A wing drop fuel tank it is provided comprising a rigid external casing 1 and a second tank 2 arranged inside said rigid casing 1, said second tank 2 being made of flexible material. A production process of said wing drop tank it is also provided which comprises the following steps: construction of two rigid half-shells 10 and 11, and the subsequent mutual coupling of the former creates a single rigid structure 1; making of a first port and a second port at the upper part of the half-shell 10, said second port having same size of a fuel filling flange 23 on said tank 1; inserting of a second tank 2 made of a flexible material through said first port in said first tank 1; and applying a closing plate 12 at said upper port, said closing plate 12 being removably locked on said tank 1 by means of clamping screws 13 which engage with threaded holes 22 made on a flange 21 integral with said second tank 2.

A tiltrotor aircraft has a vertical takeoff and landing flight mode and a forward flight mode. The aircraft includes an airframe having at least one wing. First and second oppositely disposed booms extend longitudinally from the at least one wing. Forward rotors are coupled to the forward ends of the booms and aft rotors are coupled to the aft ends of the booms. The forward rotors are reversibly tiltable between a vertical lift orientation, wherein the forward rotors are above the booms, and a forward thrust orientation, wherein the forward rotors are forward of the booms. The aft rotors are reversibly tiltable between a vertical lift orientation, wherein the aft rotors are below the booms, and a forward thrust orientation, wherein the aft rotors are aft of the booms.

There is provided a composite structure for an aerodynamic component having an aerofoil-like cross-section and a leading edge, the composite structure being in the form of a torsion box arrangement made from composite materials and having a core, the torsion box having a forward wall, an aft wall, a top wall and a bottom wall, together defining the core, the front wall being formed as the leading edge of the aerodynamic component. Also provided is a load-bearing composite structure for use with an aerodynamic component and configured for supporting at least one external load, this composite structure being made from composite materials and configured for being joined to the external aerodynamic surface of the aerodynamic component such as to be in overlying abutting relationship with at least a contact surface portion of the external aerodynamic surface, including the leading edge, at least a forward portion of each of the suction surface and the pressure surface thereof.

A fuel tank comprises an interior wall, a sump, and a baffle that comprises a center fitting, a full-length containment petal, a partial-length containment petal, a dump tube. The full-length containment petal comprises a full-length side edge, extending radially outward from the center fitting. The partial-length containment petal comprises a partial-length side edge, extending radially outward from the center fitting. The dump tube is connected to the sump. The full-length side edge of the full-length containment petal is longer than the partial-length side edge of the partial-length containment petal. All of the partial-length side edge of the partial-length containment petal is attached to a linear portion of the full-length side edge of the full-length containment petal.

A vertical-takeoff-and-landing (“VTOL”) aircraft including a non-VTOL aircraft equipped for forward takeoff and flight and a modular boom system interoperably coupled to the non-VTOL aircraft. The modular boom system includes a first modular boom and a second modular boom. The first modular boom includes a first rocket-turbine engine. The first modular boom is mounted to a first wing of the non-VTOL aircraft. The second modular boom includes a second rocket-turbine engine. The second modular boom is mounted to a second wing of the non-VTOL aircraft.

A vertical-takeoff-and-landing (“VTOL”) aircraft including a non-VTOL aircraft equipped for forward takeoff and flight and a modular boom system interoperably coupled to the non-VTOL aircraft. The modular boom system includes a first modular boom and a second modular boom. The first modular boom includes a first rocket-turbine engine. The first modular boom is mounted to a first wing of the non-VTOL aircraft. The second modular boom includes a second rocket-turbine engine. The second modular boom is mounted to a second wing of the non-VTOL aircraft.

An aerodynamic braking device for a payload casing intended to be ejected from a projectile on its trajectory including at least one parachute connected to the casing by hangers, the parachute and the parachute hangers being housed in a sleeve. The sleeve is wound around an axis of winding perpendicular to its longitudinal direction and attached to a cylindrical housing the axis of which is parallel to the axis of winding, which housing is itself secured to a shell base that closes off the projectile, the hangers being connected to the casing by an extension cable which is wound around the axis of the housing and attached thereto by at least three peripheral break lines which are uniformly angularly distributed.

A wing drop fuel tank it is provided comprising a rigid external casing 1 and a second tank 2 arranged inside said rigid casing 1, said second tank 2 being made of flexible material. A production process of said wing drop tank it is also provided which comprises the following steps: construction of two rigid half-shells 10 and 11, and the subsequent mutual coupling of the former creates a single rigid structure 1; making of a first port and a second port at the upper part of the half-shell 10, said second port having same size of a fuel filling flange 23 on said tank 1; inserting of a second tank 2 made of a flexible material through said first port in said first tank 1; and applying a closing plate 12 at said upper port, said closing plate 12 being removably locked on said tank 1 by means of clamping screws 13 which engage with threaded holes 22 made on a flange 21 integral with said second tank 2.

A wing drop fuel tank it is provided comprising a rigid external casing 1 and a second tank 2 arranged inside said rigid casing 1, said second tank 2 being made of flexible material. A production process of said wing drop tank it is also provided which comprises the following steps: construction of two rigid half-shells 10 and 11, and the subsequent mutual coupling of the former creates a single rigid structure 1; making of a first port and a second port at the upper part of the half-shell 10, said second port having same size of a fuel filling flange 23 on said tank 1; inserting of a second tank 2 made of a flexible material through said first port in said first tank 1; and applying a closing plate 12 at said upper port, said closing plate 12 being removably locked on said tank 1 by means of clamping screws 13 which engage with threaded holes 22 made on a flange 21 integral with said second tank 2.

In an example, a drop tank for an aerial vehicle includes a body having an internal fuel reservoir configured to store fuel. The drop tank also includes an outlet coupled to the internal fuel reservoir for supplying the fuel from the internal fuel reservoir to a propulsion system of the aerial vehicle. Additionally, the drop tank includes a plurality of flight control surfaces extending outwardly from the body. The flight control surfaces are actuatable to adjust a flight attitude of the drop tank. The drop tank further includes a flight control system including a processor and configured to actuate the plurality of flight control surfaces to fly the drop tank to a target location when the drop tank is jettisoned from the aerial vehicle.