CH480945A - Composite safety pane - Google Patents

Description

  

      Composite safety pane The commercially available composite safety panes are normally available from two about 2 to 4, preferably about 3 mm thick glass plates, which are covered by an about 0.05 to 1.0, preferably about 0.1 to 0.5 mm thick layer of an elastic adhesive , usually soft polyvinyl butyral, are cemented together.



  At room temperature, these composite panes generally withstand impacts with an energy of up to about 1.5 mkp. They are pierced when subjected to heavy loads. In such a case, the advantage of these panes is that the majority of the resulting glass splinters does not jump off, but is held in place by the adhesive layer and the rest falls down without energy. But if the puncture occurs through a human body part, e.g. B. the head, such as an automobile windshield, there is still the risk of severe injuries Schnittver injuries for this body part, namely by the formation of the so-called ruff.



  Safety panes have also been proposed which consist of a plate of high molecular weight, linear bisphenol polycarbonate that is at least about 2 mm thick and which in turn is provided with scratch-resistant surface layers. In one embodiment of these safety panes, the one scratch-resistant surface layer consists of a glass plate, preferably at most about 1.5 mm thick, connected to the polycarbonate plate by an approximately 0.1 mm thick adhesive layer,

   while the other surface is provided with a vapor-deposited layer of SiO "where x has a value between 1 and 2. In these safety panes, the polycarbonate plate makes up the majority of the total mass, since the glass plate only serves to make the polycarbonate plate scratch-resistant The other properties of these safety panes are therefore almost exclusively determined by the properties of the polycarbonate sheet.



  The most important advantage of these safety panes is that, thanks to the high impact resistance of the polycarbonate sheet, they cannot be punctured even by violent blows; at most the glass cover plate cracks, but practically no glass splinters are pushed off because they adhere to the adhesive layer. The dreaded ruff cannot appear.



  Another advantage of these panes is the favorable absorption behavior of the polycarbonates compared to light rays, so that there are hardly any losses in the visible spectrum, while the mostly undesired ultraviolet and infrared rays are practically completely retained. Mention should also be made of the better thermal insulation compared to panes that consist only of glass, which, among other things, is largely due to the fact that these panes are less likely to fog up than glass panes when there are temperature differences.



  As far as these safety panes consist of a clear polycarbonate and a clear glass plate and the adhesive layer is chosen to be clear, these panes can, for. B. in vehicle construction, especially in motor vehicles and rail vehicles are used. However, they are less suitable as windshields, since if the head of a vehicle occupant hits, for example, a reclamation takes place, which can lead to severe concussion (pendulum trauma), if not to a fracture of the cervical vertebrae.



  The present invention now relates to composite safety panes, which are characterized in that, as a departure from the basic idea that is essential to the known safety panes mentioned above, they are made from a thicker glass plate onto which a comparatively thin polycarbonate film is glued, exist, d. H.

   that they consist of an optionally curved 2.5 to 7 mm, preferably 2.8 to 3.5 mm, thick, clear, optionally colored, optionally tempered glass plate, which is preferably ground and polished on both sides, on which a 0 , 5 to at most 2 mm, preferably 0.7 to 1.5 mm, thick, transparent, optionally colored film made of high molecular weight polycarbonate of dihydric phenols is glidably glued on by means of a 0.05 to 1.0 mm thick, transparent adhesive layer, with the surface of the film facing away from the glass plate, if necessary again with a vapor-deposited, clear layer of SiOt,

      where x has a value between 1 and 2 is provided.



  It has been shown that the utility value of the type safety panes for many purposes, so in particular for glazing of vehicle convincing windows, z. B. vehicles as windshields in motor vehicles, is larger than that of the aforementioned known safety windows, for several reasons.



  These new panes are distinguished from the known, consisting of two roughly equally thick glass panes cemented to each other, initially by a lower mass per unit area, since the thickness of the polycarbonate plate is only a fraction of that of the glass plate and the specific weight of the polycarbonate is also considerable is less than that of the glass. This not only means a weight saving, but is also necessary for the use of composite panes, e.g. B. as windshield discs in automobiles, also important because, according to recent medical accident knowledge, the risk of z. B. life-threatening head injuries conditions with increasing mass per unit area of the disc against which the impact occurs, increases sharply.



  On the other hand, despite the comparatively small thickness of the polycarbonate film, such a safety pane is surprisingly just as large as the shock loads occurring in practically such panes as are the safety panes, which essentially consist of a thicker polycarbonate plate, ie. H. they are not pierced either.

   If the impact is strong enough to break the comparatively thick glass plate, the remaining impact energy is also completely absorbed by the thin polycarbonate film, but not by springback, but surprisingly because the film is at the point of impact stress as a result of stretching - kung process, through which the energy is destroyed, deformed, although the polycarbonates are normally stretchable significantly below the freezing temperature only with difficulty and only to a limited extent.

   The impact energy hitting a narrow space may lead to sufficient local heating of the polycarbonate so that the glass transition temperature is exceeded at this point and the film, as mentioned, is deformed while being stretched.



  If the glass plate and / or the polycarbonate plate were too thin, not all energy would be consumed by the breakage of the glass plate and the deformation of the polycarbonate plate, the pane could be pierced and thus behave in a similar way to the known composite panes. If the glass plate were too thick, it would not crack and the aforementioned springback would occur. If, on the other hand, the polycarbonate plate were too thick, it would not deform and therefore spring back again.



  According to the invention, the thickness of the glass plate and the thickness of the Polycarbon.at plate are selected so that the composite pane resulting from the cementing can withstand minor impacts unchanged, but that it destroys higher impact energies to the exclusion of the risk of cut injuries and pendulum trauma.

   Within the thickness limits according to the invention, the impact limit, up to which the pane remains undamaged, can be adjusted to a certain extent at will, depending on whether a thinner or thicker glass and / or polycarbonate plate is chosen. It is usually beneficial to combine a thinner glass plate with a thicker polycarbonate plate or vice versa, or to use both plates of medium thickness.



  It should be emphasized that the aforementioned permanent deformation of the polycarbonate sheet is due to the special property of the polycarbonates in particular, that they are below the freezing temperature, which is consistently very high and z.

   B. polycarbonate made of bisphenol A (2,2-bis- (phenylene) propane) is around 140 C, are very stiff, do not show a cold flow and are therefore not plastically deformable in the true sense of the word - otherwise the panels would be open the duration is not dimensionally stable - but on the other hand can be stretched under certain conditions. The permanent deformation is a consequence of a stretching process that absorbs considerable energy.



  Furthermore, the ability of the polycarbonate to absorb ultraviolet and infrared rays is so great that even a thin film is sufficient to hold back these rays practically completely through the safety panes. With regard to the optical properties, there is also the fact that glass plates with a thickness of about 2.5 and in particular about 2.8 mm upwards, in contrast to the thinner glass plates, can be ground and polished on both sides, so that plates of so-called mirror glass are preferred can fall back on.

   As a result, the new safety panes meet to a much greater extent the very high requirements placed on the optical quality of windscreens in motor vehicles, which are usually curved (see e.g. Verkehrsblatt, Official Gazette of the Federal Minister for Verkehr der Bundesrepublik Deutschland, 19th year, <B> 1965, </B> Issue 3, pp. 61-116, in particular p. 89, para. B, 25 (2) 1c) and p. 91, left Column, 3).



  Last but not least, the production of larger, namely curved panes by gluing a thin, flexible polycarbonate film to a thicker, possibly previously curved glass plate is technically considerably easier to carry out than a practically already rigid, thicker polycarbonate plate with a practically also rigid, albeit thinner, glass plate connect.



  The combination of these properties cannot be found in any other plastic known to date. Finally, it should also be mentioned that the comparatively low thermal conductivity of the polycarbonates also has a beneficial effect in that the tendency to fog up in the event of temperature differences is greatly reduced. That is why the aforementioned polycarbonates in combination with glass are particularly suitable for the use of composite safety panes.



  The production of high molecular weight thermoplastic polycarbonates dihydric phenols, in particular special bisphenylolalkanes, is known and z. B. in German Patent Nos. 1011178, 971777 and 971790. From these polycarbonates the approximately 0.5 to 2 mm thick plates can be cast in a known manner from the melt through slot nozzles.

   In order to give these plates practically completely plane-parallel surfaces and thus optical isometry, it is generally expedient to post-treat them, again in a known manner, in a plate press or a calender.



  Suitable adhesives are the adhesives that can be used in the aforementioned known safety panes, e.g. B. silicone rubber and curable polyester-styrene mixtures, preferably those in which the. Mi mixture ratio polyester: styrene is at least about 4: 1, as well as plasticized epoxy resins, also the polyvinyl butyral films and the like known from composite pane production.

   The more or less soft polyacrylate adhesives known per se as adhesives have proven to be particularly advantageous, since they have particular optical clarity, excellent adhesion to glass and polycarbonate, and a slippery cementation suitable even in comparatively thick layers Have cohesion that is adequately maintained at temperatures as low as -30 C.



  The two panes are cemented in a manner known from the manufacture of composite panes. The new laminated safety panes can be used wherever it is desired that the panes are not pierced by violent blows and the risk of cuts should be excluded. Because of the properties of the new windows described in more detail above, they should be used in particular as safety windows in vehicles of all kinds, namely as windshields in road vehicles, the windows being placed so that the glass plate faces outwards and the polycarbonate plate faces inwards to lie down.

    <I> Example 1 </I> On a 30 x 30 cm, 3.0 mm thick mirror glass plate, a 30 x 30 cm, 0.5 mm thick film made of a mixed polymer of 65 percent by weight 2-ethylhexyl acrylate and 35 Percent by weight of methyl methacrylate with a relative viscosity of 1.815, measured on a solution of 0.5 g of substance in 100 ml of benzene at 20.degree.

   A 30 x 30 cm, 1.0 mm thick plate made of bisphenol A polycarbonate with a relative viscosity of 1.30, measured on a 0.5% strength methylene chloride solution at 25 ° C., is placed on one side 3.5 u thick quartz layer is vapor-deposited with the non-coated side. The laminate is held together with clamps to prevent the three layers from shifting against each other in the subsequent work step.

   It is then heated to 130 ° C. in an autoclave at a pressure of 100 torr and then slowly cooled to room temperature over 60 minutes while increasing the pressure to atmospheric pressure. A clear, transparent composite pane is obtained.



  <I> Example 2 </I> The procedure described in Example 1 is followed, but a 5 mm thick plate made of tempered mirror glass is used. <I> Example 3 </I> The procedure is as in Example 1, but using an adhesive film of the same size made from a mixed polymer of 65 percent by weight butyl acrylate and 35 percent by weight methyl methacrylate with a relative viscosity of 1.75.

 

Claims (1)

PATENT CLAIM Composite safety pane, characterized in that it consists of a 2.5 to 7 mm thick, transparent glass plate on which a 0.5 to at most 2 mm thick, transparent film made of high molecular weight polycarbonate of dihydric phenols by means of a 0.05 to 1 mm thick, transparent adhesive layer is stuck on. SUBClaims 1. Disc according to claim, characterized in that the glass plate is 2.8 to 3.5 mm thick. 2. Disc according to claim, characterized in that the glass plate is curved. 3. Disc according to patent claim, characterized in that the glass plate is ground and polished on both sides. 4. Disc according to claim, characterized in that the glass plate is colored. 5. Disc according to claim, characterized in that the glass plate consists of toughened glass. 6. Disc according to claim, characterized in that the polycarbonate film is 0.7 to 1.5 mm thick. 7. Disc according to claim, characterized in that the polycarbonate film is colored. B. disc according to claim, characterized in that the adhesive layer consists of a polyacrylate adhesive. 9. Window according to patent claim, characterized in that the surface of the polycarbonate film facing away from the glass plate is provided with a vapor-deposited, clear, transparent layer of SiO, where x has a value between 1 and 2. <I> Note from the </I> Federal <I> Office for Intellectual Property: </I> If parts of the description are inconsistent with the definition of the invention given in the claim, it should be remembered that according to Art. 51 of the Patent Act, the patent claim is authoritative for the material scope of the patent.