An aircraft is provided and includes fuselage having a nose, a main section aft of the nose and a tail aft of the main section, an engine nacelle partially embedded in the tail and including a boundary layer ingestion (BLI) propulsor with an inlet directly adjacent to the fuselage and a nozzle element disposed upstream from the inlet and configured to accelerate boundary flows flowing toward the interior side of the engine nacelle.

There is disclosed an aircraft including a fuselage extending along a longitudinal axis; forward swept wings extending from the fuselage; at least one horizontal stabilizer secured to the fuselage; and a distributed electrical propulsion system operatively connected to an electrical power source. The distributed electrical propulsion system have an air intake located rearward of an intersection between the forward swept wings and the fuselage open to a boundary layer region on a surface of the fuselage.

An inlet for a nacelle and an AM system and method for manufacturing the inlet having fewer discontinuities on the exterior surface to achieve a smoother flow over the inlet. The inlet includes an annular lip-cowl and a supporting framework. The AM system includes a support structure providing a form, and AM heads for depositing materials onto the form, with the materials subsequently hardening to become the lip-cowl. The support structure may have an upright or inverted orientation, is rotatable, and may be tiltable. Components may protrude from the form to be incorporated into the lip-cowl. The AM heads are mounted on moveable arms and are computer-controlled to deposit the material onto the form, and may be moveable along a radial axis to accommodate an asymmetrical portion of the form. The AM system may further include one or more machining heads for subtractively machining the deposited material.

In order to further benefit from the principle of boundary layer ingestion by engines of an aircraft assembly, the rear portion of the fuselage of this aircraft assembly includes a front portion which splits up into at least two distinct rear portions, spaced apart from each other, and each integrating the rotary ring of the receiver of one of the engines.

An exemplary gas turbine engine includes a turbine section and a fan mechanically connected to the turbine section such that rotation of the turbine drives rotation of the fan. The fan includes a hub, a plurality of blade bodies extending radially outward from the hub to a first partial shroud, and a plurality of blade tips extending radially outward from the partial shroud.

An active laminar flow control arrangement may comprise a modular arrangement comprising a plurality of frames and cover panels coupled to an outer skin having a plurality of hat stiffeners and stringers. A first cover panel may be coupled between a first frame and a first hat stiffener. A second cover panel may be coupled between a second frame and a second hat stiffener. A third cover panel may be coupled between the first cover panel and the second cover panel. The cover panels may enclose associated plenums whereby a flow of air is pumped into the arrangement for maintaining a laminar flow across an aerodynamic surface of the outer skin.

A device for an aircraft powerplant de-icing system making it possible to reduce or eliminate a tonal noise generated by a flow of air along a surface having an orifice opening into a cavity extending on the side opposite this surface, the orifice having a downstream edge relative to the direction of flow of the air, includes a deflector positioned next to the downstream edge, extending towards the inside of the cavity, and oriented perpendicularly to the direction of flow of the air to divert towards the outside of the orifice vortices formed in the shear layer due to the flow of the air along the surface over each orifice. The deflector at the downstream edge of each exhaust orifice of the de-icing system makes it possible to redirect the vortices outside the cavity while preventing them from being greatly deformed when they pass over the downstream edge.

A nacelle defining an intake is provided for channelling and conditioning freestream airflow to a fan of a ducted fan gas turbine engine. The nacelle intake comprises in flow series an intake lip, and a diffuser. The intake lip has at its forwardmost end a highlight which is a closed loop defining a boundary between inner and outer surfaces of the nacelle, and the diffuser terminates at its rearwardmost end at a front face of the fan. The intake has a circumferentially extending shock control bump or a series of circumferentially spaced shock control bumps formed thereon. On longitudinal cross sections through the intake containing the bump or series of bumps: the bump or each bump of the series of bumps has a profile which forms in flow series an up-ramp, a maximum and a down-ramp, at least one of the up-ramp and the down-ramp forming an inflection point or curvature discontinuity point on the profile, and the inflection point or curvature discontinuity point being axially located between the highlight and a position which is axially rearward therefrom by a distance of no more than 0.6 L, where L is the axial distance between the highlight and the front fan face.

A panel for an active laminar flow control arrangement may comprise a longitudinal wall and one or more division walls extending from the longitudinal wall and extending between the first end and the second end. The panel may be coupled to a nacelle outer skin via a plurality of adhesive fasteners pre-installed onto an inner surface of the outer skin and onto stiffeners and/or stringers associated with the outer skin.

An active laminar flow control arrangement may comprise an outer skin having an inner surface, an outer surface, and a perforated area, and a panel coupled to the inner surface. The panel may comprise a longitudinal wall, a sidewall extending from the longitudinal wall, a ridge intersecting the sidewall, a cavity disposed in the panel and at least partially defined by the sidewall and the longitudinal wall, and a division wall disposed in the cavity and extending from the longitudinal wall, wherein the division wall divides the cavity into a first plenum and a second plenum. The longitudinal wall, the sidewall, the ridge, and the division wall may comprise a single, monolithic piece.