A casing structure of electronic device including a metal base plate, a transparent cathodic electrodeposition paints layer, and a transparent paints coating layer is provided. The metal base plate has brushed texture and high gloss surface. The transparent cathodic electrodeposition paints layer is disposed on the base metal base plate. The transparent paints coating layer is disposed on the transparent cathodic electrodeposition paints layer. A manufacturing method of casing structure of electronic device is also provided.

A casing structure of electronic device including a metal base plate, a transparent cathodic electrodeposition paints layer, and a transparent paints coating layer is provided. The metal base plate has brushed texture and high gloss surface. The transparent cathodic electrodeposition paints layer is disposed on the base metal base plate. The transparent paints coating layer is disposed on the transparent cathodic electrodeposition paints layer. A manufacturing method of casing structure of electronic device is also provided.

A process for producing an optical element, which may be suitable for use in an infrared camera with sharp surface features and low emissivity surfaces, including the steps of casting the element in the desired shape in a zinc alloy, deburring the zinc alloy element with a thermal deburring operation, and coating the deburred zinc alloy element with an electrocoating operation.

A process for producing an optical element, which may be suitable for use in an infrared camera with sharp surface features and low emissivity surfaces, including the steps of casting the element in the desired shape in a zinc alloy, deburring the zinc alloy element with a thermal deburring operation, and coating the deburred zinc alloy element with an electrocoating operation.

A method is provided for electrodepositing a coating a conductive workpiece. The method provides for individually switching on or off electrodes both interior to and exterior to the workpiece so as to control the deposition of the coating material on the interior surface and the exterior surface of the workpiece. Further, an electrode having insulating positioners can be utilized to provide for better centering of the electrode in the interior of the workpiece.

A method is provided for electrodepositing a coating a conductive workpiece. The method provides for individually switching on or off electrodes both interior to and exterior to the workpiece so as to control the deposition of the coating material on the interior surface and the exterior surface of the workpiece. Further, an electrode having insulating positioners can be utilized to provide for better centering of the electrode in the interior of the workpiece.

Methods, systems, and kits provide robust and biologically active coatings for implanted medical devices. The methods are based on electrostatic attraction between a conductive or non-conductive material surface on the medical device and a coating material including a charged biopolymer or pharmaceutical agent. Surface charge is induced or enhanced in the conductive or non-conductive material using a physical method. The methods are applicable to a wide variety of conductive or non-conductive substrate materials and coatings containing any of a wide variety of biological molecules and pharmaceutical agents.

Methods, systems, and kits provide robust and biologically active coatings for implanted medical devices. The methods are based on electrostatic attraction between a conductive or non-conductive material surface on the medical device and a coating material including a charged biopolymer or pharmaceutical agent. Surface charge is induced or enhanced in the conductive or non-conductive material using a physical method. The methods are applicable to a wide variety of conductive or non-conductive substrate materials and coatings containing any of a wide variety of biological molecules and pharmaceutical agents.

A substrate with a Micro-Arc Oxidation (MAO) layer or an electrophoretic deposition (ED) layer on a first side of the substrate and an electrically insulating layer on a second side of the substrate.

A substrate with a Micro-Arc Oxidation (MAO) layer or an electrophoretic deposition (ED) layer on a first side of the substrate and an electrically insulating layer on a second side of the substrate.