Kentaro Kobayashi
Kentaro Kobayashi, Nishinomiya-Shi JP
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20090001200 | Electrostatically Atomizing Device - The present invention provides an electrostatically atomizing device capable of instantly giving an electrostatically atomizing effect without requiring a water tank. The electrostatically atomizing device includes an emitter electrode, an opposed electrode opposed to the emitter electrode, a water feeder configured to give water on the emitter electrode, and a high voltage source configured to apply a high voltage across said emitter electrode and said opposed electrode to electrostatically charge the water on the emitter electrode for spraying charged minute water particles from a discharge end of the emitter electrode. The water feeder is configured to condense the water on the emitter electrode from within the surrounding air, enabling to supply the water on the emitter electrode in a short time without relying upon an additional water tank. Thus, an atomization of the charged minute water particles can be obtained immediately upon use of the device. | 01-01-2009 |
20100277004 | PLANAR COIL AND CONTACTLESS ELECTRIC POWER TRANSMISSION DEVICE USING THE SAME - This invention has an object to a planar coil, a contactless electric power transmission device using the same. This planar coil is configured to suppress an eddy current developed between adjacent turns of wire for minimizing adverse effects on ambient electrical appliances resulting from heat generation. The planar coil | 11-04-2010 |
Kentaro Kobayashi, Hyogo-Ken JP
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20120160940 | ELECTROSTATIC ATOMIZATION DEVICE - An electrostatic atomization device that prevents the cooling capability from being lowered due to contact of an atomization electrode with another ember, while effectively preventing surplus production of condensed water that would destabilize discharging at the distal end of the atomization electrode. the electrostatic atomization device includes an atomization electrode having a cylindrical electrode body and a base which is informed at a basal end of the electrode body and has a larger diameter than the electrode from the base to produce condensed water on the atomization electrode. Voltage is applied to the atomization electrode when the condensed water is produced to generate charged fine water droplets. A partition plate includes an insertion hole that receives the electrode body of the atomization electrode. The partition plate and the base of the atomization electrode form a water collection region in between. | 06-28-2012 |
20120175439 | ELECTROSTATIC ATOMIZATION DEVICE - An electrostatic atomization device having a simple structure and allowing for reduction in size. The electrostatic atomization device has an atomization electrode including a P type Peltier element and an N type Peltier element joined with the P type Peltier element. The atomization electrode is cuspate so as to form a projection with a joined portion of the P type Peltier element and the N type Peltier element. High voltage is applied to the P and N type Peltier elements so that discharging occurs at a distal portion of the atomization electrode, current flows to the P and N type Peltier elements to produce a cooling effect at the joined portion, and condensed water generated by the cooling effect is atomized by the discharging to generate charged fine water droplets. | 07-12-2012 |
Kentaro Kobayashi, Tokyo JP
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20140044391 | OPTICAL INTERCONNECTION DEVICE AND METHOD OF MANUFACTURING THE SAME - An optical interconnection device includes a light-emitting element, a light-receiving element, and an optical waveguide. Both the light-emitting element and the light-receiving element have a layered structure and are formed on a silicon substrate. At least a portion of the light-emitting element is embedded in an insulator. At least a portion of the light-receiving element is embedded in the insulator. The optical waveguide is formed over the insulator, and is optically coupled to the light-emitting element and the light-receiving element by distributed coupling. | 02-13-2014 |
20140252505 | SEMICONDUCTOR ANALYSIS MICROCHIP AND METHOD OF MANUFACTURING THE SAME - According to one embodiment, a semiconductor analysis microchip configured to detect a fine particle in a sample liquid, including a semiconductor substrate, a first flow channel provided in the semiconductor substrate, to which the sample liquid is introduced, and a pore provided in the first flow channel and configured to pass the fine particle in the sample liquid. | 09-11-2014 |
20140255911 | SAMPLE DETECTION APPARATUS AND DETECTION METHOD - According to one embodiment, a sample detection apparatus including an insulating partition to divide a first and a second region, a pore formed in the partition, a first electrode arranged in the first region, a second electrode arranged in the second region, a power source configured to apply electrical current between the first and second electrode in a state in which a reagent containing a capture substance to be bound to a target and a tag particle bound to the capture substance is introduced into the first region together with a sample, and an electrolyte solution is introduced into the second region, a measurement unit configured to observe a change in a conductive state, and a detection unit to detect presence/absence of the target in the sample based on an observation result. | 09-11-2014 |
20140256028 | SEMICONDUCTOR MICRO-ANALYSIS CHIP AND MANUFACTURING METHOD THEREOF - According to one embodiment, a semiconductor micro-analysis chip for detecting fine particles in sample liquid includes a semiconductor substrate, a first flow channel that is formed in the semiconductor substrate and into which the sample liquid is introduced, and a plurality of columnar structures fully arranged in the first flow channel at regulation distance. | 09-11-2014 |
20140256031 | SEMICONDUCTOR MICRO-ANALYSIS CHIP AND SAMPLE LIQUID FLOWING METHOD - According to one embodiment, a semiconductor micro-analysis chip for detecting fine particles in sample liquid includes a semiconductor substrate, a flow channel formed in the semiconductor substrate and having a sample liquid inlet and sample liquid outlet at end portions thereof, and an absorber provided on at least part of the sample outlet of the flow channel to absorb the sample liquid. | 09-11-2014 |
20150041316 | SEMICONDUCTOR MICRO-ANALYSIS CHIP AND METHOD OF MANUFACTURING THE SAME - One of embodiments is a semiconductor micro-analysis chip for detecting particles in a sample liquid. The chip comprises a semiconductor substrate, a first flow channel provided on the semiconductor substrate to allow the sample liquid to flow therein, a second flow channel provided at a different position from the first flow channel of the semiconductor substrate to allow the sample liquid or an electrolyte solution to flow therein, a contact portion where a portion of the first flow channel and a portion of the second flow channel abut each other or intersect one another with a partition being arranged between the flow channels, and a fine hole provided on the partition of the contact portion to allow the particles to pass therethrough. | 02-12-2015 |
Kentaro Kobayashi, Tokyo-To JP
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20140305841 | METHOD FOR OPTIMIZING CATALYST/OIL MIXING IN AN FCC REACTOR FEED ZONE - A method of improving the uniformity of the contacting of a heavy oil feed with FCC cracking catalyst in the feed zone of an FCC cracking riser in which the heavy oil feed is injected into the catalyst in the riser by means of feed injectors located around the riser, the method comprising minimizing the differences in the temperature profile in the oil/catalyst mixture across the feed zone by varying the oil feed rate to the injectors. | 10-16-2014 |
Kentaro Kobayashi, Otsu-Shi JP
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20150210579 | FRESH WATER GENERATION METHOD - A fresh water generation method using a fresh water-generating device. The fresh water generation method includes a first treatment process for treating sewage and wastewater using a biological treatment unit and a first solid-liquid separation unit; a second treatment process for treating sewage and wastewater with a second solid-liquid separation unit; and a first detection process for detecting the treatment capacity level of the biological treatment unit; and which adjusts the volume of sewage and wastewater treated with the second treatment process on the basis of the results of the first detection process. | 07-30-2015 |
Kentaro Kobayashi, Otsu-Shi, Shiga JP
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20150321934 | WATER PRODUCTION METHOD - Provided is a process for producing water including generating a water to be filtrated wherein a water to be treated is treated to generate a water to be filtrated; filtration wherein the water to be filtrated is filtrated through a separation membrane module having a separation membrane to generate a filtrated water; back washing wherein the substance to be removed by filtration which has blocked the separation membrane in the step of filtration is washed away by using a cleaning water; and drainage wherein cleaning drainage generated in the step of back washing is drained; wherein the step of generating the water to be filtrated has a coagulation substep of adding a first pH adjuster and a cationic coagulant to coagulate the substance to be removed by filtration in the water to be treated to thereby generate the pretreated water; the water to be filtrated used in the step of filtration satisfies the following expression (i); and the step of back washing has at least first back washing substep wherein the separation membrane is back-washed by the cleaning water satisfying the following expressions (ii) and (iii): | 11-12-2015 |