Provided are a buoyant body disposed in a water tank, floating in water, and configured to ascend by water being, injected and descend by water being drained, a variable capacity tank having a changeable filling capacity of air put inside, a weight placed on an upper part of the variable capacity tank in order to exhaust air in the variable capacity tank, and a generator configured to generate power by rotating a turbine with the air exhausted from the variable capacity tank, in which the upper part of the variable capacity tank is configured to be pulled up by a motion conversion device to take air inside when the buoyant body ascends by the water being injected, and the air exhausted from the variable capacity tank by a weight of the weight is utilized for a rotation of the turbine of the generator to generate power.

A collapsible wind turbine includes a turbine with a vertical axis (A). The turbine is supported by a vertical pylon, pivotably mounted about a hinge, and by linking members connecting the rotation shaft of the turbine to the pylon while maintaining a separation therebetween. The wind turbine includes: —an electricity generator of which the axis of rotation is perpendicular to the longitudinal axis of the pylon, the generator being secured to the ground; and—at least one flexible link connecting and synchronising the rotation of the generator with the rotation shaft of the turbine by linear travel of the flexible link in a closed-circuit path, so as to drive the rotation shaft of the generator by the movement of the turbine. The present structure is, in particular related to land-based wind turbines in a cyclone-prone area.

A method and a device for measuring the torque in the drivetrain (1) of a wind power plant is described, having at least two incremental encoders (7, 8) which are positioned at two different positions on at least one shaft (3) of the drivetrain (1) and which each supply periodic rotational signals, wherein the phases of the rotational signals are evaluated in order to detect a phase shift, and a torque of the shaft (1) is determined from the phase shift. The detected phase shift is corrected as a function of a zero load phase shift (A.sub.Zero), using a rigidity factor K, wherein, in order to determine the zero load phase shift (A.sub.Zero) and the rigidity factor K, in-situ calibration is carried out before and/or between the torque-determining processes. The in-situ calibration is performed at zero load of the wind power plant, i.e. below a rated rotational speed and with a generator torque equal to zero, and at the rated load of the wind power plant, i.e. at the rated rotational speed and with a generator torque greater than zero.

A wind turbine drive train component (22) comprising a rotating shaft (61) with a radial seal (50) is provided. The radial seal (50) comprises a stationary part and a rotating part. The stationary part comprises a ring (51) with an inner edge and an outer edge, the inner edge being configured for contactlessly surrounding the shaft (61). The rotary part comprising a disc (52), coaxially connected to the shaft (61) for rotation therewith and comprising a flange (53) that wraps around the outer edge of the ring (51). The radial seal (50) further comprises an annular air lock gap (55) for containing an amount of lubrication fluid (64) and thereby closing off the air lock gap (55) when the rotary part rotates at a rotational speed above a predetermined threshold speed, the annular air lock gap (55) being formed by an inner surface of the flange (53), an outer part of the opposing parallel surface of the disc (52) and the outer edge of the ring (51).

The present invention provides a power generation system installed in a river, a channel, a coast, a windy place, or the like to thereby enable power generation using a natural energy such as hydraulic power, wind power, or the like.

The power generation system 1 of the present invention comprises a turbine 2, a cam wheel device 6, a power generator 7, and an arm mechanism 8. The turbine 2 comprises a rotating shaft 11 that rotates by the application of hydraulic power or wind power. In the cam wheel device 6, the torque of the rotating shaft 11 is transmitted to the cam wheel 18, thereby rotating the cam wheel 18. The power generator 7 can generate power by converting the rotational energy of the rotating shaft 28, which is generated as the rotating shaft 28 rotates with the rotation of the drive wheel 29, to electric energy. When the cams 21 come in contact with the arm mechanism 8 with the rotation of the cam wheel 18, a rotary motion is generated in the arm mechanism 8. This rotary motion brings the arm mechanism 8 in contact with the drive wheel 29, thereby rotating the drive wheel 29.

A wind turbine includes a main shaft rotatable around a rotation axis. The main shaft includes a first piece axially extending along the rotation axis, at least a second piece axially extending along the rotation axis, the second piece being axially adjacent to the first piece, a plurality of connections for fixing the second piece to the first piece.

The present invention relates to a device for transferring a continuous rotary motion, characterized in that said device comprises one crankshaft unit (4, 14) at each of the two ends thereof, said units each comprising one crankshaft (5, 15) having at least three crank offsets (1, 2, 3, 11, 12, 13) distributed uniformly about the axis of the corresponding crankshaft (5, 15) with respect to the angular range from 0 to 360, wherein the crankpins of opposing crank offsets (1, 11, 2, 12, 3, 13) of the crankshafts (5, 15) of the two crankshaft units (4, 14) are connected to each other by a rope or cable (8, 9, 10), and to the use of such a device for transferring a rotary motion in a bicycle or in a wind power plant.

A planetary transmission includes a ring gear holder and a ring gear for accommodating at least one planetary gear. The ring gear holder can be connected to a housing component at its end face, and a plurality of recesses for accommodating fastening means are embodied at an end face of the ring gear holder. Accommodated in at least one of the recesses is a hollow element, in which a fastening screw is accommodated. The hollow element establishes a positive-fit engagement between the ring gear holder and the housing component.

A powertrain component (21, 22, 23) for a wind turbine (100) is provided, comprising a powertrain component housing (20) with at least one rotating part (49) and a dry sump 5 lubrication system for lubricating the rotating part (49). The lubrication system comprises a dry sump lubricant tank (51, 52, 53) and a pump (60) for pumping the lubricant from the tank (51, 52, 53) towards a lubricant release point, the lubricant release point being provided at a level above at least part of the rotating part (49) for receiving the lubricant from the tank (51, 52, 53) and allowing the lubricant to lubricate the rotating part (49). 10 The tank (51, 52, 53) is integrated in or directly attached to the powertrain component housing (20) at a level below the at least one rotating part (49).

Wind-driven energy converting device (2) is disclosed. The wind-driven energy converting device (2) comprises a main pendulum (20) comprising a pendulum bob (10) attached to a pendulum rod (6). A sail member (4) attached to the pendulum rod (6) in a higher position than the pendulum rod (6). The main pendulum (20) is suspended in a frame (8) by means of a bearing unit (18) allowing the pendulum rod (6) to be rotated about two perpendicular horizontal axes (X, Y) at the same time. The main pendulum (20) is mechanically attached to at least one secondary pendulum (14) by means of a connection structure (16). The secondary pendulum (14) is connected to and being configured to rotate a driving shaft (36) upon being moved due to motion of the main pendulum (20).