DE2754684C2 - Breakthrough-resistant composite pane using flexibilized epoxy resin - Google Patents

Description

The invention relates to a break-through-resistant composite pane according to the preamble of the claim 1.

Breakthrough-resistant composite washers are used in private, commercial and public areas as security panes for objects in need of protection

used. For example, break-through-resistant laminated panes are used for glazing in jewelry stores, Goods automater., Showcases in museums, shields on machine tools and electrical telephones Devices as well as in bunkers or laboratories. Such composite panes should not only ensure an unobstructed view, but rather shield the glazed room from outside interference. Such effects cannot only be of a mechanical nature, namely caused, for example by blows with a hoe, hatchet, crowbar or hammer or by fragments of bursting high-speed grinding wheels, but also from thermal loads from cutting torches or caused by explosions, deflagrations or fires of all kinds. In order to be able to exert the necessary protective effect, composite panes of the type described consequently a resistance value that is as high as possible even in the case of strong shock or impact loads have, defined as the time it takes to achieve a breakthrough or as that Energy or the impulse that the pane can withstand after a single load.

There are already glass-plastic composite panes with different thicknesses of the individual panes known, where the composite intermediate layers are polyvinyl butyral, polymethyl methacrylate or epoxy resins be used. It has also already been proposed to use certain individual panes of the composite panes to be designed as solid plastic panes and / or to incorporate air gaps. the However, resistance values of these known composite panes are not yet sufficient, in particular with combined effects of mechanical and thermal loads.

A composite pane of the generic type has now become known through DE-AS 2017723, which can be used as bulletproof glass with a high level of bullet resistance and all of them Individual panes are made of silica glass. Due to the special selection of the individual panes of the composite pane epoxy resin adhering to one another is used for bulletproof glass according to DE-AS 2017 723 an abrupt improvement in the bulletproof security compared to the previously known bulletproof ones Slices scored. In principle, the bulletproof glass according to DE-AS 2017 723 is also suitable for use as a break-through-resistant composite pane, however, it has been shown that the resistance value is the pane structure proposed there when used as a break-through-resistant composite pane is not yet satisfactory. Similarly, US Pat. No. 3,624,238 discloses the use of a polycarbonate layer in the lamellar structure of a bulletproof glass pane made of polyacrylic layers and silicate glass panes known that a significantly improved bullet resistance compared to a structure made of silicate glass panes and polyacrylic layers with a smaller thickness. However, the structure of this disk only offers short-term protection against Handguns, and such panes cannot be regarded as break-through-resistant.

The invention is therefore based on the object of providing the composite pane according to DE-AS 2017 723 to that effect continue to train that they ensure problem-free installation in door or window frames with the usual Overall thickness has a higher resistance value than previously known breakthrough

retardant composite panes.

According to the invention, this object is achieved by those mentioned in the characterizing part of claim 1 Feature resolved.

Particularly preferred embodiments of the invention, which of course also includes the idea to continue or to repeat the sequence of slices given above, with greater overall thicknesses then of up to 150 mm, which protect against bursting grinding wheels etc., where fragment energies of approx. 2000 kpm with shock pulses of up to 70 kps occur are suitable, result from the subclaims. Furthermore, to supplement the invention, the specification the epoxy resin interlayers are fully referred to in DE-AS 2017723.

The composite pane according to the invention shows, even with the usual, installation in door or window frames Thickness that enables problem-free surprisingly high resistance values. For larger thicknesses On the other hand, the composite pane is suitable for dimensions of up to 150 mm as a protective shield against bursting grinding wheels or the like, with the correspondingly high Impact energies. The breakthrough-resistant composite panes according to the invention have when used as a single structure thicknesses of approx. 15 to 30 mm, but are also suitable as Building block for thicker composites, the break-through-resistant composite panes according to the invention both with mutual distance and in direct succession, of course with each other Epoxy resin intermediate layers of the type according to the invention between adjoining silicate glass panes, can be used.

With regard to the specified degree of crosslinking of 0.72 to 0.76, it is also noted that this includes the product of the epoxy value (number of epoxy groups per 100 g resin) and the functionality (number the epoxy group per molecule).

The breakthrough-resistant composite pane according to the invention is already available at thicknesses of 15 to 30 mm compared to any break-in tools or combinations of different tools previously unattainable resistance value. On high-speed grinding machines the operator is safely protected from accidents. The disk also has a high level of bullet resistance. Of the The composite pane according to the invention is based on a surprisingly high resistance value the special combination of flexibilized epoxy resin from DE-AS 2017723 known type, polycarbonate, Glass, epoxy resin and again polycarbonate.

An exemplary embodiment of the invention is detailed below with reference to the schematic drawing explained.

The drawing, which consists of one figure, shows an embodiment of the anti-penetration device Composite pane according to the invention in section.

As the drawing shows, the break-through-resistant composite pane shown there consists of a machine glass pane (silicate glass) 10 with a thickness of 5 mm, an epoxy resin intermediate layer 12 with a thickness of 0.8 mm, a polycarbonate pane 14 with a thickness of 5 mm, an epoxy resin intermediate layer 16 with a thickness of 0.8 mm, a disk made of optical glass (silicate glass) 18 with a thickness of 5 mm, an epoxy intermediate layer 20 with a thickness of 0.8 mm, a polycarbonate pane 22 with a thickness of 5 mm, an epoxy resin intermediate layer 24 with a thickness of 0.8 mm and a sheet of machine glass (silicate glass) 26 with a thickness of 5 mm. The total thickness of the switching structure carries 28.2 mm in the embodiment shown. Of course, the breakout-resistant one shown Composite pane according to the invention not only as a single pane, but also as a structural

There is then a particularly high resistance value delivering composite are summarized. For example, five of the in the drawing breakthrough-resistant composite panes reproduced directly with one another according to the invention

ii are connected, with the outer silicate glass panes Adjacent composite panes then each in turn by epoxy resin intermediate layers of 0.8 mm are connected to each other. A particularly thick pane constructed in this way is able to

iii Fragments with a kinetic energy of up to 2000 kpm and pulses of up to 70 kps can be safely intercepted. With a transparent one constructed in this way Protective shield, a soft braking of fast particles is achieved, such as those caused by grinding

2ϊ occur in the form of grinding wheel fragments can.

In the embodiment shown, a simple break-through-resistant composite pane according to of the invention make the two built-in poly-

i »carbonate disks make a breakthrough with mechanically acting tools such as hammer, hoe or Hatchet, almost impossible. A use of saws remains ineffective because the silicate glass pane (spectacle lens) between the polycarbonate panes, the plastic part

makes η of the composite (polycarbonate) unspeakable.

If a cutting torch is used as a break-in tool, the one provided according to the invention shows Material combination of flexible epoxy resin polycarbonate - glass - flexible epoxy resin -

-ι »polycarbonate their special advantages by namely the thermosetting epoxy resins as ablation material serve and the epoxy resin "burns", but its coked residue is excellent Thermal insulation layer is used. Upon exposure

• The cutting torch heats up strongly of the epoxy resin, for melting and decomposition of the same. The porous, coked ones Pyrolysis products then form an insulating layer. Another benefit of char ablation is

-> (i the large amount of radiated heat. Due to the At high burner temperatures, a large part of the heat supplied is dissipated again as radiation, since the radiation intensity according to Boltzmann's As is well known, radiation law with the

■ -, -, fourth power as the temperature increases. What remains is a solid, charred layer with a high resistance value.

Overall, the transparent, breakthrough-resistant composite pane according to the invention enables

bo reliable protection against criminal offenses, like burglaries. The disk can still be carried to avoid accidents on machines Use fast moving tools, especially rotating tools. The through-

hi break-resistant composite pane according to the invention to ward off thermal dangers such as deflagrations, fires or explosions, to serve.

lliu-r / u I Bhiti Z

Claims (8)

Patent claims: 1. Breakthrough-resistant composite pane, with several, 0.2 to 1.0 millimeter thick adhesive Interlayers made of flexibilized epoxy resin with a degree of crosslinking of 0.72 to 0.76, in which long-chain molecular segments (mol. wt. approx 600) are installed, silicate glass and polycarbonate panes connected to one another in alternating sequence, characterized by the following pane structure: Silicate glass pane 3-7 mm (10); Epoxy resin interlayer (12); Polycarbonate pane 3-7 mm (14); Epoxy resin interlayer (16); Silicate glass pane 3-7 mm (18); Epoxy resin interlayer (20); Polycarbonate pane 3-7 mm (22); Epoxy resin interlayer (24); Silicate glass pane 3-7 mm (26). 2. Composite pane according to claim 1, characterized in that at least one of the silicate glass panes (10, 18, 26) has a thickness of 5 mm. 3. Composite pane according to claim 1 or 2, characterized in that at least one of the Polycarbonate panes (14, 22) has a thickness of 5 mm. 4. Composite pane according to one of claims 1 to 3, characterized in that at least one of the epoxy resin intermediate layers (12, 16, 20, 24) has a thickness of 0.8 mm. 5. Composite pane according to one of claims 1 to 4, characterized in that the outer Silicate glass panes (10, 26) made from machine glass and the inner silicate glass pane (18) consist of optical glass. 6. Composite pane according to claim 5, characterized by the following layer structure: Machine glass pane 5 mm (10); Epoxy resin intermediate layer 0.8 mm (12); Polycarbonate lens 5 mm (14); Epoxy resin intermediate layer 0.8 mm (16); Optical glass 5 mm (18); Epoxy resin intermediate layer 0.8 mm (20); Polycarbonate pane 5 mm (22); Epoxy resin interlayer 0.8 mm (24); Machine glass pane 5 mm (26). 7. Composite pane according to one of claims 1 to 6, characterized in that the epoxy resin a resin component made from a difunctional bisphenol diglycidyl ether and long-chain Polyalkylene oxide diglycidyl ethers (molar weight approx. 600) and with cycloaliphatic Amines is hardened with the addition of heat. 8. Composite pane according to one of claims 1 to 6, characterized in that the epoxy resin a resin component made of polyurethane-polyethylene oxide and with cycloaliphatic Amines or N-Aminoäthylpiperazin is hardened