Patent application number | Description | Published |
20080285417 | Optical Information Recording Medium and Method for Recording to the Same - An optical information recording medium with favorable recording/reproducing characteristics and corrosion resistance is offered. To this end, the optical information recording medium of the present invention comprises in this sequence at least substrate | 11-20-2008 |
20090286037 | INFORMATION RECORDING MEDIUM, TARGET AND METHOD FOR MANUFACTURING OF INFORMATION RECORDING MEDIUM USING THE SAME - An information recording medium of the present invention includes a recording layer whose phase changes by irradiation with a laser beam or application of current. The recording layer contains, as its main component, a composite composed of Ge and Sb that are essential components, and Te that is an optional component. The composite has a composition within a region enclosed by: point (a) (35, 65, 0), point (b) (36.9, 60, 3.1), point (c) (3.2, 60, 36.8), and point (d) (5, 95, 0) in terms of a coordinate (Ge, Sb, Te)=(x, y, z) on the triangular coordinate shown in FIG. | 11-19-2009 |
20090317581 | OPTICAL INFORMATION RECORDING MEDIUM - An optical information recording medium having the same recording volume as that of DVD-ROM is obtained which shows excellent characteristics at recording linear velocities within a range of twice linear velocity of DVD (about 8.2 m/s) to five times liner velocity of DVD (about 20.5 m/s) and excellent archival stability, by a construction including a transparent substrate, a recording layer which is formed on the substrate directly or with another layer interposed therebetween and can change in phase reversibly by a laser beam irradiation, wherein the composition of the recording layer is within a region bounded by composition points A(41.2, 7.4, 51.4), B(39.8, 10.5, 49.7), C(28.5, 21.7, 9.8), and D(30.6, 15.8, 53.6) in a triangular coordinate graph represented with a coordinate of (Ge, Sb—Bi, Te) and a Bi content in the recording layer is 4 atom % and more and less than 13 atom %. | 12-24-2009 |
20100046346 | OPTICAL INFORMATION RECORDING MEDIUM AND METHOD FOR MANUFACTURING THE SAME - An optical information recording medium of the present invention includes at least a recording layer ( | 02-25-2010 |
20100151179 | Optical Information Recording Medium, Method Of Manufacturing The Same, And Sputtering Target - An optical information recording medium ( | 06-17-2010 |
20100279053 | INFORMATION RECORDING MEDIUM AND METHOD FOR PRODUCING SAME, AND SPUTTERING TARGET - An information recording medium ( | 11-04-2010 |
20110058463 | OPTICAL INFORMATION RECORDING MEDIUM AND RECORDING/REPRODUCING METHOD THEREFOR - An optical information recording medium ( | 03-10-2011 |
20130071600 | INFORMATION RECORDING MEDIUM AND METHOD FOR MANUFACTURING THE SAME - An optical information recording medium including three or more information layers, wherein at least one information layer provided on the light incident side is an information layer which enables information to be overwritten and includes a recording film, a transmittance adjusting film of a dielectric containing Bi, Ti and O, and an isolation film in this order from a light incident side; and the isolation film is provided between and adjacent to the transmittance adjusting film and an intermediate separation layer which separate the information layer from another information layer on the side opposite to the light incident side; and the isolation film has an optical constant at a wavelength of 405 nm such that a refractive index is 1.8 or less and an extinction coefficient is 0.05 or less. This information recording medium prevents the repeated overwriting characteristics in a sever environment from being deteriorated. | 03-21-2013 |
20130071653 | INFORMATION RECORDING MEDIUM AND METHOD FOR PRODUCING SAME - An information recording medium including three or more information layers, wherein: at least one information layer includes a recording layer and a nucleation layer; the recording layer contains a material that is represented by formula (1) [(Ge | 03-21-2013 |
20150083181 | THERMOELECTRIC GENERATOR AND PRODUCTION METHOD FOR THERMOELECTRIC GENERATOR - An exemplary thermoelectric generator disclosed herein includes: a first electrode and a second electrode opposing each other; and a stacked body having a first end face and a second end face. The stacked body is structured so that first layers made of a first material and second layers made of a second material are alternately stacked, the first material containing a metal and particles having a lower thermal conductivity than that of the metal, the particles being dispersed in the metal, and the second material having a higher Seebeck coefficient and a lower thermal conductivity than those of the first material. Planes of stacking between the first layers and the second layers are inclined with respect to a direction in which the first electrode and the second electrode oppose each other. | 03-26-2015 |
20150188018 | THERMOELECTRIC GENERATOR SYSTEM - A thermoelectric generator system according to this disclosure includes a thermoelectric generator unit which performs thermoelectric generation using first and second heat transfer media at different temperatures. The unit includes a tubular thermoelectric generator which generates electromotive force in its axial direction based on a temperature difference between its inner and outer surfaces. The generator system further includes a flow rate control system which controls the flow rate of at least one of the first heat transfer medium flowing through a flow path defined by the inner surface and the second heat transfer medium in contact with the outer surface by reference to either information about an operation condition of the generator system or a preset target power output level. | 07-02-2015 |
20150194588 | THERMOELECTRIC GENERATOR UNIT AND THERMOELECTRIC GENERATOR SYSTEM - An exemplary thermoelectric generator unit according to the present disclosure includes a plurality of tubular thermoelectric generators. Each generator generates electromotive force in an axial direction based on a difference in temperature between its inner and outer peripheral surfaces. The unit further includes a container housing the generators inside and a plurality of electrically conductive members providing electrical interconnection among the generators. The container has fluid inlet and outlet ports through which a fluid flows inside the container, and a plurality of openings into which the respective generators are inserted. In one implementation, the unit includes a baffle, which is provided between the fluid inlet port and the generators and changes the flow direction of the fluid that has flowed into the container through the fluid inlet port. | 07-09-2015 |
20150207054 | THERMOELECTRIC GENERATOR UNIT AND METHOD OF TESTING THE THERMOELECTRIC GENERATOR UNIT - A thermoelectric generator unit according to this disclosure includes a plurality of tubular thermoelectric generators, each of which generates electromotive force based on a difference in temperature between the inner and outer peripheral surfaces. The unit further includes a plurality of electrically conductive members providing electrical connection for the generators and a container housing the generators inside. The container includes a shell surrounding the generators and a pair of plates, at least one of which has a plurality of openings and channels. Each channel houses an electrically conductive member. The generators are electrically connected together in series via the electrically conductive member. At least one of the channels has an interconnection which connects at least two of the openings together and a testing hole portion. The testing hole portion runs from the interconnection through an outer edge of the at least one plate. | 07-23-2015 |
20150214460 | THERMOELECTRIC GENERATOR SYSTEM - A thermoelectric generator system according to the present disclosure includes first and second thermoelectric generator units, each including tubular thermoelectric generators. Each of the generators has a flow path defined by its inner peripheral surface, and generates electromotive force in an axial direction thereof based on a temperature difference between its inner and outer peripheral surfaces. Each unit further includes: a container housing the generators inside; and electrically conductive members providing electrical interconnection for the generators. The container has fluid inlet and outlet ports through which a fluid flows inside, and openings into which the generators are inserted. A buffer vessel is arranged between the first and second units, and has a first opening communicating with the flow paths of the generators in the first unit and a second opening communicating with the flow paths of the generators in the second unit. | 07-30-2015 |
20150221849 | THERMAL POWER GENERATION UNIT AND THERMOELECTRIC POWER GENERATION SYSTEM - A thermoelectric power generation system of the present disclosure includes first and second thermoelectric power generation units. Each of the thermoelectric power generation units includes a plurality of tubular thermoelectric generators. The first and second thermoelectric power generation units are electrically connected to each other such that a first impedance caused by the tubular thermoelectric generator included in the first thermoelectric power generation unit is matched with a second impedance caused by the tubular thermoelectric generator included in the second thermoelectric power generation unit. | 08-06-2015 |
20150228882 | THERMAL POWER GENERATION UNIT AND THERMOELECTRIC POWER GENERATION SYSTEM - A thermoelectric power generation system of the present disclosure includes first and second thermoelectric power generation units. Each of the thermoelectric power generation units includes a plurality of tubular thermoelectric generators. The thermoelectric power generation units comprises a vessel in which the tubular thermoelectric generator is accommodated and a breakdown determination unit. The vessel includes a fluid inlet, a fluid outlet, and an opening. The fluid inlet and the fluid outlet are used to cause a fluid to flow in the vessel. The tubular thermoelectric generator is inserted in the opening. The breakdown determination unit that determines whether the thermal power generation unit breaks down based on power generation efficiency that is obtained using a temperature difference between the fluid inflowing from the fluid inlet and the fluid discharging from the fluid outlet and the electromotive force generated by the tubular thermoelectric generator. | 08-13-2015 |