181 |
Process of treating carbonaceous articles |
US47879930 |
1930-08-29 |
US1804361A |
1931-05-05 |
MARCIN MICHAEL J |
|
182 |
Process for surface-coloring bodies |
US9015626 |
1926-02-23 |
US1798996A |
1931-03-31 |
CLEMENTS BATCHELLER |
|
183 |
Method of producing artificial marble |
US30833928 |
1928-09-25 |
US1755399A |
1930-04-22 |
JOHANN KNEIFL |
|
184 |
Method of laying concrete pavements |
US22477327 |
1927-10-07 |
US1705088A |
1929-03-12 |
HIPPLE PERCY A |
|
185 |
Ceramic-glazing process |
US2850025 |
1925-05-06 |
US1693252A |
1928-11-27 |
PROUTY WILLIS O |
|
186 |
Preservation of stone |
US73257424 |
1924-08-16 |
US1585103A |
1926-05-18 |
PILLANS LAURIE ARTHUR |
|
187 |
Process for the production of lasting colored stains in and upon the surface of cement or other building material |
US74739824 |
1924-11-01 |
US1577729A |
1926-03-23 |
JULIUS KOEBIG |
|
188 |
Process of glazing brick |
US72149724 |
1924-06-21 |
US1570137A |
1926-01-19 |
FISCHER JR ANDREW |
|
189 |
Method of treating concrete |
US71424524 |
1924-05-19 |
US1555209A |
1925-09-29 |
HONBERGER FRANK S |
|
190 |
Metallizing articles |
US49982021 |
1921-09-10 |
US1452281A |
1923-04-17 |
QUINTIN MARINO |
|
191 |
Process for weatherproofing clay |
US49887921 |
1921-09-06 |
US1421888A |
1922-07-04 |
ALLEN WILLIAM H |
|
192 |
Method of manufacturing an insulating material |
US23137118 |
1918-04-29 |
US1353621A |
1920-09-21 |
ASHENHURST HAROLD S |
|
193 |
Method of staining glass |
US30515819 |
1919-06-18 |
US1328833A |
1920-01-27 |
HASBURG JOHN W |
|
194 |
SEALANT FOR A CONCRETE ELEMENT AND METHOD FOR PRODUCING A SEALANT |
US15880144 |
2018-01-25 |
US20180237674A1 |
2018-08-23 |
ADRIAN PFLIEGER |
A sealant for a concrete element, having a planar carrier and an active substance applied onto the carrier, wherein the active substance is designed to be chemically reactive with water. The carrier is flexible. |
195 |
Method for restoring a cementitious system |
US14759366 |
2013-12-19 |
US09670102B2 |
2017-06-06 |
Thomas Dünne |
Described is a method for restoring a cementitious system, the method having the following steps: a) securing a filling body provided with holes at a distance from the cementitious system to be restored, b) applying mortar to the cementitious system to be restored and to the filling body provided with openings, and c) introducing a cement containing an alkali storage system into the filling body provided with openings so that the cement containing an alkali storage system is in contact with the mortar. A corresponding cementitious system is also described. |
196 |
Method for applying sealing material paste to peripheral surface of ceramic block |
US14495896 |
2014-09-25 |
US09610606B2 |
2017-04-04 |
Tomohiro Takano; Kazuya Bando |
A method of manufacturing a honeycomb structured body, includes providing an application jig. A sealing material paste is put on a peripheral surface of a pillar-shaped ceramic block. The application jig is set in such a manner that a first principal surface of the application jig faces upward and a second principal surface of the application jig faces downward. The ceramic block is placed inside a second opening section of the application jig. The ceramic block is passed through an opening section of the application jig so that a face defining the second opening section spreads an entire peripheral surface of the ceramic block with the sealing material paste to manufacture a honeycomb structured body with a peripheral sealing material layer formed on the peripheral surface of the ceramic block. |
197 |
Encapsulated Ceramic Element and Method of Making the Same |
US12840464 |
2010-07-21 |
US20110020585A1 |
2011-01-27 |
Jeffrey A. Steinfeldt; Carl Jojola; Bruce Johnson |
A PZT (lead zirconate titanate) element including one or more outside surfaces including a layer of encapsulation and metallization material and the method of making the same including at least the steps of providing a wafer of ceramic material including a base and one or more walls defining one or more recesses in the wafer which are filled with an encapsulation material. The encapsulation material is then cured and a layer of metallization is applied to one or more of the outside surfaces of the wafer and encapsulation material. Cuts are then made through the layer of metallization and cured encapsulation material to divide the wafer into a plurality of individual and separate ceramic elements with one or more surfaces including a layer of metallization and encapsulation. |
198 |
Formation of corrosion-resistant coating |
US10530541 |
2003-10-07 |
US20060166014A1 |
2006-07-27 |
Brian Klotz; Kevin Klotz |
A coating process comprising: (A) applying to a surface, for example, a metallic surface, a coating compositions consisting essentially of an alkali metal silicate and an aqueous liquid phase having dispersed therein solid aluminum particles to form on the surface a wet coating; and (B) drying said wet coating : (I) under conditions which convert said wet coating to an electrically conductive, corrosion-resistant, solid coating; or (ii) under conditions which form a solid coating which is not electrically conductive (non-conductive) and thereafter treating said non-conductive coating under conditions which convert said non-conductive coating to an electrically conductive, corrosion-resistant coating compositions for use in the process, and the provision of highly corrosion-resistant coated articles. |
199 |
Electrically conductive ceramics |
US09869544 |
2001-10-15 |
US06797662B1 |
2004-09-28 |
Donald Jaffrey |
A metal oxide ceramic material such as alumina or chromia which has been rendered electrically conductive through its thickness by the incorporation of silver into the material. The metal oxide ceramic material may be in the form of a layer on a substrate such as a bipolar plate or other component for a fuel cell assembly. The electrical conductivity may be achieved by heating the ceramic material and a silver-containing material in contact with each other to at least 750° C. such that silver migrates from the silver-containing material the metal oxide ceramic material and creates electrically conductive pathways through the ceramic material. In a particular embodiment, the substrate is a steel which forms an alumina, chromia or alumina-rich or chromia-rich surface layer in oxidizing atmosphere and the silver-containing material is heated in an oxidizing atmosphere in contact with the steel to cause the surface layer to form on the steel and to cause silver from the silver-containing material to occur in and create the electrically conductive pathways through the layer. The silver-containing material may be commercially pure silver or other forms of silver. |
200 |
Composition and method for forming a protective coating on carbon-carbon
chemical vapor deposition densified substrates |
US531944 |
1983-09-13 |
US5518816A |
1996-05-21 |
David M. Shuford |
In accordance with the invention, a composition of matter is provided for forming a coating for protecting carbonaceous substrates from degradation at elevated temperatures. The composition is a mixture of particulate silicon, silicon carbide and boron. The mixture contains between about 25% and 40% silicon by weight of the total composition, between about 50% and 70% by weight silicon carbide by weight of the total composition, between about 1% and 15% boron by way of the total composition and a minor amount of magnesium. The compositions can be used in a method for forming a primary protective coating on carbonaceous substrates including, in particular, reinforced carbon-carbon materials produced using chemical vapor deposition techniques. |