The invention provides automated spacer processing systems and methods. The systems and methods involve at least one robot arm that is configured to process spacers for multiple-pane insulating glazing units. In some embodiments, the systems also include an insulating glazing unit assembly line and a spacer conveyor system. Additionally or alternatively, the systems may include a sealant applicator.

An ultrasonic vibration welding apparatus includes an air cylinder that is coupled to an ultrasonic welding head unit and executes a pressurizing operation of pressurizing on the ultrasonic welding head unit, and a lifting-lowering servomotor that executes a lifting-lowering operation including a lowering operation of lowering the ultrasonic welding head unit and the air cylinder at once, as components separate from each other.

A housing assembly, a method for manufacturing the housing assembly, and an electronic device are provided according to the present disclosure. The housing assembly includes a housing body and a flexible film layer. The housing body has a bottom portion and at least one side wall connected with an outer edge of the bottom portion, and each of the at least one side wall and the bottom portion cooperatively define a bending angle larger than 70 degrees. The flexible film layer is disposed on a first surface of the housing body, and the flexible film layer has an elongation at break higher than or equal to 150%.

The invention provides automated spacer processing systems and methods. The systems and methods involve at least one robot arm that is configured to process spacers for multiple-pane insulating glazing units. In some embodiments, the systems also include an insulating glazing unit assembly line and a spacer conveyor system. Additionally or alternatively, the systems may include a sealant applicator.

Methods for preparing multi-layer optical laminates include placing an optical film that is free form an adhesive layer between first and second glass substrates that are free of an adhesive layer, placing this laminate under vacuum, and then heating the laminate under pressure to a temperature above the softening temperature of the optical film. The glass substrates are free of an adhesive layer but may include a silane surface treatment. The resulting multi-layer laminate is optically clear and does not show scattering of reflected light by the optical film.

Disclosed are UV curable adhesive compositions and methods to adhere polycarbonate substrates containing UV absorbers to glass for use in ophthalmic lenses.

A method of forming a bond between substrates and manipulating the bond comprises: emitting a first laser energy onto a strip of an absorption material disposed between a first substrate and a second substrate until the strip diffuses into the first substrate and the second substrate resulting in workpiece with a bond between the first substrate and the second substrate; emitting a second laser energy through the workpiece at the bond to create a fault line through the bond, the first substrate, and the second substrate, the second laser energy provided by an approximated Bessel beam, the approximated Bessel beam incident upon the bond having a diameter that is greater than a width of the bond; and repeating emitting the second laser energy step along a length of the bond to create a series of fault lines through the bond, the series of fault lines forming a contour.

A method of manufacturing a display device includes: preparing a cover window including a bent part on a side surface thereof, and a guide film including a surface on which a display panel and an adhesive layer are arranged; arranging the cover window and the guide film in a face-to-face manner such that the adhesive layer faces the cover window; seating the guide film onto a seating pad of a first jig; pre-forming the display panel by bringing opposite ends of the guide film into close contact with opposite side surfaces of the seating pad using a pair of push members; and joining the display panel with the cover window by bringing the adhesive layer into contact with the cover window.

A process for manufacturing a micro-fluidic device, the device including a substrate made of thermoplastic polymer having a face called the upper face and a first micro-fluidic circuit that includes at least one aperture that opens onto the upper face, and a component bearing pads arranged to become anchored in the substrate on the periphery of the aperture, the process including the following steps: heating so that the anchoring pads of the component reach a temperature at least equal to the glass-transition temperature of the substrate; fastening the component to the substrate by embedding then anchoring its pads in the substrate.

A material system may include: an aluminum layer; a glass composite layer adjacent to the first aluminum layer; and a carbon composite layer adjacent to the first glass composite layer, and opposite to the first aluminum layer. A method of manufacturing a material system may include: stacking an aluminum layer, glass composite layer that may include thermoplastic prepreg plies, and carbon composite layer so that the aluminum layer is adjacent to the glass composite layer, and the glass composite layer is adjacent to the carbon composite layer; and consolidating the thermoplastic prepreg plies to soften the aluminum layer. A method of manufacturing a material system may include: stacking an aluminum layer, glass composite layer that comprises thermoplastic resin, and carbon composite layer so that the glass composite layer is between the aluminum and carbon composite layers; and adjusting temperature and pressure to consolidate the stack.