Patent application number | Description | Published |
20110017253 | Thermionic converter - A thermionic converter includes an emitter electrode and a collector electrode. The emitter electrode includes a P-type diamond semiconductor layer doped with a P-type impurity. The emitter electrode is configured to emit a thermion from the P-type diamond semiconductor layer when heat is applied from an external power source. The collector electrode includes an N-type diamond semiconductor layer doped with an N-type impurity. The N-type diamond semiconductor layer opposes the P-type diamond semiconductor layer and is located at a predetermined distance from the P-type diamond semiconductor layer. The collector electrode is configured to receive the thermion emitted from the emitter electrode at the N-type diamond semiconductor layer. | 01-27-2011 |
20110139205 | THERMIONIC CONVERTER - A thermionic converter for converting thermal energy to electrical energy includes an emitter and a collector. The emitter emits thermionic electrons upon receipt of heat from a heat source. The emitter is made of a first semiconductor material to which a first semiconductor impurity is doped with a first concentration. The collector is spaced and opposite to the emitter to receive the thermionic electrons emitted from the emitter so that the thermal energy is converted to electrical energy. The collector is made of a second semiconductor material to which a second semiconductor impurity is doped with a second concentration less than the first concentration. | 06-16-2011 |
20110192446 | SOLAR CELL MODULE AND SOLAR PANEL - A solar cell module includes a solar cell and a wavelength conversion optical plate. The solar cell is attached on the optical plate in a thickness direction of the optical plate. The optical plate converts wavelength of solar light. An end portion of the optical plate in a planar direction thereof has an end face inclined relative to the planar direction, so that light, whose wavelength is converted in the optical plate, enters into the solar cell. A solar panel includes a frame and the solar cell modules. The solar cell modules are arranged in the frame in a planar direction of the frame. The frame includes a fixing part, to which an end portion of each of the solar cell modules in a planar direction thereof is fixed in a state where each of the solar cell modules is arranged at a corresponding predetermined fixing position of the frame. | 08-11-2011 |
20120299438 | THERMIONIC GENERATOR - A thermionic generator for converting thermal energy to electric energy includes: an emitter electrode for emitting thermal electrons from a thermal electron emitting surface when heat is applied to the emitter electrode; a collector electrode facing the emitter electrode spaced apart from the emitter electrode by a predetermined distance, and receiving the thermal electrons from the emitter electrode via a facing surface of the collector electrode; and a substrate having one surface. The emitter electrode and the collector electrode are disposed on the one surface of the substrate, and are electrically insulated from each other. The thermal electron emitting surface and the facing surface are perpendicular to the one surface. | 11-29-2012 |
20140158179 | THERMIONIC CONVERTER AND MANUFACTURING METHOD OF ELECTRODE OF THERMIONIC CONVERTER - In a method of manufacturing an electrode of a thermionic converter, a carbide layer is formed on a base material by a vapor synthesis, an N-type diamond layer doped with a donor impurity is formed on the carbide layer by a vapor synthesis, and a surface of the N-type diamond layer is terminated with hydrogen. The base material is made of a metal, and the carbide layer is made of a metal carbide. | 06-12-2014 |
20150075579 | THERMIONIC POWER GENERATOR - A thermionic power generator includes an emitter generating thermions and a collector collecting the thermions. The emitter includes an emitter substrate having an electric conductivity, a low resistance layer stacked to the emitter substrate and made of an n-type diamond semiconductor that includes phosphorus as a donor, and an electron emission layer stacked to the low resistance layer and made of an n-type diamond semiconductor that includes nitrogen as a donor. The collector includes a collector substrate having an electric conductivity and is disposed opposite to the emitter via a clearance. The electron emission layer has a thickness equal to or less than 40 nm. | 03-19-2015 |
Patent application number | Description | Published |
20100089629 | ELECTRONIC COMPONENT DEVICE AND METHOD FOR PRODUCING THE SAME - In a method for producing an electronic component device, a heat bonding step is performed in a state in which low melting point metal layers including low melting point metals including, for example, Sn as the main component, are arranged to sandwich, in the thickness direction, a high melting point metal layer including a high melting point metal including, for example, Cu as the main component, which is the same or substantially the same as high melting point metals defining first and second conductor films to be bonded. In order to generate an intermetallic compound of the high melting point metal and the low melting point metal, the distance in which the high melting point metal is to be diffused in each of the low melting point metal layers is reduced. Thus, the time required for the diffusion is reduced, and the time required for the bonding is reduced. | 04-15-2010 |
20100132185 | METHOD FOR MANUFACTURING ELECTRONIC COMPONENT - A triaxial acceleration sensor which has a structure including a cover joined to a substrate including a mechanically operable functional unit to be sealed, is adapted in such a way that the joined state can be reliably obtained so as to not interfere with a displacement of the functional unit. A sealing frame is made of a heated polyimide on a periphery of an upper main surface of a substrate provided with a functional unit, and a sealing layer made of a polyimide is formed over an entire lower main surface of a cover. For integrating the substrate and the cover so as to seal the functional unit, the sealing frame and the sealing layer are joined to each other by heating and pressurizing the sealing frame and the sealing layer at a temperature that is about 50° C. to about 150° C. higher than a glass transition temperature of the polyimide while bringing the sealing frame and the sealing layer into contact with each other. In this case, a recess is formed in the vicinity of a portion of the sealing layer to be brought into contact with the sealing frame so that a bump, generated from the sealing layer which is deformed in the joining step, is prevented from protruding toward the functional unit. | 06-03-2010 |
20110265929 | METHOD FOR MANUFACTURING ELECTRONIC COMPONENT - A triaxial acceleration sensor which has a structure including a cover joined to a substrate including a mechanically operable functional unit to be sealed, is adapted in such a way that the joined state can be reliably obtained so as to not interfere with a displacement of the functional unit. A sealing frame is made of a heated polyimide on a periphery of an upper main surface of a substrate provided with a functional unit, and a sealing layer made of a polyimide is formed over an entire lower main surface of a cover. For integrating the substrate and the cover so as to seal the functional unit, the sealing frame and the sealing layer are joined to each other by heating and pressurizing the sealing frame and the sealing layer at a temperature that is about 50° C. to about 150° C. higher than a glass transition temperature of the polyimide while bringing the sealing frame and the sealing layer into contact with each other. In this case, a recess is formed in the vicinity of a portion of the sealing layer to be brought into contact with the sealing frame so that a bump, generated from the sealing layer which is deformed in the joining step, is prevented from protruding toward the functional unit. | 11-03-2011 |
20110268977 | ELECTRONIC COMPONENT DEVICE AND METHOD FOR PRODUCING THE SAME - In a method for producing an electronic component device, a heat bonding step is performed in a state in which low melting point metal layers including low melting point metals including, for example, Sn as the main component, are arranged to sandwich, in the thickness direction, a high melting point metal layer including a high melting point metal including, for example, Cu as the main component, which is the same or substantially the same as high melting point metals defining first and second conductor films to be bonded. In order to generate an intermetallic compound of the high melting point metal and the low melting point metal, the distance in which the high melting point metal is to be diffused in each of the low melting point metal layers is reduced. Thus, the time required for the diffusion is reduced, and the time required for the bonding is reduced. | 11-03-2011 |
Patent application number | Description | Published |
20110132655 | Electronic Component Device and Method for Manufacturing the Same - An electronic component device having a first sealing frame formed on a main substrate and a second sealing frame formed on a cover substrate, both of which are composed of a Ni film. A bonding section bonds the first sealing frame to the second sealing frame. For example, a Bi layer is formed on the first sealing frame and an Au layer is formed on the second sealing frame, and then the first sealing frame and the second sealing frame are heated at a temperature of 300° C. for 10 seconds while applying pressure in the direction in which the first sealing frame and the second sealing frame are close contact with each other to form the bonding section. The bonding section is constituted by a mixed layer predominantly composed of a mixed alloy of a Ni—Bi—Au ternary alloy and Au | 06-09-2011 |
20110132656 | Electronic Component Device and Method for Manufacturing the Same - An electronic component device having a first sealing frame formed on a main substrate and a second sealing frame formed on a cover substrate, the first and second sealing frames being composed of a Ni film. A bonding section constituted by a Ni—Bi alloy is formed between the first and second sealing frames. For example, a Bi layer is formed on the first sealing frame, and then the first sealing frame and the second sealing frame are heated at a temperature of 300° C. for at least 10 seconds while applying pressure in the direction in which the first sealing frame and the second sealing frame are in close contact with each other, and thus the bonding section, which bonds the first sealing frame to the second sealing frame, is formed. | 06-09-2011 |
20140033525 | METHOD FOR MANUFACTURING ELECTRONIC COMPONENT DEVICE WITH A NI-BI ALLOY SEALING FRAME - An electronic component device having a first sealing frame formed on a main substrate and a second sealing frame formed on a cover substrate, the first and second sealing frames being composed of a Ni film. A bonding section constituted by a Ni—Bi alloy is formed between the first and second sealing frames. For example, a Bi layer is formed on the first sealing frame, and then the first sealing frame and the second sealing frame are heated at a temperature of 300° C. for at least 10 seconds while applying pressure in the direction in which the first sealing frame and the second sealing frame are in close contact with each other, and thus the bonding section, which bonds the first sealing frame to the second sealing frame, is formed. | 02-06-2014 |