| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | Battery circuit control system | JP2008295039 | 2008-11-19 | JP2010124575A | 2010-06-03 | MIYAUCHI TSUTOMU; ISHIDA SEIJI; TOYODA EIICHI; SHIMADA MOTOMI |
| PROBLEM TO BE SOLVED: To eliminate the temperature difference in respective power storage devices, as much as possible, and to reduce a difference of deterioration, by deciding charging/discharging current to the respective power storage devices so that dispersion of a power storage device temperature is reduced, as much as possible, in a range where charging/discharging power of power storage device as a whole is protected, as much as possible, since a difference is easily produced in the temperatures of the respective power storage devices and a difference is easily produced in deterioration, when new and old power storage devices coexist, or a case when there is dispersion even in new products. SOLUTION: A power supply circuit control system includes the power storage device, to which one or above power storage elements are connected and a power conversion device converting input/output power of the power storage device. A plurality of the power storage devices and the power conversion devices are connected in parallel. The system is also provided with a power storage device monitoring device for monitoring the temperature of the power storage device and a controller receiving temperature information of the power storage device from the power storage device monitoring device and outputting a charging/discharging current command to the power conversion device. COPYRIGHT: (C)2010,JPO&INPIT | ||||||
| 182 | Power supply and electronic equipment | JP2004176695 | 2004-06-15 | JP4367251B2 | 2009-11-18 | 和利 野本 |
| 183 | Renewable energy system | JP2007532895 | 2005-09-22 | JP2008515367A | 2008-05-08 | アロイス・ヴォベン |
| 本発明は第1および第2のエネルギー発生装置を備えた再生エネルギーシステムに関し、その目的は孤立した電力ネットワークの環境持続性を改善することである。 第1の装置のエネルギー生成は天候や太陽の位置に依存するが、第1の装置は電気エネルギー(これは複数の利用者とつながったネットワークに供給される)を発生できる発電機を具備し、第2の装置は発電機およびそれに接続されたエンジンを具備し、第2の装置は燃料タンクを備え、燃料は必要に応じてエンジンに供給できる。 再生可能原料から燃料を生産するユニットが設けられ、特に第1の装置がネットワークにつながった利用者が使用できるよりも多い電力を発生できる場合および/またはネットワークから第1の装置に対するエネルギー要求があった場合、燃料生産ユニットは第1の装置からその運転のためにエネルギーを取り出すが、これは第2の装置へのエネルギー導入を可能とする。 | ||||||
| 184 | Vehicle AC generator | JP2000050033 | 2000-02-25 | JP3563659B2 | 2004-09-08 | 進 佐々木; 英治 内藤; 慎司 山崎; 誠 平間; 義明 本田; 謙一郎 松原; 田島 進; 栄 石田 |
| 185 | Energy storage element | JP53670496 | 1996-05-31 | JPH11506259A | 1999-06-02 | スーアード,デイ・クリント; チエン,チピング; テムキン,リチヤード・ジエイ |
| (57)【要約】 電子が真空内のスパイラル通路に沿って循環するように配置されている。 該通路はトロイド(環状体)面により形成される中空の対称な形状を有している。 該形状は磁場により制御可能であり、該形状内に該電子を閉じ込めることが出来る。 閉じ込める力は外部電磁場、該真空内のイオン、又は該軌道を回る電子自体の間の相互作用により創生される。 閉じ込められた電子は後で引き出すためのエネルギーを貯蔵する。 | ||||||
| 186 | Parallel connection power stabilization system | JP17430792 | 1992-07-01 | JP2796471B2 | 1998-09-10 | SAN EICHI KIMU; HOORU EFU KETSUPU; KARERU SHII DEUINKERU |
| 187 | Hollow plate-like conductor laminated superconducting magnet | JP3968995 | 1995-02-28 | JPH08236341A | 1996-09-13 | MAKI NAOKI; HARA NOBUHIRO; KADOKAWA SHIGERU; SHIBATA MASAYUKI; HINO TOKUAKI; HATTORI KENICHI |
| PURPOSE: To prevent quenching from occurring in a conductor-type superconducting magnet by a method wherein a large number of hollow plate- like superconductors are piled up into a multi short-circuit superconductor group. CONSTITUTION: A large number of hollow plate-like superconductors 1 are piled up into a multi short-circuit superconductor group 2. The multi short-circuit superconductor group 2 is composed of a large number of short-circuit superconductor plates 1 each of thickness 1mm or so. When a current is applied to an exciting coil 3 from an outer power supply 4, a current is inductively introduced into the multi short-circuit superconductor group 2, the multi short-circuit superconductor group 2 serves as a superconducting magnet when it is made to operate in a permanent current mode. Even if quenching occurs in a part of the superconductor group 2, the other residual superconductors carry an operating current provisionally, so that quenching is prevented from occurring in the superconductor group 2 as a superconducting magnet. | ||||||
| 188 | JPH07501198A - | JP50900792 | 1992-11-20 | JPH07501198A | 1995-02-02 | |
| 189 | Parallel connection power stabilizer | JP17430792 | 1992-07-01 | JPH05211732A | 1993-08-20 | SAN EICHI KIMU; POORU EFU KETSUPU; KARERU SHII DEUINKERU |
| PURPOSE: To prevent instantaneous power interruption by connecting a superconducting power stabilizer in parallel with a circuit breaker and a disconector interposed between a power system and a load and supplying power stored in a superconducting induction energy storage unit to the load in case of voltage drop or power interruption. CONSTITUTION: Power is fed from a power supply 24 through a switch 54, disconnectors 70, 72 and a circuit breaker 60 to a load 58. A superconducting power backup/recovery unit 20 is connected in parallel between the power supply 24 and the load 58 through a phase shift transformer and an effective power generator/reactive power compensator 44. The unit 20 converts 22 AC power from the power supply 24 into DC power which is stored in a retrigerated 30 superconducting magnet 28. A voltage regulator 34 controls power storage in the superconductinq magnet 28 and power supply to an energy storage cell 36. A controller 38 detects power supply voltage drop or power interruption and opens an interruption switch 60 to supply power from the energy storage cell 36 to the load 58 and/or the power supply 24 through the effective power generator/reactive power compensator 44 and a phase shift transformer 50 thus preventing instantaneous power interruption. COPYRIGHT: (C)1993,JPO | ||||||
| 190 | JPH0482115B2 - | JP10117087 | 1987-04-25 | JPH0482115B2 | 1992-12-25 | BERUTORUTO GURYUTSUMATSUHAA; PEETAA TEOBARUTO BURAAZAAA; MIHYAERU KURYUUGAA |
| 191 | JPH0481946B2 - | JP10018087 | 1987-04-24 | JPH0481946B2 | 1992-12-25 | BERUTORUTO GURYUTSUMATSUHAA; PEETAA TEOBARUTO BURAAZAAA; MIHYAERU KURYUUGAA |
| 192 | JPH023380B2 - | JP8727881 | 1981-06-03 | JPH023380B2 | 1990-01-23 | TONO SHIGENORI |
| 193 | Multispoke energy storage | JP18868987 | 1987-07-28 | JPS63114538A | 1988-05-19 | JIYOOJI TEII PINSON |
| 194 | Printer, particularly, sheet offset printer | JP10116987 | 1987-04-25 | JPS62259852A | 1987-11-12 | BERUTORUTO GURIYUTSUMATSUHAA; PEETAA TEOBARUTO BURAAZAAA; MIHIYAERU KURIYUUGAA |
| 195 | Printer, particularly, sheet offset printer | JP10018087 | 1987-04-24 | JPS62259851A | 1987-11-12 | BERUTORUTO GURIYUTSUMATSUHAA; PEETAA TEOBARUTO BURAAZAAA; MIHIYAERU KURIYUUGAA |
| 196 | Superconductive coil/energy storage circuit | JP10143685 | 1985-05-15 | JPS61262038A | 1986-11-20 | TONO SHIGENORI |
| 197 | Flywheel power source | JP5178684 | 1984-03-16 | JPS60197197A | 1985-10-05 | NISHIHIRO AKINORI; TEZUKA KAZUO; TANAKA KAZUHIKO; MIYAZAKI MASAYUKI |
| PURPOSE:To always obtain stable power source by producing the power source of a power source circuit from the output of a converter of a main circuit. CONSTITUTION:An output side of a power source 8 is normally output through a switch 20 to the primary winding 21a of a transformer 21, and the secondary winding 21b is supplied through a converter 4 of a main circuit S, a DC/DC converter 22, a DC filter 23, an inverter 5, and a switch circuit 67 to a load 9. A flywheel unit R is driven by a drive circuit 25 at this time. If a power interruption or a voltage drop occurs to cause a malfunction, the output of the flywheel unit R is supplied through the converter 2 and the switch 3 to the converter 22. A power source circuit 27 for supplying a constant voltage to the controller 26 supplies the output of the converter 4 or the output voltage of the converter 2 as a power input. | ||||||
| 198 | Flywheel type energy storage device | JP578884 | 1984-01-18 | JPS60152238A | 1985-08-10 | KAWAMURA TOSHIZOU |
| 199 | Energy Storage and Conversion Systems | US15607746 | 2017-05-30 | US20180351181A1 | 2018-12-06 | John Read; Daniel Sweeney |
| Energy storage and conversion systems are, formed when tightly integrated components including thermochemical storage subsystem with a concentration cell to provide very high capacity and high energy density systems. Systems taught here include the unique combination of a thermochemical energy storage module in close thermal communication with a direct energy converter in the form of a concentration cell. A closed-loop thermochemical module receives heat input at a receiving port to drive a reversible chemical reaction. The end-to-end system achieves an ‘on-demand’ functionality because the reagents of said chemical reaction may be safely stored for long periods of time without detrimental effect. When these reagents are again reunited, they produce heat that may be transmitted to the direct energy converter arranged to convert so received heat directly into an electric output suitable for doing work on an external system. Heat from the storage system drives a working fluid of the concentration cell type direct converter to ionize it. Electrons separated from atoms or molecules of the gas at a very special membrane arranged to efficiently facilitate ion migration form an electrical current that is operable for doing work when applied to an external load. Upon recombination with the ions the working fluid is restored to its original state and becomes available for another cycle. Thus, the direct energy converter or concentration cell is also a closed-loop system. | ||||||
| 200 | Ridgeline cable drive electric energy storage system | US15443816 | 2017-02-27 | US10069333B2 | 2018-09-04 | William R. Peitzke; Matthew B. Brown |
| A highly efficient, utility scale energy storage system employs large masses transported uphill to store energy and downhill to release energy. An electric powered cable winch or chain drive shuttles the masses between two storage yards of different elevations separated by a steep incline on rail vehicles supported by track and operated by an automated control system. | ||||||
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