| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 428420000 | Including interfacial reaction product of adjacent layers | 9 |
| 20080318056 | Method for Making a Composite Product, and a Composite Product - Fibre material and at least one plastic material is extruded in such a way that a composite product ( | 12-25-2008 |
| 20100173165 | Intercalated Superlattice Compositions and Related Methods for Modulating Dielectric Property - Compositions, methods of using inorganic moieties for dielectric modulation, and related device structures. | 07-08-2010 |
| 20130034737 | PRODUCTION METHOD OF CURED MULTILAYER SHEET AND CURED MULTILAYER SHEET - Disclosed is a cured multilayer sheet production method, comprising adjacently laminating a first uncured layer formed by a first curable resin and a second uncured layer formed by a second curable resin to form a laminated body, wherein the first curable resin contains a first monomer or partial polymer thereof, and an immiscible substance, the second curable resin contains a second monomer and polymer, the first monomer concentration in the first curable resin is higher than the polymerizable monomer concentration in the second curable resin, wherein in the laminating step, the immiscible substance is eccentrically distributed on or near an interface on the side opposite to the second uncured layer, and thereafter curing the layers, so that a cured multilayer sheet, wherein a substance different from a polymer cured layer is eccentrically located on the surface of the polymer cured layer, is produced at high productivity. | 02-07-2013 |
| 20130065060 | GRAPHENE PAPER WHICH REDUCED GRAPHENE OXIDE LAYERS AND COATING LAYERS ARE STACKED IN SEQUENCE AND PREPARATION METHOD THEREOF - The present disclosure relates to a graphene paper which reduced graphene oxide layers and coating layers are stacked in sequence. The graphene paper prepared according to a preparation method of the present invention has excellent electrical conductivity and mechanical properties, and can be economically prepared in large-sized graphene paper, therefore may be efficiently applied to various electrical devices such as thin-film electrodes, flexible electrodes, super capacitors, semiconductor insulating layer reinforcements and TFT semiconductor layer-electrodes, and the like. | 03-14-2013 |
| 20130089744 | Chemically-welded optical devices - Chemically-welded optical devices and associated methods for chemically welding optical devices are disclosed herein. Such optical devices may be used in display systems, and may include subcomponents comprising one or more optical films employed for polarization manipulation, as well as a substrate for protecting the optical film(s). An optical film may be chemically welded directly to the substrate using a solvent, and any additional optical films may be chemically welded to a prior optical film previously welded to the substrate. The chemical welding process of the present disclosure may include applying the solvent on the optical film in order to partially dissolve the surface of the optical film prior to adhesion to the substrate. Macromolecules on the dissolved surface of the optical film may be in a loosened state and may be realigned when the solvent evaporates. | 04-11-2013 |
| 20130177770 | BONDING METHOD, BONDABILITY IMPROVING AGENT, SURFACE MODIFICATION METHOD, SURFACE MODIFYING AGENT, AND NOVEL COMPOUND - To provide a technique by which an —OH group can be effectively formed on a material surface for the purpose of making the material suitable for bonding (for example, for molecular bonding) that utilizes a chemical reaction (chemical binding). [Solution] A bonding method for bonding a substrate A and a substrate B, which comprises: a step for applying an agent that contains the compound (α) described below on the surface of the substrate A; a step for arranging the substrate B so as to face the compound (α) that is present on the surface of the substrate A; and a step for integrally bonding the substrate A and the substrate B by applying a force onto the substrate A and/or the substrate B. The compound (α) is a compound that has an OH group or an OH-forming group, an azide group and a triazine ring in each molecule, and the substrate A is configured using a polymer. | 07-11-2013 |
| 20130302622 | Layered Bonded Structures Formed From Reactive Bonding of Zinc Metal and Zinc Peroxide - A system, method, and apparatus for layered bonded structures formed from reactive bonding between zinc metal and zinc peroxide are disclosed herein. In particular, the present disclosure teaches a layered bonded structure wherein two structures are bonded together with a layer including zinc oxide. The zinc oxide is formed through a method that includes processing the two structures by contacting the structures under pressure and applying heat to the structures to promote a reaction with zinc peroxide and zinc metal on one or both of the two structures. | 11-14-2013 |
| 20140170419 | METHOD OF COATING A CHROME PLATED PART - One variation may include a method including providing a substrate having a layer comprising chrome thereon, the chrome having exposed surface; exposing the layer comprising chrome to a gas comprising ionized oxygen to activate the exposed surface of the chrome to provide an activated surface; applying a coating over the activated surface so that the coating is adhered to the layer comprising chrome, and wherein the coating is at least one of a primer, clear coat, tinted clear coat or opaque paint. | 06-19-2014 |
| 20160160072 | PHOTO-ACTIVATED HYDROPHILIC COATINGS AND METHODS FOR THEIR PREPARATION AND USE - Disclosed herein are coating compositions and methods of making and using the same. The coating composition includes a first polymer having at least one positively charged group; a second polymer having at least one negatively charged group; and at least one protecting group contacting the positively charged group of the first polymer, the negatively charged group of the second polymer, or both. The protecting group is configured to be removed by photocleavage to form a salt bridge between the positively and negatively charged groups. The coating composition may be hydrophilic when the salt bridge is formed. | 06-09-2016 |
