METHOD TO PRODUCE INSULATING GLASS UNITS

Abstract

The present invention relate to a method to produce an insulating glass unit (IGU) comprising the following steps: Forming a first assembly by fastening to a first glass plate (3) an IGU spacer (1) and, apart from said IGU spacer (1), an edge element (2) comprising at least one through hole (10), said edge element (2) being fastened with the help of one of an immediate tack and green strength adhesive (5) or a compressible adhesive seal (8); Fastening by pressing a second glass plate (6) to said first assembly, said second glass plate (6) being fastened to the IGU spacer (1) and to the edge element (2), said edge element (2) being fastened thanks to the other one of an immediate tack and green strength adhesive (5) or a compressible adhesive seal (8); Injecting a structural sealant (9) into said at least one through hole (10) of said edge element (2) to fill up the space between the IGU spacer (1) and the edge element (2).

Claims

1. A method to produce an insulating glass unit (IGU) comprising: forming a first assembly by fastening to a first glass plate an IGU spacer and, apart from said IGU spacer, an edge element comprising at least one through hole, said edge element being fastened with the help of one of an immediate tack and green strength adhesive or a compressible adhesive seal; fastening by pressing a second glass plate to said first assembly, said second glass plate being fastened to the IGU spacer and to the edge element, said edge element being fastened thanks to the other one of an immediate tack and green strength adhesive or a compressible adhesive seal; and injecting a structural sealant into said at least one through hole of said edge element to fill up the space between the IGU spacer and the edge element.

2. The method according to claim 1 wherein the IGU spacer is fastened to the first glass plate and/or to the second glass plate thanks to a thermoplastic sealant.

3. The method according to claim 1, wherein the forming the first assembly comprises: pressing the IGU spacer coated with a thermoplastic sealant on the first glass plate; and pressing said edge element on the first glass plate with a layer of immediate tack and green strength adhesive being placed between said first glass plate and a first face of said edge element, the opposite face of said edge element being coated with said compressible adhesive seal.

4. The method according to claim 1, wherein the edge element is a continuous peripheral element with a surrounding structure surrounding the IGU spacer.

5. The method according to claim 1 wherein the edge element comprises a plurality of disconnected elements in the periphery of the IGU spacer.

6. The method according to claim 1 wherein said immediate tack and green strength adhesive between said edge element and said first glass plate comprises a double side mounting tape with structural properties.

7. The method according to claim 1 wherein said immediate tack and green strength adhesive comprises an adhesive without structural properties.

8. The method according to claim 1, wherein said compressible adhesive seal between said edge element and said second glass plate comprises a double side soft foam tape or a thermoplastic sealant.

9. The method according to claim 1 wherein a third glass plate is fastened to the first or second glass plate in order to obtain a triple glazing IGU.

10. The method according to claim 1, wherein one of the glass plates is a standard insulating glass unit.

11. The method according to claim 1, wherein the glass plates have different dimensions.

12. An insulating glass unit (IGU) obtained by the method of claim 1.

13. A window comprising the IGU according to claim 12.

14. A door comprising the IGU according to claim 12.

Description

[0025] The invention will be better understood upon reading the following description in view of the attached figures that will in no way limit the scope of the invention and wherein:

[0026] FIG. 1 represents the successive steps of a method to manufacture IGUs according to the invention;

[0027] FIG. 2 shows a side view an IGU obtained with a first embodiment of the method according to the invention;

[0028] FIG. 3 shows a side view an IGU obtained with a second embodiment of the method according to the invention;

[0029] The figures are not drawn to scale. Generally, identical components are denoted by the same reference numerals in the figures.

[0030] FIG. 1 represents the successive steps of a method to manufacture IGUs according to the invention.

[0031] At step i), a first glass plate 3 comprising an enamelled area 11 over its entire periphery is disposed.

[0032] At step ii), an IGU spacer 1 coated with a thermoplastic sealant 4 is pressed on the first glass plate 3. In the present invention, the thermoplastic sealant 4 comprises for example polyisobutylene. Although in FIG. 1 the same sealant 4 is used for both sides of the IGU spacer 1, in other embodiments, a different sealant can be used for each side of the IGU spacer 1. The IGU spacer 1 will delimit a cavity between the first glass plate 3 and a second glass plate as detailed in the subsequent steps. The IGU spacer 1 has consequently a surrounding shape in order to space apart the glass plates on their edge. The IGU spacer 1 can be made of one piece or can alternatively comprise a plurality of elements having their extremities abutted to form the surrounding shape. The IGU spacer 1 can be metallic, polymeric, in composite materials reinforced by glass fibres or a mix of several of these materials. The IGU spacer can be hollow in order to be able to receive for example some drying material. Such IGU spacer 1 is then perforated to allow the drying material to trap water vapor that is coming in the cavity of the IGU.

[0033] At step iii), an edge element 2 comprising through holes 10 is pressed on the first glass plate 3 with a layer of immediate tack and green strength adhesive 5, for example a double side mounting tape, being placed between said first glass plate 3 and a first face of said edge element 2, the opposite face of said edge element 2 being coated with a compressible adhesive seal 8.

[0034] In the present invention, the edge element 2 can either be a continuous peripheral element with a structure surrounding the IGU spacer 1 or can comprise a plurality of disconnected elements placed in the periphery of the IGU spacer 1. When the edge element 2 comprises a plurality of disconnected elements, the through holes 10 in said edge element 2 can be either through holes in the disconnected elements or gaps between said disconnected elements or both of them. The use of disconnected elements is advantageous as it allows saving edge element material by placing disconnected elements only where needed to realize their functions. It is also advantageous as it allows bringing different functions in different disconnected elements. Furthermore, the edge element 2 can be hollow or filled. The edge element can have different shapes. It can for instance be U-shaped what is interesting in the case of a frameless window or door as it can receive the fastening or fixing means. Any shape that can fulfil this function is also suitable for frameless window or door. Advantageously, it comprises two opposite surfaces to bond the edge element 2 to the two glass planes 3 and 6. The edge element 2 can be metallic, polymeric, in composite materials reinforced by glass fibres or a mix of several of these materials.

[0035] As already explained above, the edge element 2 of the invention can have different uses, for example:

[0036] to receive fastenings or fixing means to connect the IGU with another IGU, with a fixed frame or with a building structure;

[0037] to strengthen the IGU and reduce its deflection;

[0038] to make a seal between the IGU and another IGU, a frame or a building structure;

[0039] to protect the edge of the IGU;

[0040] to put some cables or wires.

[0041] In this regard, the edge element 2 can be protruding from the IGU, for example to make a seal with surrounding parts.

[0042] In the present invention, the immediate tack and green strength adhesive 5 can be a double side mounting tape with structural properties comprising a polyurethane or an acrylic foam carrier or an acrylate based adhesive. When structural anchoring of edge element 2 is assured by structural sealant 9, the immediate tack and green strength adhesive 5 can also comprise a soft double-side foam tape or a thermoplastic sealant, without structural properties.

[0043] As illustrated in FIG. 1, the layer of immediate tack and green strength adhesive 5 will allow a very accurate positioning of the edge element 2 while also making possible to move the first glass plate in a vertical position right after the positioning of the edge element 2 and to store vertically the IGU just after the structural sealant 9 application. This feature is advantageous in terms of production efficiency.

[0044] At step iv), a second glass plate 6 also comprising an enamelled area 12 is placed parallel to first glass plate of the assembly obtained at step ii). In an advantageous embodiment, the IGU is filled with a thermal insulating gas before both glass plates are pressed, during this step.

[0045] At step v), both glass plates 3, 6 are pressed in order to reach the requisite distance between said glass plates 3 and 6 before releasing the pressure. In this way, the second glass plate 6 is fastened to the IGU spacer frame 1 with the help of the thermoplastic sealant 4 and to the edge element 2 thanks to the compressible adhesive seal 8. The thermoplastic sealant 4 on both sides of the IGU spacer constitutes an IGU double seal preventing water vapor to get in the IGU cavity and potentially to keep an insulating gas inside the IGU cavity.

[0046] The compressible adhesive seal 8 according to the invention can be a double side soft foam tape, for example a polyethylene foam carrier and an acrylate based adhesive, or alternatively a thermoplastic sealant. The compressible adhesive seal 8, on one hand, holds the edge element 2 in position, and on the other hand, delimits a specific space between the IGU spacer 1 and the edge element 2. Another characteristic of this compressible adhesive seal 8 is its capacity to deform itself and to maintain this deformation with a very low force. During the pressing step, the compressible adhesive seal 8 deforms itself and, during the release step, it maintains its deformation in order not to stretch or even destroy the seals comprising thermoplastic sealant 4 between the spacer 1 and glass plates 3 and 6.

[0047] The enamelled areas 11 and 12 will have an aesthetic function by concealing the IGU spacer 1 and the edge element 2 from the view of the people looking through the frameless window or door comprising the IGU according to the invention.

[0048] At step vi), a structural sealant 9 is injected into said through holes 10 of said edge element 2 until the space between the IGU spacer 1 and the edge element 2 is filled.

[0049] In the present invention, the structural sealant 9 can comprise a two components sealant comprising a base and a hardener. In an advantageous embodiment, said two components sealant comprises silicone, polyurethane or polysulfide sealants, preferably the two components sealant is a silicone sealant.

[0050] In the present invention, the presence of through holes 10 in the edge element 2 allows indeed an injection of structural sealant 9, which is generally a very viscous substance, into said through holes 10. The presence of the through holes renders unnecessary the gap between the edge element 2 and the second glass plate 6 required in the prior art discussed above. The method according to the invention will consequently provide flexibility in the choice of the width and shape for the edge element 2.

[0051] In the present invention, the total width of the edge element 2, the green strength and immediate tack adhesive 5 and the compressible adhesive seal 8 is equal to the distance between said first glass plate 3 and second glass plate 6 after pressing. This distance is determined by the width of the IGU spacer 1 and its thermoplastic sealant 4. It advantageously minimizes the waste of expensive structural sealant 9 as geometry of the cavity to be filled with structural sealant is optimized and no structural sealant 9 can flow out of the cavity delimited by the edge element 2, the IGU spacer 1 and the 2 glass plates 3 and 6.

[0052] In an advantageous embodiment, after the curing of the structural sealant 9 injected in said through holes 10 of said edge element 2, a mask is applied to cover said through holes 10.

[0053] FIG. 2 shows a side view of an IGU obtained with a first embodiment of the method according to the invention. In this embodiment, the edge element 2 is made of a continuous peripheral element and through holes 10 to inject the structural sealant 9 are punched into said edge element 2. It is fastened to the glass plates 3 and 6 by the immediate tack and green strength adhesive 5 and the compressible adhesive seal 8.

[0054] FIG. 3 shows a side view of an IGU obtained with a second embodiment of the method according to the invention. In this embodiment, the edge element comprises a plurality of disconnected elements 21. The through holes in the edge element to inject the structural sealant 9 are in this case spaces 10 between the successive disconnected elements 21. The immediate tack and green strength adhesive 5 and the compressible adhesive seal 8 are not illustrated in FIG. 3.