FR3114810A1 - ASSEMBLY AND DISASSEMBLY OF A GLASS SOLUTION - Google Patents

Abstract

Method of assembling: - a plurality of components of an assembly (2) with a canopy function, between them, or - said assembly (2) with a canopy function to a support structure (3), characterized in that it implements at least one removable fixing element (4A, 4B) adapted to pass, under the effect of a so-called "separation" distant excitation, from an adhesion state satisfying the adhesion criterion established by the standard EN 1279-4:2018, towards a state of separation. Figure for abstract: Fig. 1

Description

ASSEMBLY AND DISASSEMBLY OF A GLASS SOLUTION

The present invention relates to the field of glazing for vehicles or buildings for interior and exterior applications and more specifically, to the recycling of glass function assemblies (glazing for vehicles, single, double or triple glazing for buildings, etc.) used. The invention relates in particular to a method for assembling and/or disassembling a plurality of components of an assembly with a canopy function, between them, and/or to a support structure (structural elements of a vehicle, 'a building). The invention also covers the products obtained after the implementation of such assembly/disassembly processes.

The recycling of sets with a glass function is today a problem of primary importance, having in particular the challenges of reducing the cost of vitrifiable raw materials and reducing the environmental footprint of newly manufactured products. Such a problem implies in particular the separation of the different components of a set with a glass function, with a view to their separate recycling and their future reuse.

In the field of glazing, such a separation is traditionally carried out mechanically, that is to say via an action of direct contact, and necessarily involves the destruction of one or more of the components of said glass function assembly, and in particular of the or glazing. Evidenced by the patent document WO2020/002640 which relates to the fragmentation of used windows, with a view to their recycling.

The impurities and in particular the mastic residues present in the cullet during the mechanical separation of the glass solution harm the quality of the latter, and limit or even prohibit any reuse of this cullet for the manufacture of flat glass. Regarding the non-glass components integrated in the glass solution, their deterioration generates operational constraints and a non-negligible environmental cost, since it involves the replacement of this component, or at least the implementation of a specific reprocessing process.

The proposed technique makes it possible to respond to the aforementioned drawbacks and relates more particularly, in at least one embodiment, to an assembly method:
- A plurality of components of a canopy function assembly, between them, or
- From said glass function assembly to a support structure,
characterized in that it implements at least one removable fixing element adapted to pass, under the effect of a so-called "separation" distant excitation, from an adhesion state satisfying the adhesion criterion established by the standard EN 1279-4:2018, towards a state of separation.

Throughout the description, an assembly with a glass function designates a technical solution implementing at least one glass element derived from flat glass. As the EN 1279-4:2018 standard relates to sealed prefabricated insulating glazing, a fixing element satisfying the adhesion criteria established by this standard is therefore specifically suited to this field of application. In contrast to such a state of adhesion, a fastener is in a so-called "separation" state or in other words when it does not meet or no longer meets the criteria established by EN 1279-4:2018 or preferentially, when this state of separation is equivalent to a loss of at least 50%, preferably 80%, of the mechanical properties characterizing the state of adhesion of the removable fastening element.

The invention is based on a new and inventive concept consisting in implementing a removable attachment between two parts of the same assembly, at least one of which is made of glass. Throughout the text, the term “removable” describes reversible fixing, without deterioration of the parts fixed together. In contrast, the welding of two parts together is considered an irreversible attachment.

The removable nature of the fastener used thus makes it possible, during future disassembly, repair, maintenance, improvement and/or end-of-life operations, to preserve the integrity of the parts while separating them from one another. others in order to facilitate their recycling. In the specific case of glass, isolating it from the other components of the glass function assembly makes it possible to obtain better quality cullet, which can be used in particular for the manufacture of flat glass. It is thus possible to set up a closed recycling cycle for flat glass.

A removable fastener according to the invention has the additional characteristic of being "deactivated" or in other words, passed from a state of adhesion to a state of separation, following the application of a remote excitation. Within the meaning of the invention, the remote excitations are exerted by means of electromagnetic radiation which may for example be in the form of infrared, ultraviolet, microwaves, an electric field, including a electric current, and/or a magnetic field. They are thus opposed by nature to contact excitations, which result from mechanical contact between two objects.

In addition to the advantages related to the removable nature of the binding, the fact that this binding can be deactivated remotely facilitates maintenance and/or disassembly operations while limiting the risk of damage. Indeed, given the fact that the fixing element no longer exerts an adhesive action after excitation, or at least more than a negligible action, manual manipulation of the parts of the assembly, carried out without tools, enough to separate them from each other.

According to a particular embodiment, said assembly method is characterized in that:
- said assembly fulfills a glazing function by preferentially presenting itself in the form of single glazing, double glazing or triple glazing suitable for the building, and/or fulfilling a decorative function by preferentially presenting in the form of a mirror, a credenza, a worktop, a decorative wall covering, or a shower screen, and/or
- Said support structure belongs to said building, and is preferably a window frame, a wall, a door, a structural element, or a decorative element of said building.

The term “double glazing” means a set of two glazing units spaced apart and separated by a gas or vacuum layer and by “triple glazing” a set of three glazing units spaced apart and separated by two respective layers of gas or vacuum. According to particular embodiments, each of the glazings can be heat-treated, have functional layers and/or or decorative coatings. As described above, at least one of the spaced panes of a multiple pane may be laminated. In all configurations, the counter-substrate is intended to be positioned outwards.

According to a particular embodiment, said assembly method is characterized in that:
- said glass function assembly is a windshield, vehicle side glazing or vehicle roof glazing, and/or
- Said support structure belongs to said vehicle.

For the purposes of the invention, vehicle means any means of transport, whether air (plane), land (train, bus) or sea (boat).

According to a particular embodiment, a single glazing is a laminated glazing.

According to a particular embodiment, at least one of the spaced panes of a multiple pane is laminated.

According to a particular embodiment, the passage of said removable fastening element from its state of adhesion to its state of separation is temporary.

According to this particular embodiment, it is thus possible to reuse the fastening element. In other words, said removable fastener is also recyclable.

According to a particular embodiment, said remote separation and/or assembly excitation is generated by means of infrared, ultraviolet, an electric field, including an electric current, and/or a magnetic field.

According to a particular embodiment, said remote separation excitation is generated by means of infrared, and in that the temperature at which said removable fixing element passes from said state of adhesion to said state of separation is between 100 and 250 °C.

Below 100°C, there is a risk that the gasket will come off during the life of the glazing, and above 250°C, the energy consumption is considered too high.

According to a particular embodiment, said removable fastening element is a polymer.

According to a particular embodiment, said removable fixing element is a vitrimer.

Throughout the text, the term vitrimer designates a polymer developing a covalent dynamic network with exchangeable bonds, such as that described in patent document WO2012/101078. Such a polymer has the particular advantage of being recyclable.

According to a particular embodiment, said removable fixing element comprises at least one agent suitable for producing gas under the effect of said remote separation excitation in order to cause said removable fixing element to pass from said state of adhesion to said state of seperation.

Such an agent is described in patent document FR2837114. In comparison with vitrimer, it has the disadvantage of being destroyed during its deactivation, and is therefore not recyclable.

The invention also relates to an assembly with a canopy function obtained by implementing such an assembly method.

According to a particular embodiment, said removable fastening element is a secondary seal of double-glazing or triple-glazing forming said glass function assembly.

According to a particular embodiment, the glass function assembly complies with all of the EN 1279-4:2018 standard.

The invention also relates to an assembly formed by an assembly with a canopy function and a support structure, said assembly being obtained by implementing such an assembly method.

The invention also relates to a method for disassembling such an assembly with a glass function and/or such an assembly, comprising a step of applying said remote separation excitation to said removable fastening element.

Other characteristics and advantages of the invention will appear on reading the following description of particular embodiments, given by way of simple illustrative and non-limiting examples, and of the appended figure, for which:
there is a schematic cross-sectional representation of an assembly formed by a canopy function assembly and a support structure, according to a particular embodiment of the invention,
there is a schematic representation of a sealant stress-strain curve and an OAB triangle as defined by EN 1279-4:2018.

The various elements illustrated by the figures are not necessarily represented on a real scale, the emphasis being placed more on the representation of the general operation of the invention. On the , unless otherwise indicated, reference numerals that are the same represent similar or identical elements. A particular embodiment of the invention is described below. It is understood that the present invention is in no way limited by this particular embodiment and that other embodiments can perfectly well be implemented.

There illustrates an assembly (1) according to a particular embodiment of the invention, formed by double glazing (2) and a window frame (3). This double glazing (2) comprises a layer of inert gas (argon) (7) partitioned between two substrates (5) by means of spacers (6), primary seals (4C) and secondary seals (4A ) arranged on the periphery of the two substrates (5). This double glazing (2) is fixed to the window frame (3) by means of structural joints (4B).

According to this particular embodiment, the secondary seals (4A) and the structural seals (4B) are removable fastening elements. Thus, and as illustrated by the , when during a disassembly operation, the assembly (1) is subjected to a distant source of excitation, in this case infrared radiation, the secondary and structural seals (4A, 4B) pass from a state of adhesion, in which the various elements constituting the double glazing (2) and the window frame (3) are fixed together by means of said seals (4A, 4B), towards a state of separation in which these same seals (4A, 4B) no longer perform their adhesion function, which allows easy disassembly of the assembly (1), without damage to the parts fixed together. The quality of the recovered cullet is therefore better, which allows its reuse for the manufacture of flat glass.

According to alternative embodiments not shown in the figures, only part of the seals (4A, 4B) has these removable fixing properties.

According to alternative embodiments, either the loss of adhesion of the seals (4A, 4B) is irreversible - the seal is then degraded - or the loss of adhesion is only temporary, which allows its future reuse or all of the less, its recycling.

According to the invention, this state of adhesion satisfies the adhesion criterion established by standard EN 1279-4:2018. More specifically, and with reference to the , this criterion is satisfied when H-shaped specimens made of the same material as the targeted fastener and prepared according to appendix A of this same standard, exhibit a failure on adhesion against the glass positioned outside the triangle OAB defines by the abscissa axis (elongation %) and the ordinate axis (tensile strength in MPa) and a straight line passing through point B at 50% elongation for 0 MPa and point A at 0% elongation elongation and 0.5 MPa).

In the particular case of a secondary seal (4A) at the periphery of a glass substrate (5), in contact with a metallic or plastic spacer (6), and having a removable fixing function, the rupture at the adhesion against the metal or plastic surface of the spacer (6) is evaluated according to a protocol established by the same standard EN 1279-4:2018.

With the aim of determining a posteriori whether a fastening element (4A, 4B) integrated into an assembly (1) satisfies this adhesion criterion or not, it is possible to isolate said targeted fastening element and to extract, by chemical analysis, its chemical signature. Once this chemical signature has been established, its adhesion failure behavior can then be determined either by consulting pre-existing tables of adhesion values, or by reproducing the evaluation protocol set out by the standard using test specimens presenting the same chemical signature.

Claims (13)

1. Process comprising an assembly step:
- a plurality of components of an assembly (2) with canopy function, between them, or
- said assembly (2) with glass function to a support structure (3),
characterized in that it implements at least one removable fixing element (4A, 4B) adapted to pass, under the effect of a so-called "separation" distant excitation, from a state of adhesion satisfying the criterion of adhesion established by standard EN 1279-4:2018, towards a state of separation. 2. Assembly method according to claim 1, characterized in that:
- said assembly (2) fulfills a glazing function by preferably being in the form of single glazing, double glazing or triple glazing suitable for the building, and/or fulfills a decorative function by preferentially in the form of a mirror, a credenza, a worktop, a decorative wall covering, or a shower screen, and/or
- said support structure (3) belongs to said building, and is preferably a window frame, a wall, a door, a structural element, or a decorative element of said building. 3. Assembly method according to claim 1, characterized in that:
- said assembly (2) with glass function is a windshield, vehicle side glazing or vehicle roof glazing, and/or
- said support structure (3) belongs to said vehicle. 4. Assembly method according to one of claims 1 to 3, characterized in that the passage of said removable fastening element (4A, 4B) from its state of adhesion to its state of separation is temporary. 5. Assembly method according to one of claims 1 to 4, characterized in that said remote separation excitation is generated by means of infrared, ultraviolet, an electric field, including an electric current , and/or a magnetic field. 6. Assembly method according to claim 4, characterized in that said remote separation excitation is generated by means of infrared, and in that the passage temperature of said removable fixing element (4A, 4B) from said state of adhesion to said state of separation is between 100 and 250°C. 7. Assembly method according to one of claims 1 to 6, characterized in that said removable fastening element (4A, 4B) is a polymer. 8. Assembly method according to claims 4 and 7, characterized in that said removable fixing element (4A, 4B) is a vitrimer. 9. Assembly method according to claim 7, characterized in that said removable fixing element (4A, 4B) comprises at least one agent suitable for producing gas under the effect of said remote separation excitation in order to cause said removable fastener (4A, 4B) from said adhesion state to said separation state. 10. Assembly (2) with canopy function, preferably obtained by implementing an assembly method according to one of claims 1 to 9, characterized in that it implements at least one removable fastening element ( 4A, 4B) adapted to pass, under the effect of a so-called "separation" remote excitation, from a state of adhesion satisfying the adhesion criterion established by standard EN 1279-4: 2018, to a state of separation. 11. Set (2) with glass function according to claim 10, characterized in that said removable fixing element is a secondary seal (4A) of double-glazing or triple-glazing forming said set ( 2) with canopy function. 12. Assembly (1) formed of an assembly (2) with glass function according to one of claims 10 and 11, and a support structure (3). 13. Disassembly process:
- an assembly (2) with a canopy function according to one of claims 10 and 11, and/or
- an assembly (1) according to claim 12,
comprising a step of applying to said removable fixing element (4A, 4B) said remote separation excitation.