EP4061628A1 - Laminated glass panel with improved resistance to relatively specific types of impact - Google Patents

Abstract

The invention relates to - a laminated glass panel comprising a transparent structural substrate (1) bonded to a glass film (2) between 0.5 and 4 mm thick, which film is intended to constitute an external surface of the laminated glass panel, by means of an adhesive interlayer (3) between 4 and 10 mm thick, which interlayer comprises, in sequence, between 0.25 and 2.5 mm of a first flexible polymer material (4a) having a maximum relaxation modulus of 2 GPa for minimum relaxation times of 10 minutes, at minimum temperatures of -40°C, and is in contact with the glass film (2), then a second rigid polymer material (5) having a minimum modulus of relaxation of 4 GPa, for maximum time constants of 0.1 milliseconds and maximum temperatures of 40°C. The invention also relates to the application of the laminated glass panel as a glass panel for an air, land or water vehicle, or for building construction.

Description

Description

Title of the invention: Laminated glazing with improved resistance to relatively punctual types of impact

The present invention relates to a glazing for an aerial vehicle, land or water, or for the building, preferably an aeronautical glazing, having an increased performance in several types of impacts including hail and small birds. Airplanes with heated glazing are more particularly concerned, such as business jets, regional aircraft of the type marketed by the ATR Company, for example, commercial, medium, long-haul aircraft, etc.

Aircraft windshields in particular consist of a so-called structural block with a mainly mechanical function (resistance to pressure forces and impact to larger birds) associated such as by lamination to a sheet (or fold) such as than glass providing the interface with the exterior of the aircraft. This sheet, thanks to a heating function, prevents the appearance of frost in flight; it must also withstand windshield wipers and sandblasting.

These constraints make glass a material of choice for this outer ply, because of its good scratch resistance properties, its good thermal properties and the possibility of applying heating conductive layers delivering high specific powers. .

[0004] Furthermore, for reasons of aerodynamic continuity, the outer glass is laminated with a relatively thick interlayer adhesive mat. An intermediate adhesive here denotes a polymer material bonding two sheets of mineral and / or organic glass together. Examples of organic glass are poly (methyl methacrylate) (PMMA), polycarbonate (PC), polyurethane (PU) and, as an interlayer adhesive, polyvinyl butyral (PVB), thermoplastic polyurethane (TPU), ethylene vinyl acetate (EVA) copolymer.

Due to the relatively large thickness of the interlayer adhesive mat, the outer glass, under the impact of hail (up to 50 mm in diameter) or small birds, is flexed up to when it breaks. This stress prevents reducing the thickness of this outer glass which is typically 3 mm. However, reducing this thickness can make it possible to reduce the mass of the glazing.

[0006] If you reduce the thickness of the outer glass, its resistance to hail is inherently lower, and the midsole mat is thickened to maintain aerodynamic continuity.

[0007] A frequent reason for removing glazing remains their failure under the impact of hail or small birds.

To overcome these drawbacks, the invention relates to a laminated glazing comprising a transparent structural substrate bonded to a glass sheet of thickness between 0.5 and 4 mm, intended to constitute an outer surface of the laminated glazing , by means of an intermediate adhesive layer with a thickness of between 4 and 10 mm, characterized in that the intermediate adhesive layer successively comprises a thickness of between 0.25 and 2.5 mm of a first flexible polymer material having a relaxation modulus at most equal to 2 GPa for relaxation times at least equal to 10 min, at temperatures at least equal to -40 ° C, in contact with the glass sheet, then a thickness of a second stiff polymer material having a relaxation modulus of at least 4 GPa, for time constants at most equal to 0.1 milliseconds and temperatures at most equal to 40 ° C (conditions representative of a hail-type impact on an airplane ).

[0009] Due to mechanical and thermomechanical stresses in the phases of production and use of the glazing, a flexible behavior of the gluing interlayer of the glasses is desirable in order to limit the excessive stresses in the glass which may cause it to break or to damage. bonded interfaces that can cause detachment. For these reasons, it is advantageous to combine between the median (or second, starting from the external atmosphere) and external glasses a so-called stiff polymer material allowing good performance against hail and a so-called flexible polymer material making it possible to limit thermomechanical stresses. and mechanical in the glazing. The stiffness of the stiff material is evaluated according to the typical impact stresses, while that of the This material is flexible with respect to thermomechanical and mechanical stresses, in particular associated with the pressurization speeds of airplanes.

[0010] The structural transparent substrate consists of a sheet of glass or more frequently of several laminates, the cumulative thickness of which is relatively large to perform the mechanical function mentioned above. It can be mineral glass, but also organic such as poly (methyl methacrylate) (PMMA), polycarbonate (PC) or polyurethane (PU).

[0011] Thanks to the invention, the increased stiffness of the interlayer adhesive layer limits the deformations of the glass sheet and therefore repels the speed of impact of hail or small birds causing breakage. It is therefore possible to use a thinner glass sheet reducing the mass of the laminated glazing.

[0012] Preferably, 40 to 90% of the thickness of the interlayer adhesive layer is made of said stiff second polymeric material, and 10 to 60% of that thickness is made of said first flexible polymer material.

Preferably, a thickness of said first flexible polymeric material is interposed between and in contact with the thickness of said second stiff polymeric material and the transparent structural substrate.

Preferably, the relaxation modulus of said first polymer material is at most equal to 2, preferably 0.5 GPa for relaxation times at least equal to 10 min, at temperatures at least equal to -40 ° vs.

Preferably, the elastic modulus of said second polymer material is at least equal to 5 GPa, for time constants at most equal to 0.1 milliseconds and temperatures at most equal to 40 ° C.

Preferably, the thickness of the glass sheet is between 1.5 and 3 mm.

[0017] Preferably, said sheet of glass consists of chemically reinforced glass, in particular soda-lime or aluminosilicate, or is thermally toughened.

Preferably, the structural transparent substrate comprises at least one sheet of glass or several laminates, in particular aluminosilicate or soda-lime, at least one of which can be chemically reinforced; the term “Glass” here also denotes a structural transparent organic polymer material such as. poly (methyl methacrylate) (PMMA), polycarbonate (PC), polyurethane (PU), polyester such as poly (ethylene terephthalate) (PET) or equivalent.

Preferably, said first polymer material is chosen from a thermoplastic polyurethane (TP U), polyvinyl butyral (PVB), ethylene - vinyl acetate (EVA) alone or as a mixture or copolymer of several of them.

Preferably, said second polymer material is chosen from a poly (methyl methacrylate) (PMMA), polycarbonate (PC), polyurethane (PU), polyester such as poly (ethylene terephthalate) (PET) alone or in mixture or copolymer of several of them.

Frequently, said second stiff polymeric material extends to the edges of said sheet of glass. Preferably, however, said second stiff polymeric material is recessed from the edges of said sheet of glass. This arrangement softens the periphery of the glazing (area most subject to cold temperatures), so as to improve reliability. Such encapsulation of the interfaces between stiff and flexible polymer materials limits the risks of delamination. In addition, space is thus freed up to allow connection elements to walk.

Preferably, the glass sheet intended to constitute an outer surface of the laminated glazing and the stiff polymeric material are set back relative to the transparent structural substrate, so as not to form part of the attachment of the laminated glazing.

Another object of the invention consists of the application of a laminated glazing as described above as glazing for an air, land or water vehicle, or for the building, in particular as an aircraft glazing.

[0024] The accompanying drawings illustrate the invention:

[0025] [Fig. 1] shows schematically in section, a laminated glazing according to the invention.

[0026] [Fig. 2] is a graph representing the results of a second series of hail impact tests. [0027] [Fig. 3] is a schematic sectional representation of a laminated glazing according to the invention, the outer glass sheet and the stiff polymeric material of which are set back relative to the structural transparent substrate, so as not to form part of the attachment of the laminated glazing.

[0028] [Fig. 4] shows schematically the attachment of the glazing of Figure 3 to the cabin of an aircraft.

[0029] [Fig. 5] shows schematically in section a laminated glazing according to the invention which differs from that of Figure 3 only by a stiff polymer material set back relative to the outer sheet of glass.

This laminated glazing comprises two main glass elements: a substrate or transparent structural block 1 and a glass sheet 2 intended to be in contact with an external atmosphere from which a relatively punctual / light impact such as hail is likely to originate. or little bird.

The transparent structural block 1 is formed so as to guarantee the laminated glazing all the required mechanical resistance, vis-à-vis the pressure variations to which an aircraft may be subjected, for example, and the most significant shocks, such as that big birds. It consists of two sheets of chemically reinforced aluminosilicate glass 8 mm thick 1 a and 1 b glued to each other by a layer 6 of PVB 2.28 mm thick, this thickness possibly being in generally between 1, 5 and 3 mm.

[0032] The glass sheet 2 is made of chemically reinforced soda-lime glass and of a thickness of between 1.5 and 3 mm. It is bonded to the transparent structural block 1 by a relatively thick intermediate adhesive layer 3. In the event of an almost punctual impact of the hail type, the mattress formed by this intermediate adhesive layer 3 deforms under the glass sheet 2, thus allowing it to flex under the effect of the impact.

The intermediate adhesive layer 3 consists of a layer of polymethyl methacrylate (PMMA) 5 from 1 to 9 mm thick, between two layers of thermoplastic polyurethane (TPU) 4a, respectively 4b from 0.25 to 2, 5, respectively 0.25 to 5 mm thick. The relaxation modulus of PMMA 5 for time constants at most equal to 0.1 milliseconds and temperatures at most equal to 40 ° C, is between 6 and 7 GPa, the modulus of relaxation of the TPU for relaxation times at least equal to 10 min, at temperatures at least equal to -40 ° C., is 1 GPa.

For carrying out hail impact tests, test specimens of 500 mm X 500 mm were used consisting of a monolithic structural fold and a glass exposed to hail, glued one to the other. 'the other by an interlayer mattress (TPU) possibly reinforced by a PMMA. The composition of these laminated glazing is shown in the following table.

[0035] [Table 1]

These five laminated glazing are subjected to hailstones 25 mm in diameter at incremental speeds (increment of 5 m / s) until breakage. Ten test pieces are used for each laminated glazing composition. The results are shown in Figure 2, in which

- standard glazing is represented by black circles;

- the glazing lightened by white circles,

- the glazing reinforced with black squares,

- reinforced glazing lightened by white squares, and

- PMMA glazing reinforced with gray triangles.

[0037] Figure 2 shows

- that thinning the external glass without reinforcements of the interlayer generates weakening vis-à-vis hail,

- that the substitution of 2/3 of the interlayer by PMMA doubles the performance against hail, and - that the lightened reinforced glazing is more resistant to hail than the standard glazing while being lighter by 1.8 kg / m ² .

Figure 3 shows a glass sheet 2 intended to be in contact with the external atmosphere and a complex interlayer adhesive layer 4a, 5, 4b according to the invention, which are set back relative to the transparent structural substrate 1a, 6, 1b.

In Figure 4, the interlayer 4a, 5, 4b of Figure 3 is shown diagrammatically in a single block of reference number 3. The parts of the glazing allowing the mechanical connection (attachment) to the cabin of the plane, either pinched or bolted, are represented by two dotted areas. Glass sheet 2 and interlayer 3 (including stiff polymeric material 5) are not part of the laminated glazing attachment. The total thickness of the glass sheet 2 and of the interlayer 3 is adjusted to achieve aerodynamic continuity with the ice press 7, the thickness of which is itself conditioned by the need to withstand pressurization forces. The material of the glass sheet 2 ensures resistance to abrasion, and the possibility of supporting heating layers with an anti-icing function based on ITO (indium tin-doped oxide). The intermediate layer 3 therefore consists of three layers of polymer material, with a density 2.5 times lower than that of glass 2. For the purpose of lightening, it is advantageous to minimize the thickness of the glass sheet 2, and therefore to increase the thickness of the intermediate layer 3. To increase the resistance to hail, the invention uses a complex intermediate layer as described above, in which it is in particular important that the layer of flexible polymer material 4a does not is not too thick.

In Figure 5, the stiff polymer material 5 is set back relative to the outer glass sheet 2. The peripheral part of the polymer material 5 is extended by filling or plugging with the flexible polymer material 4c of the same characteristics than flexible polymer materials 4a, 4b.

Claims

Claims [Claim 1] Laminated glazing comprising a structural transparent substrate (1) bonded to a sheet of glass (2) with a thickness of between 0.5 and 4 mm, intended to constitute an outer surface of the laminated glazing, by means of 'an intermediate adhesive layer (3) with a thickness of between 4 and 10 mm, characterized in that the intermediate adhesive layer (3) successively comprises a thickness (4a) of between 0.25 and 2.5 mm of a first flexible polymer material having a relaxation modulus at most equal to 2 GPa for relaxation times at least equal to 10 min, at temperatures at least equal to -40 ° C, in contact with the glass sheet (2), then a thickness (5) of a second stiff polymer material having a relaxation modulus at least equal to 4 GPa, for time constants at most equal to 0.1 milliseconds and temperatures at most equal to 40 ° C. [Claim 2] Laminated glazing according to claim 1, characterized in that 40 to 90% of the thickness of the intermediate adhesive layer (3) consists of said stiff second polymeric material (5), and 10 to 60% of this. thickness are made of said first flexible polymer material (4a, 4b). [Claim 3] Laminated glazing according to one of the preceding claims, characterized in that a thickness (4b) of said first flexible polymer material is interposed between and in contact with the thickness (5) of said stiff second polymer material and the transparent structural substrate (1). [Claim 4] Laminated glazing according to one of the preceding claims, characterized in that the relaxation modulus of said first polymer material (4a, 4b) is at most equal to 0.5 GPa for relaxation times at least equal to 10 min, at temperatures at least equal to - 40 ° C. [Claim 5] Laminated glazing according to one of the preceding claims, characterized in that the elastic modulus of said second polymer material (5) is at least equal to 5 GPa, for time constants at most equal to 0.1 milliseconds and temperatures at most equal to 40 ° C. [Claim 6] Laminated glazing according to one of the preceding claims, characterized in that the thickness of the glass sheet (2) is between 1, 5 and 3 mm. [Claim 7] Laminated glazing according to one of the preceding claims, characterized in that the glass sheet (2) consists of chemically reinforced glass, in particular soda lime or aluminosilicate, or is thermally toughened. [Claim 8] Laminated glazing according to one of the preceding claims, characterized in that the structural transparent substrate (1) comprises at least one sheet of glass or several laminates (1a, 1b), in particular aluminosilicate or soda-lime, one of which at least can be chemically enhanced. [Claim 9] Laminated glazing according to one of the preceding claims, characterized in that said first polymer material (4a, 4b) is chosen from a thermoplastic polyurethane (TPU), polyvinyl butyral (PVB), ethylene - vinyl acetate (EVA) alone or as a mixture or copolymer of several of them. [Claim 10] Laminated glazing according to one of the preceding claims, characterized in that said second polymeric material (5) is chosen from a poly (methyl methacrylate) (PMMA), polycarbonate (PC), polyurethane (PU), polyester such as poly (ethylene terephthalate) (PET) alone or as a mixture or copolymer of several of them. [Claim 11] Laminated glazing according to one of the preceding claims, characterized in that said stiff second polymeric material (5) is recessed with respect to the edges of said glass sheet (2). [Claim 12] Laminated glazing according to one of the preceding claims, characterized in that the glass sheet (2) and the stiff polymer material (5) are set back relative to the structural transparent substrate (1; 1a, 6, 1b ), so as not to be part of the attachment of the laminated glazing. [Claim 13] Application of a laminated glazing according to one of the preceding claims as glazing for an air, land or water vehicle, or for the building.