Patent application number | Description | Published |
20080286631 | Thermo-mechanical robust solid oxide fuel cell device assembly - A solid oxide fuel cell device assembly comprising: (i) at least one solid oxide fuel cell device including one electrolyte sheet sandwiched between at least one pair of electrodes; and (ii) a non-steel frame fixedly attached to said at least one fuel cell device without a seal located therebetween. | 11-20-2008 |
20090075802 | GLASS-CERAMIC SEALS FOR USE IN SOLID OXIDE FUEL CELLS - The invention is directed to highly crystalline, frit-sintered glass-ceramic materials and seals made using them that are suitable for solid oxide fuel cell applications. The seals have a coefficient of thermal expansion in the range of 70-130×10 | 03-19-2009 |
20090110993 | Segmented solid oxide fuel cell stack and methods for operation and use thereof - Disclosed is a segmented modular solid oxide fuel cell device having a plurality of independently controllable electrical power producing segments disposed within a common thermal environment. Also disclosed are methods for selectively operating one or more segments of the disclosed segmented modular solid oxide fuel cell device. Also disclosed are methods for performing a maintenance process on one or more segments of a segmented modular fuel cell device during fuel cell operation. | 04-30-2009 |
20110033779 | Insulation for SOFC Systems - The invention is directed to insulating compositions for use in solid oxide fuel cells. Such compositions can be used to prevent seal damage and increase the electrical and ion efficiency. | 02-10-2011 |
20110113855 | Analyte Gas Sensors - Apparatuses and methods for determining the concentration of an analyte gas in a gas stream with a sensor are described. The analyte gas sensor may include a mass-sensitive resonator and a diffusion barrier. The mass-sensitive resonator may be coated with an absorptive material which is reactive with an analyte gas, such as NOx. The diffusion barrier may be positioned to limit a gas flow with the analyte gas towards the absorptive material, and a ratio of the diffusion time of the gas flow through the diffusion barrier to the reaction time of the analyte gas with the absorptive material may be from about 0.1 to about 100. | 05-19-2011 |
20110117466 | Solid Oxide Fuel Cell Systems - According to one embodiment of the present invention a fuel cell system comprises: (i) a plurality of fuel cell packets, each packet comprising at least one fuel inlet, at least one fuel outlet, a frame, and two multi-cell fuel cell devices, the fuel cell devices situated such that an anode side of one fuel cell device faces an anode side of another fuel cell device, and the two fuel cell devices, in combination, at least partially form a fuel chamber connected to the fuel inlet and the fuel outlet; (ii) a plurality of heat exchange packets, each packet comprising at least one oxidant inlet, at least one oxidant outlet, and an internal oxidant chamber connected to the at least one oxidant inlet and the least one oxidant outlet; the heat exchange packets being parallel to and interspersed between the fuel cell packets, such that the heat exchange packets face the fuel cell packets and form, at least in part, a plurality of cathode reaction chambers between the heat exchange packets and the fuel cell packets; (iii) a housing supporting and enclosing the fuel packets and the heat exchange packets; (iv) an oxidant inlet plenum operatively connected to oxidant inlets of the heat exchange packets; (v) an oxidant exhaust plenum operatively connected to the cathode reaction chambers; (vi) an inlet fuel manifold connected to fuel inlets of the fuel cell packets; and (vii) an exhaust fuel manifold connected to the fuel outlets of the fuel cell packets. | 05-19-2011 |
20110229794 | Composite Cathode for Use in Solid Oxide Fuel Cell Devices - Disclosed are composite electrodes for use in a solid oxide fuel cell devices. The electrodes are comprised of a sintered mixture of lanthanum strontium ferrite phase and yttria stabilized zirconia phase. The lanthanum strontium ferrite phase has the general formula (La | 09-22-2011 |
20120003532 | PROTECTED METAL ANODE ARCHITECTURE AND METHOD OF FORMING THE SAME - The invention provides a protected metal anode architecture comprising: a metal anode layer; and an organic protection film formed over and optionally in direct contact with the metal anode layer, wherein the metal anode layer comprises a metal selected from the group consisting of an alkaline metal and an alkaline earth metal, and the organic protection film comprises a reaction product of the metal and an electron donor compound. The invention further provides a method of forming a protected metal anode architecture. | 01-05-2012 |
20130084504 | MICROMACHINED ELECTROLYTE SHEET - The disclosure relates to ceramic lithium ion electrolyte membranes and processes for forming them. The ceramic lithium electrolyte membrane may comprise at least one ablative edge. Exemplary processes for forming the ceramic lithium ion electrolyte membranes comprise fabricating a lithium ion electrolyte sheet and cutting at least one edge of the fabricated electrolyte sheet with an ablative laser. | 04-04-2013 |
20130137010 | REACTIVE SINTERING OF CERAMIC LITHIUM-ION SOLID ELECTROLYTES - A method of forming a solid, dense, hermetic lithium-ion electrolyte membrane comprises combing an amorphous, glassy, or low melting temperature solid reactant with a refractory oxide reactant to form a mixture, casting the mixture to form a green body, and sintering the green body to form a solid membrane. The resulting electrolyte membranes can be incorporated into lithium-ion batteries. | 05-30-2013 |
20130256598 | BISMUTH BORATE GLASS ENCAPSULANT FOR LED PHOSPHORS - Embodiments are directed to glass frits containing phosphors that can be used in LED lighting devices and for methods associated therewith for making the phosphor containing glass frit and their use in glass articles, for example, LED devices. | 10-03-2013 |
20130330640 | METAL SUPPORTED NANOWIRE CATHODE CATALYSTS FOR LI-AIR BATTERIES - A cathode current collector includes a porous metallic or conductive ceramic support and an oxide catalyst in the form of nanowires formed over the support. The nanowire catalyst may be oriented substantially perpendicular to surfaces of the substrate. An example oxide catalyst is cobalt oxide, and an example substrate is nickel foam. | 12-12-2013 |
20140065513 | ION-CONDUCTING COMPOSITE ELECTROLYTE COMPRISING PATH-ENGINEERED PARTICLES - An ion-conducting composite electrolyte is provided comprising path-engineered ion-conducting ceramic electrolyte particles and a solid polymeric matrix. The path-engineered particles are characterized by an anisotropic crystalline structure and the ionic conductivity of the crystalline structure in a preferred conductivity direction H associated with one of the crystal planes of the path-engineered particle is larger than the ionic conductivity of the crystalline structure in a reduced conductivity direction L associated with another of the crystal planes of the path-engineered particle. The path-engineered particles are sized and positioned in the polymeric matrix such that a majority of the path-engineered particles breach both of the opposite major faces of the matrix body and are oriented in the polymeric matrix such that the preferred conductivity direction H is more closely aligned with a minimum path length spanning a thickness of the matrix body than is the reduced conductivity direction L. | 03-06-2014 |
20140084503 | FLAME SPRAY PYROLYSIS METHOD FOR FORMING NANOSCALE LITHIUM METAL PHOSPHATE POWDERS - A flame spray pyrolysis method for making nanoscale, lithium ion-conductive ceramic powders comprises providing a precursor solution comprising chemical precursors dissolved in an organic solvent, and spraying the precursor solution into an oxidizing flame to form a nanoscale, lithium ion-conductive ceramic powder, wherein a concentration of the chemical precursors in the solvent ranges from 1 to 20 M. The precursor solution can comprise 1-20% excess lithium with respect to a stoichiometric composition of the ceramic powder. Nominal compositions of the nanoscale, ceramic powders are Li | 03-27-2014 |
20140150386 | SUBSTRATE WITH SINUOUS WEB AND PARTICULATE FILTER INCORPORATING THE SAME - Described herein is a substrate including a central longitudinal axis, a first support web, and a second support web. A sinuous web may be positioned between the first support web and the second support web. The sinuous web may include transverse web portions and bridging web portions, where the bridging web portions alternatively connect ends of adjacent transverse web portions. The sinuous web may be connected to the first support web by support legs extending between bridging web portions and a surface of the first support web. The sinuous web may be connected to the second support web by support legs extending between bridging web portions and a surface of the second support web. A support leg length to distance between transverse web portions ratio may be from about 1.0 to about 4.0. | 06-05-2014 |
20140220439 | COMPOSITE PROTECTIVE LAYER FOR LITHIUM METAL ANODE AND METHOD OF MAKING THE SAME - The present disclosure relates to protected metal anode architecture and method of making the same, providing a protected metal anode architecture comprising a metal anode; and a composite protection film formed over and in direct contact with the metal anode, wherein the metal anode comprises a metal selected from the group consisting of an alkaline metal and an alkaline earth metal, and the composite protection film comprises particles of an inorganic compound dispersed throughout a matrix of an organic compound. The present disclosure also provides a method of forming a protected metal anode architecture. | 08-07-2014 |
20140295286 | CERAMIC ELECTROLYTE MATERIAL COMPRISING A MODIFIED POLYCRYSTALLINE LITHIUM METAL PHOSPHATE - There is disclosed a polycrystalline lithium-ion conductive membrane for a lithium-air battery that comprises at least one surface, a polycrystalline lithium-ion conductive material comprising grain boundaries, and at least one modifying phase, wherein (a) the at least one modifying phase is incorporated into the grain boundaries to form a modified polycrystalline lithium-ion conductive material comprising modified grain boundaries, (b) the at least one modifying phase is incorporated into the at least one surface to form a modified surface, or both (a) and (b). Various lithium based batteries, including lithium ion, lithium-air, and lithium-water batteries are disclosed, as well as methods for modifying the polycrystalline lithium-ion conductive membrane to allow it to be used in such battery applications. | 10-02-2014 |