A method for producing polymer coated steel sheet for 3-piece cans and 3-piece cans produced thereof.

An electronic device display may have a color filter layer and a thin film transistor layer. A layer of liquid crystal material may be interposed between the color filter layer and the thin film transistor layer. A layer of polarizer may be laminated onto the surface of the color filter layer. Laser trimming may ensure that the edges of the polarizer are even with the edges of the color filter layer. The thin film transistor layer may have an array of thin film transistors that control pixels of the liquid crystal material in the display. Driver circuitry may be used to control the array. The driver circuitry may be encapsulated in a planarized encapsulant on the thin film transistor layer or may be mounted to the underside of the color filter layer. Conductive structures may connect driver circuitry on the color filter layer to the thin film transistor layer.

A system for applying thermal interface materials to components includes a supply of thermal interface material and a die. The die is operable for pushing against and/or removing a portion of the thermal interface material that is between the die and a corresponding one of the components. The portion of the thermal interface material is removed from the supply and applied to the corresponding one of the components.

Heat sink and method of manufacturing a graphene based heat sink, the method comprising: providing a first and second graphene film; arranging a layer of nanoparticles on a surface of the first and second graphene film to improve an adhesion strength between the graphene films; attaching the second graphene film to the first graphene film by means of an adhesive and the layer of nanoparticles; forming a laminated graphene film comprising a number of graphene film layers by repeating the steps, wherein the laminated graphene film is formed to have an anisotropic thermal conductivity; assembling a plurality of laminated graphene films by applying pressure and heat to cure the adhesive to form a graphene block; and removing selected portions of the graphene block to form a heat sink comprising fins extending from a base plate of the heat sink.

Method of manufacturing a vertically aligned laminated graphene based thermally conductive film. The method comprising: attaching first and second graphene film using a layer of nanoparticles and an adhesive; forming a layered film comprising a predetermined number of graphene film layers by repeating the steps of arranging a layer of nanoparticles, arranging an adhesive and attaching a graphene film; and laminating the layered film by applying pressure and heat to cure the adhesive, thereby forming a laminate film; cutting the laminate film at an angle in relation to a surface plane of the film to form the vertically aligned laminated graphene based thermally conductive film.

Inflatable medical devices and methods for making and using the same are disclosed. The inflatable medical devices can be medical balloons. The balloons can be configured to have a through-lumen or no through-lumen and a wide variety of geometries. The device can have a high-strength, non-compliant, fiber-reinforced, multi-layered wall. The inflatable medical device can be used for angioplasty, kyphoplasty, percutaneous aortic valve replacement, or other procedures described herein.

An electronic device is disclosed, which includes: a panel, including: a first substrate; a second substrate, disposed opposite to the first substrate; a first protection element, disposed on a surface of the first substrate away from the second substrate; and a first polarizer, disposed on the first protection element.

A Smart Patch comprising a label layer, an adhesive layer, a release liner layer and a RFID inlay, wherein the release liner comprises a separable inner release liner portion and a separable outer release liner portion; and the RFID inlay is adhered to a back surface of the inner release liner portion. The Smart Patches for uses including mounting to tires and other rubber materials. Methods of manufacturing including subjecting a release liner of the label to a die cut slightly larger than the size of an intended RFID inlay to form the separable inner release liner portion and outer release liner portion and applying a RFID inlay to a back surface of a release liner within the die cut inner release liner portion.

A method for manufacturing an electronic device is disclosed, which includes the following steps: assembling a first mother substrate and a second mother substrate; disposing a first protection element on a surface of the first mother substrate away from the second mother substrate; disposing a first mother polarizer on the first protection element; and processing an assembly of the first mother substrate, the second mother substrate, the first protection element, and the first mother polarizer into a plurality of panels.

Inflatable medical devices and methods for making and using the same are disclosed. The inflatable medical devices can be medical balloons. The balloons can be configured to have a through-lumen or no through-lumen and a wide variety of geometries. The device can have a high-strength, non-compliant, fiber-reinforced, multi-layered wall. The inflatable medical device can be used for angioplasty, kyphoplasty, percutaneous aortic valve replacement, or other procedures described herein.