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 |
|---|---|---|---|---|---|---|
| 201 | Wind-motor | US259569D | US259569A | 1882-06-13 | ||
| 202 | Improvement in wind-engines | US207545D | US207545A | 1878-08-27 | ||
| 203 | Improvement in windmills | US190296D | US190296A | 1877-05-01 | ||
| 204 | Improvement in windmills | US168574D | US168574A | 1875-10-11 | ||
| 205 | Improvement in windmills | US151932D | US151932A | 1874-06-09 | ||
| 206 | Improvement in windmills | US102364D | US102364A | 1870-04-26 | ||
| 207 | Improvement in wind-wheels | US92697D | US92697A | 1869-07-20 | ||
| 208 | Improvement in wind- wheels | US85508D | US85508A | 1869-01-05 | ||
| 209 | Improvement in wind-wheels | US83928D | US83928A | 1868-11-10 | ||
| 210 | Improvement in windmills | US54407D | US54407A | 1866-05-01 | ||
| 211 | Improvement in wind-wheels | US50825D | US50825A | 1865-11-07 | ||
| 212 | Improvement in windmills | US24472D | US24472A | 1859-06-21 | ||
| 213 | Xwindmill | US15714D | US15714A | 1856-09-09 | ||
| 214 | WIND TURBINE, BEARING HOUSING AND METHOD FOR OPERATING A WIND TURBINE | US16322176 | 2017-06-27 | US20190195205A1 | 2019-06-27 | Uffe Erikson; Edom Lemma; Thorkil Munk-Hansen; Kim Thomsen |
| Provided is a wind turbine, including a rotor with a rotor shaft connected to a generator and a bearing housing, whereby the bearing housing includes at least a first bearing group and a second bearing group each comprising at least a primary bearing setup and a secondary bearing setup in which bearing is receivable, whereby the rotor shaft is rotatably arranged by the primary bearing setups or the secondary bearing setups. | ||||||
| 215 | ROTOR ARRESTING DEVICE FOR A WIND TURBINE AND METHOD | US16331504 | 2017-08-24 | US20190195197A1 | 2019-06-27 | Jochen RÖER |
| A rotor arresting device for a wind turbine, to a wind turbine and to methods for arresting and for moving a rotor of a wind turbine. A rotor arresting device for a wind turbine having a rotor and a rotation assembly which is connected to the rotor in a rotationally rigid manner, comprising at least one coupling device which can be arranged on a static assembly, which is positionally fixed relative to the rotation assembly, of the wind turbine, having a first actuator, a second actuator, and a coupling element which is connected to the first and the second actuator, and a counterpart coupling element which can be arranged on the rotation assembly, wherein the coupling element and the counterpart coupling element are releasably connected, preferably in a form-fitting manner, in an arresting position of the coupling device. | ||||||
| 216 | ENCLOSURE FOR A NACELLE OF A WIND TURBINE | US15970330 | 2018-05-03 | US20180320665A1 | 2018-11-08 | Nils Lieckfeldt |
| An enclosure for a nacelle of a wind turbine is connected to a substructure in a manner that allows the enclosure to move relative to the substructure. An imaginary straight line extends over the panel and is aligned with an edge of the panel. The imaginary straight line defines a first sub-portion of the panel, said first sub-portion comprising the edge. The first sub-portion butts against the substructure. The first sub-portion is retained against the substructure by a tension element acting in a direction of tension. The first sub-portion can be displaced relative to the substructure in a direction which intersects the direction of tension. The invention facilitates the operation of assembling the enclosure. | ||||||
| 217 | APPARATUS AND METHOD OF GENERATING ENERGY FROM RENEWABLE ENERGY SOURCES | US15765934 | 2016-08-25 | US20180287461A1 | 2018-10-04 | Christopher John Anthony Coman |
| An electrical energy generator array generates electricity from at least one form of natural flow, the generator having a drive shaft driven by energy from a natural energy flow and connected to a drive mechanism. The generator includes an integrated electric motor and a plurality of individual generators disengageably connected to the drive mechanism. Each generator is connected via a series of ties to form a connected generator array, the array being rotated by the drive mechanism when connected thereto, or by the integrated electric motor when disconnected from the drive mechanism, to generate electricity. The generator may include an electrical storage device arranged to power the integrated electric motor. A method of generating electricity from at least one natural energy flow, for supply to an electrical storage device, for local use or for supply to an electric grid includes using an electrical energy generator array as described. | ||||||
| 218 | Mounting ring arrangement | US14752954 | 2015-06-28 | US10024298B2 | 2018-07-17 | Kasper Koops Kratmann; Karsten Schibsbye |
| A mounting ring arrangement adapted for alignment of root bushings in a rotor blade root end during a rotor blade assembly step includes a mounting ring segment; and a partial mounting ring, which partial mounting ring is a closed annular component and includes a recess dimensioned to accommodate the mounting ring segment. A method of manufacturing a rotor blade, includes (A) arranging a fiber layup in a first blade mold and arranging a fiber layup in a second blade mold; (B) arranging the partial mounting ring of a mounting ring arrangement in the first blade mold and arranging the mounting ring segment of the mounting ring arrangement in the second blade mold; and (C) joining the first and second blade molds such that the partial mounting ring and the mounting ring segment join to form a full mounting ring. | ||||||
| 219 | Wind turbines and methods | US14592501 | 2015-01-08 | US10018186B2 | 2018-07-10 | Roger Bergua; Jordi Jové |
| Wind turbines are provided comprising a support structure having a tower and a nacelle mounted on the support structure. A first region (damper region) of the wind turbine including at least a first part of the nacelle is flexibly coupled to a second region (to be damped) of the wind turbine including at least the support structure. Methods are also provided for determining a suitable stiffness of the flexible coupling of the damper region to the region to be damped of any one of said wind turbines. These methods comprise determining a modal mass of the region to be damped depending on a given tower bending mode; and determining the stiffness of the flexible coupling of the damper region to the region to be damped depending on the calculated modal mass of the region to be damped and on the mass of the damper region. | ||||||
| 220 | Turbine Energy Device | US15118492 | 2015-02-11 | US20180135600A1 | 2018-05-17 | Doron .E Ezoory |
| A turbine energy device having one or more rotors and one or more stators in one or more generator sets wherein said rotors and stators are adapted to be rotated in opposite directions, by means of gear stages adapted to produce counter-rotation in these elements and to produce high relative rotation rates between said elements according to the gear ratios involved, thereby obtaining increased power density. | ||||||
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