A method for recycling of laminated glass is disclosed. The laminated glass comprises at least one glass layer and at least one polyvinyl butyral (PVB). The method comprises mechanical removal of at least part of the glass, placing residual waste with glass particles in a vat comprising a separation fluid to produce a mixture of glass particles and one polyvinyl butyral (PVB) pieces from the residual waste, from which the one polyvinyl butyral (PVB) pieces can be screened off, washed, and dried for reuse. The separation fluid comprises water and butyl diglycol.

A method for processing a transparent mother sheet includes forming one or more closed contours in the transparent mother sheet that each define a perimeter of a transparent article. Forming each of the one or more closed contours includes directing a pulsed laser beam into the transparent mother sheet to produce defect within the transparent mother sheet and translating the transparent mother sheet and the pulsed laser beam relative to each other thereby laser forming defects along the one or more closed contours. The method further includes separating a portion of the transparent mother sheet along the closed contours, thereby forming one or more transparent articles, where the transparent articles are frictionally engaged with a frame portion of the transparent mother sheet, applying material to a surface the transparent articles, and releasing the transparent articles from frictional engagement with the frame portion.

A laminated includes two bent glass substrates, a polymer interlayer between the glass substrates, and a notch or orifice cut in an entire thickness of the glazing. The glazing includes a border of compressive edge stresses obtained by general controlled cooling of the substrates in a paired state so that compressive stresses are generated at the border, and a local compression zone, different from the border, and obtained by local controlled cooling of a local area of a main surface of the glazing so that compressive stresses are generated in theid local compression zone. The notch or orifice is located in the local compression zone and made in the substrates in a paired state after forming the local compression zone so that cut contours of the substrates in the notch or orifice have a perfect superposition. The compressive edge stresses of the cut contours are greater than 4 MPa.

Method of processing a panel of multilayer tempered glass comprising the steps of: providing a panel of multilayer tempered glass having at least a first and a second plate of tempered glass and an intermediate layer of bonding material interposed between the first and the second sheet of glass to make firmly join together the first and the second glass plate; breaking the first and the second plate of tempered glass so that the panel can be bent; bending the panel until reaching a desired shape in which both said first plate and said second plate are bent; applying to said first plate and to said second plate a hardening substance adapted to stabilize the panel into said desired shape.

A method of shaping a laminated glass structure includes providing the laminated glass structure comprising a flexible glass sheet having a thickness of no greater than about 0.3 mm laminated to a non-glass substrate by an adhesive layer. The flexible glass structure and adhesive layer are ground using a first tool to remove glass material. The non-glass substrate is cut with a second tool different from the first tool through a kerf formed through the flexible glass structure thereby forming a shaped laminated glass structure. A glass edge strength of a cut edge of the shaped laminated glass structure is at least about 20 MPa.

A method of field shaping a laminated glass structure is provided. The method includes providing the laminated glass structure comprising a flexible glass sheet having a thickness of no greater than about 0.3 mm laminated to a non-glass substrate by an adhesive material. The laminated glass structure is field cut using a handheld power tool thereby forming a shaped laminated glass structure. An edge strength of a cut edge of the shaped laminated glass structure at least about 20 MPa.

A method for manufacturing a laminated glass panel, which includes at least two glass substrates and at least one intermediate layer made of a polymeric material arranged between the substrates, the method including in the following order: the bending of the substrates; the controlled cooling of the substrates; and the formation of a laminated assembly that includes the substrates and the intermediate layer; the cutting of the laminated assembly straight through the entire thickness thereof along a line on one of the main surfaces thereof, the controlled cooling including general controlled cooling and local controlled cooling of an area that includes the cutting line, the local controlled cooling being faster than the general controlled cooling.

A method for manufacturing dished laminated glazing including two sheets of glass, a separator layer made of polymer material arranged between the sheets of glass, and an electrical conductor, the method including the simultaneous thermal dishing of the sheets of glass in the paired state followed by their cooling and then the assembly of the laminated glazing by bonding of the sheets of glass to the separator layer on either side thereof, the cooling including a controlled cooling of the sheets of glass in the paired state, the controlled cooling including a general controlled cooling and a local controlled cooling of a cutting zone, the local controlled cooling being faster than the general controlled cooling, a cutting of one of the sheets of glass along a cutting line in the cutting zone to form a holed zone, the electrical conductor being placed between the sheets of glass and exiting from the laminated glazing through the holed zone.

A method and a device for cutting a laminate including at least one glass layer with a thickness less than or equal to 0.3 mm and including at least one polymeric layer are disclosed. The method includes generating a surface scratch on a first surface of the glass layer, wherein the scratch, starting from a lateral edge, extends along a cutting line. The method further includes moving a first laser beam, starting from the scratch, across the first surface along the cutting line. The method also includes cooling the glass layer along the cutting line, wherein the glass layer breaks along the cutting line The polymeric layer is severed by moving a second laser beam along the cutting line. The device includes means for cutting the laminate according to the disclosed method.

A method for processing a transparent mother sheet includes forming one or more closed contours in the transparent mother sheet that each define a perimeter of a transparent article. Forming each of the one or more closed contours includes directing a pulsed laser beam into the transparent mother sheet to produce defect within the transparent mother sheet and translating the transparent mother sheet and the pulsed laser beam relative to each other thereby laser forming defects along the one or more closed contours. The method further includes separating a portion of the transparent mother sheet along the closed contours, thereby forming one or more transparent articles, where the transparent articles are frictionally engaged with a frame portion of the transparent mother sheet, applying material to a surface the transparent articles, and releasing the transparent articles from frictional engagement with the frame portion.