Process for encapsulation of a microelectronic device comprising the following steps in sequence: supply a support substrate comprising a first principal face on which a microelectronic device is placed, a second principal face, and a lateral face, deposit a bonding layer on the first principal face of the substrate, position an encapsulation cover comprising a first principal face, a second principal face, and a lateral face, on the bonding layer, deposit a lateral protection layer on: the lateral face and the periphery of the second principal face of the support substrate, the lateral face and the periphery of the second principal face of the encapsulation cover, the lateral protection layer delimiting a protected zone, thinning of the second principal face of the support substrate and/or the second principal face of the encapsulation cover outside the protected zone.

The present invention relates to a laminated plate (laminated glass plate 102 for a vehicle) including a first plate (first glass plate 201) being curved in a first curved shape, a second plate (second glass plate 202) having a second shape that is different from the first curved shape, and an intermediate film 301 bonding the first plate and the second plate, in which the laminated plate has, in a planar view thereof, a peripheral region 313 and an in-plane region 314, and the peripheral region 313 has a flat region 313a and an undulating region 313b.

A light transmissive substrate having a coating is disclosed. The coating is formed of an adhesion promoter that includes a metal, a metal oxide, or a metal nitride. A laminate including a coated substrate is also disclosed. A method of coating a substrate is further disclosed.

The present invention relates to an automotive curved laminated glazing (1) comprising (i) a first glass sheet (11) having an outer (P1) and an inner (P2) faces, (ii) an electrically powered functional film (13), (iii) a second glass sheet (12) having an outer (P3) and an inner (P4) faces. (iv) at least one optical coupling material (14) being a layer of polymer that is polymerized or cured from a liquid resin and provided between the said functional film and the at least first (11) and/or the second (12) glass sheets. According to the present invention, the curved laminated glazing has at least 50% of the total surface area of the outer face (P1) of the first glass sheet (11) and the inner face (P4) of the second glass sheet (12), having a minimum radius of curvature (R min) comprised between 75-8500 mm.

Methods of manufacturing electrochromic windows are described. An electrochromic device is fabricated to substantially cover a glass sheet, for example float glass, and a cutting pattern is defined based on one or more low-defectivity areas in the device from which one or more electrochromic panes are cut. Laser scribes and/or bus bars may be added prior to cutting the panes or after. Edge deletion can also be performed prior to or after cutting the electrochromic panes from the glass sheet. Insulated glass units (IGUs) are fabricated from the electrochromic panes and optionally one or more of the panes of the IGU are strengthened.

Methods of manufacturing electrochromic windows are described. Insulated glass units (IGU's) are protected, e.g. during handling and shipping, by a protective bumper. The bumper can be custom made using IGU dimension data received from the IGU fabrication tool. The bumper may be made of environmentally friendly materials. Laser isolation configurations and related methods of patterning and/or configuring an electrochromic device on a substrate are described. Edge deletion is used to ensure a good seal between spacer and glass in an IGU and thus better protection of an electrochromic device sealed in the IGU. Configurations for protecting the electrochromic device edge in the primary seal and maximizing viewable area in an electrochromic pane of an IGU are also described.

A frame for bonding a first glass component to a second glass component with a desired thickness of adhesive is disclosed. The frame has a horizontal top portion sized to overlap the top surface of the first glass component. The horizontal top portion has a distal surface which is configured to contain the adhesive when poured on the top surface of the first glass component. The horizontal top portion is thicker than the layer of adhesive to be used so that the second glass component may be placed within the frame to abut the distal surface. The frame also has a vertical side portion which extends downward from the horizontal top portion and is sized to wrap around the first perimeter.

A method for manufacturing a design object from a plurality of glass sheets. The method comprises cleaning at least one surface of a glass sheet, mixing a dye in a solvent to form a coloured mixture, mixing a hardener into the coloured mixture and filtering the coloured mixture. The filtered coloured mixture is mixed with an epoxy resin to form a coloured resin and the coloured resin is applied in one direction to the cleaned at least one surface of the glass sheet and allowed to dry.

Methods of manufacturing electrochromic windows are described. Insulated glass units (IGU's) are protected, e.g. during handling and shipping, by a protective bumper. The bumper can be custom made using IGU dimension data received from the IGU fabrication tool. The bumper may be made of environmentally friendly materials. Laser isolation configurations and related methods of patterning and/or configuring an electrochromic device on a substrate are described. Edge deletion is used to ensure a good seal between spacer and glass in an IGU and thus better protection of an electrochromic device sealed in the IGU. Configurations for protecting the electrochromic device edge in the primary seal and maximizing viewable area in an electrochromic pane of an IGU are also described.

Methods of manufacturing electrochromic windows are described. Insulated glass units (IGU's) are protected, e.g. during handling and shipping, by a protective bumper. The bumper can be custom made using IGU dimension data received from the IGU fabrication tool. The bumper may be made of environmentally friendly materials. Laser isolation configurations and related methods of patterning and/or configuring an electrochromic device on a substrate are described. Edge deletion is used to ensure a good seal between spacer and glass in an IGU and thus better protection of an electrochromic device sealed in the IGU. Configurations for protecting the electrochromic device edge in the primary seal and maximizing viewable area in an electrochromic pane of an IGU are also described.