Patent application number | Description | Published |
20080292932 | SOLID OXIDE FUEL CELL - A fuel cell has a stack structure in which fired sheet bodies (laminates each including a fuel electrode layer, a solid electrolyte layer, and an air electrode layer) and support members for supporting the sheet bodies are stacked in alternating layers. Each of the sheet bodies is warped downward (toward an air-electrode-layer side). Because of a magnitude relationship of thermal expansion coefficient among the layers in the sheet body and that between the support member and the sheet body, a warp height gradually lessens in the course of temperature rise at start-up. However, even when a working temperature (800° C. or the like) is reached, the sheet bodies are still warped downward. By virtue of presence of the warp, the sheet bodies become unlikely to be deformed at the working temperature. | 11-27-2008 |
20090023045 | REACTOR - A solid oxide fuel cell has a stack structure in which sheet bodies and support members are stacked in alternating layers. A space through which a fuel gas or air flows is formed between the adjacent sheet body and support member. Partitions are provided on the support member in such a manner as to stand in the space, thereby forming a “first flow F | 01-22-2009 |
20090023048 | REACTOR - In a fuel cell, perimetric portions of each sheet body, an upper support member, and a lower support member are sealed against one another by a seal including first and second seal portions. The first seal portion is of glass having a softening point lower than a working temperature of the reactor and seals against the upper surface of the perimetric portion of the sheet body and the lower surface of the perimetric portion of the upper support member as well as the lower surface of the perimetric portion of the sheet body and the upper surface of the perimetric portion of the lower support member. The second seal portion is of glass having a softening point higher than the working temperature and seals against the lower side end and upper side end of the perimetric portions of the upper and lower support members, respectively. | 01-22-2009 |
20090169940 | REACTOR - A fuel cell employs a stack structure in which a plurality of sheet bodies and a plurality of separators are stacked and joined together in alternating layers. Chemical reactions occur in the sheet bodies. The separators separate, from each other, two kinds of gasses (air and fuel gas) which are necessary for the chemical reactions. The plurality of separators consist of high-rigidity separator(s), and ordinary separators, which are lower in rigidity than the high-rigidity separator. This configuration reliably suppresses the occurrence of “separation of a joint region” attributable to “stress concentration caused by increase in the number of the stacked separators. | 07-02-2009 |
20090191440 | SOLID OXIDE FUEL CELL - A solid oxide fuel cell has a stack structure in which sheet bodies and separators for separating air and fuel gas are stacked in alternating layers. Each of the sheet bodies includes an electrolyte layer, a fuel electrode layer formed on the upper surface of the electrolyte layer, and an air electrode layer formed on the lower surface of the electrolyte layer, wherein these layers are stacked and fired in such a manner that the electrolyte layer is sandwiched between the fuel electrode layer and the air electrode layer. The thickness of the electrolyte layer is 0.3 μm or more and 5 μm or less, and the electrolyte layer is composed of a single particle of YSZ in the thickness direction. Thus, the electrolyte layer is extremely thin, and further, the grain boundary in the thickness direction is small. Accordingly, the IR loss (electric resistance) of the electrolyte layer can remarkably be reduced. | 07-30-2009 |
20100047651 | SHEET BODY OF SOLID OXIDE FUEL CELL, AND SOLID OXIDE FUEL CELL - A sheet body | 02-25-2010 |
20100050422 | ASSEMBLING METHOD OF SOLID OXIDE FUEL CELL - An assembling method of a solid oxide fuel cell, having a stack structure in which sheet bodies and separators are stacked in alternating layers, includes a stacking step, a sealing step, and a reduction process step. In the sealing step, a laminate in which a crystallized glass material is interposed between the perimetric portions adjacent to each other is heated, so that the crystallization rate of the crystallized glass is increased to 0 to 50%. Accordingly, the perimetric portions adjacent to each other are integrated and sealed, and a room for glass softening is left. In the reduction process step, the laminate is heated, and a reduction gas is supplied into a fuel channel, whereby the reduction process is performed to the fuel electrode layer, and the crystallization rate is increased to 70 to 100%. Thus, the assembly of the fuel cell is completed. | 03-04-2010 |
20100055531 | SOLID OXIDE FUEL CELL, AND ASSEMBLING METHOD OF THE SAME - A reduction process is performed to each fuel electrode layer by supplying a reduction gas into each fuel channel | 03-04-2010 |
20100194003 | METHOD FOR MANUFACTURING A FIRED CERAMIC BODY INCLUDING A METALLIC WIRE INSIDE - A method for manufacturing a fired ceramic body including a metal wire wherein the metal wire is placed in a mold, and then, a ceramic slurry having a heat-gelling characteristic or a thermoset characteristic is poured into the mold. Subsequently, the ceramic slurry is dried and hardened to form a ceramic-compact-before-fired, and then, the ceramic-compact-before-fired is fired. In this firing process, a degreasing of the ceramic compact is firstly performed, and thereafter, a temperature of the ceramic compact is increased up to a second temperature at which the metal wire is softened and the ceramic compact is fired at a second temperature increasing rate. The second temperature increasing rate is set at such a rate that a shrinkage ratio of the ceramic compact when the temperature of the ceramic compact reaches the second temperature is smaller than or equal to a predetermined threshold shrinkage ratio. | 08-05-2010 |
20100194511 | COMPACT INDUCTOR AND A METHOD FOR MANUFACTURING THE SAME - A compact inductor comprises a coil, a coil-burying body, and a body for a closed magnetic circuit. The coil-burying body is a fired porous ceramic body having a first magnetic permeability, in which the coil is buried. In the coil-burying body, “a through-hole | 08-05-2010 |
20100194513 | LAYERED INDUCTOR - A layered inductor | 08-05-2010 |
20110121930 | COIL-BURIED TYPE INDUCTOR AND A METHOD FOR MANUFACTURING THE SAME - The invention relates to a coil-buried type inductor. The inductor comprises a conductive coil, a first fired ceramics body arranged at least in an area along an inner periphery of the coil, and a second fired ceramics body arranged so as to surround the entire of the coil along with the first fired ceramics body. The first fired ceramics body has porosity equal to or larger than 40 percent and smaller than 70 percent. | 05-26-2011 |
20120236459 | COMPOSITE ELECTRONIC COMPONENT - The present invention relates to a composite electronic component having a dielectric body portion inside of which a conductive body is provided, and a magnetic body portion inside of which a conductive body is provided. In the present invention, a layer made of a metal material is arranged between the dielectric body portion and the magnetic body portion as an intermediate layer. | 09-20-2012 |