| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 204484000 | Plural coating operations | 15 |
| 20110168559 | Nanoscale Surface Plasmonics Sensor with Nanofluidic Control - A microfluidically-controlled transmission mode nanoscal surface plasmonics sensor device comprises one or more arrays of aligned nanochannels in fluid communication with inflowing and outflowing fluid handling manifolds that control the flow of fluid through the array(s). Fluid comprising a sample for analysis is moved from an inlet manifold, through the nanochannel array, and out through an exit manifold. The fluid may also contain a reagent used to modify the interior surfaces of the nanochannels, and/or a reagent required for the detection of an analyte. | 07-14-2011 |
| 204485000 | Using mask | 2 |
| 20140318967 | Damascene Template for Directed Assembly and Transfer of Nanoelements - Damascene templates have two-dimensionally patterned raised metal features disposed on an underlying conductive layer extending across a substrate. The templates are topographically flat overall, and the patterned conductive features establish micron-scale and nanometer-scale patterns for the assembly of nanoelements into nanoscale circuits and sensors. The templates are made using microfabrication techniques together with chemical mechanical polishing. These templates are compatible with various directed assembly techniques, including electrophoresis, and offer essentially 100% efficient assembly and transfer of nanoelements in a continuous operation cycle. The templates can be repeatedly used for transfer of patterned nanoelements thousands of times with minimal or no damage, and the transfer process involves no intermediate processes between cycles. The assembly and transfer processes employed are carried out at room temperature and pressure and are thus amenable to low cost, high-rate device production. | 10-30-2014 |
| 20160111608 | THIN FILM WAVELENGTH CONVERTERS AND METHODS FOR MAKING THE SAME - Thin film wavelength converters and methods for making the same are disclosed. In some embodiments, the thin film converters include a first thin film layer of first wavelength conversion material, a conductive layer, and a second thin film layer of a second wavelength conversion material. In one embodiment, a photoresist mask is applied to the conductive layer to form a pattern of by which the second wavelength conversion material may be applied by electrophoretic deposition to the exposed regions of the surface of the conductive layer. | 04-21-2016 |
| 204486000 | Including nonelectrophoretic coating | 12 |
| 20110094885 | Flexible Drug Delivery Chip, its Fabrication Method and Uses Thereof - Nanodevice and method for in vivo monitoring and release of drugs are provided. The disclosed nanodevice is characterized in having a drug-loaded nanosphere that is capable of releasing the encapsulated drugs upon magnetically stimulation. The nanodevice may also be used as a contrast agent for in vivo imaging and monitoring the concentration and distribution of the released drugs and/or active compounds injected separately into a target site of a subject. | 04-28-2011 |
| 20120181177 | METHOD OF PREPARING DOUBLE-LAYER ANTIMICROBIAL COATING - A method of a preparing double-layer antimicrobial coating comprises: placing a plastic substrate into a PVD vacuum equipment for a vacuum process; rinsing and activating the substrate when the vacuum level reaches 10 | 07-19-2012 |
| 20130146460 | RESIN BASED POST RINSE FOR IMPROVED THROWPOWER OF ELECTRODEPOSITABLE COATING COMPOSITIONS ON PRETREATED METAL SUBSTRATES - Disclosed are methods for treating metal substrates, including ferrous substrates, such as cold rolled steel and electrogalvanized steel. The methods include (a) contacting the substrate with a pretreatment composition including a group IIIB or IVB metal and an electropositive metal, (b) contacting the substrate with a post rinse composition and (c) electrophoretically depositing an electrodepositable coating composition to the substrate, wherein the post rinse composition improves the throwpower of the subsequently applied electrodepositable coating composition. The present invention also relates to coated substrates produced thereby. | 06-13-2013 |
| 20130233710 | METHOD OF MANUFACTURING LIGHT EMITTING DIODE PACKAGING LENS AND LIGHT EMMITING DIODE PACKAGE - A method of manufacturing light emitting diode packaging lens and packages made by using the method are disclosed in the present invention. By using electrophoretic deposition, one or more layers of phosphors are coated onto one surface of a cup which has a curved portion. The cup is used for the packaging lens. Thickness of phosphor layer can be controlled and distribution of phosphor particles is uniform. Therefore, light emitting diode packages with the lens can be a uniform light source. | 09-12-2013 |
| 20130233711 | RESIN BASED POST RINSE FOR IMPROVED THROWPOWER OF ELECTRODEPOSITABLE COATING COMPOSITIONS ON PRETREATED METAL SUBSTRATES - Disclosed are methods for treating metal substrates, including ferrous substrates, such as cold rolled steel and electrogalvanized steel. The methods include (a) contacting the substrate with a pretreatment composition including a group IIIB or IVB metal and an electropositive metal, (b) contacting the substrate with a post rinse composition and (c) electrophoretically depositing an electrodepositable coating composition to the substrate, wherein the post rinse composition improves the throwpower of the subsequently applied electrodepositable coating composition. The present invention also relates to coated substrates produced thereby. | 09-12-2013 |
| 20140202860 | System and method for integrating a single nanowire into a nanocircuit - A non-volatile bistable nano-electromechanical switch is provided for use in memory devices and microprocessors. The switch employs carbon nanotubes as the actuation element. A method has been developed for fabricating nanoswitches having one single-walled carbon nanotube as the actuator. The actuation of two different states can be achieved using the same low voltage for each state. | 07-24-2014 |
| 20150315718 | METAL PRETREATMENT MODIFICATION FOR IMPROVED THROWPOWER - A pretreatment composition and a method for pretreating a metal substrate is disclosed. The method comprises:
| 11-05-2015 |
| 204487000 | With heat treatment of a coated layer (e.g., curing, sintering, etc.) | 5 |
| 20090166204 | Corrosion-resistant layered coatings - In general, the present invention provides coating systems and processes for applying a selected coating system on a metallic substrate. The coating system includes two or more coating layers. A first layer comprises a MCrAl(Y, Hf)-type coating. The MCrAl(Y, Hf) coating is overlaid with a second coating composition that includes a metallic composition different from the MCrAl(Y, Hf) coating composition and includes one or more of: a platinum, silicon containing composition; a platinum, silicon, aluminum containing composition; a platinum, silicon, chromium containing composition; an aluminum, silicon containing composition; and an aluminum, silicon, chromium containing composition; each optionally combined with one or more of chromium, hafnium, lanthanum, manganese, yttrium and mixtures of these metals. Additionally the platinum in the metallic compositions can be exchanged in whole or in part by another noble metal. The resulting coating composition is subsequently heat treated to provide a diffused multilayer corrosion-resistant coating. | 07-02-2009 |
| 20090211909 | MARKED PRECOATED MEDICAL DEVICE AND METHOD OF MANUFACTURING SAME - A method of manufacturing a coated medical device, includes applying a first low-friction coating to a surface of the medical device. The first low-friction coating includes a first colored pigment, such as a relatively light colored pigment. After applying the first low-friction coating, a suitable laser and laser energy is selectively applied to different areas of the coated medical device. The laser ablates or removes the first low-friction coating (at the different areas of the medical device) to leave the bare metal substrate of the medical device exposed. After selectively removing one or more portions of the first low-friction coating, a second low-friction coating is applied to the exposed bare metal substrate of the medical device and suitably cured. The second low-friction coating includes a second colored pigment, such as a relatively dark colored pigment, wherein the second colored pigment contrasts the first colored pigment of the first low-friction coating. | 08-27-2009 |
| 20120055796 | METHOD OF FABRICATING ELECTRODE STRUCTURES ON SUBSTRATE - Methods for fabricating electrode structures on a substrate are presented. The fabrication method includes providing a substrate with a patterned metal layer thereon, defining an electrode area. A passivation glue is formed on the patterned metal layer. An electrode layer is formed in the electrode area. A filling process is performed to deposit nano metal oxides on the electrode layer to extensively fill the entire electrode area. | 03-08-2012 |
| 204488000 | Organic (e.g., curing thermoset resin, etc.) | 2 |
| 20120160685 | COATING LINE AND PROCESS FOR FORMING A MULTILAYER COMPONENT COATING ON A SUBSTRATE - A process for forming a multilayer composite coating on a substrate is provided. The process includes forming an electrodeposition coating layer on the substrate by electrodeposition of a curable electrodepositable coating composition over at least a portion of the substrate. Optionally, the coated substrate is heated to a temperature and for a time sufficient to cure the electrodeposition coating layer. A basecoating layer is formed on the electrodeposition coating layer by depositing an aqueous curable basecoating composition directly onto at least a portion of the electrodeposition coating layer. Optionally, the basecoating layer is dehydrated. A top coating layer is formed on the basecoating layer by depositing a curable top coating composition which is substantially pigment-free directly onto at least a portion of the basecoating layer. The top coating layer, the basecoating layer, and, optionally, the electrodeposition coating layer are cured simultaneously. | 06-28-2012 |
| 20160024661 | Surface Processing Method For A High Hardness And Abrasion Resistant Zinc Alloy Surface Of Imitation Plating Hexvalent Chromium - A surface processing method for a high hardness and abrasion resistant zinc alloy surface of imitation plating hexavalent chromium, includes following steps. Perform polishing for surface of zinc alloy workpiece, and leave it to dry; place the dried up workpiece into Hydrofluoric Acid solution to raise adhesion; wash the activated workpiece clean with pure water, and then place it in a silane oxide solution, to process it into silane conversion film; place the workpiece into an electrophoresis solution to perform electrophoresis, to achieve an electrophoresis application layer; use an UF solution to wash the workpiece; perform pre-drying for the workpiece; perform UV curing for the workpiece ; hang the workpiece in a PVD furnace, perform sputtering of chromium, to form a metal-ceramic composite film; and perform PVD on surface of the workpiece, to deposit a layer of transparent DLC film on the workpiece. | 01-28-2016 |
