarbonate is.

In particular, dimensions of the glazing of at least 15 m ² and preferably at least 20 m ² can be realized by using a polycarbonate-free ballistic block, and in particular by using an ionoplast interlayer as energy-absorbing plastic interlayer. This is due in particular to the fact that the high-strength intermediate layer on the one hand, the amount of plastic material per unit area can be reduced, which has a positive effect on the fire behavior of the glazing, and on the other hand, the ballistic block is statically self-supporting even with an area over 15 m ² .

The evaluation of the bullet-resistant effect is carried out after five shelling classes. In the current highest fire class or resistance class BR7, for example, the bombardment test with the NATO rifle G3 with a 7.62 x 51 full-sheath / hard-core ammunition takes place. In this class of fire then the highest demands are placed on the bullet resistance.

According to embodiments of the present invention has - seen in the direction of bombardment - the ballistic block on a thickness which resists bombardment with a 7.62 x 51 mm solid shell / hard core cartridge according to DIN EN 1063, wherein the thickness of the ballistic block is in particular formed by a corresponding number of transparent panes, which are each connected to one another via an intermediate layer, and / or by corresponding thicknesses of the transparent panes of the ballistic block.

In order to further optimize the heat insulation of the bullet-resistant glazing, according to embodiments it can be provided that the cavity between the ballistic block on the one hand and the at least one further transparent pane is hermetically sealed and with a gas having a low heat transfer coefficient, such as argon and / or krypton, is filled.

In contrast to the ballistic block constructed as a composite, with regard to the at least one further transparent pane spaced from the ballistic block, it is not necessary to provide it with a high-strength intermediate layer, provided that a laminated glass is used here again. Rather, a laminated glass pane is preferably used as at least one further pane, which consists of a plurality of individual panes, which are connected to one another via an elastic, tear-resistant polymer film. When Polymer film is for example polyvinyl butyral (PVB) used.

The PVB layer has a thickness of at least 0.76 mm, preferably at least 0.90 mm, and more preferably at least 1.52 mm. Polyvinyl butyral (PVB) is characterized by its high tear strength and also has a high splinter-binding effect due to its high bond strength.

Between the ballistic block on the one hand and the at least one further transparent disc on the other hand, a gap is provided, in which, if necessary, occurring splinters are collected. The gap also serves to allow the glazing to sag to a limited extent. In this case, a distance between the ballistic block and the at least one further disc of 8 mm to 24 mm, preferably of 12 mm to 16 mm, has proved to be advantageous.

For the thickness of the ballistic block, values between 13 mm and 60 mm and for the thickness of the at least one further disk values between 9 mm and 21 mm have proven to be advantageous. Both the highest possible protection and the weight of the entire glazing play a role here.

In embodiments of the bivalve glazing according to the invention, this has a total thickness of about 60 mm, wherein the ballistic block arranged on the bombardment wall has a total thickness of 30 to 40 mm and an overall intermediate layer thickness of 3 to 5 mm.

The air gap between the ballistic block on the one hand and the at least one further transparent pane is preferably 12 to 16 mm, the at least one further pane, in particular laminated pane facing away from the firing side, having a thickness of 9 to 21 mm. This at least one further pane can, for example, consist of a thin silicate glass pane facing the air gap and a thermally toughened silicate glass pane directed towards the outside.

This composite glass sheet is constructed so that the outer thermally toughened high-bending-strength glass sheet can endure without breaking due to the deflection of the broken front laminated glass sheet formed as a ballistic block and the bending stresses acting on it by the outgoing chips. It is protected against damage to its surface by the occurring splinters and / or by contact with the baggy front disks of the ballistic block by the thin normal glass sheet executed to the air gap, so that the surface of this tempered glass pane remains intact and thus the full high bending strength of the thermal tempered glass pane comes into play.

According to a further aspect of the present invention, the thickness and / or the material of the at least one intermediate layer of the ballistic block and / or the at least one further transparent pane designed as laminated glass is chosen such that the calorific value of the material is less than 55 MJ / kg, and preferably less than 50 MJ / kg and more preferably less than 45 MJ / kg.

In this way, the fire classification of the glazing can be improved. It offers itself if the mass distribution of the intermediate layer of the ballistic block and / or as a laminated glass executed at least one further transparent sheet is between 0.02 g / m ² and 0.10 g / m ^2, preferably between 0.05 g / m ² and 0.08 g / m ² and in particular 0.07 g / m ² .

Hereinafter, an exemplary embodiment of the bullet-resistant glazing according to the invention will be described in more detail with reference to the accompanying drawings.

• 1 schematisch und in einer Querschnittansicht einen Ausschnitt eines Randbereiches einer exemplarischen Ausführungsform der erfindungsgemäßen Verglasung.

It shows:

• 1 schematically and in a cross-sectional view a section of an edge region of an exemplary embodiment of the glazing according to the invention.

A bulletproof glazing 100 without splitter outlet according to the classes BR1-NS to BR7-NS according to the standard EN 1063 based on the current state of the art primarily on the approach, by on the inside of the glazing 100 applied tough layers to retain the outgoing splinters. These applied layers usually consist of either polycarbonate or a tear-resistant clear anti-shatter film.

These layers, which are always due to their function on the innermost side, have the disadvantage that they do not have the scratch resistance which is comparable to glass surfaces. Laying the splinter protection for this reason in the space between the panes, currently leaves no way to apply suitable sunscreen coatings, which very often for correspondingly required building physics values of the glazing 100 becomes necessary.

In addition, the currently available anti-shatter films or polycarbonate sheets are limited in their manufacturing size. From certain sizes of insulating glass or equivalent static Requirements, the use of TPU composite films for lamination of polycarbonate on glass necessary for load transfer is no longer sufficient. The fire protection classification of this glazing 100 is also very unfavorable due to the large flammable mass of polycarbonate.

These and other disadvantages are caused by the glazing according to the invention 100 repealed, in which it is provided in particular that occurring during the bombardment glass and projectile splitter outlets of the outer unclassified bulletproof glass in the form of a ballistic block in the space between the panes of bullet-resistant glazing 100 be caught. The space between the panes is used as a buffer for the pressure wave and the splitter outlets. This achieves the end of the entire executed as insulating glass unit glazing 100 the necessary classification.

Specifically, at the in 1 schematically illustrated embodiment of the glazing according to the invention 100 this with an external bulletproof glass as a ballistic block 10 executed. The ballistic block 10 has at least two and - as in 1 indicated - for example, four transparent discs 11 . 12 . 13 . 14 on, each with an intermediate layer 19 connected to each other.

Parallel to the discs 11 . 12 . 13 . 14 the ballistic block 10 and a circumferential spacer 21 spaced from this is a laminated glass pane 15 with a total of two (further) transparent discs 15 . 16 provided, which via the spacer 21 such with the ballistic block 10 connected is that between the ballistic block 10 on the one hand and the laminated glass pane 15 on the other hand a cavity 20 is formed.

Accordingly, the bullet-resistant glazing exists 100 from the ballistic block facing the shelling side 10 which is designed overall as a laminated glass pane, and the at least one further transparent pane facing away from the firing side 15 . 16 , here also as laminated glass 15 is executed.

This as a laminated glass pane 15 executed at least one more transparent disc 15 . 16 is with the ballistic block 10 and the interposition of an air gap 20 combined into a double-shell insulating glazing, namely by the ballistic block 10 and the at least one more transparent pane 15 . 16 via adhesive layers with the spacer frame or spacer 21 are connected. The through the border areas of the ballistic block 10 and the at least one further transparent pane 15 . 16 as well as the spacer 21 / Spacer formed groove are designed with a sealant.

The designed as laminated glass ballistic block 10 indicates at the in 1 shown exemplary embodiment a total of four panes of glass 11 . 12 . 13 . 14 These are, for example, each silicate glass panes, which with the help of intermediate layers 19 are connected together from an ionoplast polymer.

The glass panes 11 . 12 . 13 . 14 of the laminated glass block designed as a ballistic block 10 each may have the same thickness; but it would also be conceivable, the outer glass panes 11 . 14 of the laminated glass block designed as a ballistic block 10 significantly thinner than the middle glass panes 12 . 13 , In these embodiments, the thicknesses of the glass sheets are 11 . 12 . 13 . 14 of the laminated glass block designed as a ballistic block 10 for example, at about 8 to 15 mm.

The air gap 20 between the ballistic block 10 and the at least one further laminated glass pane 15 is preferably at least about 12 mm.

The at least one further laminated glass pane 15 includes the air gap 20 facing glass, which may be configured for example as silicate glass with a thickness of for example about 3 mm. This glass pane facing the air gap 17 is about an intermediate layer 22 , in particular a polyvinylbutyral intermediate layer with a thickness of, for example, 1.5 mm, with an outer pane of glass 16 made of thermally toughened silicate glass. This outer glass pane 16 the at least one further laminated glass pane 15 can have the same thickness as the inner glass pane 16 ,

It is also conceivable, however, for the outer glass pane 16 to choose a greater thickness, for example, a thickness of 6 mm, so that a bending strength of at least 500 kg / cm ^{2 can be} achieved.

The glazing according to the invention 100 has a bullet-resistant effect according to the resistance class BR37-NS, whereby no splitter outlet takes place on the side facing away from the bullet.

For the production of bullet-resistant glazing 100 no classified bullet-proof outer pane is needed, what the overall structure the glass thickness and thus the weight and the cost of the entire glazing 100 significantly reduced.

By this new application, the previous size restriction is also repealed for example by the availability of polycarbonate sheets of bulletproof glasses. Theoretically, sizes of, for example, at least 20 m × 3.5 m are possible as a result.

In addition, the cleaning of the glass surfaces is quite normal as with all glass surfaces possible. In particular, no consideration has to be given to the scratching of polycarbonate or anti-shatter films.

Furthermore, the application of sunscreen and thermal insulation coatings on any surfaces in the space between the panes 20 the glazing 100 easily possible.

By using high strength, durable load transfer composite films such as e.g. Ionoplasts or high-strength PVB films in the outer ballistic block, these glasses can be statically charged in addition higher. The main advantage here is that the ballistic block simultaneously represents the statically resilient outer pane of the insulating glass structure. This is particularly relevant in the use of correspondingly high-loaded (for example hurricane loads) or simply oversized insulating glass. For the internal composite disc remains so only the task to produce a insulated space between the panes and capture the splitter outlets.

All this is not possible if the splinter protection polycarbonate plates or anti-shatter films are used. Since in a lamination process with appropriate composite films, such as TPU film (thermoplastic polyurethane), not simultaneously high-strength films can be connected in the same package. These high strength foils, e.g. Ionoplast films, require their own program history with e.g. higher temperatures, the TPU film would overheat and become unusable.

Finally, there is no deterioration of fire classification by use of standard VSG composite units.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 2901951 A1 [0003]

Cited non-patent literature

• Standard EN 1063 [0013]

Claims (14)

Bombardment-resistant glazing (100) comprising a ballistic block (10) comprising at least two transparent panes (11, 12, 13, 14) which are interconnected via an intermediate layer (19) and at least one further transparent pane (16, 17) parallel to and spaced apart from the discs (11, 12, 13, 14) of the ballistic block (10) and connected to the ballistic block (10) by a circumferential spacer (21) in such a way that between the ballistic block (10) 10) and the at least one further disc (16, 17) a cavity (20) is formed, wherein the bullet-resistant glazing (100) and in particular the ballistic block (10) of the bullet-resistant glazing (100) without an energy-absorbing layer or film of polycarbonate is executed. Glazing (100) after Claim 1 wherein the intermediate layer (19) between the at least two transparent panes (11, 12, 13, 14) of the ballistic block (10) at least partially or partially formed of an ionoplast polymer or of a material having similar material properties, such as from a high-strength polyvinyl butyral (PVB) material or from a two-component and in particular crystal-clear silicone material, in particular reactive silicone material, which reacts at a critical temperature which can be predetermined beforehand. Glazing (100) after Claim 1 or 2 in that the intermediate layer (19) between the at least two transparent panes (11, 12, 13, 14) of the ballistic block (10) is formed from a material which is highly resistant to polycarbonate. Glazing (100) according to one of Claims 1 to 3 wherein the glazing (100) has an uninterrupted or monolithic transparent area of at least 15 m ² and preferably at least 20 m ² . Glazing (100) according to one of Claims 1 to 4 , wherein the at least one intermediate layer (19) between the at least two transparent discs (11, 12, 13, 14) of the ballistic block (10) is formed such that the ballistic block (10) simultaneously loadable, supporting structure, especially in sizes over 15 m ² forms. Glazing (100) according to one of Claims 1 to 5 in which - as seen in the direction of firing (R) - the ballistic block (10) has a thickness which resists bombardment with a 7.62 x 51 mm solid shell / hard core cartridge according to DIN 1063, the thickness of the ballistic block (10) is formed in particular by a corresponding number of transparent panes (11, 12, 13, 14) which are each connected to one another via an intermediate layer (19), and / or by corresponding thicknesses of the transparent panes (11, 12, 13, 14) of the ballistic block (10). Glazing (100) according to one of Claims 1 to 6 wherein the cavity (20) is hermetically sealed and filled with a gas having a low heat transfer coefficient, in particular argon and / or krypton. Glazing (100) according to one of Claims 1 to 7 in that the glazing (100) comprises a laminated glass as at least one further transparent pane (16, 17), wherein the laminated glass has at least two transparent panes (16, 17) which are interconnected via an intermediate layer (22) this intermediate layer (22) in particular polyvinyl butyral (PVB) has. Glazing (100) after Claim 8 wherein the interlayer (22) of the laminated glass is a PVB sheet having a thickness of at least 0.76 mm, preferably at least 0.90 mm and more preferably at least 1.52 mm. Glazing (100) according to one of Claims 1 to 9 wherein the distance between the ballistic block (10) and the at least one further transparent disc (16, 17) is between 10 mm to 40 mm, preferably between 15 mm to 35 mm and more preferably between 20 mm and 30 mm. Glazing (100) according to one of Claims 1 to 10 , wherein at least one pane (11, 12, 13, 14, 15, 16) of the glazing (100) is provided with a coating (25, 26), in particular a sunscreen coating (25). Glazing (100) after Claim 11 , wherein on the in the direction of the cavity (20) facing surface of the immediately adjacent to the cavity (20) adjacent discs (14) of the ballistic block (10), a coating, in particular a sunscreen coating (25) is provided; and / or wherein on the in the direction of the cavity (20) facing surface of the directly adjacent to the cavity (20) adjacent discs (17) of the at least one further disc (16, 17), a coating, in particular a heat protection layer (26) is provided , Glazing (100) according to one of Claims 1 to 12 , wherein the at least one intermediate layer (19, 22) of the ballistic block (10) and / or the at least one further transparent pane (16, 17) designed as laminated glass consists of a Material having a calorific value of less than 55 MJ / kg, preferably less than 50 MJ / kg and more preferably less than 45 MJ / kg. Glazing (100) according to one of Claims 1 to 13 in which the mass distribution of the intermediate layer (19, 22) of the ballistic block (10) and / or the at least one further transparent pane (16, 17) designed as laminated glass is between 0.02 g / m ² and 0.10 g / m ² , preferably between 0.05 g / m ² and 0.08 g / m ² and in particular about 0.07 g / m ² .

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