| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 161 | Method for manufacturing glass-ceramic composite | US13736242 | 2013-01-08 | US09321695B2 | 2016-04-26 | Mohammed A Binhussain; Paolo Colombo; Enrico Bernardo; Majed A Binmajed; Mauro Marangoni; Hamad H Atalasi; Amer M Alajmi |
| The invention provides a method for manufacturing a glass-ceramic composite using natural raw material and waste glasses. The invention provides a method for manufacturing a white glass-ceramic composite using waste glass and a whitening agent. The invention also provides a method for manufacturing a colored glass-ceramic composite using waste glass, the whitening agent and a coloring agent. | ||||||
| 162 | ENGINEERED GLASS SEALS FOR SOLID-OXIDE FUEL CELLS | US13949964 | 2013-07-24 | US20150030963A1 | 2015-01-29 | Wayne SURDOVAL; Edgar LARA-CURZIO; Jeffry STEVENSON; Joseph MUTH; Beth L. ARMSTRONG; Amit SHYAM; Rosa M. TREJO; Yanli WANG; Yeong Shyung CHOU; Travis SHULTZ |
| A seal for a solid oxide fuel cell includes a glass matrix having glass percolation therethrough and having a glass transition temperature below 650° C. A deformable second phase material is dispersed in the glass matrix. The second phase material can be a compliant material. The second phase material can be a crushable material. A solid oxide fuel cell, a precursor for forming a seal for a solid oxide fuel cell, and a method of making a seal for a solid oxide fuel cell are also disclosed. | ||||||
| 163 | METHOD FOR MANUFACTURING GLASS-CERAMIC COMPOSITE | US13736242 | 2013-01-08 | US20140191448A1 | 2014-07-10 | Mohammed A. Binhussain; Paolo Colombo; Enrico Bernardo; Majed A. Binmajed; Mauro Marangoni; Hamad H. Atalasi; Amer M. Alajmi |
| The invention provides a method for manufacturing a glass-ceramic composite using natural raw material and waste glasses. The invention provides a method for manufacturing a white glass-ceramic composite using waste glass and a whitening agent. The invention also provides a method for manufacturing a colored glass-ceramic composite using waste glass, the whitening agent and a coloring agent. | ||||||
| 164 | MAGNETIC GLASS PARTICLES FOR USE IN BIOGAS PLANTS, FERMENTATION AND SEPARATION PROCESSES | US13763331 | 2013-02-08 | US20130224823A1 | 2013-08-29 | Friedrich Ruf; Ulrich Sohling; Elisabeth Neitmann; Bernd Linke; Jan Mumme; Patrice Ramm; Oliver Menhorn; Karl Weinberger; Peter Kumpf |
| A method for treating an organic and/or inorganic substrate utilizing a granular material made of a solid foam as support for an active component, for example a biocatalyst such as a microorganism or an enzyme. The solid foam has a continuous phase in which magnetizable particles are embedded, such that the support with the biologically active component immobilized thereon can be separated from a mixture with a magnetic separation device. | ||||||
| 165 | LUMINESCENT GLASS, PRODUCING METHOD THEREOF AND LUMINESCENT DEVICE | US13497822 | 2009-09-25 | US20120225238A1 | 2012-09-06 | Mingjie Zhou; Wenbo Ma; Guitang Chen |
| A luminescent glass comprises glass matrix. Said glass matrix comprises a glass part and a complex part of glass and fluorescent powder, which is embedded in said glass part. Said complex part of glass and fluorescent powder comprises glass material and fluorescent powder dispersed in said glass material. A method for producing the luminescent glass and a luminescent device comprising the luminescent glass are also provided. The luminescent glass and the luminescent device have good luminescence reliability, high luminescence stability and long service life. The method can be carried out at a relatively low temperature. | ||||||
| 166 | Contrast-Enhancing UV-Absorbing Glass and Articles Containing Same | US12445847 | 2007-10-11 | US20100073765A1 | 2010-03-25 | Yves Andre Henri Brocheton |
| Disclosed are CuX-containing, Nd2O3-containing, UV-absorbing and contrast-enhancing glasses and article comprising the same. The glass has improved UV-absorption and color enhancing capabilities compared to glasses described in the prior art. The glass can be used in sunglass lenses and light filters of information displays. | ||||||
| 167 | Metal nanostructured colorants for high redox glass | US12017211 | 2008-01-21 | US07659221B2 | 2010-02-09 | Mehran Arbab; Larry Shelestak; Songwei Lu |
| A colorant for a high redox glass composition comprising: total iron (Fe2O3) 0 to 1.1 weight percent; and from 0.0001 to 0.15 weight percent of at least one of the following: Cu nanostructures, Au nanostructures, or Ag nanostructures, wherein the weight percents are based on the total weight of the glass composition. The colorant of the invention can be used to make glass compositions having various colors. | ||||||
| 168 | Fluorescent substance composite glass, fluorescent substance composite glass green sheet, and process for producing fluorescent substance composite glass | US11919209 | 2006-04-11 | US20090314989A1 | 2009-12-24 | Masaru Iwao; Yoshio Umayahara |
| The present invention is to provide a fluorescent substance composite glass which is chemically stable, has a large size, is reduced in wall thickness, has a uniform thickness and therefore has a high energy conversion efficiency, a fluorescent substance composite glass green sheet and a process for producing the fluorescent substance composite glass. The fluorescent substance composite glass of the present invention is produced by baking a mixture containing a glass powder and an inorganic fluorescent substance powder, in which the energy conversion efficiency to a visible light wavelength region of 380 to 780 nm is 10% or more, when light having an emission peak in a wavelength range of 350 to 500 nm is applied. | ||||||
| 169 | GLASS CERAMIC SELF-SUPPORTING FILM AND PROCESS FOR ITS PRODUCTION | US12282596 | 2007-03-26 | US20090061195A1 | 2009-03-05 | Toshihiro Kasai |
| A glass ceramic self-supporting film that includes silica (SiO2) matrix glass and fine crystalline zirconia (ZrO2) particles dispersed in the matrix glass. A process for production of a glass ceramic self-supporting film wherein the process includes the steps of combining a colloidal silica sol having a pH of 4 or less, a zirconium-containing compound and an organic binder to produce a mixture, coating the mixture onto a base material, drying the mixture on the coated base material to form a precursor film on the base material, releasing the precursor film from the base material, and firing the released precursor film. | ||||||
| 170 | Optical composite material and method for its production | US11816981 | 2006-02-22 | US20090036289A1 | 2009-02-05 | Eric Eva; Wilfried Clauss |
| An optical composite material comprises an amorphous optical material (6) with a first refractive index (na), into which crystalline nanoparticles (7) having a second, higher refractive index (nn) are embedded, wherein the amorphous material (6) and the nanoparticles (7) are resistant to UV radiation. A microlithography projection exposure apparatus comprises a projection objective (2) with at least one optical element (3) which is, in particular, operated in transmission and consists of an optical composite material of this type. In a method for producing the optical composite material, crystalline nanoparticles are introduced into the amorphous optical material during flame deposition in a soot or direct process. | ||||||
| 171 | Heat Insulating Composite and Methods of Manufacturing Thereof | US11916195 | 2006-05-30 | US20080207426A1 | 2008-08-28 | Olivier Ralston Forsman-White |
| Heat insulating panels are widely used in various domains, for example construction sites or hospitals. These panels require adhesives which may generate heat when the panels are subjected to high temperatures. In the field of high temperature insulation, ceramics are brittle and may not be suitable in some applications. This invention discloses a heat-insulating composite including a plurality of glass, and a binder composition for fusing the glass when the heat-insulting composite is exposed to a temperature higher than 1000C. It was found that as the heat progresses from the outer surface to the inner surface of the composite, plurality of laminated ceramic-like structures are formed, which may assist further in insulating the heat. Interestingly, these laminated ceramic-like structures are found to be rubber-like and therefore not brittle. | ||||||
| 172 | Metal Nanostructured Colorants for High Redox Glass | US12017211 | 2008-01-21 | US20080163649A1 | 2008-07-10 | Mehran Arbab; Larry Shelestak; Songwei Lu |
| A colorant for a high redox glass composition comprising: total iron (Fe2O3) 0 to 1.1 weight percent; and from 0.0001 to 0.15 weight percent of at least one of the following: Cu nanostructures, Au nanostructures, or Ag nanostructures, wherein the weight percents are based on the total weight of the glass composition. The colorant of the invention can be used to make glass compositions having various colors. | ||||||
| 173 | Polyphosphate glasses as a plasticizer for nylon | US11717934 | 2007-03-14 | US20070290405A1 | 2007-12-20 | Joshua Otaigbe; Kevin Urman |
| The present invention discloses the miscibility of inorganic phosphate glass and organic polymer prepared by blending both components in the liquid phase using conventional polymer processing methods. By utilizing low Tg phosphate glasses to plasticize nylon, e.g. polyamide 6, a new class of plasticizer is introduced that allows for the creation of unique nylon polymer composites. These materials display tunable morphologies, interesting properties, and significant reduction in flammability, while easing the processing of nylon through a substantial reduction of viscosity. The addition of a low Tg phosphate glass in small amounts (less than 10% by volume) to a nylon matrix results in a drastic reduction in viscosity and a decrease in the nylon glass transition temperature and flammability, with the capability of adding a low Tg phosphate glass up to 60% by volume. The observed mechanical properties of the nylon/phosphate glass hybrid are consistent with that of plasticized polymers. | ||||||
| 174 | Multilayer ceramic substrate and method for manufacture thereof | US11085564 | 2005-03-22 | US07229939B2 | 2007-06-12 | Hiroshi Nonoue; Hideki Yoshikawa; Kenichiro Wakisaka |
| A multilayer ceramic substrate which is obtained by firing multilayers of ceramic green sheets each having a dielectric layer, made of a glass-ceramic material comprising a mixture of alumina and a glass containing at least Si and Ca, and an electrode layer made of Ag and formed on the dielectric layer. The dielectric layer after firing includes anorthite (CaAl2Si2O8) crystals having a grain size of up to 84 nm. | ||||||
| 175 | Porous ceramic, polymer and metal materials with pores created by biological fermentation | US11531025 | 2006-09-12 | US20070042456A1 | 2007-02-22 | Gary Pickrell |
| Porous polymers are made by adding biologically active agent and growth substrates (e.g., yeast and sugar, preferably in the presence of water or other suitable fluid) to a polymer forming material, which may be a liquid. The yeast acts on the sugar, forming carbon dioxide gas bubbles. The material is then polymerized so that the gas bubbles create permanent pores within the polymeric material. The polymer can be an epoxy for example. The pores will contain residue of the yeast. Also, porous metals can be made by combining a metal powder with yeast, sugar, and water. The porous metal paste is then sintered. Porous ceramics and semiconductors can be made by combining the yeast and sugar with a ceramic forming liquid such as polysilazane. Polysilazane converts to silica when heated, which helps to bind the ceramic or semiconductor powder particles at a reduced temperature. Biological agents other than yeast (e.g. bacteria, enzymes), and growth substrates other than sugar can also be used. | ||||||
| 176 | Process for the constrained sintering of a pseudo-symmetrically configured low temperature cofired ceramic structure | US10994423 | 2004-11-22 | US07068492B2 | 2006-06-27 | Carl B. Wang; Kenneth Warren Hang; Christopher R. Needes |
| This invention relates to a process which produces flat, distortion-free, zero-shrink, low-temperature co-fired ceramic (LTCC) bodies, composites, modules or packages from precursor green (unfired) laminates of three or more different dielectric tape chemistries that are configured in an uniquely or pseudo-symmetrical arrangement in the z-axis of the laminate. | ||||||
| 177 | Synergistic composition for preparing high concentration fullerene (c60) glass and a method for preparing the glass in bulk monolith | US10491371 | 2003-10-23 | US20060111230A1 | 2006-05-25 | Radhaballabh Debnath; Rampada Sahoo |
| The present invention relates to a synergistic composition for preparing high concentration fullerene (C60)-glass and a method for preparing glass doped with fullerene (C60) in bulk monolith using the synergistic composition, which may be used as a nonlinear photonic material and more particularly as a nonlinear optical medium and optical limiter. | ||||||
| 178 | Dielectric material and dielectric sintered body, and wiring board using the same | US11165020 | 2005-06-24 | US20060083930A1 | 2006-04-20 | Hiroshi Sumi; Masashi Suzumura; Tsutomu Sakai; Hidetoshi Mizutani; Manabu Sato |
| A dielectric material comprising: a glass powder constituted of a glass comprising Si, B and an alkali metal element, the glass being amorphous in sintering at a temperature of 1,050° C. or lower; and a ceramic filler comprising at least one member of SiO2, Al2O3 and 3Al2O3.2SiO2, and an alkali metal element, wherein when a total sum of Si converted into SiO2, B converted into B2O3 and the alkali metal element converted into A2O, wherein A represents an alkali metal element, all of which are contained in the glass, is 100 mole %, the content of the alkali metal element converted into A2O, which is contained in the glass, is 0.5 mole % or less; and when a total sum of at least one member of SiO2, Al2O3 and 3Al2O3.2SiO2, and the alkali metal element converted into A2O, all of which are contained in the ceramic filler, is 100 mole %, a content of the alkali metal element converted into A2O, which is contained in the ceramic filler, is 0.5 mole % or less. | ||||||
| 179 | Nanocrystallite glass-ceramic and method for making same | US11145132 | 2005-06-03 | US20050279966A1 | 2005-12-22 | Matthew Dejneka; Christy Powell |
| Glass-ceramic materials are fabricated by infiltrating a porous glass matrix with a precursor for the crystalline phase, drying, chemically reacting the precursor, and firing to produce a consolidated glass-ceramic material. The pore size of the glass matrix constrains the growth and distribution of nanocrystallite size structures. The precursor infiltrates the porous glass matrix as an aqueous solution, organic solvent solution, or molten salt. Chemical reaction steps may include decomposition of salts and reduction or oxidation reactions. Glass-ceramics produced using Fe-containing dopants exhibit properties of magnetism, low Fe2+ concentrations, optical transparency in the near-infrared spectrum, and low scattering losses. Increased surface area permits expanded catalytic activity. | ||||||
| 180 | Methods for making and using self-constrained low temperature glass-ceramic unfired tape for microelectronics | US10778627 | 2004-02-13 | US06949156B2 | 2005-09-27 | Frans P. Lautzenhiser; Edmar M. Amaya; J. Thomas Hochheimer |
| A monolithic self-constrained green body tape for use in low temperature ceramic co-firing is provided. The tape contains at least two layers: one low temperature ceramic layer containing particles of a glass, a ceramic, and an organic binder, and a self-constraining layer containing a refractory ceramic and a wetting agent for the glass in the first layer. When the tape is fired at a sintering temperature of the low temperature ceramic layer, densification occurs in the z (thickness) direction, but essentially no shrinkage (less than about 1%) occurs in the x-y planes. A method for forming a multilayer green body tape using simultaneous wet on wet ceramic slurry deposition is also provided. A dense, monolithic, low temperature, co-fired, self-constrained, multicomponent structure is also provided. The structure contains at least two multilayer ceramic substrates having electronic circuit components mounted thereon or therein. Each multilayer ceramic substrate contains at least two layers with one being a self-constraining layer. | ||||||
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