A spreader tool is provided for spreading viscous material on the surface, for example an edge, of a wind turbine blade. The spreader tool comprises at least one bendable spreader wing, for example provided as a fin-ray construction, for pressing a flexible band against a curved section of the blade and for dragging viscous material along it by the flexible band during movement of the spreader tool along the blade surface. The spreader tool is advantageously part of a robot system used to work the surface of the blade.

A spreader tool is provided for spreading viscous material on the surface (5′), for example an edge (5″), of a wind turbine blade (5). The spreader tool (52) comprises at least one bendable spreader wing (54A, 54B), for example provided as a fin-ray construction, for pressing a flexible band (53) against a curved section of the blade (5) and for dragging viscous material along it by the flexible band during movement of the spreader tool (52) along the blade (5) surface (5′). The spreader tool is advantageously part of a robot system used to work the surface (5′) of the blade (5).

A closed strap collar for securing cargo by friction, a device for lifting cargo and a lifting method, the collar being formed by a strap and a tensioner which, by tightening the strap around an element, allows cargo to be secured to the element being held or the held element to be raised by pulling the strap collar.

A hoisting system includes an upper cable support system to be mounted on a top end of a wind turbine, a lower cable support system at a lower end of the wind turbine, and left and right cables extended between the cable support systems. A clamping yoke arranged approximately at the centre of gravity of a rotor blade includes left and right climbing systems adapted to climb on the cables with first and second rollers spaced in a longitudinal direction of the blade whereby the first rollers are nearer a root end of the blade than the second rollers. A position at least in the longitudinal direction of the blade of the first roller of at least one of the left and the right climbing systems is adjustable by an actuator.

A tool chain (10) is provided for performing a method of removing internal components such as a bearing cassette (64) from the interior of a generator (12) and/or a gearbox (14) of a wind turbine. The tool chain (10) includes a tube (30) that extends through the interior of the generator (12), at least one clamp element (36) that concentrically fixes the tool chain (10) in position on at least one output shaft (60, 62) of the gearbox (14), and a sliding tool (50) that moves along the tube (30) into and out of the generator to couple with and pull out internal components to be repaired or replaced. For example, the tool chain (10) can remove the bearing cassette (64) located adjacent the junction of the gearbox (14) and the generator (12) without necessitating disassembly of the gearbox (14) from the generator (12).

A wind turbine nacelle configured for mounting on a wind turbine tower and for supporting a rotor-supporting assembly, the nacelle comprising a main unit, and at least one auxiliary unit. The auxiliary unit accommodates at least one operative component, e.g. a converter, a transformer, an electrolysis cell, or a battery. An operative component having a similar function is accommodated in another auxiliary unit which thereby facilitate shared operation, and easy and fast maintenance or replacement of the operative component.

A nacelle-mounted multiple-appliance lift system has a first lifting appliance and a second lifting appliance mounted in a nacelle of a wind turbine. The first and second lifting appliances are each mounted on main bearing housing securements, gearbox pillow blocks, or both the main bearing housing securements and the gearbox pillow blocks. The first and second lifting appliances share one or both of the main bearing housing securements and the gearbox pillow blocks. The system permits having multiple lifting appliances mounted at the same in the restricted space of the nacelle.

A nacelle housing of a nacelle of a wind turbine is provided. The nacelle housing includes a ventilation opening of a cooling system of the wind turbine, a cover closing the ventilation opening, the cover being configured to allow an airflow through the cover and the ventilation opening, and a service hatch for hoisting a load into or out of the nacelle housing. The service hatch is provided by the ventilation opening and the cover, wherein the cover is configured as a service door of the service hatch that is opened to allow the hoisting of a load through the ventilation opening into or out of the nacelle housing. Furthermore, a method of hoisting a load into or out of a nacelle housing of a wind turbine is provided.

A method for lifting/lowering a long object in a wind power generating apparatus which includes a rotatably disposed rotor head, the rotor head having an openable and closable opening which causes an interior space of the rotor head and an exterior of the rotor head to communicate with each other, the interior space being disposed with a long jig for hanging the long object, the method includes a horizontal movement step of moving the long object in a horizontal attitude along a horizontal direction to be close to the opening or to be away from the opening in the interior space, an attitude change step of changing an attitude of the long object between the horizontal attitude and a vertical attitude vertically above the opening in the interior space, and a lifting/lowering step of lifting/lowering the long object in the vertical attitude while hanging the long object from the jig.

Method for lifting a wind turbine component The present invention relates to a method for lifting a wind turbine component, such as a rotor blade (2), gearbox or a rotor, with a lifting yoke (10) comprising a first structural body (20) comprising a crane hook attachment point (21), a first connection point (22) and a second connection point (23), a second structural body (30) comprising a third connection point (31) and a fourth connection point (32). First and second tensional elements (24, 25) such as slings or wires, are connected to the connection points, the length of the second tensional element being variable. An inertial measurement unit (40) determines the angle of the second structural body to the horizontal and the angle of the second tensional element is determined by an angle sensor. The distance (D) from the fourth connection point to the intersection between an axis (V) extending vertically through the center of gravity of the wind turbine component and the lifting plane is determined and provided to a crane operator. The invention also concerns a corresponding yoke.