A propulsion system for an includes a combustion engine, a propulsor, and an electric machine configured to either be driven by the combustion engine or configured to drive the propulsor. The electric machine defines an axis. The electric machine includes a rotor extending along and rotatable about the axis, and a stator having a plurality of winding assemblies, the plurality of winding assemblies spaced along the axis of the electric machine, each winding assembly operable with the rotor independently of an adjacent winding assembly during operation of the electric machine.

A propulsion system for an includes a combustion engine, a propulsor, and an electric machine configured to either be driven by the combustion engine or configured to drive the propulsor. The electric machine defines an axis. The electric machine includes a rotor extending along and rotatable about the axis, and a stator having a plurality of winding assemblies, the plurality of winding assemblies spaced along the axis of the electric machine, each winding assembly operable with the rotor independently of an adjacent winding assembly during operation of the electric machine.

A propulsion system for an aircraft including a fuselage and a wing assembly. The propulsion system includes a first propulsion device at the level of the rear part of the fuselage and constituted of at least one BLI propulsion unit including a fan, a second propulsion device constituted of at least one conventional propulsion unit, and a transmission device coupling the first and second propulsion devices. The second propulsion system therefore generates the energy necessary for driving in rotation the fan of the BLI propulsion unit or units. The thrust produced by the propulsion devices contributes to generating the total thrust of the aircraft. In this propulsion system at least one conventional propulsion unit constituting the second propulsion device is situated on one side of the rear part of the fuselage between the tail of the fuselage and the wing assembly of the aircraft.

An aircraft comprising a fuselage and propelled by a turbine engine having two coaxial and contrarotating fans, the turbine engine comprising a power turbine having two contrarotating rotors, one of which drives a fan upstream from the turbine, the other a fan downstream from the turbine, each fan comprising a ring of blades, and the assembly of the fans and the power turbine being incorporated at the rear of the fuselage, in the extension of same. The aircraft comprises, for at least one of the fans, a device for blocking the rotation of the fan and a device configured to modify the pitch of the blades of the fan in such a way as to make it operate as a flow straightener with respect to the other fan.

An aircraft comprising a fuselage and propelled by a turbine engine having two coaxial and contrarotating fans, the turbine engine comprising a power turbine having two contrarotating rotors, one of which drives a fan upstream from the turbine, the other a fan downstream from the turbine, each fan comprising a ring of blades, and the assembly of the fans and the power turbine being incorporated at the rear of the fuselage, in the extension of same. The aircraft comprises, for at least one of the fans, a device for blocking the rotation of the fan and a device configured to modify the pitch of the blades of the fan in such a way as to make it operate as a flow straightener with respect to the other fan.

An apparatus configured with two subsystems comprising a torus tube, linear flow, and turboplant assemblies that form of cavity for externally supplied and rotating subsonic working fluid. The working fluid rotation is provided by turboplant assemblies with throttle control. The rotating working fluid inside the cavities will conserve angular momentum. As a result of the conservation of angular momentum, poinsot flow fields are seen within the working fluid. A stable, resultant force is generated from the pressure and area forces inside the cavity. The apparatus usage is either with manual operation or as an unmanned, autonomous vehicle.

An apparatus configured with two subsystems comprising a torus tube, linear flow, and turboplant assemblies that form of cavity for externally supplied and rotating subsonic working fluid. The working fluid rotation is provided by turboplant assemblies with throttle control. The rotating working fluid inside the cavities will conserve angular momentum. As a result of the conservation of angular momentum, poinsot flow fields are seen within the working fluid. A stable, resultant force is generated from the pressure and area forces inside the cavity. The apparatus usage is either with manual operation or as an unmanned, autonomous vehicle.

An aircraft propulsion assembly includes a first engine and a second engine that are adjacent and a nacelle in which the engines are installed. The nacelle includes a common air inlet lip for the first engine and the second engine, the air flow being divided between the first engine and the second engine by a median lip which extends, at least partly, set back from said common air inlet lip. The common are inlet lip includes, directly in line with the median lip, a bottom lobe and a top lobe extending forward of the nacelle. Such a configuration makes it possible to be able to provide a high aerodynamic form between the fairings of the engines, without the risk of generating overspeeds in the air flow.

An aircraft propulsion assembly includes a first engine and a second engine that are adjacent and a nacelle in which the engines are installed. The nacelle includes a common air inlet lip for the first engine and the second engine, the air flow being divided between the first engine and the second engine by a median lip which extends, at least partly, set back from said common air inlet lip. The common are inlet lip includes, directly in line with the median lip, a bottom lobe and a top lobe extending forward of the nacelle. Such a configuration makes it possible to be able to provide a high aerodynamic form between the fairings of the engines, without the risk of generating overspeeds in the air flow.

The invention relates to a method for detecting a malfunction in a first turboshaft engine, referred to as an inoperative engine (4), of a twin-engine helicopter, and for controlling a second turboshaft engine, referred to as a healthy engine (5), each engine (4, 5) comprising protective stops regulated by a regulation device which define a maximum power regime, characterised in that it comprises: a step (10) of detecting an indication of failure of said inoperative engine (4); a step (11) of modifying said protective stops of said healthy engine (5) into protective stops which correspond to a maximum power single-engine regime, in the case of the detected indication of failure; a step (12) of confirming a failure of said inoperative engine (4); a step (13) of controlling an increase in the flow rate of fuel supply of said healthy engine (5), in the event of a confirmed failure.