A nacelle for a wind turbine extends along a longitudinal axis between a front side where a wind rotor is rotatably attachable to the nacelle for rotating about the longitudinal axis and a longitudinally opposite rear side is provided. The nacelle includes an outer surface delimiting an inner volume of the nacelle, a cooling path for circulating a cooling flow in the inner volume. The nacelle further includes a pressure source for generating an overpressure inside the inner volume of the nacelle, the pressure source including an inlet at the outer surface for receiving the cooling flow and an outlet for delivering the cooling flow in the inner volume, at least one heat exchanger provided in the outer surface for receiving the cooling flow from the inner volume.

The present disclosure relates to fastener assemblies (400) for a wind turbine blade (22) to rotor hub (20) connection, wherein the fastener assembly (400) comprises a fastener (401) and one or more sleeves (410) configured to absorb the ingress of liquid into a blade root insert (220). The present disclosure also relates to wind turbine hub assemblies (1000) and associated methods (700).

Disclosed herein is a hydropower electric generator, in accordance with some embodiments. Accordingly, the hydropower electric generator may include a closed conduit. Further, the closed conduit may include a reservoir, a downward flow pipe, a horizontal pipe, an upward flow pipe. Further, the downward flow pipe may include a first turbine configured to intercept the downward flow of the water and generate rotational force. Further, the upward flow pipe may include an airlift assembly configured to receive compressed air into the upward flow pipe. Further, the upward flow pipe may include a second turbine configured to intercept an upward flow of the water and generate rotational force. Further, the hydropower electric generator may include an air pump configured to generate the compressed air based on electrical energy. Further, the hydropower electric generator may include an energy storage device.

Provided is a wind turbine cooling arrangement, including a first cooling circuit arranged to transport a fluid cooling medium to absorb heat from a first component group; and a second cooling circuit arranged to transport a fluid cooling medium to absorb heat from a second component group, which second cooling circuit includes a primary heat exchanger arranged to dissipate heat from the cooling medium of the second cooling circuit; and a secondary heat exchanger arranged to heat the cooling medium of the first cooling circuit. A wind turbine including a cooling arrangement, and a method of cooling components of a wind turbine is also provided.

A ventilation device for filtering air and for separating water aerosols from air may include at least one filter element, at least one housing, at least one fan, and at least one flow adapter. The filter element may be secured in the housing such that air is flowable through an inlet opening of the housing to an outlet opening of the housing in a flow direction. The fan may be secured on the outlet opening downstream of the housing in the flow direction. The flow adapter may be secured on the inlet opening upstream of the housing in the flow direction. A coupling frame may be secured in an airtight manner between the housing and the flow adapter. The coupling frame may include a discharge channel arrangement for draining water collected in the at least one filter element.

Disclosed is wind flow operated ventilation and energy harnessing device, comprising an L-shaped flow pipe (101/201) with one arm sweeping horizontally while the other rotatable on a stationary vertical pipe (102/202) connected with the space being ventilated. The open end of the horizontal portion is flared into collar (106) or bell-shaped mouth (206) forming evacuating or pressurizing flow pipe respectively. The direction changers (108/208) are used to maintain the back of collar (107) of flared portion (106) or open end (207) of bell-shaped mouth (206) facing upstream wind. The wind on striking the back of collar (107) or the open end (207) of bell-shaped mouth (206) creates evacuation or pressurization effect respectively for ventilation. A wind turbine fitted inside stationary vertical pipe harnesses energy.

A nacelle for a wind turbine extends along a longitudinal axis between a front side where a wind rotor is rotatably attachable to the nacelle for rotating about the longitudinal axis and a longitudinally opposite rear side is provided. The nacelle includes an outer surface delimiting an inner volume of the nacelle, a cooling path for circulating a cooling flow in the inner volume. The nacelle further includes a pressure source for generating an overpressure inside the inner volume of the nacelle, the pressure source including an inlet at the outer surface for receiving the cooling flow and an outlet for delivering the cooling flow in the inner volume, at least one heat exchanger provided in the outer surface for receiving the cooling flow from the inner volume.

A self-orienting gas evading intake for a submersible pump provides an efficient, reliable and inexpensive system for pumping a downhole fluid to a surface. An intake section of a submersible pumping system may comprise a blocker sleeve disposed between an external housing and an eccentric intake. The intake section may be self-orienting such that a gas component of the fluid ascends the borehole to separate from a liquid component of the fluid. Actuation of a blocker sleeve exposes one or more ports of the external housing while blocking one or more other ports. The liquid component is drawn into the intake section through an exposed port and through one or more openings of the eccentric intake. The liquid component may then be drawn into the pump. As the liquid component comprises non-detrimental amounts, if any, of a gas component, the pump operates efficiently and effectively.

An energy generator system is provided that is capable of capturing the transitory energy contained within the wind and converting it to a form of storable energy for later use in generating electricity. The energy generator system includes a compression system including an air compressor for compressing incoming air and a rotor for operating the compressor in response to the wind flowing over the rotor. An intake system is associated with the compression system and provides clean ambient air to the air compressor. The compression system and the intake system c contained in a wind tower having a head for supporting the rotor and an elongate pylon for positioning the rotor at a sufficient height to capture the energy of the wind. The natural energy system additionally includes a storage system for storing the compressed air produced by the air compressor.

A tower bottom cooling device for a wind turbine includes a tower and a heat sink configured to cool a heat generating component arranged at a bottom of the tower; a main air duct is provided inside the tower, and the heat sink is disposed inside the main air duct; a first fan is arranged in the main air duct, and is configured to drive air in the main air duct to flow to cool the heat sink; and the main air duct and an external environment of the tower together form an open cycle.