A sealing arrangement is provided between inner and outer coaxial ring-shaped walls of an aircraft engine. The outer wall has an axial end with a U-shaped cross-section parallel to axis, the opening therein being oriented axially in a first direction. The inner wall has an axial end with a U-shaped cross-section parallel to axis, the opening therein being oriented axially in the opposite direction. The U-shaped end of the outer wall includes a ring-shaped free edge axially engaged in the opening in the axial end of the inner wall. The U-shaped end of the inner wall includes a ring-shaped free edge axially engaged in the opening in the axial end of the outer wall. The walls define therebetween a ring-shaped gas channel having a substantially S-shaped axial cross-section.

A safe control method and a safe control system for performing control relative to an authorized flight envelope of an aircraft. The aircraft includes a digital main measurement system for measuring flight characteristics of the aircraft, a flight control system for automatically piloting the aircraft, and said safe control system. The safe control system includes an analog backup measurement system that delivers at least one analog signal that is a function of the at least one flight characteristic, and a switch-over device that is configured so that the flight control system uses the at least one analog signal delivered by the backup measurement system for automatically piloting the aircraft whenever at least one flight characteristic of the aircraft exceeds a predetermined limit of the authorized flight envelope.

A method of generating a momentum change in a vehicle by phase changing matter in a closed system is used to change the momentum of the vehicle without the need of a combustion system for propulsion. The method uses the multi-phase dynamics of fluidic matter to create a momentum differential within a closed system that results in a momentum excess that changes the overall momentum of the system. The change of the overall momentum of the system results in a change in motion of the vehicle. The momentum differential is achieved by phase changing the fluidic matter moving through a heat exchanger. The phase change of the fluidic matter is arranged so that the momentum of the fluidic matter is reduced as the fluidic matter leaves the heat exchanger. The reduction in momentum of the fluidic matter results in the momentum differential that changes the overall momentum of the system.

A motor (more-broadly, induction device) is based around stacked rotor and stator boards rather than coils. The advance is analogous to using circuit boards rather than wires. Distinct advantages exist when the circuit board motor embodiment is combined with a novel open-burner combustor to form a hybrid electric-fuel jet engine (a culmination of three embodiments). The preferred application of the hybrid fuel-electric engine is in highly efficient (high lift-to-drag) aircraft utilizing towed platforms having high surfaces areas for both generating lift and collecting solar energy. The final combination yields advantages for an aerial platform towed via a front hinge joint that enables both vertical takeoff/landing and advantageous failsafe landing options. The aircraft is preferably powered by the hybrid electric-fuel jet engine.

A feed-through assembly for a bulkhead for moving and static engine components. The feed-through assembly can be configured to include flexible convolutions that allow for movement and sealing of the engine component relative to the bulkhead. In one aspect, a flexible convoluted spherical element can be provided in the feed-through assembly. In another aspect, a flexible convoluted bellow element can be provided in the feed-through assembly. These flexible convoluted elements can have multiple convolution sections including convolution sections with varying stiffness. The convolution sections can be configured to allow movement of the shaft relative to the bulkhead, including, transverse deflection and tilt.

A feed-through assembly for a bulkhead for moving and static engine components. The feed-through assembly can be configured to include flexible convolutions that allow for movement and sealing of the engine component relative to the bulkhead. In one aspect, a flexible convoluted spherical element can be provided in the feed-through assembly. In another aspect, a flexible convoluted bellow element can be provided in the feed-through assembly. These flexible convoluted elements can have multiple convolution sections including convolution sections with varying stiffness. The convolution sections can be configured to allow movement of the shaft relative to the bulkhead, including, transverse deflection and tilt.

A gyroplane employing torque compensated main rotor and hybrid power train is disclosed. The invention incorporates a torque-compensated main rotor system with a common Collective pitch control, which can be driven transiently during flight to allow Vertical Take-Off, Landing and Hovering (VTOLH) flight operations. Torque compensation is via a coaxial counter-rotating (CACR) rotor system, or alternatively using a single rotor in conjunction with one or more electronically-controlled, fixed-pitch, thruster motors. The use of electric motors for lift and torque compensation facilitates electronic and potentially autonomous control of all phases of vertical flight.

Mounting support assemblies for fire and overheat detection systems are described. The mounting support assemblies include a support tube connector having a first portion and a second portion, wherein a captive space is defined between the first portion and the second portion, a fastener arranged at least partially within the captive space and passing through the first portion of the support tube connector, and a biasing element arranged about the fastener and positioned between an end of the fastener and the first portion of the support tube connector, the biasing element biasing the fastener in a direction toward the second portion.

An aircraft equipped with a distributed fan propulsion system and methods of operating such aircraft are provided. In one aspect, an aircraft includes a wing having a top surface and a bottom surface. The aircraft also has a distributed propulsion system that includes a suction fan array having one or more fans mounted to the wing and a pressure fan array having one or more fans mounted to the wing. The fans of the suction fan array are each positioned primarily above the top surface of the wing and the fans of the pressure fan array are each positioned primarily below the bottom surface of the wing. The fans of the suction fan array are controllable independent of the fans of the pressure fan array so that the air pressure above and/or below the wing can be locally controlled, allowing for adjustment of lift on the wing.

A flow path duct system for a propulsion system of an aircraft includes a base defining a flow surface. The base has an internal surface and an external surface. A plurality of perforations are formed through the base between the internal surface and the external surface. A plurality of supports define a plurality of cavities. The plurality of supports extend outwardly from the external surface of the of the base. One or more of the plurality of cavities are in fluid communication with the one or more of the plurality of perforations. A backing surface is secured to the plurality of supports. The plurality of supports are disposed between the base and the backing surface. The one or more of the plurality of cavities are in fluid communication with an internal volume defined by the internal surface of the base through the one or more of the plurality of perforations. The base, the plurality of supports, and the backing surface can be integrally formed together as a monolithic, load-bearing structure.