221 |
High strength, density controlled cold fusion concrete cementitious spray applied fireproofing |
US15474074 |
2017-03-30 |
US09932269B2 |
2018-04-03 |
Rodney Zubrod |
A density controlled cold fusion concrete cementitious spray applied fireproofing material including a mixture of water, one or more of silicon dioxide, expanded glass, vermiculite, bottom ash, perlite, expanded shale, or other lightweight aggregates of various diameter sizes ranging from about 0.025 mm to about 12.5 mm in diameter; anhydrous or hydrous sodium or potassium metasilicate; waste from steel production consisting of Granulated Ground Blast Furnace Slag (GGBFS); high calcium or low calcium waste from coal combustion (fly ash or bottom ash); sodium tetraborate, sodium citrate dihydrate, citric acid, or boric acid; and an alkali-resistant micro-. |
222 |
Acoustical ceiling tile |
US14866055 |
2015-09-25 |
US09896807B2 |
2018-02-20 |
Mark H. Englert; William A. Frank |
An acoustical tile including: 8 to 25 wt % mineral wool, 9 to 15 wt % starch binder, 9 to 15 wt % cellulosic fiber, wherein preferably the cellulosic fiber is newsprint, and 40 to 65 wt % perlite, wherein the weight ratio of the starch to the cellulosic fiber is 0.6 to 1.3:1; and a process for making the acoustical tile. |
223 |
WASTE TO ENERGY ASH AND ENGINEERED AGGREGATE IN ROAD CONSTRUCTION |
US15631743 |
2017-06-23 |
US20170370050A1 |
2017-12-28 |
Timothy G. Townsend; Justin G. Roessler; Christopher C. Ferraro |
Described herein are compositions and methods for waste-to-energy ash in engineered aggregate in road construction. |
224 |
COBALT FREE PREPROMOTED UNSATURATED POLYESTER RESIN SYSTEM FOR ENGINEERED STONE |
US15321136 |
2015-06-29 |
US20170197881A1 |
2017-07-13 |
José Luís Miquel Peraire; Javier López De Alda Madorran; Tuomo SJÖBERG |
The invention relates to a formable composition for the preparation of engineered stone comprising a cobalt free prepromoted unsaturated polyester resin system, an inorganic particulate material and a peroxide component. The invention also relates to a method for the preparation of engineered stone as well as to the use of the cobalt free prepromoted unsaturated polyester resin system for the preparation of engineered stone. |
225 |
High strength, density controlled cold fusion concrete cementitious spray applied fireproofing |
US15228829 |
2016-08-04 |
US09670096B1 |
2017-06-06 |
Rodney Zubrod |
A density controlled cold fusion concrete cementitious spray applied fireproofing material including a mixture of water, one or more of silicon dioxide, expanded glass, vermiculite, bottom ash, perlite, expanded shale, or other lightweight aggregates of various diameter sizes ranging from about 0.025 mm to about 12.5 mm in diameter; anhydrous or hydrous sodium or potassium metasilicate; waste from steel production consisting of Granulated Ground Blast Furnace Slag (GGBFS); high calcium or low calcium waste from coal combustion (fly ash or bottom ash); sodium tetraborate, sodium citrate dihydrate, citric acid, or boric acid; and an alkali-resistant micro-. |
226 |
Method of manufacturing a corrosion-resistant sacrificial protective coating |
US14332409 |
2014-07-16 |
US09644102B2 |
2017-05-09 |
Emeline Pedoni; Polina Volovitch; Kevin Ogle |
The present disclosure provides an aqueous binder composition for forming a sacrificial corrosion-protective coating, said composition being free of chromates and also preferably free of borates and molybdates. Said binder composition advantageously has a pH of less than 6 and comprises a binder, particles of at least one metal oxide and at least one metallic phosphate, said binder comprising a hydrolyzed organosilane oligomer. In addition, the proportion by weight of said particles of at least one metal oxide relative to the total dry weight of said binder composition is greater than or equal to 75%. |
227 |
ACOUSTICAL CEILING TILE |
US14866055 |
2015-09-25 |
US20170089014A1 |
2017-03-30 |
Mark H. Englert; William A. Frank |
An acoustical tile including: 8 to 25 wt % mineral wool, 9 to 15 wt % starch binder, 9 to 15 wt % cellulosic fiber, wherein preferably the cellulosic fiber is newsprint, and 40 to 65 wt % perlite, wherein the weight ratio of the starch to the cellulosic fiber is 0.6 to 1.3:1; and a process for making the acoustical tile. |
228 |
Process to produce a durable concrete at hot ambient conditions |
US14425949 |
2013-09-23 |
US09328019B2 |
2016-05-03 |
Wolfram Franke |
The invention relates to the use of calcium nitrate for producing a cementitious composition and/or a cementitious solid at high ambient temperatures. The invention is directed to ensuring sufficient hydration by a limitation of the maximum hydration temperature. |
229 |
Ultra-Lightweight Gypsum Wallboard |
US14317647 |
2014-06-27 |
US20150376063A1 |
2015-12-31 |
Hubert C. Francis |
A gypsum wallboard and a method of making the wallboard using a modified beta-gypsum hemihydrate obtained by calcining gypsum in the presence of a calcination modifier, under conditions for forming a beta-gypsum hemihydrate, wherein the wallboard is prepared using a stucco slurry formed by mixing the modified beta-gypsum hemihydrate with water, pre-gelatinized starch and a stucco dispersant. |
230 |
BINDER COMPOSITION, A METHOD OF MANUFACTURING A CORROSION-RESISTANT SACRIFICIAL PROTECTIVE COATING USING SAID COMPOSITION, AND A SUPPORT COATED WITH SUCH A COATING |
US14332409 |
2014-07-16 |
US20150337141A1 |
2015-11-26 |
Emeline PEDONI; Polina VOLOVITCH; Kevin OGLE |
The present disclosure provides an aqueous binder composition for forming a sacrificial corrosion-protective coating, said composition being free of chromates and also preferably free of borates and molybdates. Said binder composition advantageously has a pH of less than 6 and comprises a binder, particles of at least one metal oxide and at least one metallic phosphate, said binder comprising a hydrolyzed organosilane oligomer. In addition, the proportion by weight of said particles of at least one metal oxide relative to the total dry weight of said binder composition is greater than or equal to 75%. |
231 |
CEMENT COMPOSITIONS CONTAINING METAPHOSPHATE AND METHODS OF USE |
US14636964 |
2015-03-03 |
US20150175870A1 |
2015-06-25 |
Rahul Chandrakant Patil; Sandip Prabhakar Patil; Sohini Bose; Ashok K. Santra; Balasundaram Balaraman |
In an embodiment, the cement compositions comprise: (i) hydraulic cement, wherein the hydraulic cement has a ratio of CaO to SiO2 in the range of 2.0 to 4.0; and (ii) a water-soluble metaphosphate in a concentration of at least 2.5% bwoc. In another embodiment, the cement compositions comprise: (i) hydraulic cement, wherein the hydraulic cement has a ratio of CaO to SiO2 of less than 2.0; and (ii) a water-soluble metaphosphate; wherein any alkali nitrate is in a concentration of less than 2% bwoc; and wherein any alkali hydroxide, alkali carbonate, or alkali citrate is in a concentration of less than 0.2% bwoc. Methods of cementing in a well comprising forming either of such cement compositions and introducing it into the well are provided. |
232 |
Aqueous gypsum plaster-cement composition and its use |
US13821487 |
2011-09-08 |
US09027303B2 |
2015-05-12 |
Hubert Lichtinger; Bernd Bruno Winfried Eck |
An aqueous gypsum plaster-cement composition comprises a hydraulic binder consisting of calcined gypsum and hydraulic cement in a weight ratio of from about 4:1 to about 2:1, an aggregate which comprises sand, a foam, a perlite, rice hulls or a mixture thereof, a superplasticizer comprising an air entraining agent, a retarder, and water in an amount of from about 0.4 to about 0.75 parts by weight per part of binder, with the proviso that the gypsum plaster-cement composition contains essentially neither a pozzolana nor lime. The use thereof, a method of constructing buildings using this composition and the buildings obtainable in this way are also described. |
233 |
JOINT COMPOUND, WALL ASSEMBLY, AND METHODS AND PRODUCTS RELATED THERETO |
US14500333 |
2014-09-29 |
US20150083303A1 |
2015-03-26 |
Robert H. Negri; Mark Miklosz |
Disclosed are aspects of board finishing systems. For example, in various aspects, disclosed are joint compound compositions, wall assemblies, methods of treating walls, and products related to any of the foregoing, including reinforcement trim, e.g., for protecting corners where boards meet, fasteners, and tape. The joint compound preferably is a drying type composition with reduced shrinkage property, and includes binder and hollow spheres, resulting in an ultra lightweight formulation in some embodiments. The joint compound composition can be applied in a one-coat treatment in preferred embodiments. Other aspects of board finishing system accommodate such a one-coat treatment to thusly allow a user to manipulate the compound closer to the plane of board as compared with conventional formulations. Joint tape and reinforcement trim can include non-swelling synthetic paper facing material in some embodiments. |
234 |
Process for producing honeycomb structure |
US12367879 |
2009-02-09 |
US08974723B2 |
2015-03-10 |
Yasushi Noguchi; Takehiko Watanabe; Takeshi Tokunaga; Yukari Nakane |
A process for producing a honeycomb structure includes: a mixing step where forming raw materials including a ceramic raw material are mixed to obtain a forming blended material, a kneading step where the forming blended material is kneaded to obtain kneaded clay, a forming step where the kneaded clay is formed into a honeycomb shape to obtain a honeycomb formed article, and a firing step where the honeycomb formed article is fired to obtain a honeycomb structure. The ceramic raw material is a cordierite forming raw material, and a magnetic powder contained in the kneaded clay is at a ratio of 400 ppm or less with respect to solid content conversion mass of the whole kneaded clay. There is provided a honeycomb structure capable of improving trapping efficiency, in particular, initial trapping efficiency by reducing the number of coarse pores in the partition walls. |
235 |
Joint compound, wall assembly, and methods and products related thereto |
US13842342 |
2013-03-15 |
US08931230B2 |
2015-01-13 |
Robert H. Negri; Mark Miklosz |
Disclosed are aspects of board finishing systems. For example, in various aspects, disclosed are joint compound compositions, wall assemblies, methods of treating walls, and products related to any of the foregoing, including reinforcement trim, e.g., for protecting corners where boards meet, fasteners, and tape. The joint compound preferably is a drying type composition with reduced shrinkage property, and includes binder and hollow spheres, resulting in an ultra lightweight formulation in some embodiments. The joint compound composition can be applied in a one-coat treatment in preferred embodiments. Other aspects of board finishing system accommodate such a one-coat treatment to thusly allow a user to manipulate the compound closer to the plane of board as compared with conventional formulations. Joint tape and reinforcement trim can include non-swelling synthetic paper facing material in some embodiments. |
236 |
JOINT COMPOUND, WALL ASSEMBLY, AND METHODS AND PRODUCTS RELATED THERETO |
US14492905 |
2014-09-22 |
US20150007519A1 |
2015-01-08 |
Robert H. Negri; Mark Miklosz |
A kit for assembling walls and ceilings is provided. The kit comprises at least two gypsum boards, each with at least one tapered edge, and a self-drying joint compound comprising a polymeric binder and hollow spheres. Methods for wall and ceiling installation are provided as well. |
237 |
MONOLITHIC COMPOSITION |
US14361863 |
2012-11-09 |
US20140378596A1 |
2014-12-25 |
Ken Yonaiyama; Tetsuya Mihara; Tomohiko Kishiki; Tetsuya Ishihara |
A paste-like unshaped composition including inorganic fibers that have the following composition ratio and are not coated with a coating layer; an inorganic binder; and a solvent, wherein the composition further optionally comprises inorganic powder, the ratio of the inorganic fibers and the inorganic powder is 100:0 to 10:90, the composition comprises no pH adjuster and no organic fibers, and when the inorganic powder is contained, the inorganic powder does not contain a needle-like crystal structure, [Composition ratio of inorganic fibers] SiO2 66 to 82 wt %; CaO 10 to 34 wt %; MgO 3 wt % or less; Al2O3 5 wt % or less; and the total of SiO2, CaO, MgO and Al2O3 is 98 wt % or more. |
238 |
Use of a concrete-based element for treatment of gases and volatile compounds |
US13501375 |
2010-10-11 |
US08888894B2 |
2014-11-18 |
Isabelle Dubois-Brugger; Mélanie Dykman; Matthieu Horgnies |
A method includes using an element which includes a monoblock concrete body with a volume greater than 1 L and a surface porosity greater than 8%, which body includes in the body and/or on a surface thereof a compound having a BET specific surface greater than 100 m2/g, and which element does not include a photocatalytic agent, to absorb from the atmosphere a gas selected from the group consisting of nitrogen oxides, carbon oxides, sulphur oxides, and ozone, or a volatile organic compound. |
239 |
Calcium sulfoaluminate cement-containing inorganic polymer compositions and methods of making same |
US13307188 |
2011-11-30 |
US08864901B2 |
2014-10-21 |
Redmond Richard Lloyd; Louise Margaret Keyte; Russell L. Hill; Zhaozhou Zhang; Mark Hollett; Li Ai |
Inorganic polymer compositions and methods for their preparation are described herein. The compositions include the reaction product of a reactive powder, an activator, and optionally a retardant. The reactive powder includes fly ash, calcium sulfoaluminate cement, and less than 10% by weight portland cement. In some examples, the composition is substantially free from alkanolamines. In some examples, the ratio of water to reactive powder is from 0.06:1 to less than 0.2:1. Also described herein are building materials including the compositions. |
240 |
Biodegradable retarder for cementing applications |
US10979681 |
2004-11-02 |
US08858860B2 |
2014-10-14 |
Ashok K. Santra; B. Raghava Reddy; D. Chad Brenneis |
Cement compositions comprising carboxylated inulin and methods of using the same to cement a workspace. In one embodiment, a method of cementing includes providing a cement composition comprising a carboxylated inulin, for example, in a subterranean formation. The method further includes allowing the cement composition to set. In some embodiments, the cement composition has a thickening time of from about 2 hours to about 11 hours. In other embodiments, the cement composition has a viscosity that is about constant for a period of time after the cement composition is placed. |