| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 241 | Metal-carbon compositions | US13677686 | 2012-11-15 | US08541335B2 | 2013-09-24 | Jason V. Shugart; Roger C. Scherer |
| A lead-carbon compound that is a reaction product of lead and carbon, wherein the lead and the carbon form a single phase material that is meltable. The compound is one in which the carbon does not phase separate from the lead when the single phase material is heated to a melting temperature. | ||||||
| 242 | METAL-CARBON COMPOSITIONS | US13677793 | 2012-11-15 | US20130084232A1 | 2013-04-04 | Jason V. Shugart; Roger C. Scherer |
| A gold-carbon compound that is a reaction product of gold and carbon, wherein the gold and the carbon form a single phase material that is meltable. The compound is one in which the carbon does not phase separate from the gold when the single phase material is heated to a melting temperature. | ||||||
| 243 | METAL-CARBON COMPOSITIONS | US13677681 | 2012-11-15 | US20130084229A1 | 2013-04-04 | Jason V. Shugart; Roger C. Scherer |
| A tin-carbon compound that is a reaction product of tin and carbon, wherein the tin and the carbon form a single phase material that is meltable. The compound is one in which the carbon does not phase separate from the tin when the single phase material is heated to a melting temperature. | ||||||
| 244 | SOLID COMPOSITION HAVING ENHANCED PHYSICAL AND ELECTRICAL PROPERTIES | US13004807 | 2011-01-11 | US20120011719A1 | 2012-01-19 | John M. Bourque |
| A method of making a treating wash includes mixing brass granules with acetone, mixing carbon nanotube material, iron pyrite granules and copper granules in the acetone brass mixture, and straining the liquid from the remaining solid material. Methods of treating materials such as brass granules, iron pyrite granules, carbon nanotube material, and brass granules comprises washing the materials in the treating wash, followed by straining and drying the materials. | ||||||
| 245 | SOLID COMPOSITION HAVING ENHANCED PHYSICAL AND ELECTRICAL PROPERTIES | US13004798 | 2011-01-11 | US20120011718A1 | 2012-01-19 | John M. Bourque |
| A method of making a treating wash includes mixing brass granules with acetone, mixing carbon nanotube material, iron pyrite granules and copper granules in the acetone brass mixture, and straining the liquid from the remaining solid material. Methods of treating materials such as brass granules, iron pyrite granules, carbon nanotube material, and brass granules comprises washing the materials in the treating wash, followed by straining and drying the materials. | ||||||
| 246 | METHODS AND SYSTEM FOR MANUFACTURING LEAD BATTERY PLATES | US13128064 | 2008-11-07 | US20110314885A1 | 2011-12-29 | Russell Derex; Anders Persson |
| Disclosed are methods and a system for manufacturing a lead or lead alloy plate lattice for a lead-acid battery, comprising continuous extrusion of a melt of lead or lead alloy under temperatures lower by 10-100° C. than the melting point of lead, or the lead alloy, the extrudate being subsequently subjected to a flattening process under a temperature lower by more than at least 230° C. than the melting point of lead or the lead alloy, with a total draft rate less than 10%, and thereafter the extrudate may be processed so as to manufacture a plate lattice. | ||||||
| 247 | Solid composition having enhanced physical and electrical properties | US12755587 | 2010-04-07 | US08075806B2 | 2011-12-13 | John M. Bourque |
| A method of making a treating wash includes mixing brass granules with acetone, mixing carbon nanotube material, iron pyrite granules and copper granules in the acetone brass mixture, and straining the liquid from the remaining solid material. Methods of treating materials such as brass granules, iron pyrite granules, carbon nanotube material, and brass granules comprises washing the materials in the treating wash, followed by straining and drying the materials. | ||||||
| 248 | Solid composition having enhanced physical and electrical properties | US12755582 | 2010-04-07 | US08057709B2 | 2011-11-15 | John M. Bourque |
| A method of making a treating wash includes mixing brass granules with acetone, mixing carbon nanotube material, iron pyrite granules and copper granules in the acetone brass mixture, and straining the liquid from the remaining solid material. Methods of treating materials such as brass granules, iron pyrite granules, carbon nanotube material, and brass granules comprises washing the materials in the treating wash, followed by straining and drying the materials. | ||||||
| 249 | SOLID COMPOSITION HAVING ENHANCED PHYSICAL AND ELECTRICAL PROPERTIES | US12755582 | 2010-04-07 | US20100193749A1 | 2010-08-05 | John M. Bourque |
| A method of making a treating wash includes mixing brass granules with acetone, mixing carbon nanotube material, iron pyrite granules and copper granules in the acetone brass mixture, and straining the liquid from the remaining solid material. Methods of treating materials such as brass granules, iron pyrite granules, carbon nanotube material, and brass granules comprises washing the materials in the treating wash, followed by straining and drying the materials. | ||||||
| 250 | Solid composition having enhanced physical and electrical properties | US12268315 | 2008-11-10 | US07767121B2 | 2010-08-03 | John M. Bourque |
| A method of making a treating wash includes mixing brass granules with acetone, mixing carbon nanotube material, iron pyrite granules and copper granules in the acetone brass mixture, and straining the liquid from the remaining solid material. Methods of treating materials such as brass granules, iron pyrite granules, carbon nanotube material, and brass granules comprises washing the materials in the treating wash, followed by straining and drying the materials. | ||||||
| 251 | CONDUCTIVE RESIN COMPOSITION, CONNECTION METHOD BETWEEN ELECTRODES USING THE SAME, AND ELECTRIC CONNECTION METHOD BETWEEN ELECTRONIC COMPONENT AND CIRCUIT SUBSTRATE USING THE SAME | US12424867 | 2009-04-16 | US20090200522A1 | 2009-08-13 | Seiichi NAKATANI; Seiji KARASHIMA; Takashi KITAE; Susumu SAWADA |
| The present invention provides a conductive resin composition for connecting electrodes electrically, in which metal particles are dispersed in a flowing medium, wherein the flowing medium includes a first flowing medium that has relatively high wettability with the metal particles and a second flowing medium that has relatively low wettability with the metal particles, and the first flowing medium and the second flowing medium are dispersed in a state of being incompatible with each other. Thereby, a flip chip packaging method that can be applied to flip chip packaging of LSI and has high productivity and high reliability is provided. | ||||||
| 252 | Lead acid batteries with plates that contain silver | US11332385 | 2006-01-17 | US20070166619A1 | 2007-07-19 | Maureen Kerchner |
| Lead acid batteries of the gel, or absorbment glassmat (AGM) type with lead plates that have a silver content in the range of 19 to 185 PPM, which silver enhances their performance. | ||||||
| 253 | Thermo-mechanical treated lead and lead alloys especially for current collectors and connectors in lead-acid batteries | US10716507 | 2003-11-20 | US20040112486A1 | 2004-06-17 | Karl T. Aust; David L. Limoges; Francisco Gonzalez; Gino Palumbo; Klaus Tomantschger; Peter K. Lin |
| Recrystallized lead and lead alloy positive current collectors and connectors such as straps and lugs for use e.g. in lead acid batteries and electrowinning anodes, having an increased percentage of special grain boundaries in at least part of the microstructure, which have been provided by a process comprising of (i) cold or hot rolling or cold or hot extrusion or (ii) steps of deforming the lead or lead alloy, and subsequently annealing the lead or lead alloy. Either a single cycle of working and annealing can be provided, or a plurality of such cycles can be provided. The amount of deformation, the recrystallization time and temperature, and the number of repetitions of such steps are selected to ensure that a substantial increase in the population of special grain boundaries is provided in the microstructure, to improve resistance to creep, intergranular corrosion and intergranular cracking of the current collectors and connectors during battery service, and result in extended battery life and the opportunity to reduce the size and weight of the battery. | ||||||
| 254 | Sliding member with composite plating film | US10263816 | 2002-10-04 | US06740426B2 | 2004-05-25 | Toshiaki Kawachi; Hideo Ishikawa; Masaaki Sakamoto |
| Disclosed is a sliding member having a bearing alloy layer and a composite plating film provided on the bearing alloy layer. The composite plating film is made of a lead alloy containing 0.1 to 10 mass percent in total of copper and 0.3 to 25 volume percent in total of co-deposited inorganic particles. The outermost surface layer of the composite plating film, which has a thickness proportion of 10 to 40% to the entire thickness of the composite plating film, does not contain inorganic particles and copper. The lower layer of the composite plating film contains Cu and inorganic particles, such as Si3N4, dispersed therein. | ||||||
| 255 | Lead and lead alloys with enhanced creep and/or intergranular corrosion resistance, especially for lead-acid batteries and electrodes therefor | US09935704 | 2001-08-24 | US06592686B2 | 2003-07-15 | Gino Palumbo |
| Recrystallized lead and lead alloy positive electrodes for lead acid batteries having an increased percentage of special grain boundaries in the microstructure, preferably to at least 50%, which have been provided by a process comprising steps of working or straining the lead or lead alloy, and subsequently annealing the lead or lead alloy. Either a single cycle of working and annealing can be provided, or a plurality of such cycles can be provided. The amount of cold work or strain, the recrystallization time and temperature, and the number of repetitions of such steps are selected to ensure that a substantial increase in the population of special grain boundaries is provided in the microstructure, to improve resistance to creep, intergranular corrosion and intergranular cracking of the electrodes during battery service, and result in extended battery life and the opportunity to reduce the size and weight of the battery. | ||||||
| 256 | Sliding member with composite plating film | US10263816 | 2002-10-04 | US20030118862A1 | 2003-06-26 | Toshiaki Kawachi; Hideo Ishikawa; Masaaki Sakamoto |
| Disclosed is a sliding member having a bearing alloy layer and a composite plating film provided on the bearing alloy layer. The composite plating film is made of a lead alloy containing 0.1 to 10 mass percent in total of copper and 0.3 to 25 volume percent in total of co-deposited inorganic particles. The outermost surface layer of the composite plating film, which has a thickness proportion of 10 to 40% to the entire thickness of the composite plating film, does not contain inorganic particles and copper. The lower layer of the composite plating film contains Cu and inorganic particles, such as Si3N4, dispersed therein. | ||||||
| 257 | Lead and lead alloys with enhanced creep and/or intergranular corrosion resistance, especially for lead-acid batteries and electrodes therefor | US09935704 | 2001-08-24 | US20020050311A1 | 2002-05-02 | Gino Palumbo |
| Recrystallized lead and lead alloy positive electrodes for lead acid batteries having an increased percentage of special grain boundaries in the microstructure, preferably to at least 50%, which have been provided by a process comprising steps of working or straining the lead or lead alloy, and subsequently annealing the lead or lead alloy. Either a single cycle of working and annealing can be provided, or a plurality of such cycles can be provided. The amount of cold work or strain, the recrystallization time and temperature, and the number of repetitions of such steps are selected to ensure that a substantial increase in the population of special grain boundaries is provided in the microstructure, to improve resistance to creep, intergranular corrosion and intergranular cracking of the electrodes during battery service, and result in extended battery life and the opportunity to reduce the size and weight of the battery. | ||||||
| 258 | Conductor used as a fuse | US477132 | 1990-02-07 | US5019457A | 1991-05-28 | Masanobu Nishio |
| A conductor for a fuse has a main composition of a Pb-Ag alloy containing silver of 0.5 to 20 wt. % and lead and unavoidable impurity for the rest. A conductor for a fuse in another example includes a Pb-Ag-Cu or/and Te alloy obtained by adding copper or/and tellurium of 0.05 to 1 wt. %, respectively, to the above mentioned Pb-Ag alloy. Each of those conductors for fuses has a diameter in the range from 0.05 to 0.3 mm and it is used as a fuse contained in a capacitor of a tantalum chip for example. Those conductors for fuses have excellent pre-arcing time/current characteristics and good drawability. | ||||||
| 259 | Process for the electrochemical oxidation of organic products | US72738 | 1987-07-13 | US4759834A | 1988-07-26 | Andreas M. J. Thomas; Franciscus van den Brink; Rudolf van Hardeveld |
| The invention relates to a process for the electrochemical oxidation of organic products at a lead-silver anode in acid medium, in which process the organic products used are alkyl-substituted heterocycles and in which process a lead-silver anode with 2-10% (wt) silver is used. | ||||||
| 260 | Wetting of low melting temperature solders by surface active additions | US854455 | 1986-04-21 | US4734256A | 1988-03-29 | Howard H. Liebermann; Debasis Bose |
| A lead based alloy is modified by adding thereto a surfactant consisting of about 0.01 to 0.5 weight percent tellurium, about 0.01 to 0.5 weight percent selenium, about 0.01 to 0.5 weight percent selenium plus about 0.1-0.5 weight percent antimony, and mixtures thereof. The alloy is rapidly solidified by forming a melt thereof containing the surfactant addition and quenching the melt on a moving chill surface at a quenching rate of at least about 10.sup.3 .degree. C./sec. Addition of the surfactant lowers melt surface tension and thereby promotes improved wetting. | ||||||
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