子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | 放熱装置 | JP2014131632 | 2014-06-26 | JP2015010821A | 2015-01-19 | YANG TAI-HER |
| 【課題】埋込式支柱管体で構成されており内循環伝熱流体を有する放熱装置を提供する。【解決手段】本発明は支柱管体(101)の中に内管(103)を設け、大きさが異なる支柱管体(101)内径と内管(103)外径により流体流路の空間が構成され、支柱管体(101)の管体上段に電気エネルギ応用装置アセンブリ(108)が設置され、伝熱流体流路に直列に接続されている流体ポンプ(105)により、伝熱流体をポンピングし密閉循環流動を構成して、かつ上述の密閉循環へ流れる伝熱流体通路中の支柱管体(101)や関連構造の外部露出部を通して、外部気相、固相、液相環境と浅層地熱エネルギ体の土壌、及び液体との均熱化を図る。【選択図】図40 | ||||||
| 102 | 空気流制御装置 | JP2014105979 | 2014-05-22 | JP2014230487A | 2014-12-08 | GIOVANNI AIROLDI; ERIKSEN UFFE; SOEREN GUNDTOFT; CLAUS MICHAELSEN; MUNK-HANSEN THORKIL; PETER HESSELLUND SOERENSEN; CLAUS THYGESEN; XAVIER TOURDE |
| 【課題】直接駆動風車内の環境を制御し、従来技術の問題を回避するためのより経済的でかつ簡単な方法を提供する。【解決手段】ロータ11およびステータ12を含む発電機14を備え、空気流制御装置100は、出口ダクト4を通って出口空気流AF_outを引き込むように配置された流出ファン1を含み、前記出口ダクト4は、ステータ12の内部キャビティ120から風車10の外部へ延びている。【選択図】図1 | ||||||
| 103 | Power generation system | JP2012138977 | 2012-06-20 | JP5598501B2 | 2014-10-01 | 徹 岡崎; 敏広 林; 剛三 藤野; 剛 佐波; 孝治 久田 |
| There is provided an electric power generation system utilizing wind power, being excellent in maintainability, and capable of reducing in size and weight a nacelle provided at an upper portion of a tower. An electric power generation system (W) includes a wind turbine (10), a conductor (20) rotating as the wind turbine (10) rotates, a heat transfer medium vessel (30), a magnetic field generator (40), a heat accumulator (50), and an electric power generation unit (60). The wind turbine (10) is attached to a nacelle (102) provided at an upper portion of a tower (101), and the conductor (20), the heat transfer medium vessel (30) and the magnetic field generator (40) are housed in the nacelle (102). Furthermore, the heat accumulator (50) and the electric power generation unit (60) are provided in a building (103) built at a lower portion (or a base) of the tower (101). The magnetic field generator (40) is operated to generate a magnetic field and therein the conductor (20) is rotated and thus heated through induction, and the conductor's heat is transmitted to the water in the heat transfer medium vessel (30) to generate steam which is in turn supplied to a steam turbine (61) and thus drives an electric power generator (62) to generate electric power. | ||||||
| 104 | Wind power generation equipment | JP2011524914 | 2009-09-01 | JP5367822B2 | 2013-12-11 | テ キム,ヒョン; ポ パク,ジョン; ヒョン イ,ジン; イル キム,ジョン; ギュ イ,ビョン |
| Provided is a nacelle cooling system of a wind turbine. The disclosed nacelle cooling system of a wind turbine comprises cooling blocks which are arranged in order to respectively surround one or more heating devices installed inside a nacelle, a passage pipe line which is connected to the cooling blocks for coolant to flow, a primary heat exchanger which is connected to the passage pipe line and arranged on the outer lateral surface of the nacelle, and a secondary heat exchanger which is capable of absorbing heat generated inside the nacelle and discharging the heat. The nacelles of the primary and secondary heat exchangers are sealed from the outside. Therefore, when the nacelle of the wind turbine is operated in a coastal environment, the present invention can prevent performance of turbine facilities from lowering caused by erosion because the nacelle is completely sealed from external salt. | ||||||
| 105 | System for the conversion of wind energy | JP2013530118 | 2010-10-06 | JP2013542358A | 2013-11-21 | オイニ、アニス、エム. |
| 本発明は、風力エネルギー(SCEE)を機械的、次に電気的エネルギーへと変換するためのシステムから成る。 このシステム(SCEE)は理論的Betzリミット(59%)に従わない。 本システム(SCEE)は、その全周に配置された一連のブレイドを備えたホイール(F)を有する。 ホイール(F)は、固定軸(L)の周りを旋回接続において回転する。 軸(L)に設置されて、支持体(E)は一連の複動式発動シリンダー(D)のエンドプレートの固定を確実にする。 複動式発動シリンダー(D)のロッドは、スペース内で最大限の自由度を本体(A)に提供するため、本体(A)とボールジョイントで接続される。 剛性のあるアーム(C)は、一方側でホイール(F)に設置され、他方側ではU形の部分品(B)に旋回接続で保持される。 円形の衛星運動を有し、部分品(B)は本体(A)の周辺領域にわたって滑りながらホイール(F)と共に回転する。 風が本体(A)に作用するとき、本体(A)は部分品(B)と共に旋回し、発動シリンダー(D)のロッドを押す。 円形の衛星運動を有し、部分品(B)は本体(A)の周辺領域にわたって滑りながら回転し、従って本体(A)に加えられる風の合力のモーメントの軸(部分品(B)の旋回接続)を変化させる。 発動シリンダー(D)のロッドは、周期的な並進運動を行いながら、結果的に引かれ、そして押されるであろう。 軸(L)に設置されて、ナセル(J)は、増速歯車を介して連結され得る、油圧モーター(H)及び発電機(G)を主として含む。 発動シリンダー(D)のピストンの往復動の間、一組の弁は、発動シリンダー(D)のピストンを引くか、又は押すかのいずれかによって、「go and return」油圧回路内の作動液の一方向の流れを確実にする。 「go and return」油圧回路はさらに、油圧モーター(H)につながれる。 本システム(SCEE)が風に向かって保持され、支柱(I)上で旋回することを可能にするため、その方向は、支持体を介してナセル(J)に固定されている尾翼(K)によって確保され得る。 | ||||||
| 106 | Power generation system | JP2010041030 | 2010-02-25 | JP5024736B2 | 2012-09-12 | 孝治 久田; 剛 佐波; 徹 岡崎; 敏広 林; 剛三 藤野 |
| There is provided an electric power generation system utilizing wind power, being excellent in maintainability, and capable of reducing in size and weight a nacelle provided at an upper portion of a tower. An electric power generation system (W) includes a wind turbine (10), a conductor (20) rotating as the wind turbine (10) rotates, a heat transfer medium vessel (30), a magnetic field generator (40), a heat accumulator (50), and an electric power generation unit (60). The wind turbine (10) is attached to a nacelle (102) provided at an upper portion of a tower (101), and the conductor (20), the heat transfer medium vessel (30) and the magnetic field generator (40) are housed in the nacelle (102). Furthermore, the heat accumulator (50) and the electric power generation unit (60) are provided in a building (103) built at a lower portion (or a base) of the tower (101). The magnetic field generator (40) is operated to generate a magnetic field and therein the conductor (20) is rotated and thus heated through induction, and the conductor's heat is transmitted to the water in the heat transfer medium vessel (30) to generate steam which is in turn supplied to a steam turbine (61) and thus drives an electric power generator (62) to generate electric power. | ||||||
| 107 | Hard substance coated body mainly consisting of boron for wind power generation facility component | JP2011006396 | 2011-01-14 | JP2011144809A | 2011-07-28 | HOHLE ANDREAS CHRISTIAN; HOHMANN CHRISTIAN; KUMMER CLAUDIA; KOELPIN HELMUT; LI YING; TCHEMTCHOUA BRICE |
| <P>PROBLEM TO BE SOLVED: To provide advantageous wind power generation facilities, an advantageous wind park and an advantageous method for improving a characteristic of a surface of a wind power generation facility component. <P>SOLUTION: In wind power generation facilities 1 including at least one component 10 having a surface 12, the surface 12 is at least partly covered with a hard substance layer 13. <P>COPYRIGHT: (C)2011,JPO&INPIT | ||||||
| 108 | Electric power generation system | JP2010041030 | 2010-02-25 | JP2011102576A | 2011-05-26 | OKAZAKI TORU; HAYASHI TOSHIHIRO; FUJINO KOZO; SAWA TAKESHI; HISADA KOJI |
| <P>PROBLEM TO BE SOLVED: To provide an electric power generation system which utilizes wind power, has superior maintainability, and enables the nacelle installed at the top of a tower to be manufactured compact and lightweight. <P>SOLUTION: This electric power generation system W includes a wind turbine 10, an electric conductor 20 which is rotated when the wind turbine 10 is rotated, a heat medium tank 30, a magnetic field generator 40, a heat accumulator 50, and an electric power generation section 60. The wind turbine 10 is attached to the nacelle 102 installed at the top of the tower 101, and the electric conductor 20, the heat medium tank 30, and the magnetic field generator 40 are stored in the nacelle 102. The heat accumulator 50 and the electric power generation section 60 are disposed in a building 103 built on the lower part (base) of the tower 101. The heat of the electric conductor 20 induction-heated by rotating in a magnetic field generated by the magnetic field generator 40 is transmitted to the water in the heat medium tank 30 to generate steam, and the steam is supplied to a steam turbine 61 to drive an electric power generator 62 for electric power generation. <P>COPYRIGHT: (C)2011,JPO&INPIT | ||||||
| 109 | Drive assembly for a wind turbine | JP2002519799 | 2001-08-03 | JP4308516B2 | 2009-08-05 | デ・ヴィルデ,マルセル; フラマング,ピーター; ボゲルト,ロジャー |
| A drive assembly for a wind turbine includes a rotor hub, a supporting structure, a planetary gear transmission unit having sun, planet and ring gears and a planet carrier. The ring gear is non-rotatably secured to the supporting structure. A main bearing rotatably supports the rotor hub and planet carrier relative to the ring gear and supporting structure. The drive assembly further includes two substantially independent force transmission paths for transmission of forces reacting with forces exerted by the wind turbine rotor hub. A first of the force transmission paths acts from the rotor hub via the main bearing to the supporting structure primarily for transmission of overhang load forces and bending moment forces and a second of the force transmission paths acts from the rotor hub via the planet carrier primarily for transmission of rotational forces. | ||||||
| 110 | Wind speed acceleration type fluid intertia-utilizing wind power generation system | JP2001319971 | 2001-09-11 | JP2003083227A | 2003-03-19 | TOMOYASU YOSHIOKI |
| PROBLEM TO BE SOLVED: To grow up a wind power generation system to a large pillar of clean energy by releasing the wind power generation system bearing one end from geographical restriction on its mechanism and spreading it to a wide range since requirement of the clean energy with no environment pollution and a danger on an earth scale is required at present. SOLUTION: The wind power generation system is made to a structure that a rotor 1 is covered with a case 2 and a cross section of an entrance is opened to a rear space without being closed by making a cross section circular such that the cross section of the entrance does not inhibit a passage of air flow and is not downwardly recessed. Thereby, a wind speed is accelerated and a rotation force of the rotor 1 is increased to enhance an efficiency of power generation based on the fact that the product of a flowing width of fluid and a flow speed is constant, i.e., a basic principle of a fluid motion of Bernoulli. Much more amount of natural energy is taken in a power generation by enlarging a contact area of natural wind to obtain a high power generation efficiency. | ||||||
| 111 | Self-control-type fluid energy turbine | JP51934996 | 1995-06-08 | JP3226279B2 | 2001-11-05 | エディソン アイラー,エルモ |
| 112 | JPS58501780A - | JP50281782 | 1982-09-17 | JPS58501780A | 1983-10-20 | |
| The invention relates to a wind-driven generating plant for utilizing the energy contained in land and sea winds with at least one blade rotatable about a rotation axis, which is arranged in oblique-angled manner to the horizontal and is optionally connected to a pylon arranged so as to rotate coaxially to the rotation axis of the blade or blades, whereby the hub thereof used for receiving the blade base with associated energy transmission means is connected to a supporting member. Each rotor blade is at an angle beta of approximately 40 DEG to 80 DEG to the rotation axis of the rotor, which is oriented at an angle alpha of approximately 30 DEG to 70 DEG to the horizontal. The supporting member is arranged on a frame so as to rotate about a vertical axis or at an axis arranged in oblique-angled manner to the vertical. | ||||||
| 113 | JPS57500204A - | JP50111681 | 1981-02-26 | JPS57500204A | 1982-02-04 | |
| 114 | Wind turbine | JP7636181 | 1981-05-19 | JPS5716268A | 1982-01-27 | GURITSUDEN SUIITO DOOMAN |
| 115 | JPS5526307B2 - | JP1407276 | 1976-02-13 | JPS5526307B2 | 1980-07-12 | |
| A wind-driven power plant comprising at least one rotor having a gyration axis, a base, a carrier construction pivotable on said base about an upstanding axis, a support structure pivotable on said carrier construction about a tilt axis in a manner permitting precession of said rotor, said rotor being rotatably supported by said support structure and rotatable about said gyration axis, an adjusting device for pivoting said carrier construction on said base in response to changes in horizontal wind direction, a setting device for exerting torque directly or indirectly on the rotor gyration axis or on the rotor which has a torque vector component extending perpendicularly to the rotor gyration axis and perpendicularly to the upstanding axis, said tilt axis intersecting both the rotor gyration axis and the upstanding axis and forming an angle with both, and a control device for controlling the magnitude of movement of said adjusting and setting devices in response to the rotor rotational speed and the desired wind direction orientation to be exerted on the rotor in accordance with the torque to be exerted by the upstanding axis adjusting device and in compliance with the laws of gyroscopic precession. | ||||||
| 116 | Ryutaiokanetsusurutamenikazeno enerugiioryosurusetsubi | JP12334375 | 1975-10-15 | JPS5166541A | 1976-06-09 | MITSUSHERU DOYUUKU |
| 117 | 一种立体式太阳能与风能吸收及转换装置 | CN200920206260.9 | 2009-10-29 | CN201523246U | 2010-07-07 | 胡锦 |
| 本实用新型涉及一种立体式太阳能与风能吸收及转换装置,其特征在于,包括立式安装基座、安装在所述基座不同位置的太阳能及风能转换装置、与所述太阳能转换装置及风能转换装置电连接的蓄电池以及与所述蓄电池电连接的照明装置。实施本实用新型的立体式太阳能与风能吸收及转换装置,具有以下有益效果:由于将太阳能转换装置与风能转换装置安装在同一个基座上,所以其占地面积较小,较能适合多种场合的使用。 | ||||||
| 118 | 风力发电机及其组件 | CN200820119834.4 | 2008-05-30 | CN201228864Y | 2009-04-29 | 潘和煊 |
| 本实用新型提供为比较小的电器供电的风力电动组件。此风力电动组件包括电器和发电机。发电机可与电器在电气上相连接。发电机运转时为电器提供电流使之运行。发电机具有转子。此机组还包括风力致动器组件(它受到工作风力时旋转)和安装在发电机上使发电机运转的齿轮系。所述齿轮系可包括多个齿轮,其中第一齿轮可安置弹簧组件。驱动机构的第二齿轮可安置风力致动器组件,第三齿轮可安装在发电机的转子上。 | ||||||
| 119 | TUNED MASS DAMPERS FOR DAMPING AN OSCILLATING MOVEMENT OF A STRUCTURE | US16003509 | 2018-06-08 | US20180355936A1 | 2018-12-13 | Roger BERGUA |
| A tuned mass damper for damping an oscillating movement of a structure along a first direction is provided. The tuned mass damper comprises a mass arranged to perform a reciprocating movement along the first direction in response to the oscillating movement of the structure, wherein the mass comprises a braking mechanism configured to at least partially brake the movement of the mass along the first direction when the mass exceeds a predefined speed. | ||||||
| 120 | CONNECTOR | US15770168 | 2016-10-19 | US20180306222A1 | 2018-10-25 | Jonathan Scott PRESTON; William David Loton PARRY; Daniel O'CONNOR |
| An elongate connector for subsea connection of cables and the like to wind turbine generators has a plurality of locking elements arranged on ramp surfaces and held in a plurality of cages on the connector. The cages are moveable to move the locking elements along the ramp surfaces between an engaged position and a disengaged position and the plurality of cages are moveable independently of each other. A release collar is provided, which can move all the cages simultaneously to the disengaged position, in order to allow removal of the connector. | ||||||
QQ群二维码
意见反馈
意见反馈