Having Coating In The Pores Patents (Class 429/236)
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Patent number: 12009511Abstract: A rechargeable metal halide battery fabricated with a liquid nitrogen treated metallic anode demonstrates a stable cycle life with a slow rate of degradation and high discharge capacity in comparison to battery cells with untreated anodes. The anode, which may be an alkali metal and/or an alkaline earth metal, is pretreated with the liquid nitrogen prior to formation in a battery stack. The liquid nitrogen treatment forms a metal nitride on a surface of the anode that (i) increases the surface area of the anode, (ii) acts as a passivation layer that prevents detrimental SEI-forming side reactions that degrade anodes, and (iii) suppresses dendrite growth. Where the anode is lithium, the metal nitride is lithium nitride (Li3N).Type: GrantFiled: February 18, 2022Date of Patent: June 11, 2024Assignee: International Business Machines CorporationInventors: Yumi Kim, Amaresh Samuthira Pandian, Holt Bui, Jangwoo Kim, Young-Hye Na
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Patent number: 10727537Abstract: Electrochemical devices, such as batteries, supercapacitors, etc., which may be prepared from nanoscopic electrically conductive carbon materials, and optionally electrochemically active materials. Also, methods for preparing such electrochemical devices, including components, elements, etc., of such devices by using three-dimensional (3D) printing, fused deposition modeling (FDM), selective laser sintering (SLS), etc., techniques.Type: GrantFiled: August 28, 2015Date of Patent: July 28, 2020Inventors: Daniel Stolyarov, Elena Polyakova, Irina Pomestchenko
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Patent number: 10673074Abstract: The present invention provides a battery electrode comprising an active battery material enclosed in the pores of a conductive nanoporous scaffold. The pores in the scaffold constrain the dimensions for the active battery material and inhibit sintering, which results in better cycling stability, longer battery lifetime, and greater power through less agglomeration. Additionally, the scaffold forms electrically conducting pathways to the active battery nanoparticles that are dispersed. In some variations, a battery electrode of the invention includes an electrically conductive scaffold material with pores having at least one length dimension selected from about 0.5 nm to about 100 nm, and an oxide material contained within the pores, wherein the oxide material is electrochemically active.Type: GrantFiled: November 3, 2017Date of Patent: June 2, 2020Assignee: HRL Laboratories, LLCInventors: Adam F. Gross, John J. Vajo, Ping Liu, Elena Sherman
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Patent number: 10547050Abstract: A method of preparing a hard carbon-based electrode active material having high specific surface area by carbonization process control, comprises charging polyurethane into a high temperature furnace, supplying oxygen gas to the high temperature furnace and oxidizing the polyurethane under an oxygen atmosphere, supplying a nitrogen gas to the high temperature furnace and heating to carbonize a stabilized polyurethane under a nitrogen atmosphere, thereby producing a hard carbon, heating the hard carbon under a nitrogen atmosphere and supplying steam to activate the hard carbon under a steam atmosphere, thereby producing an active carbon, supplying hydrogen and reducing the active carbon under a hydrogen atmosphere, and cooling the active carbon under a nitrogen atmosphere.Type: GrantFiled: October 26, 2016Date of Patent: January 28, 2020Assignee: KOREA INSTITUTE OF CARBON CONVERGENCE TECHNOLOGYInventors: Byungjoo Kim, Hyemin Lee
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Patent number: 10361460Abstract: A process for producing a lithium battery, comprising: (A) Preparing a plurality of conductive porous layers, wet anode layers, and wet cathode layers; (B) Stacking a desired number of porous layers and wet anode layers in an alternating manner to form an anode electrode having a thickness no less than 100 ?m; (C) Placing a porous separator layer in contact with the anode electrode; (D) Stacking a desired number of porous layers wet cathode layers in an alternating manner to form a cathode electrode in contact with the porous separator, wherein the cathode electrode has a thickness no less than 100 ?m; and (F) Assembling and sealing the anode electrode, separator, and cathode electrode in a housing to produce the lithium battery. The consolidated anode or cathode layer is preferably thicker than 300 ?m more preferably thicker than 400 ?m, and further more preferably greater than 500 ?m.Type: GrantFiled: October 2, 2015Date of Patent: July 23, 2019Assignee: Nanotek Instruments, Inc.Inventors: Aruna Zhamu, Bor Z Jang
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Patent number: 9843047Abstract: The present invention provides a battery electrode comprising an active battery material enclosed in the pores of a conductive nanoporous scaffold. The pores in the scaffold constrain the dimensions for the active battery material and inhibit sintering, which results in better cycling stability, longer battery lifetime, and greater power through less agglomeration. Additionally, the scaffold forms electrically conducting pathways to the active battery nanoparticles that are dispersed. In some variations, a battery electrode of the invention includes an electrically conductive scaffold material with pores having at least one length dimension selected from about 0.5 nm to about 100 nm, and an oxide material contained within the pores, wherein the oxide material is electrochemically active.Type: GrantFiled: September 30, 2014Date of Patent: December 12, 2017Assignee: HRL Laboratories, LLCInventors: Adam F. Gross, John J. Vajo, Ping Liu, Elena Sherman
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Patent number: 9337493Abstract: This invention provides metal-foam electrodes for batteries and fuel cells. In some variations, an electrode includes a first metal layer disposed on a second metal layer, wherein the first metal layer comprises an electrically conductive, open-cell metal foam with an average cell diameter of about 25 ?m or less. The structure also includes smaller pores between the cells. The electrode forms a one piece monolithic structure and allows thicker electrodes than are possible with current electrode-fabrication techniques. These electrodes are formed from an all-fluidic plating solution. The disclosed structures increase energy density in batteries and power density in fuel cells.Type: GrantFiled: June 15, 2014Date of Patent: May 10, 2016Assignee: HRL Laboratories, LLCInventors: Adam F. Gross, John Wang, Andrew P. Nowak
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Patent number: 9293759Abstract: A three-dimensional nanobattery formed by individually wiring nanostructured electrodes and combining them with an electrolyte. Short, capped nanotubes termed ‘nanobaskets’ are formed by sputtering coating onto nanoporous templates. Metallic nanowires are grown by electrochemical deposition from the nanobaskets and through the template, making electrical contact with each nanobasket electrode. The same procedure can be used to fabricate both a battery anode and a battery cathode. A thin layer of electrolyte is placed between the two nanobasket electrodes, and electrical contact is made through the nanowires.Type: GrantFiled: November 4, 2013Date of Patent: March 22, 2016Assignee: The University of TulsaInventors: Dale Teeters, Paige Johnson
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Patent number: 9249522Abstract: Methods for forming three-layer thin-film battery (TFB) structures by sequential electrophoretic deposition (EPD) on a single conductive substrate. The TFBs may be two-dimensional or three-dimensional. The sequential EPD includes EPD of a first battery electrode followed by EPD of a porous separator on the first electrode and by EPD of a second battery electrode on the porous separator. In some embodiments of a Li or Li-ion TFB, the separator includes a Li ion conducting solid. In some embodiments of a Li or Li-ion TFB, the separator includes an inorganic porous solid rendered ionically conductive by impregnation with a liquid or polymer. In some embodiments, the TFBs are coated and sealed with an EPDd PEEK layer.Type: GrantFiled: December 5, 2011Date of Patent: February 2, 2016Assignee: Ramot at Tel-Aviv University Ltd.Inventors: Diana Golodnitsky, Emanuel Peled, Menachem Nathan, Gilat Ardel, Hadar Mazor-Shafir, Roni Hadar, Svetlana Menkin-Bachbut, Tania Ripenbein, Kathrin Freedman
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Patent number: 9190649Abstract: A shape memory polymer material composition comprises: (1) a plurality of inorganic core nanoparticles as netpoints to which is connected; (2) a switching segment that comprises a polymer network. The polymer network comprises: (1) a corona component bonded to each inorganic core nanoparticle through a first chemical linkage; (2) a canopy component bonded to each corona component through a second chemical linkage; and (3) a plurality of cross-linking components cross-linking between different canopy components through a third chemical linkage. Given various selections for the inorganic core nanoparticles, the corona component, the canopy component, the cross-linking component, the first chemical linkage, the second chemical linkage and the third chemical linkage, various performance and composition characteristics of the shape memory polymer material compositions may be readily tailored.Type: GrantFiled: May 4, 2012Date of Patent: November 17, 2015Assignee: CORNELL UNIVERSITYInventors: Lynden A. Archer, Praveen Agarwal
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Patent number: 8980438Abstract: The porous metal foil of the present invention include a two-dimensional network structure composed of a metal fiber. This porous metal foil has a first side having a higher glossiness, and a second side having a lower glossiness located on the opposite side of the first side. The ratio of glossiness GS of the first side to glossiness GM of the second side, GS/GM, as measured at incident and reflection angles of 60 degrees in accordance with JIS Z 8741 (1997) is from 1 to 15. The present invention provides a highly useful porous metal foil which has a reduced difference in properties between both sides, in addition to the superior properties attributable to a porous metal foil, in a highly productive and cost effective manner that is suited for continuous production.Type: GrantFiled: March 23, 2012Date of Patent: March 17, 2015Assignee: Mitsui Mining & Smelting Co., Ltd.Inventors: Tetsuhiro Matsunaga, Hajime Watanabe, Joe Nishikawa
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Electrode plate, secondary battery having the same, and manufacturing method for the electrode plate
Patent number: 8956764Abstract: An electrode plate includes a current collector, the current collector being made of metal and having a 3-dimensional mesh structure, and an active material portion including an active material, the active material portion being inserted into a vacant space in the current collector and coated on top and bottom surfaces of the current collector.Type: GrantFiled: August 14, 2012Date of Patent: February 17, 2015Assignee: Samsung SDI Co., Ltd.Inventors: Manseok Han, Jongki Lee, Taesik Kim, Byungjoo Chung, Juhee Sohn, Seonggi Choo, Kyun Lim -
Patent number: 8932766Abstract: A method is disclosed for producing elements ultra-low diameter, ultra-high aspect ratio nanowires. A hierarchical template with ordered and arrayed nanopores either freestanding or on a support material is provided. The template can be pre-shaped. Optionally, one or more compounds can be layered within the nanopores to reduce the diameters thereof. The template is filled with material to form a nanostructure array configured as ultra-low diameter, ultra-high aspect ratio nanowires with a diameter of less than 10 nm. The optional layering is self-initiated by selectively adjusting pH of a coating material. The nanostructure array may be supported in a lower thermal conductivity material. The method can be used to produce elements that function as a phonon-confined thermoelectric device, a photovoltaic device and a battery.Type: GrantFiled: January 10, 2012Date of Patent: January 13, 2015Assignee: Mainstream Engineering CorporationInventor: Justin J. Hill
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Patent number: 8920978Abstract: The present invention provides a battery electrode comprising an active battery material enclosed in the pores of a conductive nanoporous scaffold. The pores in the scaffold constrain the dimensions for the active battery material and inhibit sintering, which results in better cycling stability, longer battery lifetime, and greater power through less agglomeration. Additionally, the scaffold forms electrically conducting pathways to the active battery nanoparticles that are dispersed. In some variations, a battery electrode of the invention includes an electrically conductive scaffold material with pores having at least one length dimension selected from about 0.5 nm to about 100 nm, and an oxide material contained within the pores, wherein the oxide material is electrochemically active.Type: GrantFiled: June 2, 2009Date of Patent: December 30, 2014Assignee: HRL Laboratories, LLCInventors: Adam F. Gross, John J. Vajo, Ping Liu, Elena Sherman
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Patent number: 8916296Abstract: The present application is directed to mesoporous carbon materials comprising bi-functional catalysts. The mesoporous carbon materials find utility in any number of electrical devices, for example, in lithium-air batteries. Methods for making the disclosed carbon materials, and devices comprising the same, are also disclosed.Type: GrantFiled: March 11, 2011Date of Patent: December 23, 2014Assignee: EnerG2 Technologies, Inc.Inventors: Aaron M. Feaver, Henry R. Costantino, Richard D. Varjian
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Patent number: 8883346Abstract: Provided is a method of manufacturing a prismatic battery, or a series of prismatic batteries. The method comprises stacking positive electrode plates, negative electrode plates and separator layers therebetween. The positive and negative electrode plates extend beyond a periphery of the electrode stack. The positive electrode plates are fused to form a positive current collector, and the negative electrode plates are fused to form a negative current collector.Type: GrantFiled: March 14, 2013Date of Patent: November 11, 2014Assignee: Encell TechnologyInventor: Randy Gene Ogg
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Patent number: 8883345Abstract: Provided is a prismatic battery comprising stacked positive electrode plates, negative electrode plates and separator layers therebetween. The positive and negative electrode plates extend beyond a periphery of the electrode stack. The positive electrode plates are fused to form a positive current collector, and the negative electrode plates are fused to form a negative current collector. Both the positive and negative electrode plates comprise a metal foam and are compressed between about 42 and 45% of the original thickness.Type: GrantFiled: December 23, 2008Date of Patent: November 11, 2014Assignee: Encell Technology LLCInventor: Randy Ogg
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Patent number: 8815445Abstract: Provided is a cathode active material for a lithium secondary battery, which can achieve both of excellent rate characteristic and practically sufficient durability (cycle characteristic) in the lithium secondary battery. The cathode active material for a lithium secondary battery includes therein pores. A particle or film of the cathode active material for a lithium secondary battery has formed therein a large number of pores. The inner wall of each of such pores is coated with a conductive film.Type: GrantFiled: March 27, 2012Date of Patent: August 26, 2014Assignee: NGK Insulators, Ltd.Inventors: Ryuta Sugiura, Nobuyuki Kobayashi, Tsutomu Nanataki
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Patent number: 8778540Abstract: A monolithic three-dimensional electrochemical energy storage system is provided on an aerogel or nanotube scaffold. An anode, separator, cathode, and cathodic current collector are deposited on the aerogel or nanotube scaffold.Type: GrantFiled: October 9, 2013Date of Patent: July 15, 2014Assignee: Lawrence Livermore National Security, LLCInventors: Joseph Collin Farmer, Michael Stadermann
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Patent number: 8778541Abstract: A negative electrode used for a nonaqueous electrolyte solution battery having nonaqueous electrolyte solution containing lithium ion includes a metal carbon composite material. The metal carbon composite material has a porous carbon material having cavities, and a metal material made of metal to reversibly store or emit lithium ion. The metal material is arranged on a surface of the porous carbon material including inner surfaces of the cavities. The porous carbon material has a mass of 1-65 mass % when the metal carbon composite material is defined to have a mass of 100 mass %.Type: GrantFiled: April 27, 2010Date of Patent: July 15, 2014Assignees: Denso Corporation, Inter-University Research Institute Corporation National Institutes of Natural SciencesInventors: Kouhei Yamamoto, Norikazu Adachi, Hisashi Umemoto, Manabu Yamada, Yasuyuki Ooba, Nobuyuki Nishi, Shigenori Numao
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Patent number: 8741486Abstract: In one embodiment, an energy storage device is provided which includes a cathode and an anode with a separator therebetween. At least one of the cathode or the anode has a rigid polymer matrix with an active material and elongated electrically conducting material having ion conducting moieties bonded thereto within the polymer matrix.Type: GrantFiled: March 2, 2006Date of Patent: June 3, 2014Assignee: HRL Laboratories, LLCInventors: Alan Jacobsen, Ping Liu, Kevin W. Kirby, Elena Sherman
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Patent number: 8652686Abstract: A composite solid electrolyte includes a monolithic solid electrolyte base component that is a continuous matrix of an inorganic active metal ion conductor and a filler component used to eliminate through porosity in the solid electrolyte. In this way a solid electrolyte produced by any process that yields residual through porosity can be modified by the incorporation of a filler to form a substantially impervious composite solid electrolyte and eliminate through porosity in the base component. Methods of making the composites are also disclosed. The composites are generally useful in electrochemical cell structures such as battery cells and in particular protected active metal anodes, particularly lithium anodes, that are protected with a protective membrane architecture incorporating the composite solid electrolyte.Type: GrantFiled: November 9, 2012Date of Patent: February 18, 2014Assignee: PolyPlus Battery CompanyInventors: Steven J. Visco, Lutgard C. De Jonghe, Yevgeniy S. Nimon
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Patent number: 8637185Abstract: Provided are conductive substrates having open structures and fractional void volumes of at least about 25% or, more specifically, or at least about 50% for use in lithium ion batteries. Nanostructured active materials are deposited over such substrates to form battery electrodes. The fractional void volume may help to accommodate swelling of some active materials during cycling. In certain embodiments, overall outer dimensions of the electrode remain substantially the same during cycling, while internal open spaces of the conductive substrate provide space for any volumetric changes in the nanostructured active materials. In specific embodiments, a nanoscale layer of silicon is deposited over a metallic mesh to form a negative electrode. In another embodiment, a conductive substrate is a perforated sheet with multiple openings, such that a nanostructured active material is deposited into the openings but not on the external surfaces of the sheet.Type: GrantFiled: November 11, 2010Date of Patent: January 28, 2014Assignee: Amprius, Inc.Inventors: Eugene M. Berdichevsky, Song Han, Yi Cui, Rainer J. Fasching, Ghyrn E. Loveness, William S. DelHagen, Mark C. Platshon
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Patent number: 8617746Abstract: An Si/C composite includes carbon (C) dispersed in porous silicon (Si) particles. The Si/C composite may be used to form an anode active material to provide a lithium battery having a high capacity and excellent capacity retention.Type: GrantFiled: September 5, 2012Date of Patent: December 31, 2013Assignee: Samsung SDI Co., Ltd.Inventors: Sang-kook Mah, Han-su Kim
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Publication number: 20130323602Abstract: A composite metal foil is provided comprising a porous metal foil comprising a two-dimensional network structure composed of a metal fiber, and a primer provided on at least a part of the interior and/or periphery of pores of the porous metal foil. According to the present invention, it is possible to obtain a composite metal foil which has a desired function imparted by a primer in addition to superior properties derived from a porous metal foil, in a highly productive and cost effective manner that is suited for continuous production.Type: ApplicationFiled: March 23, 2012Publication date: December 5, 2013Applicant: Mitsui Mining & Smelting Co., Ltd.Inventors: Tetsuhiro Matsunaga, Hajime Watanabe, Joe Nishikawa
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Patent number: 8592082Abstract: A secondary battery includes an electrode assembly, which has improved safety by reducing a density of an active material centrally positioned in the electrode assembly. In the secondary battery, an electrode assembly includes a first electrode plate, a second electrode plate and a separator between the first electrode plate and the second electrode plate, the first electrode plate including a first electrode current collector and a first active material layer on the first electrode current collector, the first active material layer including a first active material, a binder and a conductive agent, and a portion of the first active material layer at a central portion of the electrode assembly including the first active material at a lower density than a density of the first active material at a portion of the first active material layer at a peripheral portion of the electrode assembly.Type: GrantFiled: July 18, 2012Date of Patent: November 26, 2013Assignee: Samsung SDI Co., Ltd.Inventors: Chanho Lee, Kiwoon Kim, Young Ju Ahn, Jinho Lee, Junpyo Park
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Patent number: 8580438Abstract: A monolithic three-dimensional electrochemical energy storage system is provided on an aerogel or nanotube scaffold. An anode, separator, cathode, and cathodic current collector are deposited on the aerogel or nanotube scaffold.Type: GrantFiled: December 14, 2010Date of Patent: November 12, 2013Assignee: Lawrence Livermore National Security, LLCInventors: Joseph C. Farmer, Michael Stadermann
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Patent number: 8546017Abstract: Provided is a composite for anode material, a method of manufacturing the composite for anode material, and a cathode and a lithium battery that includes the composite for anode material, and more particularly, to a composite for anode material that has a large charge and discharge capacity and a high capacity retention, a method of manufacturing the composite for anode material, and a cathode and a lithium battery that includes the composite for anode material. Also, the composite for anode material in which Si or Si and carbon are distributed in silicon oxide particles is provided.Type: GrantFiled: May 30, 2008Date of Patent: October 1, 2013Assignee: Samsung SDI Co., Ltd.Inventors: Sang-kook Mah, Han-su Kim
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Patent number: 8497026Abstract: A porous metal foil of the present invention comprises a two-dimensional network structure composed of metal fibers. This porous metal foil has superior properties and can be obtained in a highly productive and cost effective manner.Type: GrantFiled: June 25, 2010Date of Patent: July 30, 2013Assignee: Mitsui Mining & Smelting Co., Ltd.Inventors: Tetsuhiro Matsunaga, Hajime Watanabe, Joe Nishikawa, Tetsuro Sato
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Patent number: 8357469Abstract: A bipolar battery construction is disclosed comprising a substrate, openings in the substrate, an electrically conductive material placed within the openings, a negative and positive current collector foil placed on opposing sides of the substrate and negative and positive pasting frame members. The electrically conductive material may have a melting point below the thermal degradation temperature of the substrate.Type: GrantFiled: January 20, 2010Date of Patent: January 22, 2013Assignee: Advanced Battery Concepts, LLCInventors: Edward Otto Shaffer, II, William Buttfield Brecht
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Patent number: 8334075Abstract: A composite solid electrolyte includes a monolithic solid electrolyte base component that is a continuous matrix of an inorganic active metal ion conductor and a filler component used to eliminate through porosity in the solid electrolyte. In this way a solid electrolyte produced by any process that yields residual through porosity can be modified by the incorporation of a filler to form a substantially impervious composite solid electrolyte and eliminate through porosity in the base component. Such composites may be made by disclosed techniques. The composites are generally useful in electrochemical cell structures such as battery cells and in particular protected active metal anodes, particularly lithium anodes, that are protected with a protective membrane architecture incorporating the composite solid electrolyte.Type: GrantFiled: April 23, 2012Date of Patent: December 18, 2012Assignee: PolyPlus Battery CompanyInventors: Steven J. Visco, Lutgard C. De Jonghe, Yevgeniy S. Nimon
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Patent number: 8293404Abstract: A catalyst structure body for a fuel cell includes an agglomerate structure in which agglomerates each formed by aggregation of a catalyst-supporting carbon in which a catalyst is supported on a surface of a carbon have gathered, and a polymer having proton conductivity. The agglomerate structure and the polymer coexist. The polymer has entered pores between the agglomerates in the agglomerate structure. The average thickness of the polymer is set at 3 to 50 nanometers.Type: GrantFiled: September 11, 2007Date of Patent: October 23, 2012Assignee: Toyota Jidosha Kabushiki KaishaInventor: Masahiko Morinaga
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Patent number: 8263265Abstract: An Si/C composite includes carbon (C) dispersed in porous silicon (Si) particles. The Si/C composite may be used to form an anode active material to provide a lithium battery having a high capacity and excellent capacity retention.Type: GrantFiled: May 12, 2008Date of Patent: September 11, 2012Assignee: Samsung SDI Co., Ltd.Inventors: Sang-kook Mah, Han-su Kim
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Patent number: 8236448Abstract: An electrode substrate for a battery has nickel applied as a coat on the surface of a base constituted of crossing of a plurality of fibers including a core formed of synthetic resin and a coating of synthetic resin having a softening temperature lower than the softening temperature of the synthetic resin forming the core. The electrode substrate has the fibers of the base fusion-bonded at a cross point by heat treatment. The ratio of the coating occupying a II-II cross section of the fiber cross point is larger than the ratio of the coating occupying a fiber cross section (III-III cross section) at a site other than at the cross point.Type: GrantFiled: November 30, 2010Date of Patent: August 7, 2012Assignees: Sumitomo Electric Industries, Ltd., National Institute of Advanced Industrial Science and TechnologyInventors: Kazuki Okuno, Jin-Joo Park, Masahiro Kato, Masaru Yao, Tsutomu Iwaki, Tetsuo Sakai
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Patent number: 8211573Abstract: The present invention provides a conductive sheet having a surface resistance of 10 ?/sq or lower on both surfaces, the conductive sheet comprising a sheet (A) and a sheet (B) laminated to the sheet (A), the sheet (A) having an apparent specific gravity of 0.05 g/cm3 to 0.50 g/cm3 and being formed from fibers having a diameter within the range between 3 and 20 ?m, and the sheet (B) being formed from fibers having a diameter of 3 ?m or smaller. The sheet (A) may be a fibrous material comprises an organic polymer fiber as its main component.Type: GrantFiled: September 6, 2011Date of Patent: July 3, 2012Assignee: Kuraray Co., Ltd.Inventors: Masakazu Nishiyama, Eiichi Ishida, Yoshiaki Yasuda
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Patent number: 8202653Abstract: An electrode includes a current collector comprising a grid, said grid comprising a plurality of planar, parallel rows disposed between interleaved rows having raised and lowered segments, and a tab portion extending from a side of the current collector. Raised and lowered segments are disposed horizontally relative to the tab portion, thereby providing substantially uninterrupted conductive ribbons extending from the bottom of the current collector to the tab portion.Type: GrantFiled: October 19, 2007Date of Patent: June 19, 2012Assignee: Axion Power International, Inc.Inventors: Edward R. Buiel, Joseph E. Cole
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Patent number: 8182943Abstract: A composite solid electrolyte include a monolithic solid electrolyte base component that is a continuous matrix of an inorganic active metal ion conductor and a filler component used to eliminate through porosity in the solid electrolyte. In this way a solid electrolyte produced by any process that yields residual through porosity can be modified by the incorporation of a filler to form a substantially impervious composite solid electrolyte and eliminate through porosity in the base component. Methods of making the composites is also disclosed. The composites are generally useful in electrochemical cell structures such as battery cells and in particular protected active metal anodes, particularly lithium anodes, that are protected with a protective membrane architecture incorporating the composite solid electrolyte.Type: GrantFiled: December 19, 2006Date of Patent: May 22, 2012Assignee: PolyPlus Battery CompanyInventors: Steven J. Visco, Lutgard C. DeJonghe, Yevgeniy S. Nimon
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Publication number: 20110318642Abstract: The present invention provides a conductive sheet having a surface resistance of 10 ?/sq or lower on both surfaces, the conductive sheet comprising a sheet (A) and a sheet (B) laminated to the sheet (A), the sheet (A) having an apparent specific gravity of 0.05 g/cm3 to 0.50 g/cm3 and being formed from fibers having a diameter within the range between 3 and 20 ?m, and the sheet (B) being formed from fibers having a diameter of 3 ?m or smaller. The sheet (A) may be a fibrous material comprises an organic polymer fiber as its main component.Type: ApplicationFiled: September 6, 2011Publication date: December 29, 2011Applicant: KURARAY CO., LTD.Inventors: Masakazu NISHIYAMA, Eiichi ISHIDA, Yoshiaki YASUDA
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Patent number: 7998621Abstract: A battery electrode substrate includes a metallic porous body. The metallic porous body has a structure in which a surface of a plastic fiber in a woven or unwoven fabric is coated with a nickel film. The nickel film coats the surface with an average coverage ratio of not less than 85%.Type: GrantFiled: January 10, 2006Date of Patent: August 16, 2011Assignees: Sumitomo Electric Industries, Ltd., Sumitomo Electric Toyama Co., Ltd.Inventors: Keizo Harada, Masahiro Kato, Hidetoshi Saito, Tadashi Omura, Hitoshi Tsuchida
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Publication number: 20110111296Abstract: Provided are conductive substrates having open structures and fractional void volumes of at least about 25% or, more specifically, or at least about 50% for use in lithium ion batteries. Nanostructured active materials are deposited over such substrates to form battery electrodes. The fractional void volume may help to accommodate swelling of some active materials during cycling. In certain embodiments, overall outer dimensions of the electrode remain substantially the same during cycling, while internal open spaces of the conductive substrate provide space for any volumetric changes in the nanostructured active materials. In specific embodiments, a nanoscale layer of silicon is deposited over a metallic mesh to form a negative electrode. In another embodiment, a conductive substrate is a perforated sheet with multiple openings, such that a nanostructured active material is deposited into the openings but not on the external surfaces of the sheet.Type: ApplicationFiled: November 11, 2010Publication date: May 12, 2011Applicant: AMPRIUS, INC.Inventors: Eugene M. Berdichevsky, Song Han, Yi Cui, Rainer J. Fasching, Ghyrn E. Loveness, William S. DelHagen, Mark C. Platshon
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Publication number: 20110059361Abstract: The present invention relates to the use of porous structures comprising sulfur in electrochemical cells. Such materials may be useful, for example, in forming one or more electrodes in an electrochemical cell. For example, the systems and methods described herein may comprise the use of an electrode comprising a conductive porous support structure and a plurality of particles comprising sulfur (e.g., as an active species) substantially contained within the pores of the support structure. The inventors have unexpectedly discovered that, in some embodiments, the sizes of the pores within the porous support structure and/or the sizes of the particles within the pores can be tailored such that the contact between the electrolyte and the sulfur is enhanced, while the electrical conductivity and structural integrity of the electrode are maintained at sufficiently high levels to allow for effective operation of the cell.Type: ApplicationFiled: August 24, 2010Publication date: March 10, 2011Applicant: Sion Power CorporationInventors: William F. Wilkening, Christopher T. S. Campbell, Savannah V. Burnside
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Patent number: 7811709Abstract: A negative electrode for a non-aqueous electrolyte secondary cell includes a current collector an, formed on a surface or both surfaces thereof, an active material structure containing an electroconductive material with a low capability of forming a compound with lithium, and the active material structure includes 5% to 80% by weight of active material particles containing a material having a high capability for forming a compound with lithium. The active material structure can include an active material layer containing the active material particles and a surface-covering layer on the active material layer.Type: GrantFiled: November 25, 2003Date of Patent: October 12, 2010Assignee: Mitsui Mining & Smelting Co., Ltd.Inventors: Shinichi Musha, Hitohiko Honda, Yoshiki Sakaguschi, Kiyotaka Yasuda, Akihiro Modeki, Tomoyoshi Matsushima, Takeo Taguchi, Kazuko Taniguchi, Makoto Dobashi
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Patent number: 7709139Abstract: A battery device includes a cathode current collector and an anode current collector. A fibrous electrode forms a structure defining a plurality of pores. A first portion of the fibrous electrode is in contact with a current collector. An electrolytic polymer is electrodeposited on the fibrous electrode to provide substantial uniform coverage of fibers forming the fibrous electrode. A plurality of electrode particles are disposed within the plurality of pores and separated from the fibrous electrode by the electrolytic polymer.Type: GrantFiled: January 22, 2007Date of Patent: May 4, 2010Assignee: Physical Sciences, Inc.Inventors: Kevin White, Quinn Horn, Edward Salley, John Lennhoff
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Patent number: 7598001Abstract: An alkaline battery comprises an electrode. The electrode has a current collector and an active substance filled in the current collector. The current collector includes a nonwoven fabric fabricated from a plurality of fibers and a nickel-plating film formed on the plurality of fibers. A specific surface area per unit volume of the current collector is 0.13 m2/cm3-0.35 m2/cm3.Type: GrantFiled: June 3, 2005Date of Patent: October 6, 2009Assignees: Sanoh Industrial Co., Ltd., JEMCO Inc., Japan Vilene Company Ltd.Inventors: Kazuya Tsuda, Kunikazu Nagai, Hiroyuki Imai, Yoshitaka Mayuzumi, Kazuya Sato, Toshiaki Takase, Masanao Tanaka
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Patent number: 7427455Abstract: There are provided an anode for a lithium metal polymer secondary battery comprising an anodic current collector having a surface on which a plurality of recesses having a predetermined shape are formed and a method of preparing the same. The plurality of recesses are formed on a surface of the anodic current collector using a physical method or a chemical method. In a lithium metal polymer secondary battery employing the anode, oxidation/reduction of lithium and the formation of dendrite occur only in the recesses formed by surface patterning of the anodic current collector. Thus, expanding and shrinking of a battery due to a change in the thickness of the lithium anode can be prevented and cycling stability and the lifespan of a battery can be improved.Type: GrantFiled: September 19, 2005Date of Patent: September 23, 2008Assignee: Electronics and Telecommunications Research InstituteInventors: Young Gi Lee, Yong Sik Hong, Yong Joon Park, Kwang Sun Ryu
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Patent number: 7384707Abstract: A non-aqueous electrolyte secondary battery has an electrode and an electrolyte layer. The electrode includes a collector having a lot of fine pores on its surface, and a membrane layer made of an electrode active material provided along the surface shape of the fine pores of the collector. By this structure, the battery can manifest an excellent performance even in charging and discharging at high speed without using a binder and conductive material.Type: GrantFiled: August 13, 2004Date of Patent: June 10, 2008Assignee: Nissan Motor Co., Ltd.Inventors: Mori Nagayama, Kouichi Nemoto
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Patent number: 7314685Abstract: A titanium substrate having a thickened outer oxidation layer provided thereon by a treatment process performed either in an air atmosphere at elevated temperatures or through electrolytic oxidation (anodization), is discribed. The thusly conditioned titanium substrate serving as a cathode current collector for an electrode incorporated into an electrochemical cell exhibits improved electrical performance in comparison to the prior art techniques, i.e., electrically conducted carbon coated titanium screen and use of highly corrosion resistant materials, upon subsequent elevated temperature exposure.Type: GrantFiled: October 7, 2003Date of Patent: January 1, 2008Assignee: Greatbatch Ltd.Inventors: W. Richard Brown, Christine A. Frysz, Sally Ann Smesko, Esther S. Takeuchi
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Patent number: RE41578Abstract: Thin-film micro-electrochemical energy storage cells (MEESC) such as microbatteries and double-layer capacitors (DLC) are provided. The MEESC comprises two thin layer electrodes, an intermediate thin layer of a solid electrolyte and optionally, a fourth thin current collector layer; said layers being deposited in sequence on a surface of a substrate. The MEESC is characterized in that the substrate is provided with a plurality of through cavities of arbitrary shape, with high aspect ratio. By using the substrate volume, an increase in the total electrode area per volume is accomplished.Type: GrantFiled: October 3, 2007Date of Patent: August 24, 2010Assignee: Ramot At Tel-Aviv University Ltd.Inventors: Menachem Nathan, Emanuel Peled, Dan Haronian
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Patent number: RE42073Abstract: Thin-film micro-electrochemical energy storage cells (MEESC) such as microbatteries and double-layer capacitors (DLC) are provided. The MEESC comprises two thin layer electrodes, an intermediate thin layer of a solid electrolyte and optionally, a fourth thin current collector layer; said layers being deposited in sequence on a surface of a substrate. The MEESC is characterized in that the substrate is provided with a plurality of through cavities of arbitrary shape, with high aspect ratio. By using the substrate volume, an increase in the total electrode area per volume is accomplished.Type: GrantFiled: March 6, 2003Date of Patent: January 25, 2011Assignee: Ramot At Tel Aviv UniversityInventors: Menachem Nathan, Emanuel Peled, Dan Haronian
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Patent number: RE42273Abstract: Thin-film micro-electrochemical energy storage cells (MEESC) such as microbatteries and double-layer capacitors (DLC) are provided. The MEESC comprises two thin layer electrodes, an intermediate thin layer of a solid electrolyte and optionally, a fourth thin current collector layer; said layers being deposited in sequence on a surface of a substrate. The MEESC is characterized in that the substrate is provided with a plurality of through cavities of arbitrary shape, with high aspect ratio. By using the substrate volume, an increase in the total electrode area per volume is accomplished.Type: GrantFiled: July 12, 2010Date of Patent: April 5, 2011Assignee: Ramot At Tel-Aviv University Ltd.Inventors: Menachem Nathan, Emanuel Peled, Dan Haronian