序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
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101 | Low porosity glass coatings formed on coiled wires, high temperature devices containing the same, and methods for the fabrication thereof | US16141263 | 2018-09-25 | US11437188B2 | 2022-09-06 | James Piascik; Jimmy Wiggins; Harry Lester Kington; Martin Carlin Baker |
Methods for fabricating wires insulated by low porosity glass coatings are provided, as are high temperature electromagnetic (EM) devices containing such wires. In embodiments, a method for fabricating a high temperature EM device includes applying a glass coating precursor material onto a wire. The glass coating precursor material contains a first plurality of glass particles having an initial softening point. After application onto the wire, the glass coating precursor material is heat treated under process conditions producing a crystallized intermediary glass coating having a modified softening point exceeding the initial softening point. The crystallized intermediary glass coating is then infiltrated with a filler glass precursor material containing a second plurality of glass particles. After infiltration, the filler glass precursor material is heat treated to consolidate the second plurality of glass particles into the crystallized intermediary glass coating and thereby yield a low porosity glass coating adhered to the wire. | ||||||
102 | Exterior material of home appliance, home appliance including the exterior material, and manufacturing method thereof | US16123623 | 2018-09-06 | US11078107B2 | 2021-08-03 | Kyoung Mok Kim; Seulkiro Kim; Yu Jeong Oh; Jong Ho Lee; Jung Soo Lim; Ki Hwan Kwon; Yong Jong Park; Hyun Sang Yoo; Boo-Keun Yoon; Hee Tae Lim |
A cooking apparatus including an enamel coating layer having an improved cleaning efficiency and a manufacturing method therefor are provided. The cooking apparatus includes a cooking compartment configured to accommodate a cooking object, a door configured to open and close the cooking compartment, and an enamel coating layer provided on a surface of the cooking compartment. The enamel coating layer includes, in percent (%) by weight of the entire composition, 5% or less (excluding 0%) of a silicon dioxide (SiO2), 10% to 20% of an aluminum oxide (Al2O3), 10% to 20% of a phosphorous pentoxide (P2O5), 5% to 15% of a rare earth oxide, and 5% to 10% of a ferric oxide (Fe2O3). | ||||||
103 | Highly alkali-resistant aluminum member | US16158875 | 2018-10-12 | US11035052B2 | 2021-06-15 | Jin Shinmura; Yohei Kanatani; Ryota Kakizawa |
An aluminum member exhibits improved alkali resistance with respect to an anodic oxide coating. The highly alkali-resistant aluminum member includes a material that includes aluminum or an aluminum alloy, an anodic oxide coating that is formed on the surface of the material, and a coating layer that is formed on the anodic oxide coating, and includes a siloxane glass component in a ratio of 90 mass % or more, wherein the coating layer has a thickness of 0.5 to 5.0 μm and a coating mass of 0.4 to 5.0 g/m2. | ||||||
104 | Method for Heat-Treating a Component Which Consists of a Metal Material and Comprises at Least One Surface Section Coated with a Glaze or Enamel Coating | US16081546 | 2017-03-02 | US20190085466A1 | 2019-03-21 | Bernhard Stauder; Jurij Gontarev |
A method for heat-treating a component which consists of a metal alloy, in which or on which at least one surface section is coated with a glaze or enamel coating, includes heating the component to a heating temperature which at least equals a minimum quenching temperature, and quenching the component starting from a temperature which at least equals the minimum quenching temperature in order to produce a higher-strength microstructure in the component. The components can be heat-treated such that the glaze or enamel coating is reliably prevented from chipping. The glaze or enamel coating is pre-cooled to a pre-cooling temperature at least on its free surface prior to quenching, said pre-cooling temperature maximally corresponding to the temperature at which the glaze or enamel coating begins to soften, and wherein the cooling rate at which the glaze or enamel coating is cooled is lower than the cooling rate during quenching. | ||||||
105 | HIGHLY ALKALI-RESISTANT ALUMINUM MEMBER | US15386408 | 2016-12-21 | US20170159200A1 | 2017-06-08 | Jin SHINMURA; Yohei KANATANI; Ryota KAKIZAWA |
An aluminum member exhibits improved alkali resistance with respect to an anodic oxide coating. The highly alkali-resistant aluminum member includes a material that includes aluminum or an aluminum alloy, an anodic oxide coating that is formed on the surface of the material, and a coating layer that is formed on the anodic oxide coating, and includes a siloxane glass component in a ratio of 90 mass % or more, wherein the coating layer has a thickness of 0.5 to 5.0 μm and a coating mass of 0.4 to 5.0 g/m2. | ||||||
106 | Hydrogen out gas of porous metal scaffold | US13926353 | 2013-06-25 | US09205171B2 | 2015-12-08 | Edward M. Willis; Mae Abiog; Joseph R. Vargas |
Systems and methods for hydrogen out gas of a porous metal scaffold are disclosed. A method can comprise heating a porous metal scaffold for a period of time sufficient to remove at least a portion of a hydrogen concentration from the scaffold, subjecting the porous metal scaffold to a vacuum while heating it, flowing an inert gas through or around the porous metal scaffold while heating it, and enhancing a mechanical property of the porous metal scaffold. Heating of the porous metal scaffold can include maintaining a temperature of the scaffold between 1035° C. and 1065° C., inclusive. A system can comprise a reaction chamber, a heater, a gas feed, and a vacuum apparatus. The heater can be configured to heat the reaction chamber and the porous metal scaffold, while the gas feed and the vacuum apparatus respectively flow inert gas and subject the porous metal scaffold to a vacuum. | ||||||
107 | Method for repairing a glass layer of glass-lined equipment | US790567 | 1991-11-12 | US5143275A | 1992-09-01 | Tatsuo Hara; Akihiko Hogetsu; Shigeo Uegaki |
An improved method for repairing a damaged portion of a glass layer of glass-lined equipment. In the method, a metallic fiber-containing sheet made of a metallic fiber-containing web, a metallic woven fabric sheet or a metallic nonwoven fabric sheet is disposed on the metal substrate of the damaged portion exposed by grinding, and the metallic sheet is welded partially to the metal substrate underlying the glass layer by a resistance or spot weld. After solidification of the repairing agent, e.g., of a sol-gel solution containing a metallic alkoxide which has been applied onto the partially welded sheet(s) and the sol-gel solution impregnated therein, the reapiring glass layer is formed integrally together with the sheet(s) by heating the damaged portion at a temperature from about 300.degree. to about 350.degree. to avoid the occurence of cracks on the glass layer surrounding the damaged portion. A series of the above-mentioned glass forming procedures are repeated until a satisfactory thickness of the reapairing glass layer is obtained. | ||||||
108 | Method for repairing glass-lined equipment by sol-gel process | US529935 | 1990-05-29 | US5053251A | 1991-10-01 | Tatsuo Hara; Koichi Wada; Shigeo Uegaki |
A method of repairing a damaged portion of a glass layer of glass-lined steel equipment by repeated steps of applying a repair agent to a damaged area of the glass layer and then heating the repair agent for solidification and adherence to the glass by the use of a sol-gel process, until a thickness of a repair glass layer becomes almost equal to the existing glass layer adjacent thereto without generating cracks or exfoliations in the glass. Also, an apparatus for heating the repair area of a layer of glass-lined steel equipment includes a flexible thermal insulation sheet body having a recess on a single side thereof; electric heater units provided in the recess for emitting far infrared rays; magnets provided adjacent to the recess for securing the sheet body on a wall of glass-lined equipment covering the damaged portion to be repaired; a silica glass cloth enclosing the body for maintaining configuration; a thermal sensor placed in the recess for locating adjacent to the damaged area; and a thermal controller coupled to the sensor and the heater units for automatically controlling the temperature of the heater units. | ||||||
109 | Process for forming a coating | US41330 | 1987-04-22 | US4762736A | 1988-08-09 | Michael J. Garvey; Ian C. Griffiths |
This invention discloses the preparation of coatings on substrates. The coating is derived from a film formed at a sol air interface and the film is bonded to the substrate by direct contact. The coating preferably contains silica. | ||||||
110 | Copper conductive paint for porcelainized metal substrates | US791382 | 1985-10-25 | US4623482A | 1986-11-18 | Charles C. Y. Kuo; Terry R. Bloom |
A copper conductive paint for use on a porcelanized metal substrate, which comprises a powder mixture of 82 to 98.5% copper, 0.5 to 12% copper hydroxide, and 1 to 6% non-reducable borosilicate glass frit. 75 to 90 percent of the powder mixture is blended with 10 to 25 percent screening agent to form the copper conductive paint herein disclosed. The copper conductive paint is then screened and fired upon a porcelainized metal substrate in an inert atmosphere at approximately 900.degree. C. to form a copper conductor exhibiting improved adhesion characteristics. | ||||||
111 | Method of bonding two porcelain coated objects | US3551233D | 1967-12-07 | US3551233A | 1970-12-29 | KOHNKEN DONALD H |
112 | Reconstruction of chemical equipment | US23643551 | 1951-06-07 | US2722734A | 1955-11-08 | ALVIN GRANT |
113 | Increasing the apparent surface hardness of enamels | US31805840 | 1940-02-09 | US2353165A | 1944-07-11 | IGNAZ KREIDL; WERNER KREIDL |
114 | Machine for enameling sheet metal | US56509731 | 1931-09-25 | US1976066A | 1934-10-09 | KEITH FRIEND WILLIAM |
115 | 핀튜브용 법랑 코팅 장치 및 코팅 방법 | PCT/KR2017/015327 | 2017-12-22 | WO2018131823A1 | 2018-07-19 | 서성호 |
본 발명은 핀튜브용 법랑 코팅 장치 및 코팅 방법에 관한 것으로, 보다 상세하게는 효율적으로 핀튜브를 법랑 코팅하기 위한 핀튜브용 법랑 코팅 장치에 관한 것이다. 상기와 같은 목적을 달성하기 위한 본 발명의 구성은 중공의 관 형태의 튜브와, 상기 튜브의 외주면에 나선형으로 형성된 핀을 갖는 핀튜브를 이송하는 이송부; 상기 이송부에 의해 장입된 상기 핀튜브를 향해 유약분말을 도포하는 도포부; 및 상기 도포부의 양측에 위치하여 상기 핀튜브에 열을 가하는 가열부를 포함하며, 상기 유약분말은 순수 프리트(frit)인 것을 특징으로 하는 고온에서 변형이 되지 않는 짧은 거리의 핀튜브용 법랑 코팅 장치를 제공한다. <대표도 - 도 1> |
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116 | 蓄光板の製造方法 | PCT/JP2007/064940 | 2007-07-31 | WO2008016030A1 | 2008-02-07 | 筒井 修 |
【課題】 夜間や暗い場所でも視認可能な蓄光板の製造方法に関し、特に、製造時には印刷面にひび割れ等を生じさせず、かつ薄型で高強度の製品を作ることのできる蓄光板の製造方法を提供する。 【解決手段】 ガラスフリットと蓄光材を印刷した金属板Wの端部付近を複数の支点2で支えて水平に保持し、さらに、金属板Wの撓みをを制限するストッパ3を、蓄光板中央部近辺の蓄光板裏面側に設けておき、この状態で焼成してガラスフリットを溶融させ、次に、冷却してガラスフリットを凝固させ、かつ金属板Wを収縮させることで、印刷面側が水平乃至僅かに凸状に反り返った形状の蓄光板を得る。 |
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117 | METHOD OF MASKING COATINGS AND RESULTANT OBJECT | PCT/US2001/011007 | 2001-04-03 | WO01076811A1 | 2001-10-18 | |
A method for masking electrodeposited coatings on an article surface utilizing a parylene film (30) which insulates the article surface such that charged particles do not adhere to the surface of the parylene film. Preferably, the parylene film having a thickness of up to about 1 mil is formed on a fastener (10) used in automotive assemblies such that after electrocoating of the automobile, subsequent parts may be attached via the fastener. The parylene film effectively prevents adhesion of the electrocoat on the fastener such that subsequent manual re-tapping of the fastener thread is avoided. | ||||||
118 | TEMPERATURE AND SCRATCH-RESISTANT ANTI-STICKING COATING | PCT/EP1998/004126 | 1998-07-03 | WO99002463A1 | 1999-01-21 | |
The invention relates to a carrier material having an inorganic molecular structure and a surface coating produced by applying a substance and by heat treatment. The invention also relates to a method for the production and to the appropriate uses of said surface coating. Carrier materials made of glass, metal or ceramic should be provided with a surface coating with anti-sticking properties against water-based and/or oil-based organic materials or water-oil emulsions while exhibiting at the same time essentially better temperature-resistant and anti-scratch characteristics than conventional PTFE or silicone coatings. These requirements are met by an inventive surface coating consisting of a combination of inorganic molecules of the carrier material and organic molecules of an applied substance on the uppermost molecular layer of said coating. In order to produce such a surface, an inorganic substance with silicone-like networks is initially applied. Subsequently, heat treatment is carried out, whereby the temperature and duration of said treatment are chosen in such a way that the purely organic coating applied is fully decomposed and/or removed so that a combination of inorganic molecules of the carrier material and organic molecules of the applied substance is formed. The appropriate carrier materials with the inventive surface coating can be advantageously used above all in household appliances and kitchenware. | ||||||
119 | ANTIFOULING MATTED OBJECT | EP17208235.6 | 2017-12-18 | EP3339271A1 | 2018-06-27 | SATOSHI, Shimizu; YUKIKA, Yamazawa |
An object of the present invention is to provide a matted object capable of achieving both a lower range of glossiness and an antifouling property. A matted object includes a substrate, and a glassy layer provided on the surface of the substrate. The surface of the glassy layer has a 60°-glossiness of 20 or less, a skewness Rsk of -0.5 or more, and a maximum height roughness Rz more than 2.5 µm and less than 5. 7 µm, the skewness Rsk and the maximum height roughness Rz being specified in JIS B0601 (2001). |
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120 | TEMPERATURBESTÄNDIGE UND KRATZFESTE ANTIHAFTBESCHICHTUNG | EP98940130.2 | 1998-07-03 | EP0937012B1 | 2001-12-05 | BERKENKÖTTER, Herbert; KAUP, Friedel; KRÜMPELMANN, Thomas; MANGEN, Walter; SILLMEN, Ulrich |
The invention relates to a carrier material having an inorganic molecular structure and a surface coating produced by applying a substance and by heat treatment. The invention also relates to a method for the production and to the appropriate uses of said surface coating. Carrier materials made of glass, metal or ceramic should be provided with a surface coating with anti-sticking properties against water-based and/or oil-based organic materials or water-oil emulsions while exhibiting at the same time essentially better temperature-resistant and anti-scratch characteristics than conventional PTFE or silicone coatings. These requirements are met by an inventive surface coating consisting of a combination of inorganic molecules of the carrier material and organic molecules of an applied substance on the uppermost molecular layer of said coating. In order to produce such a surface, an inorganic substance with silicone-like networks is initially applied. Subsequently, heat treatment is carried out, whereby the temperature and duration of said treatment are chosen in such a way that the purely organic coating applied is fully decomposed and/or removed so that a combination of inorganic molecules of the carrier material and organic molecules of the applied substance is formed. The appropriate carrier materials with the inventive surface coating can be advantageously used above all in household appliances and kitchenware. |