| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 具有提升装置的风轮发电机 | CN201110455430.9 | 2011-12-30 | CN102628420B | 2015-04-15 | H·莫特森; V·克里斯南 |
| 为了提供一种更有效且简单的具有提升装置的风轮发电机以及为了维护目的而使用提升装置的方法,公开了这样一种风轮发电机,其包括:塔架(108);由塔架支撑的机舱(104),该机舱包括支撑机舱的部件的基座(202);包括使机舱能够相对于塔架旋转的偏航轴承(206)的偏航系统(204);位于风轮发电机内并且能够移动物品的提升装置(214);支撑提升装置的支撑件(216;217;219;304;1102;1104),其中,提升装置能够在水平方向(118、120)从第一位置(806)移动至第二位置(808),并且这些位置中的至少一个位置在竖向上位于基座(202)的最低水平面(405)与塔架的最高水平面(403)之间。 | ||||||
| 2 | 接近风力涡轮机塔的外表面的方法以及使用这种方法的装置 | CN201280014332.4 | 2012-03-02 | CN103477005A | 2013-12-25 | 米格尔·安琪儿·费尔南怂斯·哥迈斯; 贾斯·埃米里奥·吉梅诺·祖卡 |
| 用于接近风力涡轮机塔的外表面的方法包括如下步骤:将外围轨道连接到塔的外表面上;在所述轨道上方开孔;在塔的基座上布置工作平台;在孔中插入线缆盘;通过驱动线缆盘而提升平台直到其接近外围轨道;悬挂和水平移动装置设置在水平轨道上;将平台连接到所述悬挂和水平移动装置并且根据需要移动平台。 | ||||||
| 3 | 风力涡轮机辅助驱动系统的锁定装置 | CN201180005757.4 | 2011-01-10 | CN102725521B | 2015-03-11 | S·巴莱罗拉富恩特 |
| 一种用于驱动风力涡轮机部件的辅助驱动系统,该驱动系统包括马达、可操作地与所述马达连接的传动装置、以及致动器,所述致动器可操作地与所述传动装置连接以致动所述部件,其中该辅助驱动系统还设置有一个或更多个锁定件,所述一个或更多个锁定件能够与所述传动装置的部件互锁,从而锁定辅助驱动系统。 | ||||||
| 4 | 风力涡轮机辅助驱动系统的锁定装置 | CN201180005757.4 | 2011-01-10 | CN102725521A | 2012-10-10 | S·巴莱罗拉富恩特 |
| 一种用于驱动风力涡轮机部件的辅助驱动系统,该驱动系统包括马达、可操作地与所述马达连接的传动装置、以及致动器,所述致动器可操作地与所述传动装置连接以致动所述部件,其中该辅助驱动系统还设置有一个或更多个锁定件,所述一个或更多个锁定件能够与所述传动装置的部件互锁,从而锁定辅助驱动系统。 | ||||||
| 5 | 具有提升装置的风轮发电机 | CN201110455430.9 | 2011-12-30 | CN102628420A | 2012-08-08 | H·莫特森; V·克里斯南 |
| 为了提供一种更有效且简单的具有提升装置的风轮发电机以及为了维护目的而使用提升装置的方法,公开了这样一种风轮发电机,其包括:塔架(108);由塔架支撑的机舱(104),该机舱包括支撑机舱的部件的基座(202);包括使机舱能够相对于塔架旋转的偏航轴承(206)的偏航系统(204);位于风轮发电机内并且能够移动物品的提升装置(214);支撑提升装置的支撑件(216;217;219;304;1102;1104),其中,提升装置能够在水平方向(118、120)从第一位置(806)移动至第二位置(808),并且这些位置中的至少一个位置在竖向上位于基座(202)的最低水平面(405)与塔架的最高水平面(403)之间。 | ||||||
| 6 | 风轮机用的转子锁 | CN201080019576.2 | 2010-03-08 | CN102414438A | 2012-04-11 | F·S·尼尔森; E·马库森 |
| 公开了一种用于锁定风轮机的轮毂(1)以防止旋转运动的锁定装置。锁定装置包括至少一个第一锁定部件(6)和至少一个第二锁定部件(8)。第一锁定部件(6)能相对于轮毂(1)的旋转轴线沿着大致径向方向在锁定位置和释放位置之间运动。当第一锁定部件(6)处于锁定位置时,每个第二锁定部件(8)适于保持第一锁定部件(6)。第一锁定部件(6)和第二锁定部件(8)被布置成使得它们中的一者位于轮毂(1)上,并且它们中的另一者位于基座框架(5)上。从而,第一锁定部件(6)和第二锁定部件(8)在第一锁定部件(6)处于锁定位置时防止轮毂(1)相对于基座框架(5)进行旋转运动,并在第一锁定部件(6)处于释放位置时允许上述运动。 | ||||||
| 7 | 用于风力涡轮机的维护起重机 | CN200980140793.4 | 2009-09-30 | CN102187090A | 2011-09-14 | G·K·S·彼泽森 |
| 本发明涉及一种用于风力涡轮机的维护起重机,所述风力涡轮机包括机舱和轮毂。一个或多个翼形叶片通过机翼变浆轴承安装到所述轮毂上,所述维护起重机包括用于与所述轮毂连接的安装基座。所述维护起重机适于在作业期间安装在风力涡轮机上,并且在不使用时被拆卸下来。维护起重机的所述安装基座通过机翼变浆轴承被安装在风力涡轮机的轮毂上。 | ||||||
| 8 | Rotor hub maintenance system | US13588707 | 2012-08-17 | US09353726B2 | 2016-05-31 | Kenneth A. Deese; Matthew J. McBride |
| A rotor hub maintenance system and method is disclosed. The system includes at least a rotor hub, a plurality of appendages that are operatively connectable to the hub, and a plurality of support members. The preferred embodiment provides that the support members simultaneously secure the hub and appendages a predetermined height above a reference surface and provide the only support for the hub and appendages. | ||||||
| 9 | Blade pitch-controlled wind turbine system | US13774015 | 2013-02-22 | US09249677B1 | 2016-02-02 | Cristofer D. Somerville |
| A blade pitch-controlled wind turbine system for achieving maximum wind efficiency with variable speed and blade pitch control. The blade pitch-controlled wind turbine system includes a support assembly including a tower; a turbine rotor assembly being supported upon the support assembly; and a blade pitch control assembly being supported upon the support assembly and being in communication with the said turbine rotor assembly. | ||||||
| 10 | Wind turbine having internal transportation devices specification identification | US13509921 | 2010-11-18 | US09169824B2 | 2015-10-27 | Karl Aarhus |
| The invention relates to a wind turbine with internal transport devices which comprises: a power train including a generator (41) located in front of the rotor (15) and actuated directly by said rotor (15), a tower (11) and a supporting structure (13) mounted on the tower (11); the rotor (15), which is supported by a main non-rotating shaft (29) connected to the supporting structure (13) by means of at least one bearing, comprising a hub (17) and at least one blade; the generator rotor (45) being rigidly connected to the rotor hub (17) and the generator stator (43) being rigidly connected to the main shaft (29), the main shaft (29) being a hollow shaft which includes one or more transport devices, such as a device (61) for transporting hanging loads or a carriage (71) for making it easier to replace parts of the generator and/or to transport persons. | ||||||
| 11 | Method for repairing a pitch system in a wind turbine | US13937244 | 2013-07-09 | US09140232B2 | 2015-09-22 | Jonathan Paul Signore; Kristina Anne Gerber |
| A replacement motor mount for a pitch system of a wind turbine includes a bracket assembly configured for attachment to a first motor mount and a second supporting structure. The replacement motor mount is configured for mounting and securing a pitch motor having a geared drive end. The replacement motor mount is configured to displace the pitch motor from the first motor mount by a predetermined distance. | ||||||
| 12 | Device for establishing admittance and transport of cargo to and from a wind turbine construction above ground level | US13505083 | 2010-10-28 | US09115693B2 | 2015-08-25 | Per E Fenger |
| A device for establishing admittance and transport of cargo to and from a wind turbine construction above ground level and having a part which can be raised and/or lowered by wires and winches located at ground level and connected with snatch blocks attached to a part so that it can be raised and/or lowered in relation to the construction. The part has a number of travelling crabs according to the numbers of winches and the travelling crabs are guided of the wires between the winches and the snatch blocks, and that the part with the travelling crabs is displaced upwards or downwards by the wires. Advantageously, the wires are used for both hoisting the part and as guide for the travelling crabs. | ||||||
| 13 | System for real time supervision of component wear in a wind turbine population | US12812830 | 2008-01-15 | US09103323B2 | 2015-08-11 | Pey Yen Siew; Ingemann Hvas Sandvad |
| A system for scheduling maintenance of a component in a wind turbine. The system receives signals from each of the wind turbines in a population of wind turbines. From the signals, the system detects a failure of the component in one of the wind turbine. In response to the detect failure, the system calculates a new life value for the component. The life value is then compared to a threshold value. If the life value is within a specified parameter compared to the threshold value, the system schedules a change of the component in all of the wind turbines in the population. | ||||||
| 14 | MANUAL LIFTING TOOL FOR WIND TURBINES | US13353037 | 2012-01-18 | US20130180349A1 | 2013-07-18 | Rudy Skaff; Gonzalo Palacio Gaviria |
| An apparatus for performing a supporting and/or a lifting operation to a wind turbine component inside the wind turbine nacelle is provided. The apparatus comprises at least a tool which comprises a manually operated linear actuator and a mounting device of said linear actuator in an element of the nacelle frame so that said linear actuator can be duly located with respect to the wind turbine component for performing said supporting and/or lifting operation. | ||||||
| 15 | SERVICE CRANE FOR A WIND TURBINE | US13120825 | 2009-09-30 | US20110200435A1 | 2011-08-18 | Gunnar K. Storgaard Pedersen |
| The present invention relates to a service crane for a wind turbine comprising a nacelle and a hub. One or more wing blades is attached to the hub via a wing pitch bearing, and the service crane comprises an attachment foundation for connection to the hub. The service crane is adapted to be mounted on the wind turbine during operation and to be dismounted when not being used. The attachment foundation of the service crane is mounted on the hub of the wind turbine via the wing pitch bearing. | ||||||
| 16 | SYSTEM FOR REAL TIME SUPERVISION OF COMPONENT WEAR IN A WIND TURBINE POPULATION | US12812830 | 2008-01-15 | US20110144949A1 | 2011-06-16 | Pey Yen Siew; Ingemann Hvas Sandvad |
| A system for scheduling maintenance of a component in a wind turbine. The system receives signals from each of the wind turbines in a population of wind turbines. From the signals, the system detects a failure of the component in one of the wind turbine. In response to the detect failure, the system calculates a new life value for the component. The life value is then compared to a threshold value. If the life value is within a specified parameter compared to the threshold value, the system schedules a change of the component in all of the wind turbines in the population. | ||||||
| 17 | In situ balancing of wind turbines | US621316 | 1990-12-03 | US5140856A | 1992-08-25 | Orla W. Larsen |
| A slowly turning rotating mass, such as a wind turbine rotor, is balanced in situ by measuring the magnitude of a phenomenon, such as acceleration, created by rotor unbalance at a location on a mass support shaft which is close to the mass. The measurement of the phenomenon is made along a line selected to be insensitive to the bias of gravity on the mass. The measurement is made while the mass turns at its usual operating rate. The structure which supports the shaft is fixed as rigidly as possible in space while measurements of the phenomenon are made. | ||||||
| 18 | Portable, adjustable structure and method of erecting same | US579274 | 1984-02-13 | US4590718A | 1986-05-27 | Lloyd G. Angeloff |
| A portable, adjustable structure for supporting an equipment unit at a distance above a support surface has a lower tower structural member placed on the support surface. Pivot support structural members are affixed to the lower tower structural member in a manner whereby the pivot support structural members are upright relative to the support surface. A plurality of struts are utilized to stabilize the lower tower structural member and the pivot support structural members on the support surface. A tower member is pivotally mounted on the pivot support structural members. The tower member has spaced opposite first and second ends. The equipment unit is affixed to the tower member at the first end thereof. The tower member is pivotally movable to a position substantially perpendicular to the support surface with the first end thereof spaced farther from the support surface than the second end thereof. Ballast is affixed to the tower member at the second end thereof. The second end of the tower member is coupled to the lower tower structural member whereby the tower member is normally upright and is pivotable, upon uncoupling of the tower member and the lower tower structural member, to position the equipment unit close to the support surface for maintenance and repair. | ||||||
| 19 | 浮体式風力発電装置のメンテナンス方法 | JP2014557297 | 2013-01-21 | JPWO2014112115A1 | 2017-01-19 | 橋本 淳; 淳 橋本 |
| 係留ラインによって係留位置に係留された浮体上に風力発電機が設置され、前記風力発電機で生成した電力をケーブルに供給するように構成された浮体式風力発電装置のメンテナンス方法であって、メンテナンス対象部位を有する第1浮体式風力発電装置の前記浮体から前記係留ライン及び前記ケーブルを切り離す切り離しステップと、前記切り離しステップの後、前記係留ライン及び前記ケーブルを浮体構造物に保持させる保持ステップと、前記切り離しステップの後、前記第1浮体式風力発電装置を前記係留位置から移動させる第1移動ステップと、メンテナンス対象部位を有しない第2浮体式風力発電装置を前記係留位置に移動させる第2移動ステップと、前記第2移動ステップの後、前記係留ライン及び前記ケーブルを前記浮体構造物から取り外し、前記第2浮体式風力発電装置に接続する接続ステップとを備える。 | ||||||
| 20 | 浮体式風力発電装置及び該装置の部品搬送方法 | JP2014549731 | 2012-11-30 | JP5860976B2 | 2016-02-16 | 沼尻 智裕 |
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