FLOATING WIND ENERGY

VolverGo back

Resultados 47 results. LastUpdate Updated on 03/03/2021 [00:41:00] pdf PDF xls XLS

Publicaciones de los últimos 120 días / Applications published in the last 120 days



Page1/2 nextPage   results/page


CONTROL SYSTEM FOR OPERATING A FLOATING WIND TURBINE UNDER SEA ICE CONDITIONS

Publication No.: WO2021032406A1 25/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

EP_3782898_A1

Absstract of: WO2021032406A1

It is described a control system (170) for operating a floating wind turbine (100, 200) under sea ice conditions. The control system (170) comprises a detection device (281, 282) configured for detecting a formation of ice (271, 272) in a critical zone (205) around the floating wind turbine, and an ice inhibiting device (291, 292, 293, 294) configured for manipulating the floating wind turbine (100, 200) in such a manner that the critical zone (205) is free of a threshold amount of the detected formation of ice (271, 272). Furthermore, a floating wind turbine (100, 200) is described which comprises a wind rotor comprising a wind rotor comprising a blade (140, 240), a tower (130, 230), a floating foundation (120, 220), and an above-described control system (170). Additionally, a method for operating a floating wind turbine (100, 200) under sea ice conditions is described.

traducir

FLOATING WIND TURBINE COMPRISING AN INTEGRATED ELECTRICAL SUBSTATION

Publication No.: WO2021032422A1 25/02/2021

Applicant:

ENBW ENERGIE BADEN WUERTTEMBERG AG [DE]

DE_102019122110_A1

Absstract of: WO2021032422A1

Described are a wind turbine comprising an integrated electrical substation, and a floating offshore wind farm, which are optimised with respect to capital costs, economic efficiency and installation space requirements.

traducir

CONTROL SYSTEM FOR STABILIZING A FLOATING WIND TURBINE

Publication No.: WO2021032405A1 25/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

EP_3782899_A1

Absstract of: WO2021032405A1

It is described a control system (170, 270) for stabilizing a floating wind turbine (100, 200, 300, 400, 600). The control system (170, 270) comprises a measuring device (371, 471) configured for measuring a wind field (111, 211, 311, 411, 611) and a wave field (418, 618), a determining device (373, 473), wherein the determining device (373, 473) is configured for determining an excitation frequency spectrum (591, 791) of the floating wind turbine (100, 200, 300, 400, 600) on the basis of the measured wind field (111, 211, 311, 411, 611) and/or the wave field (418, 618) and/or a current floater pitch angle of the floating wind turbine (100, 200, 300, 400, 600), and wherein the determining device (373, 473) is fur- ther configured for determining a balanced state of the floating wind turbine (100, 200, 300, 400, 600), wherein in the balanced state a natural frequency (592, 792) is outside of the excitation frequency spectrum (591, 791) and/or the current floater pitch angle is equal to a pre-defined floater pitch angle. The control system (170, 270) further comprises an adjustment device (372, 472, 672) which is configured for manipulating the current floater pitch and/or the natural frequency (592, 792) until the balanced state is met. Furthermore, a floating wind turbine (100, 200, 300, 400, 600) is described which comprises a wind rotor comprising a blade (140, 240), a tower, a floating foundation (120, 220, 320, 420, 620), and an above-described control system (170, 270).

traducir

CONTROL SYSTEM FOR STABILIZING A FLOATING WIND TURBINE

Publication No.: WO2021032407A1 25/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

EP_3782897_A1

Absstract of: WO2021032407A1

It is described a control system (170) for stabilizing a floating wind turbine (100), the control system (170) comprising a detection device (271, 272, 273, 274) configured for monitoring an offset (231) from a predetermined floater pitch angle (393) and/or an offset from a predetermined floater yaw angle of the floating wind turbine (100), wherein the detection device (271, 272, 273, 274) is further configured for monitoring an oscillating motion (396) of the floater pitch angle (392) and/or an oscillating motion of the floater yaw angle, wherein the predetermined floater pitch angle (393) and the predetermined floater yaw angle define a predetermined balanced state of the floating wind turbine (100), wherein a threshold (394, 395) of the oscillating motion (396) of the floater pitch angle (392) and a threshold of the oscillating motion of the floater yaw angle further define the predetermined balanced state of the floating wind turbine (100), and an actuation device (281, 282) configured for manipulating the floater pitch angle (392) and/or the floater yaw angle until the predetermined balanced state is met, wherein the actuation device (281, 282) is further configured for manipulating the oscillating motion (396) of the floater pitch angle (392) and/or the oscillating motion of the floater yaw angle until the predetermined balanced state of the floating wind turbine (100) is met. Furthermore, a floating wind turbine (100) is described. Additionally, a method for stabilizin

traducir

CONTROL SYSTEM FOR POSITIONING AT LEAST TWO FLOATING WIND TURBINES IN A WIND FARM

Publication No.: WO2021032370A1 25/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

EP_3783221_A1

Absstract of: WO2021032370A1

It is described a control system (111, 121) for positioning at least two floating wind turbines (110, 120) in a wind farm (100). The control system (111, 121) comprises a measuring device (112, 122) configured for measuring an incoming wind field at the two wind turbines, a determining device (114, 124), wherein the determining device (114, 124) is configured for determining a wake property (151, 252, 351, 352) at the two wind turbines, wherein the determining device (114, 124) is configured for determining a propagation path of the wake property (151, 252, 351, 352) through the wind farm (100) based on the determined wake property (151, 252, 351, 352) at the at least two floating wind turbines (110, 120), wherein the determining device (114, 124) is configured for determining a location for each of the at least two floating wind turbines (110, 120) comprising a minimized wake influence based on the determined propagation path of the wake property (151, 252, 351, 352) through the wind farm (100), and a repositioning device (113, 123) configured for repositioning each of the at least two floating wind turbines (110, 120) to the determined location. Furthermore, a wind farm (100) is described which comprises at least two floating wind turbines (110, 120), and an above-described control system (111, 121). Additionally, a method for positioning at least two floating wind turbines (110, 120) in a wind farm (100) is described.

traducir

CONTROL SYSTEM FOR POSITIONING AT LEAST TWO FLOATING WIND TURBINES IN A WIND FARM

Publication No.: EP3783221A1 24/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

WO_2021032370_A1

Absstract of: EP3783221A1

It is described a control system (111, 121) for positioning at least two floating wind turbines (110, 120) in a wind farm (100). The control system (111, 121) comprises a measuring device (112, 122) configured for measuring an incoming wind field at the two wind turbines, a determining device (114, 124), wherein the determining device (114, 124) is configured for determining a wake property (151, 252, 351, 352) at the two wind turbines, wherein the determining device (114, 124) is configured for determining a propagation path of the wake property (151, 252, 351, 352) through the wind farm (100) based on the determined wake property (151, 252, 351, 352) at the at least two floating wind turbines (110, 120), wherein the determining device (114, 124) is configured for determining a location for each of the at least two floating wind turbines (110, 120) comprising a minimized wake influence based on the determined propagation path of the wake property (151, 252, 351, 352) through the wind farm (100), and a repositioning device (113, 123) configured for repositioning each of the at least two floating wind turbines (110, 120) to the determined location. Furthermore, a wind farm (100) is described which comprises at least two floating wind turbines (110, 120), and an above-described control system (111, 121). Additionally, a method for positioning at least two floating wind turbines (110, 120) in a wind farm (100) is described.

traducir

CONTROL SYSTEM FOR STABILIZING A FLOATING WIND TURBINE

Publication No.: EP3782897A1 24/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

WO_2021032407_A1

Absstract of: EP3782897A1

A control system (170) for stabilizing a floating wind turbine (100), the control system comprising a detection device (271, 272, 273, 274) configured for monitoring an offset (231) from a predetermined floater pitch angle (393) and/or an offset from a predetermined floater yaw angle of the floating wind turbine, wherein the detection device is further configured for monitoring an oscillating motion (396) of the floater pitch angle (392) and/or an oscillating motion of the floater yaw angle, wherein the predetermined floater pitch angle and the predetermined floater yaw angle define a predetermined balanced state of the floating wind turbine, wherein a threshold (394, 395) of the oscillating motion of the floater pitch angle and a threshold of the oscillating motion of the floater yaw angle further define the predetermined balanced state of the floating wind turbine, and an actuation device (281, 282) configured for manipulating the floater pitch angle and/or the floater yaw angle until the predetermined balanced state is met, wherein the actuation device is further configured for manipulating the oscillating motion of the floater pitch angle and/or the oscillating motion of the floater yaw angle until the predetermined balanced state of the floating wind turbine is met. Furthermore, a floating wind turbine is described. Additionally, a method for stabilizing a floating wind turbine is described.

traducir

CONTROL SYSTEM FOR OPERATING A FLOATING WIND TURBINE UNDER SEA ICE CONDITIONS

Publication No.: EP3782898A1 24/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

WO_2021032406_A1

Absstract of: EP3782898A1

It is described a control system (170) for operating a floating wind turbine (100, 200) under sea ice conditions. The control system (170) comprises a detection device (281, 282) configured for detecting a formation of ice (271, 272) in a critical zone (205) around the floating wind turbine, and an ice inhibiting device (291, 292, 293, 294) configured for manipulating the floating wind turbine (100, 200) in such a manner that the critical zone (205) is free of a threshold amount of the detected formation of ice (271, 272). Furthermore, a floating wind turbine (100, 200) is described which comprises a wind rotor comprising a wind rotor comprising a blade (140, 240), a tower (130, 230), a floating foundation (120, 220), and an above-described control system (170). Additionally, a method for operating a floating wind turbine (100, 200) under sea ice conditions is described.

traducir

CONTROL SYSTEM FOR STABILIZING A FLOATING WIND TURBINE

Publication No.: EP3782899A1 24/02/2021

Applicant:

SIEMENS GAMESA RENEWABLE ENERGY AS [DK]

WO_2021032405_A1

Absstract of: EP3782899A1

It is described a control system (170, 270) for stabilizing a floating wind turbine (100, 200, 300, 400, 600). The control system (170, 270) comprises a measuring device (371, 471) configured for measuring a wind field (111, 211, 311, 411, 611) and a wave field (418, 618), a determining device (373, 473), wherein the determining device (373, 473) is configured for determining an excitation frequency spectrum (591, 791) of the floating wind turbine (100, 200, 300, 400, 600) on the basis of the measured wind field (111, 211, 311, 411, 611) and/or the wave field (418, 618) and/or a current floater pitch angle of the floating wind turbine (100, 200, 300, 400, 600), and wherein the determining device (373, 473) is further configured for determining a balanced state of the floating wind turbine (100, 200, 300, 400, 600), wherein in the balanced state a natural frequency (592, 792) is outside of the excitation frequency spectrum (591, 791) and/or the current floater pitch angle is equal to a pre-defined floater pitch angle. The control system (170, 270) further comprises an adjustment device (372, 472, 672) which is configured for manipulating the current floater pitch and/or the natural frequency (592, 792) until the balanced state is met. Furthermore, a floating wind turbine (100, 200, 300, 400, 600) is described which comprises a wind rotor comprising a blade (140, 240), a tower, a floating foundation (120, 220, 320, 420, 620), and an above-described control system (170, 270). Ad

traducir

FLOATING SUPPORT STRUCTURE FOR OFFSHORE WIND TURBINE AND METHOD FOR INSTALLING A WIND TURBINE PROVIDED WITH SUCH A SUPPORT STRUCTURE

Publication No.: PH12020550612A1 22/02/2021

Applicant:

SAIPEM SA [FR]

US_2020391834_A1

Absstract of: PH12020550612A1

The invention concerns a floating support structure (10) for an offshore wind turbine, comprising a float (12) intended to be partially submerged and on which a wind turbine mast is intended to be assembled, and a counterweight linked to the float and intended to be submerged under the float, the float comprising a main structure (18), the shape of which is toroidal or polygonal with at least five sides, a central tubular structure (26) having a diameter suitable for receiving the wind turbine mast and comprising a section suitable for being ballasted in order to adjust the waterline of the float, a first series of horizontal struts (28) distributed around a vertical axis and linking the main structure to the central structure, and a second series of oblique struts (30) distributed around a vertical axis (Y-Y) and linking the main structure to the central structure, forming an angle of between 15ø and 60ø with the horizontal struts (28).

traducir

HYBRID VERTICAL/HORIZONTAL AXIS WIND TURBINE FOR DEEP-WATER OFFSHORE INSTALLATIONS

Publication No.: US2021048002A1 18/02/2021

Applicant:

CONTINUUM DYNAMICS INC [US]

US_2021040938_A1

Absstract of: US2021048002A1

A wind-driven power generating system with a hybrid wind turbine mounted on a floating platform that heels relative to horizontal in the presence of a prevailing wind. The hybrid turbine has a turbine rotor with at least two rotor blades, each mounted to a turbine shaft by at least one strut, and the system is configured so that the shaft forms a predetermined non-zero operating heel angle relative to vertical in the presence of a prevailing wind at a predetermined velocity. The blades and struts are airfoils with predetermined aerodynamic characteristics that generate lift forces with components in the direction of rotation around the shaft of the blades and struts at the operating heel angle to drive an electrical generator carried by the platform. The system can be designed to generate maximum power at the predetermined heel angle or essentially constant power over a range of heel angles.

traducir

MARINE WIND POWER GENERATION FLOATING BODY

Publication No.: WO2021029491A1 18/02/2021

Applicant:

ACE E\uFF06T ENGINEERING \uFF06 TECH [KR]

KR_102107994_B1

Absstract of: WO2021029491A1

The present invention relates to a marine wind power generation floating body, which can be coupled to a tower used for wind power generation and is provided at sea, the marine wind power generation floating body comprising: a floating main body which is formed at a predetermined length and which has a circular transverse cross section; a ballast part positioned on one side of the floating main body; a damping plate positioned at one end of the floating main body, and formed with a diameter that is larger than the outer diameter of one side of the floating main body; and a pitching/rolling damping part which is positioned on the other side of the floating main body, and which damps the horizontal pitching and rolling of the floating main body.

traducir

HYBRID VERTICAL/HORIZONTAL AXIS WIND TURBINE FOR DEEP-WATER OFFSHORE INSTALLATIONS

Publication No.: US2021040938A1 11/02/2021

Applicant:

CONTINUUM DYNAMICS INC [US]

US_2021048002_A1

Absstract of: US2021040938A1

A wind-driven power generating system with a hybrid wind turbine mounted on a floating platform that heels relative to horizontal in the presence of a prevailing wind. The hybrid turbine has a turbine rotor with at least two rotor blades, each mounted to a turbine shaft by at least one strut, and the system is configured so that the shaft forms a predetermined non-zero operating heel angle relative to vertical in the presence of a prevailing wind at a predetermined velocity. The blades and struts are airfoils with predetermined aerodynamic characteristics that generate lift forces with components in the direction of rotation around the shaft of the blades and struts at the operating heel angle to drive an electrical generator carried by the platform. The system can he designed to generate maximum power at the predetermined heel angle or essentially constant power over a range of heel angles.

traducir

Floating Airborne Wind Energy System With Submersible Platform

Publication No.: US2021033072A1 04/02/2021

Applicant:

WINDLIFT LLC [US]

Absstract of: US2021033072A1

The exemplary embodiments herein provide an airborne power generation assembly comprising an airborne power generation unit, a submersible platform, an electrified tether winch attached to the submersible platform, an electrified tether connecting between the electrified tether winch and the airborne power generation unit, and a power output exiting from the submersible platform. Embodiments include an underwater docking station with a docking station tether connecting the submersible platform to the underwater docking station. The submersible platform or the underwater docking station may be anchored to the sea bed. Other embodiments include winches for the sea bed anchor tethers and docking station tether.

traducir

YAWING BUOY MAST FOR FLOATING OFFSHORE WIND TURBINES

Publication No.: WO2021022250A1 04/02/2021

Applicant:

AQUANTIS INC [US]

Absstract of: WO2021022250A1

The present invention provides a novel, floating, offshore wind turbine (FOWT) structure, referred to as a yawing buoy mast (YBM) structure. The YBM platform vertically combines a submerged spar buoy with outrigger legs and a mast on which a wind turbine nacelle is mounted. Compared to a conventional spar buoy wind turbine, weight is significantly reduced by optimizing how loads are borne and reacted by the floating structure. The mass of the YBM platform is reduced relative to the energy captured by the turbine resulting in a reduction in the cost of energy (COE). Platform load dynamics are coupled with the dynamics of the wind turbine by integration of the YBM platform and turbine controllers.

traducir

WIND-DRIVEN POWER GENERATION DEVICE BASED ON MAGNETIC LEVITATION

Publication No.: US2021033071A1 04/02/2021

Applicant:

LIU YUN LAI [TW]

DE_202020104435_U1

Absstract of: US2021033071A1

A wind-driven power generation device based on magnetic levitation is provided. The device includes a magnetic levitation structure, a wind fan, a driving fan, and an electric power generator. Since a floating magnet floated above a fixed magnet in the magnetic levitation structure, the rotation friction of the fan shaft of the wind fan can be greatly reduced to stabilize the output electric power of the wind-driven power generation device.

traducir

OFFSHORE WIND-SOLAR-AQUACULTURE INTEGRATED FLOATER

Publication No.: US2021025369A1 28/01/2021

Applicant:

TSINGHUA SHENZHEN INT GRADUATE SCHOOL [CN]

WO_2020220913_A1

Absstract of: US2021025369A1

An offshore wind-solar-aquaculture integrated floater is provided, including vertical-axis wind turbine systems, solar photovoltaic panels, and a cube aquaculture cage. Four vertical-axis wind turbine systems are respectively rigidly connected to four corners of the cage; solar photovoltaic panels and a living and working quarter are located on cage deck; and side frames of the cage are equipped with tensile nets, the bottom frame of cage is equipped with a bottom net, and columns of the cage are equipped with lifting rails. This floater has good stability, sea-keeping performance and high strength. Utilizations of offshore wind and solar energy above the cage are high and they complement each other in power generation. This disclosure manages to exploit ocean resources to an unprecedentedly large extent, while resolving the issue of combing power generation with marine aquaculture in moderate and deep seas.

traducir

Wind turbine and method for installing a wind turbine

Publication No.: AU2019273757A1 21/01/2021

Applicant:

FLOATING ENERGY SYSTEMS LTD

KR_20210010997_A

Absstract of: AU2019273757A1

A wind turbine for deployment offshore. The wind turbine including: a tower-float assembly having a tower (3) for supporting a nacelle (13a) and a rotor (13b), and a float (5) arranged to maintain at least part of the tower above a surface of a body of water; a keel assembly (7) including at least one keel module (25) and at least one rod (9) connecting the keel module to the tower-float assembly, wherein the at least one rod is arranged to move relative to the tower-float assembly to deploy the keel module, and the keel module is movable relative to the tower-float assembly, in response to movement of the at least one rod, between a non-deployed position proximal the tower-float assembly and a deployed position which is distal from the tower-float assembly in a downwardly direction, thereby increasing an effective length of the wind turbine; and the at least one rod is arranged to transfer bending moments to the tower-float assembly.

traducir

WIND TURBINE COMPRISING A FLOATING FOUNDATION HAVING A PLURALITY OF BUOYANCY BODIES

Publication No.: WO2021005413A1 14/01/2021

Applicant:

AERODYN CONSULTING SINGAPORE PTE LTD [SG]

DE_102019118564_A1

Absstract of: WO2021005413A1

The invention relates to a wind turbine (10) comprising a floating foundation (20) having a plurality of buoyancy bodies (30, 30'), the buoyancy bodies (30, 30') being formed from a plurality of buoyancy body elements (32, 32') designed as hollow bodies, which are arranged adjacent to one another in a first plane concentrically around each central element (28, 28') extending from the floating foundation (20) and are connected to said central element, and each buoyancy body element (32, 32', 34, 34') has a surface supported on the central element (28, 28'), a convex surface arranged opposite the central element (28, 28'), and two lateral surfaces each supported on a lateral surface of an adjacent buoyancy body element (32, 32', 34, 34').

traducir

Wind turbine, heat pump, energy storage, and heat transport system and methods

Publication No.: AU2019288294A1 14/01/2021

Applicant:

ZERO E TECHNOLOGIES LLC [US]

WO_2019246128_PA

Absstract of: AU2019288294A1

A floating heat pump system including a superstructure supporting a wind turbine and at least one electric generator mechanically connected to the wind turbine. Wind-induced rotation of the wind turbine causes the electric generator to generate electricity. The generated electricity may be supplied to a power grid, or a portion of the generated electricity may be used to power a heat pump also supported at least in part by the superstructure to extract heat from the ocean or another large body of water. The heat may be stored in transportable thermal storage medium. Heat stored in the thermal storage media may be used at the system or remotely for regional or district heating and cooling, industrial purposes, or to generate electricity.

traducir

SEMI-SUBMERSIBLE FLOATER, PARTICULARLY FOR A FLOATING WIND TURBINE

Publication No.: US2021009236A1 14/01/2021

Applicant:

NAVAL ENERGIES [FR]

KR_20200133784_A

Absstract of: US2021009236A1

Disclosed is a semi-submersible floater defining an operating state and a non-operating state, and including at least two outer columns, a central column for receiving a payload, and, for each outer column, a branch in the form of pontoon connecting the outer column to the central column and defining a branch axis oriented from the central column towards the outer column. Each branch is formed from a first portion and a second portion which extend successively along the corresponding branch axis, each one over at least 10% of the total extent of the branch, along the branch axis. In the operating state of the floater, the second portion of each branch is at least partially filled with a ballast material, and the first portion does not contain any ballast material.

traducir

Bamboo wind turbine

Publication No.: US2021003112A1 07/01/2021

Applicant:

ALLINSON MARC GREGORY [US]

Absstract of: US2021003112A1

The present invention relates to a novel way of manufacturing and assembling wind turbines to harness energy from wind. Chiefly, the invention is a way to build a darrieus vertical axis wind turbine and eliminate the need for a tower. This is done by using greater than two blades, replacing the tower with high tension cable(s) and adding high tension cables to the circumference of the turbine attached to each blade. This prevents deformation, reduces weight, and makes a rigid structure using tension and compression. Furthermore, this turbine can be built from whole bamboo poles and includes blades composed of whole bamboo poles, cables, and architectural fabric/membranes/composites. The invention includes unique applications for the turbine such as floating and ground-based systems and has custom bearings, foundations, passive cooling, manufacturing, and brakes. There is also a method of generating low pressure downstream of the turbines using a jib sail like structure. There is a collapsible frame system used for quickly erecting and assembling the turbines in the field.

traducir

A FLOATING FOUNDATION FOR AN OFFSHORE WIND TURBINE, A SYSTEM FOR EXTRACTING ENERGY FROM WIND, AND A METHOD OF INSTALLING A WIND TURBINE

Publication No.: WO2021002760A1 07/01/2021

Applicant:

NEWTECH AS [NO]

Absstract of: WO2021002760A1

A floating foundation for an offshore wind turbine, the floating foundation comprising a centre pipe, a buoyancy section, a weight section, and a plurality of wire ropes, wherein: the buoyancy section is connected to the centre pipe for providing buoyancy to the foundation to keep the foundation floating; the weight section is connected to a lower end portion of the centre pipe for providing stability to the foundation; and the plurality of wire ropes extend between and are connected to the buoyancy section and the weight section and are arranged for being tensioned and for adding bending strength to the foundation when they are tensioned, a system for extracting energy from wind, and a method of installing a wind turbine.

traducir

Multiline Ring Anchor and Installation Method

Publication No.: US2020407021A1 31/12/2020

Applicant:

TEXAS A & M UNIV SYS [US]

WO_2019191486_PA

Absstract of: US2020407021A1

A multiline ring anchor and a method for installing the multiline ring anchor is disclosed herein. The multiline ring anchor can be used for mooring systems for including, but limited to, arrays of offshore floating offshore wind turbines, wave power, and floating barriers.

traducir

MARITIME TRANSPORT MEANS FOR FLOATING-TYPE WIND POWER GENERATOR

Nº publicación: WO2020256247A1 24/12/2020

Applicant:

UNIV ULSAN FOUND IND COOP [KR]

KR_20200144341_A

Absstract of: WO2020256247A1

Provided is a maritime transport means for a floating-type wind power generator, whereby the wind power generator, which uses wind power generated at sea to generate electric power, is transported to an installation site at sea. The maritime transport means comprises: a moving means part including a plurality of floating support bodies by which the wind power generator assembled on land is transported to the installation site at sea; connection bracket parts mounted to the plurality of floating support bodies and connecting the plurality of floating support bodies so that the floating support bodies are spaced apart less than a predetermined distance from each other; and wind power generator fixing parts, each of which has one end connected to one of the floating support bodies of the moving means part and the other end connected to the wind power generator positioned between the plurality of floating support bodies, and which fix the wind power generator between the plurality of floating support bodies while preventing the wind power generator from swaying while being moved by the moving means part at sea. Accordingly, the wind power generator assembled on land can be installed after being moved to an installation site at sea using the maritime transport means so as to reduce transport costs and the installation time of the wind power generator, and thereby improve economic feasibility.

traducir

Page1/2 nextPage results/page

punteroimgGo back