A rotary device assembly is provided and includes an input shaft coupled to a torque generating device, an output shaft and a rotary device disposed to transmit first torque from the input shaft to the output shaft and configured with no-back capability to prevent second torque applied to the output shaft from being transmitted to the input shaft in an event the second torque deceeds a torque-limiting threshold and the no-back capability and torsional lock-up capability to prevent an overload of the torque generating device in an event the second torque exceeds the torque-limiting threshold.

Systems and methods for aircraft flight control rigging are described. An example system includes a first set of laser rangefinders to measure, for each laser rangefinder of the first set, a distance from the laser rangefinder to a respective target location on a fixed surface of an aircraft, and a second set of laser rangefinders to measure, for each laser rangefinder of the second set, a distance to a respective target location on a control surface of the aircraft. The example system also includes a processor to (i) receive signals indicative of the distance measured by each rangefinder and (ii) generate a first plot line graphic of the measured distances of each of the rangefinders of the first set to its respective target location and a second plot line graphic of the measured distances of each of the laser rangefinders of the second set to its respective target location.

There is provided a dual rack and pinion rotational inerter system for damping movement of a flight control surface of an aircraft having a support structure. The system has a flexible holding structure disposed between the flight control surface and the support structure. The system has a dual rack and pinion assembly held by the flexible holding structure. The system has a first terminal and a second terminal, coupled to the dual rack and pinion assembly. The first terminal is coupled to the flight control surface. The system has a pair of inertia wheels coupled to the flexible holding structure. The system has an axle element inserted through the inertia wheels, the flexible holding structure, and the dual rack and pinion assembly, such that when the flight control surface rotates, the dual rack and pinion rotational inerter system translates and rotates, and movement of the flight control surface is dampened.

There is provided a dual rack and pinion rotational inerter system for damping movement of a flight control surface of an aircraft having a support structure. The system has a flexible holding structure disposed between the flight control surface and the support structure. The system has a dual rack and pinion assembly held by the flexible holding structure. The system has a first terminal and a second terminal, coupled to the dual rack and pinion assembly. The first terminal is coupled to the flight control surface. The system has a pair of inertia wheels coupled to the flexible holding structure. The system has an axle element inserted through the inertia wheels, the flexible holding structure, and the dual rack and pinion assembly, such that when the flight control surface rotates, the dual rack and pinion rotational inerter system translates and rotates, and movement of the flight control surface is dampened.

An aileron counterbalance or aircraft spade apparatus disposed to afford optimal drag force, which particularly enhances the capability of an aircraft to spin, turn and dive more quickly and efficiently in aircraft races. The aircraft spade apparatus includes a rectangular shape and which exhibits a greater surface area and higher drag force characteristics.

An aileron counterbalance or aircraft spade apparatus disposed to afford optimal drag force, which particularly enhances the capability of an aircraft to spin, turn and dive more quickly and efficiently in aircraft races. The aircraft spade apparatus includes a rectangular shape and which exhibits a greater surface area and higher drag force characteristics.

An aerodynamic structure for an aircraft including a first region having a first magnetic sealing surface, movably connected to a second region having a second magnetic sealing surface. The structure is moveable between a first configuration in which the first sealing surface contacts the second sealing surface such that the first region and the second region form a continuous aerodynamic surface, and a second configuration in which a gap exists between the first and second magnetic sealing surfaces and. The magnetic sealing surfaces are configured such that an attractive magnetic force exists between the magnetic sealing surfaces in the first configuration. The aerodynamic structure is configured such that during movement between the first and second configurations, relative movement of the first and second regions occurs along a direction at an angle in the range 1-90? to the normal of the first sealing surface and/or the second sealing surface.

An aerodynamic structure for an aircraft including a first region having a first magnetic sealing surface, movably connected to a second region having a second magnetic sealing surface. The structure is moveable between a first configuration in which the first sealing surface contacts the second sealing surface such that the first region and the second region form a continuous aerodynamic surface, and a second configuration in which a gap exists between the first and second magnetic sealing surfaces and. The magnetic sealing surfaces are configured such that an attractive magnetic force exists between the magnetic sealing surfaces in the first configuration. The aerodynamic structure is configured such that during movement between the first and second configurations, relative movement of the first and second regions occurs along a direction at an angle in the range 1-90? to the normal of the first sealing surface and/or the second sealing surface.

There is provided a dual rack and pinion rotational inerter system for damping movement of a flight control surface of an aircraft. The system has a flexible holding structure disposed between the flight control surface and a support structure of the aircraft. The system has a dual rack and pinion assembly held by and between the flexible holding structure. The dual rack and pinion assembly has a first rack, a second rack, and a pinion engaged to and between the racks. The system has a first terminal coupled to the first rack and coupled to the flight control surface, via a pivot element, and a second terminal coupled to the second rack, and coupled to the support structure. The system has a pair of inertia wheels adjacent the flexible holding structure. The system has an axle element inserted through the inertial wheels, the flexible holding structure, and the pinion.

There is provided a dual rack and pinion rotational inerter system for damping movement of a flight control surface of an aircraft. The system has a flexible holding structure disposed between the flight control surface and a support structure of the aircraft. The system has a dual rack and pinion assembly held by and between the flexible holding structure. The dual rack and pinion assembly has a first rack, a second rack, and a pinion engaged to and between the racks. The system has a first terminal coupled to the first rack and coupled to the flight control surface, via a pivot element, and a second terminal coupled to the second rack, and coupled to the support structure. The system has a pair of inertia wheels adjacent the flexible holding structure. The system has an axle element inserted through the inertial wheels, the flexible holding structure, and the pinion.