141 |
LIMESTONE MASONRY VENEER, RESURFACING AND AESTHETIC OVERLAY COMPOSITIONS, METHODS OF MAKING AND METHODS OF USE |
US14642379 |
2015-03-09 |
US20150251953A1 |
2015-09-10 |
Kenneth W. Morrison; Norman L. Hains |
A limestone based masonry veneer composition is described that may be molded, blown, sprayed, troweled, or otherwise applied to interior and exterior surfaces. The composition provides an aesthetic resurfacing, cladding and/or overlay coating. The composition is capable of being pigmented, textured, sculpted—or otherwise formed into an aesthetic, realistic, architecture, suitable as a stone veneer, an example of which is Blown Stone®, by Stone Coat®. Texturing or sculpting may occur about 1 hour and up to about 12 hours after applying the composition. The final composition is hydrophobic and breathes. Air carbonation allows the formation of a predominantly very pure calcium carbonate or limestone when fully cured, which prevents mold and algae growth and allows for autogenous healing with an increase in unit weight over time, ensuring an overall high compressive strength that endures over time. |
142 |
LOW-DENSITY PARTICLES FOR VEHICLE ARRESTING SYSTEMS |
US14639354 |
2015-03-05 |
US20150251773A1 |
2015-09-10 |
Shawn Doherty; Silvia C. Valentini |
Embodiments of the present invention provide systems and methods for vehicle arresting systems made from low-density particles and appropriate binders. The systems are designed to provide a barrier or a bed that is placed at the end of a runway or at the edge of a highway that will predictably and reliably crush (or otherwise deform) under the pressure of vehicle wheels traveling off the end of the runway or the edge of the road. |
143 |
PROTECTIVE COATING SYSTEMS FOR GAS TURBINE ENGINE APPLICATIONS AND METHODS FOR FABRICATING THE SAME |
US14156502 |
2014-01-16 |
US20150197456A1 |
2015-07-16 |
Reza Oboodi; Eric Passman; Bahram Jadidian |
Protective coating systems for gas turbine engine applications and methods for fabricating such protective coating systems are provided. An exemplary protective coating system includes a substrate formed of a ceramic matrix composite material, a first coating layer formed directly on to the substrate and comprising an oxygen barrier material, a compliance material, or a bonding material and a second coating layer formed directly on to the first coating layer and comprising a thermal barrier material. The exemplary protective coating optionally includes a third coating layer partially formed directly on to the second coating layer and partially formed within at least some of the plurality of pores of the second coating layer. |
144 |
Asbestos-treating agent and method for treating asbestos |
US13509789 |
2010-11-19 |
US08704032B2 |
2014-04-22 |
Yoshihiro Taguchi; Teruhiko Kusano; Hiroaki Harano |
To provide a treatment agent for asbestos, which has a less influence on human body, the construction and the surrounding environment and can render the asbestos harmless evenly up to the inside of the bulky covering materials, which cover the wall, or the slate materials, and a treatment method of the asbestos using the same.A treatment agent for asbestos, which contains phosphoric acid of 0.5 through 3.0% by weight, hydrogen peroxide of 1 through 20% by weight, alcohol of 0.5 through 20% by weight and pure water and a treatment method of the asbestos using the same are described. |
145 |
ASBESTOS-TREATING AGENT AND METHOD FOR TREATING ASBESTOS |
US13509789 |
2010-11-19 |
US20120289756A1 |
2012-11-15 |
Yoshihiro Taguchi; Teruhiko Kusano; Hiroaki Harano |
To provide a treatment agent for asbestos, which has a less influence on human body, the construction and the surrounding environment and can render the asbestos harmless evenly up to the inside of the bulky covering materials, which cover the wall, or the slate materials, and a treatment method of the asbestos using the same.A treatment agent for asbestos, which contains phosphoric acid of 0.5 through 3.0% by weight, hydrogen peroxide of 1 through 20% by weight, alcohol of 0.5 through 20% by weight and pure water and a treatment method of the asbestos using the same are described. |
146 |
Honeycomb structural body and manufacturing method thereof |
US12872102 |
2010-08-31 |
US07976605B2 |
2011-07-12 |
Tomohisa Takahashi |
A honeycomb structural body including a ceramic block having a flat shape and comprising a plurality of honeycomb units, a sealing material layer bonding the honeycomb units and comprising a sealing material paste, and a peripheral sealing material layer formed on a peripheral portion of the ceramic block. The flat shape has a cross-section which is bisected by an axis, the sealing material layer forms an angle diagonal with respect to the axis of the flat shape, the sealing material layer has end portions abutting against the peripheral sealing layer at a diagonal angle, and each of the honeycomb units has through holes extending in a longitudinal direction of the ceramic block and a partition wall portion between the through holes. |
147 |
Honeycomb structural body and manufacturing method thereof |
US11092902 |
2005-03-30 |
US07846229B2 |
2010-12-07 |
Tomohisa Takahashi |
A honeycomb structural body includes a ceramic block having a flat shape and including honeycomb units bonded to each other through a sealing material layer, each of the honeycomb units made of porous ceramic and having through holes extending in parallel with one another in a longitudinal direction of the ceramic block and a partition wall interposed between the through holes. The honeycomb structural body further includes a peripheral sealing material layer formed on a peripheral portion of the ceramic block. The sealing material layer is formed such that the sealing material layer abuts against the peripheral sealing layer at an angle in a diagonal direction with respect to a major axis of a contour of the ceramic block in a cross section perpendicular to the longitudinal direction. |
148 |
METHOD FOR THE PRODUCTION OF A CERAMIC SUBSTRATE, AND A CERAMIC SUBSTRATE |
US12373332 |
2007-07-13 |
US20090305867A1 |
2009-12-10 |
Marco Ebert; Martin Henrich; Andreas Lauer; Gotthard Nauditt; Thorsten Scheibel; Roland Weiss |
A method for the production of a ceramic substrate for a semiconductor component, includes the steps of producing paper containing at least cellulose fibers, as well as a filler to be carbonized and/or SiC, pyrolizing the produced paper, and siliconizing the pyrolyzed paper. |
149 |
Mortar tile and method for production thereof |
US10565035 |
2004-07-14 |
US20060185307A1 |
2006-08-24 |
Nobuyoshi Yukihira; Tetsuro Oike; Katsuyuki Nakano |
The present invention provides a mortar tile which can reduce labor, time and cost required for installation without reducing a harmful substance decomposing ability using a photoresist. To achieve such an object, a mortar which is molded in a tile shape is manufactured by forming a formed article in a state that a photocatalyst is added to the mortar and, thereafter, the pressure-forming is performed at a pressure which allows the formation of open pores in a surface thereof, and a photocatalyst is applied to a surface of the formed article. |
150 |
Pre-fabricated structural components strengthened with tensile reinforcements and method for production thereof |
US10484490 |
2002-07-18 |
US20050011147A1 |
2005-01-20 |
Herbert Giesemann |
The prefabricated structural components strengthened by tensile reinforcements, preferably metal inlays, containing binders and aggregates, wherein said binder is an alkali water glass, and the aggregates have a broad grain size distribution like aggregates added to reinforced concrete. |
151 |
BOND LAYER FOR SILICON CONTAINING SUBSTRATE |
US10443343 |
2003-05-22 |
US20040234740A1 |
2004-11-25 |
Greg
C.
Ojard; Harry
E.
Eaton; Shantikumar
V.
Nair; Yasser
A.
Gowayed |
A bond layer and a further layer on the bond layer, the bond layer comprising a silicon layer having a dispersion of fibers, wherein at least some of the fibers extend between the bond layer and the further layer. The fibers are formed from a material selected from the group consisting of (1) alumina, (2) yttria, (3) aluminum silicate, (4) silicon carbide, (5) silicon nitride, (6) compounds of rare earth elements, alkaline earth elements, aluminum, silicon, oxygen, yttrium, nitrogen, niobium, tantalum, hafnium, zirconium, carbon and mixtures of (1) thru (6). |
152 |
Process for coating a ceramic honeycomb body |
US09745176 |
2000-12-22 |
US06596056B2 |
2003-07-22 |
Rainer Domesle; Thomas Kreuzer; Egbert Lox |
A process for coating, with a suspension, a ceramic honeycomb body which has a cylindrical shape with two flat end-faces and one jacket, and through which channels parallel to the axis, formed by channel walls, run from one flat end-face to the other, the honeycomb body being coated by suitable processes. The honeycomb body is partially wetted and then coated. |
153 |
Hardenable exterior texture material in aerosol form |
US09775061 |
2001-02-01 |
US06399687B2 |
2002-06-04 |
John R. Woods |
A hardenable texture material is disclosed for application to a patch surface surrounded by a stucco-like material having an irregular surface texture to form a layer of textured patch material on the patch surface, wherein the hardenable texture material is storable in a pressurized fluid-tight aerosol dispensing container. The hardenable texture material includes a liquid base and a stucco filler substance having large particulates resembling stucco. An aerosol system with a spray nozzle is included on the container for selective discharge of the hardenable texture material onto a prepared patch area so as to match and blend with the surrounding stucco-covered surface area in order to provide a continuous and unbroken coextensive surface texture of mechanically and visually matched material. |
154 |
Hardenable exterior texture material in aerosol form |
US09312554 |
1999-05-14 |
US06225393B1 |
2001-05-01 |
John R. Woods |
A hardenable texture material is disclosed for application to a patch surface surrounded by a stucco-like material having an irregular surface texture to form a layer of textured patch material on the patch surface, wherein the hardenable texture material is storable in a pressurized fluid-tight aerosol dispensing container. The hardenable texture material includes a liquid base and a stucco filler substance having large particulates resembling stucco. An aerosol system with a spray nozzle is included on the container for selective discharge of the hardenable texture material onto a prepared patch area so as to match and blend with the surrounding stucco-covered surface area in order to provide a continuous and unbroken coextensive surface texture of mechanically and visually matched material. |
155 |
Ceramic structural body |
US894793 |
1997-09-09 |
US5914187A |
1999-06-22 |
Kazuya Naruse; Satoshi Ohno; Koji Shimato; Hiroshi Okazoe; Seiki Iwahiro |
Ceramic structural body having improved material properties of a sealing member, such as adhesion properties at room temperature and high temperature, and having an improved durability. The ceramic structural body comprises an assembly of plural united ceramic members each having a plurality of through-holes arranged side by side along a longitudinal direction, in which end faces at either side of these through-holes are closed in a checkered pattern so as to have a reverse relation of open and close between gas inlet side and gas outlet side and adjacent through-holes are permeable to each other through porous partition walls. A plurality of the ceramic members are integrally adhered by interposing a sealing member of an elastic material comprising at least inorganic fibers, an inorganic binder, an organic binder and inorganic particles and mutually bonded three-dimensionally intersected organic fibers and inorganic particles through the inorganic binder and organic binder between the mutual ceramic members. |
156 |
Use of a paste containing precious metals for the production of browning
dishes for microwave ovens |
US126096 |
1987-11-30 |
US4830894A |
1989-05-16 |
Guy Roche; Gerard Labregere |
Metal coatings for browning dishes to be used in microwave ovens are obtained by use of plastes of:(a) 50 to 80% by weight of a mixture of(aa) 5 to 70% by weight of a conductive component formed of 5 to 95% by weight ruthenium oxide, and the balance being at least one of silver, palladium, rhodium oxide and/or bismuth oxide,(bb) 30 to 95% by weight of a glass frit(b) 20 to 50% by weight of an organic binder.Coatings which are applied to glass, ceramic and/or vitreous ceramic dishes and cooking vessels are very adherent and in a few minutes reach temperatures of up to 300.degree. C. |
157 |
Highly porous ceramic material for absorption and adsorption purposes,
particularly for animal litter/bedding, process for the production
thereof and the use thereof |
US71539 |
1987-07-08 |
US4824810A |
1989-04-25 |
Rudiger Lang; Bernd Meyer |
Highly porous ceramic material for adsorption and absorption purposes, particularly for animal litter, characterized by a porosity of 50 to 300%, preferably 200 to 250%; a water absorption capacity of 50 to 200%, preferably 100 to 150%, a pH-value in the range 5 to 9, preferably 7 to 8; a bulk density of 400 to 700 g/1; an internal surface (BET-N.sub.2) between 20 and 200 m.sup.2 /g, preferably between 80 and 150 m.sup.2 /g; which can be produced by firing a foamed mixture of clay or clays, optionally aggregate or aggregates, anionic or cationic surfactant or surfactants and deflocculant or deflocculants, process for the production thereof and use thereof. |
158 |
Oxidation protection for carbon composite materials |
US646943 |
1984-09-04 |
US4582751A |
1986-04-15 |
Thomas Vasilos; Richard D. Webb |
Carbon composite materials of increased resistance to oxidation are produced by heating a porous carbon composite material to an elevated temperature in a reaction chamber and introducing into said chamber a gas mixture comprising a decomposable boron-containing gas and a diluent and effecting deposition of boron as a solid on the walls of the pores of said composite as a consequence of said boron-containing gas decomposing. |
159 |
Paste for forming a transparent, conductive film |
US448488 |
1982-12-10 |
US4460496A |
1984-07-17 |
Mitsuru Kano; Yoshimi Kamijo |
A paste for forming a transparent conductive film is provided. The paste comprises an organometallic compound convertible into a transparent conductive metal oxide by calcination, an organic solvent and a thickening agent characterized in that the paste further contains an organic monoazo compound difficultly soluble in the organic solvent, combustible at a high temperature and having the general formula: ##STR1## wherein X represents H, NO.sub.2 or OCH.sub.3 in a m- or p-position, Y represents NO.sub.2 or OCH.sub.3 in an o-position, Z represents OCH.sub.3, CH.sub.3 or H in an o-position and W represents H or CH.sub.3 in the m- or p-position. |
160 |
Method of manufacturing cement products having superior mechanical
strength |
US253747 |
1981-03-09 |
US4407769A |
1983-10-04 |
Shozo Harada; Kazuo Ito; Takayuki Shirai; Tetsuya Koide |
This invention is based on the discovery by the inventors that, if a preliminary hydration hardening process and a full-scale hydration hardening process are provided after the molding process, and a process for burning a hardened body of cement at a high temperature is provided between the preliminary and full-scale hardening processes, it is possible to obtain a molded product of cement having a higher mechanical strength than any such product according to any known method including no such burning process.According to this invention, there is provided a method of manufacturing a product of cement having high mechanical strength, which method comprises the steps in sequence of adding water, and if required, glass fibers or other reinforcing material, into a mixture of cement and an aggregate, and kneading the whole completely; molding the kneaded mixture into a desired shape; hardening the molded body preliminarily by hydration; burning the preliminarily hardened body at a high temperature; and hardening the burned body on a full scale by hydration. |