A power transmission device that transmits a rotational driving force outputted from a driving source to a target device to be driven includes: a driving rotor rotated by the rotational driving force; a driven rotor that rotates with a rotary shaft of the target device; and a connection member. The connection member has a plate shape extending perpendicular to the rotary shaft. The connection member is connected at least one of the driving rotor and the driven rotor, and is capable of connecting the driving rotor and the driven rotor to each other. The connection member has a through hole, and the driven rotor has an overlapping portion disposed overlapping with the through hole when viewed in the axial direction of the rotary shaft.

A thermal fuse is covered with a case that has a slit. A capacity of the case is larger than a volume of the thermal fuse, and the case has a space that is formed between an inner wall surface of the case and the thermal fuse. The slit is formed in the case introduce radiant heat, which is generated at a friction surface of a rotor, into an inside of the case. Thereby, the radiant heat, which is inputted into the inside of the case through the slit, can be reflected by the inner wall surface of the case and thereafter can he absorbed by the thermal fuse.

A device for securing an attachment to a coupler. The device includes: a retention pin defining an elongate direction and configured to be disposed on the coupler, where, to secure the coupler to the attachment, the pin can move in the elongate direction to insert a first end, of the retention pin, into an opening in the attachment; and a thermoactuator including: a chamber associated with the coupler and containing a material that changes volume with temperature, where an end of the chamber is sealed with a piston that is mechanically connected to the retention pin proximate to a second end of the pin, the second end being disposed opposite the first end; and an electric temperature-altering device that, when activated, changes the temperature and volume of the material causing the piston to exert a force on the pin that moves the pin relative to the opening in the attachment.

A device for securing an attachment to a coupler. The device includes: a retention pin defining an elongate direction and configured to be disposed on the coupler, where, to secure the coupler to the attachment, the pin can move in the elongate direction to insert a first end, of the retention pin, into an opening in the attachment; and a thermoactuator including: a chamber associated with the coupler and containing a material that changes volume with temperature, where an end of the chamber is sealed with a piston that is mechanically connected to the retention pin proximate to a second end of the pin, the second end being disposed opposite the first end; and an electric temperature-altering device that, when activated, changes the temperature and volume of the material causing the piston to exert a force on the pin that moves the pin relative to the opening in the attachment.

A thermal disconnect assembly for an integrated drive generator includes an input shaft, an output shaft, a eutectic solder, and a disconnect clutch. The input shaft is driven by an external mechanical source. The output shaft is coupled to the input shaft through a disconnect clutch in a coupled state, is driven by the input shaft and rotates with the input shaft in the coupled state. The eutectic solder is configured to hold the output shaft in the coupled state and melt upon reaching a threshold temperature. The disconnect clutch is configured to urge the output shaft toward a decoupled state upon melting of the eutectic solder such that the output shaft does not rotate with the input shaft in the decoupled state.

A thermal disconnect assembly for an integrated drive generator includes an input shaft, an output shaft, a eutectic solder, and a disconnect clutch. The input shaft is driven by an external mechanical source. The output shaft is coupled to the input shaft through a disconnect clutch in a coupled state, is driven by the input shaft and rotates with the input shaft in the coupled state. The eutectic solder is configured to hold the output shaft in the coupled state and melt upon reaching a threshold temperature. The disconnect clutch is configured to urge the output shaft toward a decoupled state upon melting of the eutectic solder such that the output shaft does not rotate with the input shaft in the decoupled state.

A disconnector system for disconnecting a drive shaft of a drive mechanism from rotating equipment, upon a failure of the drive mechanism or rotating equipment, includes a disconnector mechanism having a disconnector shaft disposed in a casing and moveable relative thereto, between a first position and a second position, and a cam surface on a distal end of the arm configured to engage a slidable coupler. The movement of the disconnector shaft can be triggered by an operation of a solenoid, or by a displacement of the solenoid responsive to a melting of a meltable element.

A disconnector system for disconnecting a drive shaft of a drive mechanism from rotating equipment, upon a failure of the drive mechanism or rotating equipment, includes a disconnector mechanism having a disconnector shaft disposed in a casing and moveable relative thereto, between a first position and a second position, and a cam surface on a distal end of the arm configured to engage a slidable coupler. The movement of the disconnector shaft can be triggered by an operation of a solenoid, or by a displacement of the solenoid responsive to a melting of a meltable element.

A drive shaft assembly includes an outer shaft, an inner shaft, and an interface medium. The outer shaft defines a central channel. The inner shaft extends into the central channel and defines a clearance gap between an interior surface of the outer shaft and an exterior surface of the inner shaft. The interface medium is disposed in the clearance gap and rotationally couples the outer shaft and the inner shaft in an operational state of the drive shaft assembly. In response to a temperature of the drive shaft assembly exceeding a threshold temperature, the interface medium at least partially melts and rotationally uncouples the outer shaft and the inner shaft in a fault state of the drive shaft assembly.

A drive shaft assembly includes an outer shaft, an inner shaft, and an interface medium. The outer shaft defines a central channel. The inner shaft extends into the central channel and defines a clearance gap between an interior surface of the outer shaft and an exterior surface of the inner shaft. The interface medium is disposed in the clearance gap and rotationally couples the outer shaft and the inner shaft in an operational state of the drive shaft assembly. In response to a temperature of the drive shaft assembly exceeding a threshold temperature, the interface medium at least partially melts and rotationally uncouples the outer shaft and the inner shaft in a fault state of the drive shaft assembly.