201 |
Porous ceramic articles and method of making the same |
US21104338 |
1938-05-31 |
US2297539A |
1942-09-29 |
DIAMOND GRANT S |
|
202 |
Process for making porous material |
US17887237 |
1937-12-09 |
US2271845A |
1942-02-03 |
PARSONS JOSEPH R |
|
203 |
Method of making porous articles of ceramic bonded granular material |
US964335 |
1935-03-06 |
US2007053A |
1935-07-02 |
HOWE WALLACE L |
|
204 |
Porous article of ceramic bonded granular material |
US59985132 |
1932-03-18 |
US2007052A |
1935-07-02 |
HOWE WALLACE L |
|
205 |
Refractory material and method of manufacturing |
US55321531 |
1931-07-25 |
US1939638A |
1933-12-12 |
HYDE REED W |
|
206 |
Sound-absorbing surface and process of producing same |
US21632527 |
1927-08-29 |
US1682986A |
1928-09-04 |
RYMARCZICK LYAL B |
|
207 |
POROUS STABILIZED BEDS, METHODS OF MANUFACTURE THEREOF AND ARTICLES COMPRISING THE SAME |
US15910052 |
2018-03-02 |
US20180204656A1 |
2018-07-19 |
James F. Klausner; Renwei Mei; Ayyoub Mehdizadeh Momen; Kyle Allen |
Disclosed herein is a method comprising disposing a first particle in a reactor; the first particle being a magnetic particle or a particle that can be influenced by a magnetic field, an electric field or a combination of an electrical field and a magnetic field; fluidizing the first particle in the reactor; applying a uniform magnetic field, a uniform electrical field or a combination of a uniform magnetic field and a uniform electrical field to the reactor; elevating the temperature of the reactor; and fusing the first particles to form a monolithic solid. |
208 |
SELF-SUPPORTED INORGANIC SHEETS, ARTICLES, AND METHODS OF MAKING THE ARTICLES |
US15836286 |
2017-12-08 |
US20180170789A1 |
2018-06-21 |
William Peter Addiego; Daniel Robert Boughton; Jennifer Anella Heine; Kenneth Edward Hrdina; Paul Oakley Johnson |
A method of making a self-supporting inorganic sheet, including: electrostatically depositing a dry inorganic powder on a surface to form an inorganic layer on the surface; and sintering the resulting inorganic layer to form a self-supporting sintered inorganic sheet. The method can additionally include, for example, separating of the self-supporting sintered inorganic sheet from the surface, optionally contacting the separated sintered inorganic sheet with a coupling agent, infiltrating the separated sintered inorganic sheet with a polymer with or without contacting with a coupling agent, or a combination thereof. Also disclosed is a sheet article made by the method. |
209 |
Fast firing method for ceramics |
US14196163 |
2014-03-04 |
US10000424B2 |
2018-06-19 |
Douglas Munroe Beall; David Jack Bronfenbrenner; Margaret Kathleen Faber; Sriram Rangarajan Iyer; Patrick David Tepesch; Douglas Richard Wing |
A method for firing a green honeycomb ceramic body in a kiln may include heating the green honeycomb ceramic body in four stages. The first stage may include heating the green honeycomb ceramic body from room temperature to a first temperature that at a first heating rate that is greater than or equal to about 75° C./hr. The second stage may include heating the green honeycomb ceramic body from the first temperature to a second temperature at a second heating rate that is less than or equal to the first heating rate. The third stage may include heating the green honeycomb ceramic body from the second temperature to a hold temperature at a third heating rate that is less than or equal to the first heating rate. The fourth stage may include holding the green honeycomb ceramic body at the hold temperature to remove residual carbon. |
210 |
Porous stabilized beds, methods of manufacture thereof and articles comprising the same |
US14131357 |
2012-07-06 |
US09966171B2 |
2018-05-08 |
James F. Klausner; Renwei Mei; Ayyoub Mehdizadeh Momen; Kyle Allen |
Disclosed herein is a method comprising disposing a first particle in a reactor; the first particle being a magnetic particle or a particle that can be influenced by a magnetic field, an electric field or a combination of an electrical field and a magnetic field; fluidizing the first particle in the reactor; applying a uniform magnetic field, a uniform electrical field or a combination of a uniform magnetic field and a uniform electrical field to the reactor; elevating the temperature of the reactor; and fusing the first particles to form a monolithic solid. |
211 |
Thermal insulator and method of manufacturing the same |
US15143007 |
2016-04-29 |
US09950963B2 |
2018-04-24 |
Akifumi Sakamoto; Yoshihiko Goto; Yasuo Ito; Ken Maeda |
A thermal insulator with both excellent heat insulation and strength and a method of manufacturing the thermal insulator are provided.A thermal insulator according to the present invention includes metal oxide fine particles with an average particle diameter equal to or smaller than 50 nm and a reinforcing fiber, wherein the thermal insulator has a bridge structure between the metal oxide fine particles which is formed by elution of part of the metal oxide fine particles. A method of manufacturing a thermal insulator according to the present invention includes a curing step of curing a dry pressed compact including metal oxide fine particles with an average particle diameter equal to or smaller than 50 nm and a reinforcing fiber under a pressurized vapor saturated atmosphere at a temperature equal to or higher than 100° C. for four hours and a drying step of drying the cured dry pressed compact. |
212 |
Method for the production of shaped articles from reaction-bonded, silicon-infiltrated silicon carbide and/or boron carbide and thus produced shaped body |
US15029334 |
2014-08-06 |
US09695089B2 |
2017-07-04 |
Arthur Lynen; Jens Larsen; Michael Clemens |
Method for producing shaped bodies from reaction-bonded, silicon-infiltrated silicon carbide and/or boron carbide, characterized in that a monolithic preliminary body is built up in layers using a formless granulation to which a physical or chemical hardening or melt process is applied, wherein the granulation has a weight fraction of at least 95% silicon carbide and/or boron carbide with an average grain size of 70 to 200 μm, the so-created preliminary body is impregnated at least once by the introduction of a carbon black suspension or via a gas-phase separation and secondary silicon carbide is created in contact with liquid or gaseous silicon by a subsequent reaction firing that solidifies an engagement composite produced. |
213 |
Particulate sound absorption board and preparation method thereof |
US14986098 |
2015-12-31 |
US09607597B2 |
2017-03-28 |
Weixin Qian; Jiashu Shen |
A particulate sound absorption board and its preparation method. The said particulate sound absorption board consists of binding agent and sound absorption particle; the external surface of sound absorption particle is covered with a layer of binding agent, and the angularity coefficient of particle covered with binding agent is less than 1.3; the said sound absorption particle consists of skeleton particle and filling particle, in which the former is used for sound absorption board skeleton, and the latter flows into the pore between skeleton particles to form sound absorption pore, and the average diameter of cross section of sound absorption pore is 0.07 mm. The two-stage manufacturing technology (i.e. coating, curing and then shaping) is adopted for the said preparation method to prevent the pore between particles from being blocked by excess binding agent, and further improve the angularity coefficient of particle. |
214 |
Water repellent sand mixture and water repellent sand structure |
US14567605 |
2014-12-11 |
US09409819B2 |
2016-08-09 |
Akira Taomoto; Norihisa Mino; Shoichi Kiyama; Akira Murakami; Toshihiko Kawachi |
A water repellent sand mixture includes at least water repellent sand and cement at a weight ratio of 2% or more and 5% or less relative to the water repellent sand. The mixture achieves condensation between the water repellent sand particles by the hydration reaction of the cement, which improves dynamic stability. The mixture can be kept in a block shape due to such improved dynamic stability, water repellency, and less slidable surfaces of the sand particles. |
215 |
Carbon composites |
US14488851 |
2014-09-17 |
US09325012B1 |
2016-04-26 |
Zhiyue Xu; Lei Zhao |
A carbon composite comprises carbon microstructures having interstitial spaces among the carbon microstructures; and a binder disposed in at least some of the interstitial spaces; wherein the carbon microstructures comprise unfilled voids within the carbon microstructures. |
216 |
Method for applying discriminating layer onto porous ceramic filters via gas-borne prefabricated porous assemblies |
US13813167 |
2011-08-17 |
US09321694B2 |
2016-04-26 |
Aleksander J. Pyzik; Jun Cai; Andrey N. Soukhojak; Robert A. Newman |
A porous discriminating layer is formed on a ceramic support having at least one porous wall by (a) establishing a flow of a gas stream containing highly porous particles through the support to deposit a layer of the highly porous particles of a ceramic or ceramic precursor onto wall(s) of the support and (b) calcining said deposited layer to form the discriminating layer. This method is an inexpensive and effective route to forming a discriminating layer onto the porous wall. |
217 |
Particulate Sound Absorption Board and Preparation Method Thereof |
US14986098 |
2015-12-31 |
US20160111076A1 |
2016-04-21 |
Weixin QIAN; Jiashu SHEN |
A particulate sound absorption board and its preparation method. The said particulate sound absorption board consists of binding agent and sound absorption particle; the external surface of sound absorption particle is covered with a layer of binding agent, and the angularity coefficient of particle covered with binding agent is less than 1.3; the said sound absorption particle consists of skeleton particle and filling particle, in which the former is used for sound absorption board skeleton, and the latter flows into the pore between skeleton particles to form sound absorption pore, and the average diameter of cross section of sound absorption pore is 0.07 mm. The two-stage manufacturing technology (i.e. coating, curing and then shaping) is adopted for the said preparation method to prevent the pore between particles from being blocked by excess binding agent, and further improve the angularity coefficient of particle. |
218 |
Method and Apparatus for Sintering Flat Ceramics |
US14933980 |
2015-11-05 |
US20160060178A1 |
2016-03-03 |
Hiroaki Miyagawa; Guang Pan; Hironaka Fujii; Bin Zhang; Amane Mochizuki; Toshitaka Nakamura |
A method and apparatus for sintering flat ceramics using a mesh or lattice is described herein. |
219 |
ALUMINA POROUS BODY AND METHOD FOR MANUFACTURING SAME |
US14405878 |
2013-05-17 |
US20150147561A1 |
2015-05-28 |
Hirokazu Watanabe; N. Nair Balagopal |
A ceramic porous body has an alumina porous body made up by binding aggregate alumina particles to each other, the aggregate alumina particles being bound to each other by a compound including gadolinium silicate, lanthanum silicate or yttrium silicate synthesized from a silicate mineral and at least one rare-earth oxide selected from Gd2O3, La2O3, and Y2O3, and an inorganic porous film formed on the alumina porous body. |
220 |
Concrete mixture and method of forming the same |
US13001265 |
2009-06-23 |
US08979997B2 |
2015-03-17 |
Mohammed Imbabi; Fredrik Glasser; Jim Min Wong |
A concrete mixture for forming a breathable concrete. The mixture comprises aggregate particles and a paste comprising water, cement or cement substitute, and plasticizer. The plasticizer controls the viscosity of the paste such that the paste forms a substantially uniform layer coating the particles, with the coated particles in contact, while allowing spaces to be retained there between. These spaces interconnect forming channels through the concrete, allowing air to permeate there through such that the concrete exhibits good dynamic insulation properties, whist retaining structural strength. |