Some embodiments of present disclosure are directed to a micro-perforated glass or glass-ceramics laminate, comprising a first substrate laminated to a second substrate by a first polymer interlayer, wherein the first and the second substrates are independently selected from glass or glass-ceramics, and a plurality of micro-perforations, each of the plurality of micro-perforations extending through the first substrate, the first polymer interlayer, and the second substrate. Some embodiments are directed to methods of forming such micro-perforated glass or glass-ceramics laminates.

An insulating glazing unit may be configured to provide both visible transparency and bullet-resistance. The bullet resistant properties of the unit may be achieved through the combination and coordination of different materials forming the panes of the unit. For example, the insulating glazing unit may include multiple laminate panes separated by a spacer. Each laminate pane may include at least two transparent rigid substrates joined by a layer of laminate material. The laminate material used in one laminate pane may be different than the laminate material used in another pane. For example, one pane may utilize a laminate material that is soft and flexible. This may help absorb and dissipate the impact of a projectile. By contrast, another laminate pane may utilize a laminate material that is stiff and rigid. This may help provide a final stopping force to a projectile.

The present disclosure relates to a method of providing a laminated vacuum insulated glass (VIG) unit (1), wherein the method comprises: providing a lamination assembly (10) comprising a vacuum insulated glass (VIG) unit (11) comprising at least two glass sheets (11a, 11b) separated by a plurality of support structures (12) distributed in a gap (13) between the glass sheets (11a, 11b), and a lamination layer (2) arranged between one of the glass sheets (11a, 11b) of the vacuum insulated glass (VIG) unit (11) and a further sheet (3). The further sheet (3) may be subjected to a first heating temperature (T1) by means of a first heating arrangement (9a), and the glass sheet (11a) of the vacuum insulated glass (VIG) unit (11) facing away from the further sheet (3) may be subjected to a second heating temperature (T2) by means of a second heating arrangement (9b), wherein the first heating temperature (T1) is higher than the second heating temperature (T2). The disclosure additionally relates to a system (100) for providing laminated vacuum insulated glass (VIG) units (1), and use of such a system.

A glass laminate (100) including first and second glass layers (102,104), a reflective film (110) having opposed first and second major surfaces and disposed between the first and second glass layers (102,104) with the first and second major surfaces facing the respective first and second glass layers (102,104), a first adhesive layer (117) disposed between and bonding together the first glass layer (102) and the reflective film (110), and a second adhesive layer (119) disposed between and bonding together the second glass layer (104) and the reflective film (110) is described. The second adhesive layer (119) is thicker than the first adhesive layer (117) such that the first major surface of the reflective film (110) is separated from an outermost major surface of the first glass layer (102) by distance d1, the second major surface of the reflective film (110) is separated from an outermost major surface of the second glass layer (104) by a distance d2, and 0.05<d1/d2<0.9.

Electrochromic device laminates and their method of manufacture are disclosed.

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 resin composition of the present invention is a resin composition comprising an acrylic-based polymer (A) and a urethane polymer (B), in which the acrylic-based polymer (A) is a polymer of a monomer component comprising an acrylic-based monomer (A1) having at least one functional group (X) selected from the group consisting of a hydroxy group, a carboxy group, a thiol group, an amino group, a group having an ether bond, a group having a urethane bond and a group having an amide bond.

A solar radiation shielding laminated structure, having high visible light transmission property and solar radiation shielding property, low haze value, and high environmental stability with inexpensive production cost, using solar radiation shielding fine particles having high visible light transmission property and excellent solar shielding property and weather resistance, and provides a solar radiation shielding laminated structure in which an interlayer is sandwiched between two laminated sheets; the interlayer having, as an intermediate film, one or more kinds selected from a resin sheet containing solar radiation shielding fine particles and a resin film containing solar radiation shielding fine particles, the laminated sheets being selected from a sheet-glass not containing solar radiation shielding fine particles and a resin board not containing solar radiation shielding fine particles; wherein the solar radiation shielding fine particles are solar radiation shielding fine particles containing calcium lanthanum boride fine particles represented by general formula CaxLa1-xBm.

A glass laminate includes a non-glass substrate with a first surface and a second surface opposite the first surface. A glass sheet is laminated to the first surface of the non-glass substrate. A barrier film is laminated to the second surface of the non-glass substrate and includes a first surface adjacent to the non-glass substrate, a second surface opposite the first surface. A thickness of the barrier film can be at most about 0.5 mm. The second surface of the barrier film can define an outer surface of the glass laminate. The barrier film can be a multi-layer barrier film with a metal layer and a polymer layer. An absolute value of a flatness of the glass laminate determined according to European Standard EN 438 after exposure to 23° C. and 90% relative humidity for 7 days can be at most about 3 mm/m.

A multilayer interlayer containing a specified ionomer skin layer and an acoustic damping intermediate layer, and laminate containing such interlayer are provided, wherein the laminate has a desirable combination of sound insulating, flexural strength and optical properties suitable for use in transportation and architectural end uses.