Patent application number | Description | Published |
20080230585 | DIFFERENT MATERIALS BONDED MEMBER AND PRODUCTION METHOD THEREOF - A different materials bonded member includes a ceramic base material and a metallic member which are bonded together through an Au solder material. The solder material is disposed on a bonding surface of the ceramic base through a given active metal layer or a given metalized layer and the solder material is heated and melted to form a pre-coat layer adhering to the bonding surface, the metallic member is disposed on a surface of the pre-coat layer through a barrier layer having a given function. A bonded part is formed by solidifying the pre-coat layer after it has been heated and melted under given temperature conditions to bond the ceramic base and the metallic member to one another. | 09-25-2008 |
20080272180 | METHOD OF MANUFACTURING HEAT SPREADER MODULE - A heat spreader module has a pedestal, a heat spreader member joined to the pedestal by a first active hard brazing material, an intermediate layer joined to the heat spreader member by a second active hard brazing material, an insulating board joined to the intermediate layer by a third active hard brazing material, and a circuit board joined to the insulating board by a fourth active hard brazing material. The first through fourth active hard brazing materials are supplied such that the active hard brazing materials have a thickness ranging from 3 to 20 μm when the components of the heat spreader module are joined together under pressure, and contain an active element in an amount ranging from 400 to 1000 μg/cm | 11-06-2008 |
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 |
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 |
20100190066 | REACTOR AND PRODUCING METHOD OF THE SAME - The solid oxide fuel cell has a stack structure formed by stacking sheet bodies, each of which comprises three layers of the electrolyte layer, a fuel electrode layer, an air electrode layer, and separators in alternating layers. In an air channel defined between the air electrode and the separator facing the air electrode layer, a SUS mesh made of stainless steel for electrically connecting both of them is confined. On the surface of the SUS mesh, previously by itself before the assembly of the stack structure, an Ag-plating treatment is performed and further a vacuum heat-treatment (heat-treatment under a negative pressure) is performed. | 07-29-2010 |
20100190090 | STACK STRUCTURE OF SOLID OXIDE FUEL CELL APPARATUS - A stack structure includes plate-like electrochemical cells of ceramic, each having a pair of main surfaces and a side surface, and plate-like retainer pieces. The cell includes a first electrode in contact with first gas, a solid electrolyte, and a second electrode in contact with second gas. The first electrode has a gas flow channel formed therein and adapted to allow flow of the first gas. The cell has gas inflow and outflow ports. The retainer piece includes a body portion having a through-hole formed therein, and a pair of protrusions protruding from the body portion. The retainer piece has a communication hole formed therein and adapted to establish communication between the through-hole and a space formed between the protrusions. The cell is held by the paired protrusions, thereby establishing communication between the gas inflow or outflow port of the cell and the communication hole of the retainer piece. | 07-29-2010 |
20140004439 | JOINING MATERIAL AND STACK STRUCTURE OF FUEL CELL USING THE JOINING MATERIAL | 01-02-2014 |