子分类:
- C04B41/5307: ..{物理结合水的去除,如变硬水泥 的干燥(E04B1/7007 优先)}
- C04B41/5315: ..{清洁成分,如从瓷砖上去除变硬 水泥}
- C04B41/5323: ..{制造可见颗粒,如得到暴露的集 合混凝土}
- C04B41/5338: ..{ 蚀刻 ( 获得装饰作用入 B44C 1/22;特殊电子化合物的蚀刻,见 相关位置,如 半导体的蚀刻入H01L 21/306)}
- C04B41/5369: ..{脱盐作用,如钢筋混凝土的}
- C04B41/5384: ..{电化学方法(电化学脱盐作用入
- C04B41/5392: ..{通过燃烧(C04B38/06 优先)}
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 201 | METHOD OF MANUFACTURING TERRAZZO TILES, TERRAZZO TILES AND FLOORING SYSTEM ASSEMBLED WITH TERRAZZO TILES | US12059531 | 2008-03-31 | US20080236092A1 | 2008-10-02 | John Sich |
| A method of manufacturing terrazzo tiles and tiles manufactured in accordance with the method is described. A resin, curing agent, filler, and pigment are poured into a mold. Stone chips are then poured into the mold to settle with the majority at the bottom of the mold. Thereafter, curing occurs to result in rough tiles which are ground and then polished with the upper surface being the resulting tile surface at which the majority of the stones settle. The tiles are assembled onto a floor with grout lines resulting from spacing of the tiles, one from another. Grout is then poured in and skived, and the floor polished to result in a sealed monolithic surface. | ||||||
| 202 | Uniform texture for cast in place walls | US11724452 | 2007-03-15 | US20080222994A1 | 2008-09-18 | Ronald D. Shaw; Lee A. Shaw |
| A method of forming a concrete wall having a substantially uniform exterior surface texture. The method includes the initial step of pouring concrete into a wall form. The concrete is poured from a first mixture and is allowed to cure. After the concrete is cured, the wall form is removed from the resultant concrete base structure. A roughened texture is then created on the base structure. A finishing mixture is then applied to the roughened texture. The finishing mixture may be created by separating the aggregate from a portion of the remaining first mixture. The finishing mixture creates a smooth texture on the exterior surfaces of the initially formed base structure. | ||||||
| 203 | Method of forming pavers containing waste glass particles | US11000183 | 2004-11-30 | US07364615B1 | 2008-04-29 | Fulton L. Bryant |
| A method for forming pavers includes mixing cement, water and sand to form a cement composition, and mixing waste glass particles with the cement composition to form a cement-glass particle composition. Thereafter the cement glass particle composition is poured into a mold and the composition is allowed to harden to form a molded cement glass particle block. Next the cement glass particle block is removed from the mold and sliced by cutting the cement glass particle block into a series of sections or component parts where each section or component part forms a paver. Thereafter at least one surface of the paver is ground to form a smooth surface that exposes the waste glass particles. | ||||||
| 204 | Laser-irradiated metallized electroceramic | US10885877 | 2004-07-08 | US07318844B2 | 2008-01-15 | Reto Kessler; Felix Greuter; Michael Hagemeister |
| The manufacturing method for an electroceramic component (1), for example a varistor (1), comprises a laser irradiation of a part (5; 6) of the surface of an electroceramic body (2) before a metallization (3; 4) is applied to the part (5; 6) of the surface. By means of the laser irradiation it is possible to produce a micro-roughness and/or a chemical modification of the surface which permits good adhesion of the metallization, and it is possible to reduce or eliminate areas of unevenness or waviness of that part (5; 6) of the surface of the electroceramic body (2) which is to be metallized. In addition, improved transverse conductivity can be produced, by virtue of which a low contact resistance and a very homogeneous current distribution is achieved, in particular near to the metallization (3; 4). In addition it is possible to remove residues which originate in particular from a sinter support or from the application of a passivation layer. After the laser irradiation, the electroceramic body advantageously has a border (9) which adjoins the part (5; 6) of the surface and which is not laser-irradiated. The laser beam can advantageously be pulsed and focused. | ||||||
| 205 | Methods for machining ceramics | US10423283 | 2003-04-25 | US07306748B2 | 2007-12-11 | Ronald W. Laconto; Douglas E. Ward |
| A method for machining a ceramic substrate containing Al, including providing a slurry between a substrate and a machine tool, the slurry containing alumina abrasive and an additive including a phosphorus compound, and moving the substrate relative to the machine tool. | ||||||
| 206 | CERAMIC HONEYCOMB STRUCTURE AND ITS PRODUCTION METHOD AND COATING MATERIAL USED THEREFOR | US11689880 | 2007-03-22 | US20070158879A1 | 2007-07-12 | Hirohisa Suwabe; Yasuhiko Otsubo; Toshiaki Kimura |
| A ceramic honeycomb structure comprising a ceramic honeycomb body comprising axial grooves on its periphery and cell walls constituting a larger number of flow paths inside the grooves, and a peripheral wall layer covering the grooves, wherein there are stress release portions at least partially in the peripheral wall layer and/or between the peripheral wall layer and the grooves. The thermal expansion coefficient of the peripheral wall layer is preferably smaller than those of the cell walls in a radial direction. The peripheral wall layer is preferably formed on the ceramic honeycomb body formed by removing a peripheral wall from a ceramic green body, before or after firing the ceramic honeycomb body. | ||||||
| 207 | Aluminum nitride ceramic, semiconductor manufacturing member, and manufacturing method for aluminum nitride ceramic | US11153921 | 2005-06-15 | US07211216B2 | 2007-05-01 | Yoshimasa Kobayashi; Naohito Yamada; Toru Hayase |
| An aluminum nitride ceramic including aluminum nitride grains and grain boundary phases comprises a grain boundary phase-rich layer including more amount of the grain boundary phases in a surface layer of the aluminum nitride ceramic than in an inside of the aluminum nitride ceramic. The grain boundary phases in the grain boundary phase-rich layer include at least one of rare earth element and alkali earth element. | ||||||
| 208 | NON-AQUEOUS LAPPING COMPOSITION AND METHOD USING SAME | US11426281 | 2006-06-23 | US20060289387A1 | 2006-12-28 | John Lombardi |
| Lapping compositions which do not comprise water are disclosed, wherein those lapping compositions comprise a non-aqueous fluid, and wherein the lapping compositions are useful during a process to shape the surface of a substrate, wherein that process includes contacting a target surface of the substrate with one or more abrasives while also contacting that target surface with the lapping composition. | ||||||
| 209 | Process for producing silicon carbide sinter jig | US10494258 | 2002-10-30 | US07150850B2 | 2006-12-19 | Fumio Odaka |
| The present invention provides a sintered silicon carbide jig production method capable of simply increasing the purity of a sintered silicon carbide jig. A method of producing a sintered silicon carbide jig comprising a process in which a second sintered body is heated at a temperature rising rate of 3 to 5° C./min up to heating treatment temperature selected in the range of 2200 to 2300° C. under an argon atmosphere, kept at the same heating treatment temperature for 3 hours, and cooled at a temperature lowering rate of 2 to 3° C./min down to 1000° C. | ||||||
| 210 | Bond coat for silicon-containing substrate for EBC and processes for preparing same | US11150098 | 2005-06-13 | US20060280953A1 | 2006-12-14 | Brian Hazel; Irene Spitsberg; Brett Boutwell |
| An article comprising a silicon-containing substrate, a silicide-containing bond coat layer overlying the substrate, and typically an environmental barrier coating overlaying the bond coat layer. An article is also provided wherein the environmental barrier coating comprises: (1) an optional inner silica scale layer overlaying the bond coat layer; (2) intermediate layer overlaying the inner silica scale layer, or the bond coat layer in the absence of the inner silica scale layer, and comprising mullite, or a combination of mullite with a barium strontium aluminosilicate, a yttrium silicate, or a calcium aluminosilicate; and (3) an outer steam-resistant barrier layer overlaying the intermediate layer and consisting essentially of an alkaline earth silicate/aluminosilicate. Processes are also provided for forming the silicide-containing bond coat layer over the substrate, followed by forming the environmental barrier coating over the bond coat layer. | ||||||
| 211 | Environmental barrier layer for silcon-containing substrate and process for preparing same | US11084104 | 2005-03-21 | US20060210800A1 | 2006-09-21 | Irene Spitsberg; Christine Govern; Brian Hazel; Jennifer Saak; James Steibel |
| An article comprising a silicon carbide and/or silicon metal-containing substrate and an environmental barrier layer overlaying the substrate, wherein the environmental barrier layer has a thickness up to about 5 mils (127 microns) and comprises a reaction-generated corrosion resistant metal silicate. A process is also provided for reacting a metal source and a silica source over the silicon carbide and/or silicon metal-containing substrate to form the environmental barrier layer comprising the reaction-generated corrosion resistant metal silicate. | ||||||
| 212 | Method for treating the surface of a part made of a heat-structured composite material and use thereof in brazing parts made of a heat-structured composite material | US10543363 | 2004-01-29 | US20060141154A1 | 2006-06-29 | Jacques Thebault |
| A liquid composition is applied onto the surface of the part to be treated, the composition containing a ceramic precursor polymer and a refractory solid filler. After cross-linking, the polymer is transformed into ceramic by heat treatment, and subsequently ceramic is deposited by chemical vapor infiltration. Before the chemical vapor infiltration step, the surface of the part is shaved so as to return the composite part to its initial shape so that the chemical vapor infiltration forms a deposit that fills in the residual micropores in the shaved surface of the part. | ||||||
| 213 | Semiconductor processing equipment having improved particle performance | US11103446 | 2005-04-12 | US20050181617A1 | 2005-08-18 | William Bosch |
| A ceramic part having a surface exposed to the interior space, the surface having been shaped and plasma conditioned to reduce particles thereon by contacting the shaped surface with a high intensity plasma. The ceramic part can be made by sintering or machining a chemically deposited material. During processing of semiconductor substrates, particle contamination can be minimized by the ceramic part as a result of the plasma conditioning treatment. The ceramic part can be made of various materials such as alumina, silicon dioxide, quartz, carbon, silicon, silicon carbide, silicon nitride, boron nitride, boron carbide, aluminum nitride or titanium carbide. The ceramic part can be various parts of a vacuum processing chamber such as a liner within a sidewall of the processing chamber, a gas distribution plate supplying the process gas to the processing chamber, a baffle plate of a showerhead assembly, a wafer passage insert, a focus ring surrounding the substrate, an edge ring surrounding an electrode, a plasma screen and/or a window. | ||||||
| 214 | Apparatus for atmospheric pressure reactive atom plasma processing for surface modification | US10868426 | 2004-06-15 | US20050000656A1 | 2005-01-06 | Jeffrey Carr |
| Reactive atom plasma processing can be used to shape, polish, planarize and clean the surfaces of difficult materials with minimal subsurface damage. The apparatus and methods use a plasma torch, such as a conventional ICP torch. The workpiece and plasma torch are moved with respect to each other, whether by translating and/or rotating the workpiece, the plasma, or both. The plasma discharge from the torch can be used to shape, planarize, polish, and/or clean the surface of the workpiece, as well as to thin the workpiece. The processing may cause minimal or no damage to the workpiece underneath the surface, and may involve removing material from the surface of the workpiece. | ||||||
| 215 | Plasma-resistant member for semiconductor manufacturing apparatus and method for manufacturing the same | US10208871 | 2002-08-01 | US06838405B2 | 2005-01-04 | Mitsuhiro Fujita; Keiji Morita |
| A plasma-resistant member for a semiconductor manufacturing apparatus, which can reduce the contamination level on a semiconductor wafer. The contents of Fe, Ni, Cr and Cu are made lower than 1.0 ppm respectively within a depth of at least 10 μm from surface in a plasma-resistant member. | ||||||
| 216 | Process for producing silicon carbide sinter jig for use in semicondutor production and silicon carbide sinter jig obtained by the process | US10494258 | 2004-05-04 | US20040259717A1 | 2004-12-23 | Fumio Odaka |
| The present invention provides a sintered silicon carbide jig production method capable of simply increasing the purity of a sintered silicon carbide jig. A method of producing a sintered silicon carbide jig comprising a process in which a second sintered body is heated at a temperature rising rate of 3 to 5null C./min up to heating treatment temperature selected in the range of 2200 to 2300null C. under an argon atmosphere, kept at the same heating treatment temperature for 3 hours, and cooled at a temperature lowering rate of 2 to 3null C./min down to 1000null C. | ||||||
| 217 | Method of inspecting concrete surface and method of repairing same | US10880487 | 2004-07-01 | US20040231709A1 | 2004-11-25 | Shin Narui |
| A method of inspecting a concrete surface. The method comprises ejecting highly pressurized water to a concrete surface by using a jet nozzle, thereby fracturing and spalling off deteriorated concrete deteriorated in strength, with leaving only sound concrete, for inspection of surface strength. | ||||||
| 218 | Laminate concrete panel | US10445281 | 2003-05-23 | US20040231273A1 | 2004-11-25 | Guy Bamford |
| A concrete laminate panel (1) comprising a sealant layer (2), a first layer of concrete (4), a second layer of concrete (6), and a backing board (8). The sealant layer (2) is a transparent, wear-resistant material, such as a urethane material. The sealant layer (2) provides a waterproof and alcohol-resistant layer with excellent wear properties, both in a dry and a wet condition, plus an ultraviolet filter to prevent yellowing. A two-stage, two-part polyurethane material comprises these properties, and we have found this material to be particularly useful as a sealant layer. The transparent nature of the sealant layer (2) allows the uppermost surface of the first layer of concrete (4) to be viewed therethrough. The urethane material contains an anti-microbial additive that will inhibit the growth of bacteria, fungi, molds, mildew, and algae. The first layer of concrete (4) provides a viewable thin, hardened, and decorative surface. The first layer of concrete (4) is wet bonded and cross-cured to the second layer of concrete (6). The second layer of concrete (6) comprises a fiber-reinforced concrete material and provides improved tensile strength for the laminate concrete panel (1). The backing board (8) may be any suitable fibrous board, such as MDF. The backing board (8) is bonded to the second layer of concrete (6). | ||||||
| 219 | METHOD FOR ENHANCING ADHESION OF METAL PARTICLES TO CERAMIC MODELS | US10249233 | 2003-03-25 | US20040191543A1 | 2004-09-30 | Allen Dennis Roche; John Michael Nicholson; Richard L. Allor; David Warren Worthey |
| One method of the present invention relates to a method for enhancing adhesion of sprayed metal to a ceramic model. The method is comprised of providing the ceramic model having a spray surface, and modifying at least a portion of the spray surface of the ceramic model to enhance adhesion of spray metal to the spray surface. | ||||||
| 220 | Method of making a terrazzo surface from recycled glass | US10454678 | 2003-06-05 | US06770328B1 | 2004-08-03 | Tim Whaley |
| The method of making a terrazzo surface from recycled glass involves several steps. First, the substrate over which the terrazzo layer is formed is conditioned and primed. Second, an epoxy mixture is made by mixing crushed recycled glass, epoxy resin and epoxy primer. Third, the epoxy mixture is poured over the substrate to a height of ⅜″ nominally. Fourth, the mixture is troweled and allowed to cure and harden. Fifth, the surface is ground and polished to expose glass fragments near the surface. Grout is then applied to fill any air bubbles opened during the grinding process. Finally, the floor is polished and sealed. Decorative patterns and designs may also be formed in the terrazzo by attaching metal divider strips of different shapes to the substrate before pouring the epoxy mixture, and then using different colored mixtures to create patterns and/or designs in the surface. | ||||||
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