301 |
Kotansotetsuno jikanuriseramitsukuhifukuhoho |
JP12942975 |
1975-10-29 |
JPS5180628A |
1976-07-14 |
KURIFUOODO JII RUTERAA |
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302 |
Hooroomitsuchakuseino ryokona hoorooyoreienkohan |
JP7138174 |
1974-06-24 |
JPS511311A |
1976-01-08 |
MATSUFUJI KAZUO; SHIMOMURA TAKAYOSHI; KUROKAWA TERUO; ARAYAMA TAKAO |
|
303 |
JPS50107034A - |
JP483375 |
1975-01-08 |
JPS50107034A |
1975-08-23 |
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304 |
JPS5081928A - |
JP9713974 |
1974-08-26 |
JPS5081928A |
1975-07-03 |
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305 |
JPS5071526A - |
JP12117473 |
1973-10-30 |
JPS5071526A |
1975-06-13 |
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306 |
JPS508454B1 - |
JP678870 |
1970-01-27 |
JPS508454B1 |
1975-04-04 |
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307 |
JPS503107A - |
JP3893374 |
1974-04-08 |
JPS503107A |
1975-01-14 |
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308 |
JPS49131971A - |
JP5400973 |
1973-05-15 |
JPS49131971A |
1974-12-18 |
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309 |
JPS4947003B1 - |
JP8812268 |
1968-12-03 |
JPS4947003B1 |
1974-12-13 |
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310 |
JPS49126506A - |
JP4113473 |
1973-04-11 |
JPS49126506A |
1974-12-04 |
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311 |
JPS49100148A - |
JP8690273 |
1973-08-03 |
JPS49100148A |
1974-09-21 |
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312 |
JPS4897725A - |
JP1576273 |
1973-02-09 |
JPS4897725A |
1973-12-12 |
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313 |
JPS4845531A - |
JP9995072 |
1972-10-06 |
JPS4845531A |
1973-06-29 |
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314 |
JPS4810821B1 - |
JP13047670 |
1970-12-30 |
JPS4810821B1 |
1973-04-07 |
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315 |
METHOD FOR MANUFACTURING A BRAKE DISC, AND BRAKE DISC |
PCT/EP2014072130 |
2014-10-15 |
WO2015059011A3 |
2015-06-18 |
BRODA MAIK; BRUGGEN IVAN; GRABIEC TOMASZ PAWEL; VERPOORT CLEMENS MARIA |
The invention relates to a method for manufacturing a brake disc (1) for a motor vehicle, wherein a protective layer is placed on a main body (2) of the brake disc (1), said method comprising at least the following steps: preliminary machining of at least some regions of the main body (2) in the blank; applying an enamel coating (10) to at least some regions of the main body (2), and post-treating the at least partially coated main body (2), the enamel coating (10) being metallurgically joined to the basic material of the main body (2) by phase formation. |
316 |
METHOD FOR APPLYING COLOUR GRAPHICS TO THE SOLE PLATE OF AN IRON |
PCT/IB2011054663 |
2011-10-19 |
WO2012052940A3 |
2012-06-21 |
ALBANDOZ RUIZ DE OCENDA CARMELO |
The invention relates to a method for applying colour graphics (5) to the sole plate of an iron (2), in particular a steam iron (3). According to the invention, at least one transfer with colour graphics (5) is applied to at least one area of the surface (1) of the sole plate of the iron (2) and is heated therewith (2). The at least one transfer is made from enamel power which contains at least one colouring agent. |
317 |
ARTICLES COMPRISING A GLASS - FLEXIBLE STAINLESS STEEL COMPOSITE LAYER |
PCT/US2011051514 |
2011-09-14 |
WO2012037194A3 |
2012-06-14 |
BOUSSAAD SALAH; REARDON DAMIEN FRANCIS |
The present disclosure relates to a method of manufacturing of a glass coated metal product. This invention also relates to a coated metallic substrate material that is suitable for manufacturing flexible solar cells and other articles in which a passivated stainless steel surface is desirable. |
318 |
METAL CLADDING COMPOSITION, ADDITIVE, METHOD AND SYSTEM |
PCT/US2007018005 |
2007-08-13 |
WO2008021371A3 |
2008-06-26 |
WILSON GARY |
The invented method of cladding a metal component includes creating a frit mixture in a defined ratio; wetting the mixture by adding a wetting agent in a defined volume; agitating the wetted mixture; applying the agitated mixture to a metal component by one or more processes; de-wetting the metal component having the applied mixture by gradually heating the same to a temperature from approximately 250 degrees Fahrenheit (°F) up to a high of approximately 450°F; and, fusing the de- wetted metal component at a temperature of no more than 125% of a defined withstand temperature for the clad metal component. Invented compositions can include one or more of liquid and/or colloidal sodium, potassium and/or lithium silicate, clay and/or clays, a compound of hollow micro-spheres (e.g. naturally occurring and nearly ubiquitous perlite and/or a synthetic hollow micro-sphere equivalent) and/or alumina or one or more flexible or malleable or resiliently deformable, impact-resistant materials such as plastomers, elastomers and/or other plastic, rubber, plastic-like or rubber-like materials; a wetting agent consisting of one or more of water or water and ethanol for fast drying under proper safety and venting conditions; and one or more surfactants and/or dispersants. A system and method for using the compositions and additives are also disclosed. An optional powder clad application method is included in the embodiment of the invention which method eliminates the de-wetting station(s) but makes it possible to add impact-resistant clad material for lower-temperature, higher-impact applications. |
319 |
ENAMEL COATING FOR LIQUID APPLICATION |
PCT/EP2006004323 |
2006-05-09 |
WO2006119962A3 |
2007-03-22 |
PETERSEIM JUERGEN |
The invention relates to a method for coating objects, in particular, made from metal, such as workpieces or machine components with a metallic enamel alloy, whereby a binder agent is added to the metal alloy present as a powder and optionally a liquid to give a liquid or paste enamel slip. The enamel slip is applied to the workpiece and the workpiece provided with the enamel slip is fused at a temperature in the fusion region of the enamel alloy, in particular more than 1000°C. |
320 |
METALLIC SUBSTRATES COMPRISING A DEFORMABLE GLASS-TYPE COATING |
PCT/EP2005000024 |
2005-01-04 |
WO2005066388A3 |
2006-01-05 |
ENDRES KLAUS; SCHMIDT HELMUT; MENNIG MARTIN |
The invention relates to metallic substrates comprising a deformable glass-type coating that can be obtained by applying a coating sol containing an alkali silicate to the substrate, and by thermal compression of the thus obtained layer according to a two-stage heat treatment method. The heat treatment in the first stage is carried out either (A) in an oxygen-containing atmosphere, or (B) in a vacuum, with a residual pressure of = 15 mbar, and in the second stage, in an oxygen-deficient atmosphere until the first layer has been fully compressed, forming a glass-type layer. |