An arrangement, including a gearbox, a generator, an intermediate shaft configured as a hollow shaft which is mounted at least partially in a housing of the gearbox, wherein a rotor of the generator is non-rotatably connected to the intermediate shaft and is supported by the intermediate shaft, and an intermediate piece arranged at least partially in the intermediate shaft. An output shaft of the gearbox is non-rotatably and detachably connected to the intermediate piece. The intermediate piece is non-rotatably and detachably connected to the intermediate shaft.

A wave energy conversion system is provided including a pod, multi-radius energy transmission mechanism, and an electrical generating device. The pod is rotatably supported by a platform structure and the multi-radius energy transmission mechanism is in mechanical communication with the pod. The multi-radius energy transmission mechanism is configured to transmit a variable torque over a range of motion and is in mechanical communication with the electrical generating device.

A wave energy conversion system is provided including a pod, multi-radius energy transmission mechanism, and an electrical generating device. The pod is rotatably supported by a platform structure and the multi-radius energy transmission mechanism is in mechanical communication with the pod. The multi-radius energy transmission mechanism is configured to transmit a variable torque over a range of motion and is in mechanical communication with the electrical generating device.

A power transmission system for a wind turbine includes a main shaft configured to be driven by the rotor about a main axis, a support structure including at least one bearing supporting the main shaft for rotation about the main axis, and a gearbox having a gearbox housing rigidly coupled to the support structure and a gearbox input member coupled to the main shaft. The gearbox housing supports the gearbox input member for rotation about the main axis, and the gearbox input member is coupled to the main shaft with a translational degree of freedom along the main axis and rotational degrees of freedom about axes perpendicular to the main axis. The main shaft is coupled to the gearbox input member by a flexible coupling positioned at least partially within the main shaft. The flexible coupling may be positioned entirely within the main shaft.

Provided is a power generation system capable of reducing an outer diameter of a wheel with which an arm mechanism is brought into contact after a rotational speed of a rotation body increases to a first value by applying a large torque to the rotation body until the rotational speed of the rotation body increases to the first value. A power generation system 1 of the present invention is a power generation system in which a cam member 7 is rotated by hydroelectric power or wind power to bring a cam 6 into contact with an arm mechanism 3 and to rotate the arm mechanism 3, and the arm mechanism 3 comes into contact with either of wheels 42 and 41 of a rotation body 44 during the rotation of the arm mechanism 3 to rotate the rotation body 44. The power generation system 1 includes operation control means for transitioning to an operation in a second mode in which the arm mechanism 3 is brought into contact with a small-diameter wheel 41 in response to an increase in a rotational speed of the rotation body 44 to a first value during an operation in the first mode in which the arm mechanism 3 is brought into contact with the large-diameter wheel 42, and transitioning to the operation in the first mode in response to a decrease in the rotational speed of the rotation body 44 to a second value during the operation in the second mode.

The present disclosure is related to a torque transmission system (203) for a slip ring unit (200) The slip ring unit (200) is configured for being mounted along a rotational axis (30) of the wind turbine rotor (18). The slip ring unit (200) comprises an encoder, a rotating part (201) configured for connection to a rotating component of the wind turbine and a static part (202) configured for connection to a static component of the wind turbine. The torque transmission system (203) is configured for connecting the rotating part (201) of the slip ring unit (200) to the rotating component of the wind turbine while having a degree of freedom in an axial and/or in a radial direction. Furthermore, the torque transmission system (203) is configured to prevent relative displacement between the rotating part (201) of the slip ring unit (200) and the rotating component of the wind turbine in a tangential direction. The present disclosure also relates to methods (100) of assembly of a slip ring unit (200) in a wind turbine.

An arrangement, including a gearbox, a generator, an intermediate shaft configured as a hollow shaft which is mounted at least partially in a housing of the gearbox, wherein a rotor of the generator is non-rotatably connected to the intermediate shaft and is supported by the intermediate shaft, and an intermediate piece arranged at least partially in the intermediate shaft. An output shaft of the gearbox is non-rotatably and detachably connected to the intermediate piece. The intermediate piece is non-rotatably and detachably connected to the intermediate shaft.

A wind-based power generation system includes a windmill having a wheel assembly, a gearbox coupled to the wheel assembly and configured to convert rotational motion of the wheel assembly into a reciprocal motion, and a shaft coupled to the gearbox and driven in a reciprocal motion. The wind-based power generation system also includes a crank system comprising a linkage and a pitman arm, the linkage and pitman arm configured to convert the reciprocal motion of the shaft into a rotational motion that drive a generator to produce electric power that may be used or stored.