子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | LAYER SYSTEM WITH A STRUCTURED SUBSTRATE SURFACE AND PRODUCTION PROCESS | US14354571 | 2012-09-14 | US20140302282A1 | 2014-10-09 | Alessandro Casu; Oliver Lusebrink |
| A layer system is provided having at least two layers, an inner layer on a boundary surface of a substrate, wherein the inner layer has a certain roughness in a region of the surface to an outer layer due to a coating processes, wherein a roughness of the boundary surface of the substrate is set in a targeted manner, or the boundary surface is machined, after it has been produced, such that the roughness of the boundary surface of the substrate has peaks and troughs that are at least 20% greater than the roughness of the interface if peaks and troughs were not to be present. As a result of the structured surface of the substrate, this roughness becomes positioned on an interface of the layers located above, and the adhesion of the layers to one another is thereby improved. | ||||||
| 122 | CERAMIC POWDERS AND METHODS THEREFOR | US13769538 | 2013-02-18 | US20140235426A1 | 2014-08-21 | Surinder Singh Pabla; Joshua Lee Margolies; Padmaja Parakala |
| A ceramic powder and method of forming the ceramic powder capable of being used in coatings to allow components to survive in high temperatures environments, such as the hostile thermal environment of a gas turbine engine. The ceramic powder includes powder particles each having an inner core formed of a first material and an outer region formed of a second material. The inner core has a lower thermal conductivity than the outer region, and the outer region is more erosion resistance relative to the inner core. | ||||||
| 123 | PROCESS OF FABRICATING A SHIELD, PROCESS OF PREPARING A COMPONENT, AND EROSION SHIELD | US13630644 | 2012-09-28 | US20140093365A1 | 2014-04-03 | Theodore William FANDREI, II |
| A process of fabricating a shield, a process of preparing a component, and an erosion shield are disclosed. The process of fabricating the shield includes forming a near-net shape shield. The near-net shape shield includes a nickel-based layer and an erosion-resistant alloy layer. The nickel-based layer is configured to facilitate secure attachment of the near-net shaped to a component. The process of preparing the component includes securing a near-net shape shield to a substrate of a component. | ||||||
| 124 | Process for controlling coating deposition | US13392237 | 2010-09-02 | US08673389B2 | 2014-03-18 | Markku Rajala; Juha Tikkanen |
| A method and apparatus for controlling a vapor deposition based coating process, including monitoring ultrafine particles, and adjusting at least one process parameter based on the monitoring. During at least one stage of the coating deposition process, at least one of the coating precursors includes a gas, a vapor, or an aerosol. | ||||||
| 125 | COATING AND METHODS THEREOF | US13851046 | 2013-03-26 | US20130260047A1 | 2013-10-03 | Rajan BAMOLA |
| The present invention discloses a nano-crystalline ceramic structure coat of resistive material and a method thereof for a substrate. The coating method includes the use of a resistive material solution diluted to a composition that is capable of atomization into atomized vapor particles, and conveyance of the atomized vapor particles onto a substrate, forming a conformal layer of substantially dehydrated compound. Further application of thermal energy consolidates the conformal layer into a coating of the nano-crystalline ceramic structure, with enhanced ceramic bonding with the substrate. | ||||||
| 126 | Method of making a heat exchange component using wire mesh screens | US12773606 | 2010-05-04 | US08506242B2 | 2013-08-13 | Antoine Corbeil; Gregoire Berube; Michel Houde; Eric Matte |
| A heat exchanger component is made by forming a wafer having a pair of opposed outer major faces with interstices between them from a stack of wire mesh screens. The outer major surfaces of the wafer are sealed by depositing a metal coating on them. The deposited metal coatings define between them a flow path for a heat exchange fluid extending through the interstices of the wafer. | ||||||
| 127 | Boron containing coating for neutron detection | US13228478 | 2011-09-09 | US08502157B2 | 2013-08-06 | James Michael Lustig; Jon Bennett Jansma |
| A neutron detector includes an exterior shell bounding an interior volume. The neutron detector includes at least a wall portion serving as a cathode. In one example the wall portion has microfeatures. The neutron detector includes a central structure located within the interior volume and serving as an anode. The neutron detector includes a boron coating on the wall portion. In on example, the boron coating is applied by an electrostatic spray process. In one example, the boron coating conforms to the microfeatures on the wall portion. In one example, the wall portion has a thickness of between 2 to 5 microns. The neutron detector includes an electrical connector operatively connected to the central structure for transmission of a signal collected by the central structure. An associated method provides for depositing the boron coating. | ||||||
| 128 | Thermal Metal Spraying Apparatus | US13538436 | 2012-06-29 | US20130000550A1 | 2013-01-03 | Theodore Robert Brown; John Graham |
| A thermal metal spraying apparatus for use with a thermal metal spraying torch for applying a metal coating to a workpiece through a torch spraying nozzle having a spraying orifice. The thermal metal spraying apparatus provides a substantially tubular shroud having a first end and a second end adaptable to concentrically receive the torch spraying nozzle. The shroud has an opening at the second end, wherein the opening is selectably alignable with the spraying orifice. A drive mechanism is connected to the shroud and is operable to translate the shroud between a first position, wherein the opening at the second end is not aligned with the spraying orifice, thereby preventing the spraying of the metal coating on the workpiece, and a second position, wherein the opening at the second end is aligned with the spraying orifice permitting the spraying of the metal coating toward the workpiece. | ||||||
| 129 | Spray cast mixed-material vehicle closure panels | US12240131 | 2008-09-29 | US08287966B2 | 2012-10-16 | Suresh Sundarraj; Arun M. Kumar; Anil K. Sachdev |
| Unitary closure panels for automotive vehicles may be formed to have regions of different materials by a spray casting process. Separate sprays of different materials, for example two different metal alloys, are applied to touching regions of a spray application surface. The separate sprays may be applied sequentially or simultaneously to the forming surface to coat the respective regions so that the regions are contiguous or overlapping and a unitary body is formed. The spray formed body may be compressed and trimmed between facing surfaces to form a vehicle closure panel of specified outline, curvature, thickness, and porosity. | ||||||
| 130 | Tube mill with in-line braze coating process | US11859895 | 2007-09-24 | US08272122B2 | 2012-09-25 | William E. Panthofer; Yoram Leon Shabtay |
| A tube mill apparatus and process for continuously forming and coating a tube with a braze alloy. The apparatus and process produce a continuously moving welded tube by continuously forming and welding a tubing material, after which the welded tube is passed through a sizing station to establish a desired outer shape and desired outer dimensions for the welded tube. The braze alloy is then deposited on a roughened surface of the welded tube that is clean and free of oils and coolants. The braze alloy is deposited with a wire arc spray gun that heats a wire of a metallic material and causes the heated metallic material to travel in a direction transverse to the direction of tube travel and deposit on the roughened surface of the tube to form an adherent layer of the braze alloy. Finally, any bow in the welded tube is removed as the tube travels away from the spray gun. | ||||||
| 131 | Anti-reflection plate and method for manufacturing anti-reflection structure thereof | US12343540 | 2008-12-24 | US08158211B2 | 2012-04-17 | Chih-Wei Chen; Chin-Jyi Wu; Wen-Tzong Hsieh; Wen-Tung Hsu; Chun-Hung Lin |
| A method for manufacturing an anti-reflection structure is provided. The method includes the following steps: First, a to-be-treated object is provided in a reactive area. Next, a plasma source is provided in the reactive area. Then, the plasma source is ionized to form plasma in atmospheric pressure. Next, the surface of the to-be-treated object is treated by plasma so as to form a plurality of micro-protuberances on the surface of the to-be-treated object. | ||||||
| 132 | COVALENTLY FUNCTIONALIZED PARTICLES FOR SYNTHESIS OF NEW COMPOSITE MATERIALS | US13312415 | 2011-12-06 | US20120077936A1 | 2012-03-29 | Richard B. Timmons; Dattatray Wavhal; Dhiman Bhattacharyya; Narayan Mukherjee |
| The present invention includes compositions and methods for synthesis of composite materials involving gas phase plasma polymerization to covalently plasma graft an organic molecule onto particles; covalently binding an organic monomer to the functionalized particles; and, polymerizing the organic monomers into hybrid polymer composite materials. | ||||||
| 133 | Covalently functionalized particles for synthesis of new composite materials | US12404172 | 2009-03-13 | US08088451B2 | 2012-01-03 | Richard B. Timmons; Dattatray Wavhal; Dhiman Bhattacharyya; Narayan Mukherjee |
| The present invention includes compositions and methods for synthesis of composite materials involving gas phase plasma polymerization to covalently plasma graft an organic molecule onto particles; covalently binding an organic monomer to the functionalized particles; and, polymerizing the organic monomers into hybrid polymer composite materials. | ||||||
| 134 | CERAMIC SURFACE COATINGS FOR DENTAL APPLICATIONS | US12894866 | 2010-09-30 | US20110183281A1 | 2011-07-28 | Peder Jensen |
| Disclosed herein are methodologies and compositions for coating materials, which can be used in a variety of dental applications. | ||||||
| 135 | Film forming apparatus and jetting nozzle | US11467039 | 2006-08-24 | US07866578B2 | 2011-01-11 | Motohiro Yasui; Jun Akedo |
| A film forming apparatus includes an aerosol generating section which generates an aerosol; a jetting nozzle having an internal passage formed therein and through which the aerosol flows, the internal passage having one end serving as a supply port of the aerosol and having other end serving as a jetting port of the aerosol; a narrowed channel which is provided in the internal passage and which has a channel area narrower than a channel area on an upstream of the narrowed channel; and a collision portion which is provided in the internal passage on a downstream of the narrowed channel, and against which a flow of the aerosol passed through the narrowed channel collides. Since the aggregated particles are crushed and supplied from the jetting nozzle in the form of fine particles, a thin and uniform film can be formed on the process-objective material. | ||||||
| 136 | TIRE VULCANIZING MOLD AND TIRE PRODUCED WITH THE TIRE VULCANIZING MOLD | US12842232 | 2010-07-23 | US20100282387A1 | 2010-11-11 | KARSTEN WENZEL |
| A tire vulcanizing mold has two or more mold segments with forming surfaces jointly defining the tread rubber profile of a tire to be vulcanized and with a surface area with elevations, such as webs, wherein the surface area forms the circumferential tread rubber profile area of the tire and wherein the elevations impress the depressions, such as grooves, in the tread of the tire. A tire vulcanized with the vulcanizing mold may be a motorcycle tire or an ultra-high performance tire. Certain regions of the forming surfaces of the mold segments that form the tread rubber profile are provided with a roughness, such that those regions of the vulcanizing mold which form the circumferential tread rubber profile area are provided with the roughness. The elevations, on the other hand, which impress the depressions are not provided with this roughness but they are instead smooth. | ||||||
| 137 | Piercing and Rolling Plug, Method of Regenerating Such Piercing and Rolling Plug, and Equipment Line for Regenerating Such Piercing and Rolling Plug | US12490857 | 2009-06-24 | US20100050723A1 | 2010-03-04 | Yasuyoshi Hidaka; Kazuhiro Shimoda; Kouji Nakaike; Naoya Hirase; Yasuto Higashida; Takateru Inage; Jyun Nagakita; Masaharu Nakamori; Fumihito Yoshikawa; Yoshihiko Hayashi; Takayuki Aisaka |
| A piercing and rolling plug has a film composed of oxides such as Fe3O4 and FeO and Fe (metal) as being formed on the surface of the base metal by electric arc spraying using an iron wire whose main component is Fe and, owing to this film, a plug excellent in heat-shielding and seizure-preventing effects can be realized and the lifetime of the plug can be prolonged. Further, in regenerating this plug, a film can be re-formed via the steps of shot blasting of the as-used plug in piercing and rolling and electric arc spraying in that order; thus, it is possible to regenerate the plug at low cost and in a short period of time. | ||||||
| 138 | Methods and apparatus for manufacturing components | US11231499 | 2005-09-21 | US07597762B2 | 2009-10-06 | Joseph G. Albanese; Robert Scott Shalvoy; Jon E. Dickinson |
| A method for manufacturing components is provided. The method includes coupling a drive assembly to a positioning assembly, coupling a plurality of components to be manufactured to a plurality of fixtures, securing the plurality of fixtures to the drive assembly wherein each fixture is configured to receive a component to be manufactured, and repositioning the plurality of components simultaneously using the positioning assembly to facilitate manufacturing of the plurality of components, wherein the components are configured to be oscillated in a first plane of rotation via the drive assembly and rotated through a second plane of rotation via the plurality of fixtures. | ||||||
| 139 | SPUTTERING TARGET AND PROCESS FOR PRODUCING THE SAME | US12091832 | 2006-11-02 | US20090134020A1 | 2009-05-28 | Yukinobu Suzuki; Koichi Watanabe; Toshiya Sakamoto; Michio Sato; Yasuo Kohsaka |
| There are provided a sputtering target and a process for producing a sputtering target. The sputtering target includes a first layer located on its side to be sputter treated and a second layer located on its side not to be sputter treated. The first and second layers are bonded to each other through a bonding interface between the first layer and the second layer. The sputtering target satisfying the following requirements X and Y: requirement X: A/B≦1.5 and requirement Y: A/C≦1.5, wherein A represents an oxygen peak value for the bonding interface; B represents an oxygen peak value for the first layer; and C represents an oxygen peak value for the second layer. The sputtering target is advantageous in that a spent sputtering target can be recycled to utilize resources and can form a thin film while effectively preventing the occurrence of abnormal discharge and splash. | ||||||
| 140 | Multilayer structural body and method for cleaning the same | US11988648 | 2006-07-12 | US20090133713A1 | 2009-05-28 | Tadahiro Ohmi; Akinobu Teramoto; Hitoshi Morinaga; Yukio Kishi; Hiromichi Ohtaki; Yoshihumi Tsutai |
| It has been difficult to provide a large-sized ceramic member quickly and economically. A multilayer structure is produced by forming a ceramic film on a base which is made of a material that can be shaped comparatively easily. The ceramic film is formed by a plasma spraying method, CVD method, PVD method, sol-gel method or the like. Alternatively, the ceramic film may be formed by a method combined with a spray deposit film. | ||||||
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