201 |
Coating system for cement composite articles |
US11669131 |
2007-01-30 |
US08293361B2 |
2012-10-23 |
T. Howard Killilea; Daniel W. DeChaine; Kevin W. Evanson; Stephen M. Carlson |
A coated article which includes a cement fiberboard substrate and a radiation-curable coating system applied to the substrate. The coating system includes a latex polymer, one or more olefinic compounds and water, and may be provided in the form of one or more coating compositions that may be applied in one or more layers, wherein each of the coating compositions is preferably an aqueous composition, or can be mixed with another composition (e.g., on the substrate) to form an aqueous composition. |
202 |
Coating system for cement composite articles |
US11669134 |
2007-01-30 |
US08277934B2 |
2012-10-02 |
Shaobing Wu; T. Howard Killilea; Glen Otto Vetter; Frank Bor-Her Chen; James M. Bohannon |
A coated article which includes a cement fiberboard substrate and a radiation-curable coating system applied to the substrate. The coating system includes an aqueous dispersion of water-dispersible polymer particles, one or more olefinic compounds and water, and may be provided in the form of one or more coating compositions that may be applied in one or more layers, wherein each of the coating compositions is preferably an aqueous composition, or can be mixed with another composition (e.g., on the substrate) to form an aqueous composition. |
203 |
ENGINEERED STONE AND METHODS OF MANUFACTURING SAME |
US13500125 |
2010-10-11 |
US20120196087A1 |
2012-08-02 |
Ramon Albalak |
Engineered stone, and methods of manufacturing same. An engineered stone comprises: a surface of the engineered stone, wherein the surface comprises one or more pores; and a sealant mixture including a sealant material and a functional component, wherein the functional component modifies one or more properties of said engineered stone. |
204 |
COLORED RADIATION CURABLE COATINGS FOR CONCRETE FLOORS |
US13390835 |
2011-06-30 |
US20120148833A1 |
2012-06-14 |
Huimin CAO; Wenguang LI; Tia Yeon LEE |
Radiation-curable coating compositions for a surface such as a concrete floor, which include one or more acrylate monomers or oligomers having at least four crosslinkable double bonds, at least one photoinitiator, one or more fillers, and at least one pigment or dye are described and claimed. These coating compositions allow for application of at least 0.10 mm (4 mil) thickness of the coating composition over an area larger than a radiation source, without the formation of wrinkles along the shoulder area of each pass of the radiation source in the areas where weak intensity light from a side edge of the radiation source is capable of partially curing only a portion of the coating composition thickness. The coating compositions optionally further comprise one or more tertiary amine compounds comprising zero or one crosslinkable double bonds, the one or more tertiary amine compounds providing an amine value of at least 7.5 mg KOH per gram of the total radiation-curable resins of the coating composition. In addition, a method for coating a surface, and a surface coated with the radiation curable coating compositions of the instant claimed invention are described and claimed. |
205 |
D1479 STABLE LIQUID BAP PHOTOINITIATOR AND ITS USE IN RADIATION CURABLE COMPOSITIONS |
US13388732 |
2011-06-21 |
US20120129969A1 |
2012-05-24 |
Timothy Edward Bishop; Edward Joseph Murphy; John Edmond Southwell; Satyendra Sarmah; TaiYeon Lee |
The invention relates to radiation curable compositions comprising a liquid 0/s(acyl)phosphine photo initiators of formula (Ï): wherein each of Ar1, Ar2 and Ar3 is independently a substituted or unsubstituted aryl group. The invention also relates to stabilized forms of liquid bis(acyl)phosphines of formula (I) and radiation curable composition comprising said stabilized photoinitiators. The radiation curable compositions are selected from the group consisting of an optical fiber coating composition and a coating composition capable of radiation cure on concrete and a coating composition capable of radiation cure on metal. |
206 |
Gypsum panel having UV-cured moisture resistant coating and method of making same |
US12470663 |
2009-05-22 |
US08092858B2 |
2012-01-10 |
Russell Smith |
A method of making a gypsum panel comprises sandwiching a gypsum slurry between two moving sheets of facing material, one of said sheets comprising a fibrous facing material, curing and drying the gypsum slurry to form a set gypsum panel, applying a coating of a radiation curable formulation, which is essentially free of any unreactive components, onto the fibrous facing material of the set gypsum panel, applying a surface coating of an aggregate material onto the coating of the radiation curable formulation, and curing the coating of the radiation curable formulation with high energy radiation, wherein the radiation curable formulation comprises a high energy radiation curable polymer comprising ethylenically unsaturated double bonds. |
207 |
COMPOSITION AND PROCESS FOR SEALING THE SURFACE OF BUILDING MATERIALS |
US13138326 |
2009-02-04 |
US20110293952A1 |
2011-12-01 |
Luca Bonato |
A composition is described, for filling the pores existing in the surfaces of coatings used in architecture, both for exteriors and for interiors, whose function is protecting the above surfaces against stains, comprising: sodium silicate to form a film; natural or synthetic mineral nano-charges to reduce, when drying, the shrinkage of a material deposited inside the pores; glycerine to slow-down drying; water as solvent; surface-active material to make it easier to wet the surface pores; dispersant to stabilise the nano-particles and to avoid their agglomeration and following sedimentation. |
208 |
Sealing material and method of foaming application thereof |
US13119263 |
2008-11-14 |
US20110210517A1 |
2011-09-01 |
Kazuyoshi Sekita; Hiroyuki Nakatani; Seiki Ueno |
Objective problems of the present invention are: to provide a sealing material which does not involve flowing after applied, and shows an excellent sealing performance even under severe heat resistance conditions, and also can make good independent cells inside even when used in a foamed condition; and to provide a method of foaming application of the sealing material. As means of solving these objective problems, the sealing material according to the present invention is characterized by comprising an ultraviolet-curable component and an ultraviolet polymerization initiator and having a thermoplastic elastomer (which is not ultraviolet-curable) content of not higher than 5 weight % and comprising an acrylate as the ultraviolet-curable component and having a melt-viscosity at 120° C. in a certain range wherein the acrylate has a glass transition temperature after ultraviolet curing and a weight-average molecular weight in their respective certain ranges; and the method according to the present invention of foaming application of a sealing material is characterized by comprising the steps of: hot-melting the sealing material; mixing nitrogen gas into the melted sealing material under a predefined pressurization; discharging the resultant mixture at a predefined pressure into the air to thus foam the mixture and simultaneously apply it to a place necessary to seal, thus making a sealing foam; and curing this sealing foam by ultraviolet rays. |
209 |
Clay thin film substrate, clay thin film substrate with electrode, and display device using the same |
US12067666 |
2006-09-19 |
US07898636B2 |
2011-03-01 |
Tomohito Inoue; Hajime Tsuda; Katsumi Motegi; Takeo Ebina; Fujio Mizukami |
A clay thin film substrate including a clay thin film having a structure, in which oriented clay particles are laminated; and at least a gas barrier inorganic layer which is laminated on at least one surface of the clay thin film. |
210 |
POROUS CERAMICS MANUFACTURING METHOD |
US12721782 |
2010-03-11 |
US20100234481A1 |
2010-09-16 |
Masaki SUGIMOTO; Masahito YOSHIKAWA; Akinori TAKEYAMA; Ken'ichiro KITA; Masaki NARISAWA; Hiroshi Mabuchi |
A method of manufacturing porous ceramics, for example, thin film used for gas separation is disclosed. In this method, a silicon based mixture polymeric material which is the ceramics precursor is applied on a ceramics substrate, crosslinked by using ionizing radiation under oxygen free conditions; and pyrolyzed under an inert gas after that. |
211 |
Microwave process for porous ceramic filters with passivation and catalyst coatings |
US11261226 |
2005-10-27 |
US07700163B2 |
2010-04-20 |
Roychelle Sheneen Ingram-Ogunwumi; Steven Bolaji Ogunwumi; Barbara Anna Oyer; Paul John Shustack |
A method for base-coating a porous ceramic catalyst support includes coating the support with a passivation coating via vacuum infiltration, and subsequently exposing the support to a microwave field to dry the coating and form a polymerized film. The method further includes coating the support with a catalyst coating or washcoat, and subsequently exposing the support to a second microwave field, thereby removing water from the catalyst coating or washcoat. |
212 |
Compositions and methods for sealing natural stone tiles and natural stone articles |
US12157089 |
2008-06-06 |
US20090301027A1 |
2009-12-10 |
David Pelletier; Roger Questel; Larry Wasowski; Dorian C. Guptill |
The present invention relates to a method of sealing natural stone tiles and stone articles by applying and curing by UV radiation a liquid, solventless sealant onto natural stone tiles and articles to provide permanent protection, abrasion resistance, chemical and stain resistance and resistance to mold and other biological growth stains. The UV-curable solventless sealing composition comprises an effective amount of carboxyl functional, UV-curable reagent to provide for adhesion of the cured coating to the stone article. Additionally, the method describes the application of an optional liquid primer sealant comprising a UV-curable aqueous dispersion of an acrylate-functional resin. |
213 |
Gypsum Panel Having UV-Cured Moisture Resistant Coating and Method of Making Same |
US12470663 |
2009-05-22 |
US20090223618A1 |
2009-09-10 |
Russell Smith |
A fibrous mat faced gypsum panel having on at least one of the facing sheets a moisture resistant, cured coating of a radiation curable, e.g., UV curable, polymer. |
214 |
Clay Thin Film Substrate, Clay Thin Film Substrate with Electrode, and Display Device Using the Same |
US12067666 |
2006-09-19 |
US20090141230A1 |
2009-06-04 |
Tomohito Inoue; Hajime Tsuda; Katsumi Motegi; Takeo Ebina; Fujio Mizukami |
A clay thin film substrate including a clay thin film having a structure, in which oriented clay particles are laminated; and at least a gas barrier inorganic layer which is laminated on at least one surface of the clay thin film. |
215 |
Concrete coloring compositions and methods |
US12291316 |
2008-11-07 |
US20090139435A1 |
2009-06-04 |
Sanford Lee Hertz; Ed Daraskevich; William Tao; Jason J. Netherton; Matthew S. Gebhard; T. Howard Killilea; Kevin W. Evanson |
The present invention provides acidic compositions and methods that are adapted to impart color to cementitious or mineral substrate surfaces. Specifically, the present invention relates to acidic compositions and methods adapted to treat cementitious or mineral substrate surfaces that have the advantage of using a less corrosive acid-based solution. The acidic composition incorporates species including a weak base in equilibrium with a conjugate acid. The presence of such species moderates the corrosive behavior of the acid while still allowing excellent coloring action to occur. |
216 |
Hybrid lens using translucent ceramic |
US11727616 |
2007-03-27 |
US07431984B2 |
2008-10-07 |
Yuji Kintaka; Satoshi Kuretake; Nobuhiko Tanaka |
A hybrid lens (3) has a structure in which a resin layer (2) composed of an ultraviolet curable resin is formed on the surface of a lens base material (1) composed of translucent ceramic. The lens base material (3) is composed of translucent ceramic containing as a main component an oxide with a perovskite structure represented by A{M,(B1, B2)}O3 (A is at least one selected from Ba, Sr and Ca, B1 is at least one selected from In, Y, Zn and Mg, B2 is at least one selected from Ta and Nb, and M is at least one selected from Ti, Zr, Hf and Sn) and at least Fe and Cu as sub-components. When the Fe content and Cu content in the translucent ceramic are x and y, respectively, 3x+y is 40 ppm by weight or less so that the hybrid lens (3) having excellent uniformity in optical properties and no crack defect can be obtained. |
217 |
Composite article and fabrication method |
US11713924 |
2007-03-05 |
US20080220240A1 |
2008-09-11 |
Wayde R. Schmidt |
A refractory metal composite article includes a refractory metal ceramic section and a refractory metal ceramic coating that together form a porous matrix. A solid filler is within pores of the porous matrix to, for example, reduce a porosity of the refractory metal composite article. |
218 |
Uv-Radiation-Curable Precious-Metal Preparation, Transfer Pictures Containing Said Preparation, and Process for Decoration |
US11570159 |
2005-06-22 |
US20070243336A1 |
2007-10-18 |
Kersken Knuth; Maurizio Ragnetti; Robert Sievi; Frank Walter; Andreas Schulz |
The invention relates to a radiation-curable precious-metal preparation, in particular a bright-gold preparation, that contains—in addition to a gold compound, which in particular is soluble in the printing medium, and further customary organometallic compounds—a radiation—curable, in particular UV-curable, printing medium, the polymerisation being initiated by the UV radiation and proceeding in accordance with a cationic mechanism which may optionally be assisted by y process that takes place simultaneously in accordance with a radical mechanism. The invention also relates to a transfer picture containing the precious-metal preparation, and to a process for decorating substrates that are suitable for decoration firing by direct application/printing and indirect printing (decalcomania). |
219 |
Decoration method |
US11101328 |
2005-04-07 |
US07166333B2 |
2007-01-23 |
James Anthony Lodge |
A method of decorating an article, the method comprising mixing a thermochromic ink with a transparent lacquer, applying the mixture on to part or all of the surface of an article, once the mixture is set, applying a second layer of dishwasher proof transparent lacquer. |
220 |
Method for the decoration of porous ceramic materials and in particular polished porcelain stoneware |
US10529442 |
2003-10-01 |
US20060165903A1 |
2006-07-27 |
Raffaello Mazzanti |
The present invention relates to a method for the decoration of porous ceramic materials and in particular polished porcelain stoneware comprising the application of a pigment or dye suitably carried on a ceramic substrate so as to allow said pigment or dye to penetrate the surface pores of the ceramic substrate, an optional drying of the colored substrate and the subsequent application of a hardenable composition in order to fix the decoration applied to the ceramic substrate. Another option for the decoration consists in the application of a pigmented hardenable composition. The hardenable composition advantageously consists of a photocurable composition. |