The invention relates to an assembly (10) comprising a launch motor vehicle (12) and a drone (14), the launch motor vehicle (12) being capable of travelling on a launch track to exceed a given speed threshold relative to a surrounding air mass, the launch motor vehicle (12) being provided with a launch ramp (20) cooperating with the drone (14) to, in a launching position, guide the drone (14) from a starting position in a launch direction to the front of the launch motor vehicle (12). The drone (14) comprises one or more reactors (30) and does not comprise a landing gear.

Disclosed herein is an apparatus. An embodiment of the apparatus can include a turbine aerosol generator which comprises an aerosol generator. The aerosol generator can comprise a solution tank assembly to transport an aerosol solution for vaporization. The aerosol generator includes a motor device configured to vaporize the aerosol solution and expel the aerosol solution. Aerosol generator can also comprise an engine control unit in electrical communication with the motor device. The aerosol generator includes a transmitter assembly to communicate with other components. The apparatus can also include an unmanned aerial vehicle (UAV). The UAV can comprise a vehicle body that couples to the aerosol generator. The UAV comprises a power unit that provides flight and a vehicle computer. The apparatus further comprises a remote control device to communicate with other components. The apparatus also comprises a landing platform for fueling and/or recharge of the UAV and aerosol generator.

A drone includes a frame and a fuselage. The fuselage is coupled to the frame extending away from the frame. The fuselage has a front panel and a bottom panel, and the front panel is positioned at an angle between the bottom surface of the frame and the bottom panel of the fuselage. A first wing is opposite a second wing and are coupled to the frame. The first and second wings extend outwardly from opposite sides of the frame. A first and second mounting member are coupled to the frame and extend outwardly from opposite sides of the frame. A plurality of power generator systems are included and each system is coupled to the first or second mounting member. Each power generator system comprises a power source coupled to a propeller.

A self-propelled payload (SPP) for an aircraft, such as an unmanned aircraft. The SPP includes an independent propulsion unit which is configured to counter the effect of payloads of the aircraft. This improves operational effectiveness of the aircraft.

An aircraft propulsion system capable of improving power generation efficiency is provided. When a flight state of an aircraft is a first state after a plurality of engines operate and the aircraft takes off, the aircraft propulsion system causes at least one engine among the plurality of engines to be stopped, causes another engine, which has not been stopped, to be operated in an operating range in which the other engine is able to operate efficiently, and causes a generator corresponding to the other engine to output power.

A drone includes a frame and a fuselage. The fuselage is coupled to the frame extending away from the frame. The fuselage has a front panel and a bottom panel, and the front panel is positioned at an angle between the bottom surface of the frame and the bottom panel of the fuselage. A first wing is opposite a second wing and are coupled to the frame. The first and second wings extend outwardly from opposite sides of the frame. A first and second mounting member are coupled to the frame and extend outwardly from opposite sides of the frame. A plurality of power generator systems are included and each system is coupled to the first or second mounting member. Each power generator system comprises a power source coupled to a propeller.

An assembly is provided for a gas turbine engine. This gas turbine engine assembly includes a stationary engine structure. The stationary engine structure includes a diffuser, a combustor, an engine case and a plenum. The combustor is disposed within the plenum. The engine case forms a peripheral boundary of the plenum. A gas path extends sequentially through the diffuser, the plenum and the combustor. A first section of the stationary engine structure is formed as a first monolithic body. The first section includes the diffuser and the combustor. A second section of the stationary structure is formed as a second monolithic body. The second section is configured as or otherwise includes the engine case.

A stabilizing system for a cable has a cable deployed and suspended from a helicopter, a cargo support attached at a deployed end of the cable, an end effector attached to the cable, the end effector comprising thrusters directed in a plurality of directions orthogonal to a vertical axis of the cable, first control circuitry in the helicopter, and second control circuitry in the end effector. Thrust of individual thrusters is controlled through the first and second control circuitry maintaining the axis of the cable vertical, damping swinging of the cable.

A hot section of a gas turbine engine includes a stator housing wall and an at least one insulating standoff attached to the stator housing wall, extending radially away from the stator housing wall. The hot section includes an accessory module attached to an opposite end of the at least one insulating standoff away from the stator housing wall.

An unmanned aerial vehicle (UAV), comprising a fuselage outer shell defining a lateral axis, a longitudinal axis and a plurality of shell sides; fuselage center assembly positioned within a cavity defined by the fuselage outer shell; and a rotor arm and joint assembly. The plurality of the shell sides are concave with respect to the lateral axis or the longitudinal axis. The fuselage center assembly includes a lattice center defining a superior surface and an inferior surface as well as a plurality of channels, each channel having a proximal end and a distal end, wherein each proximal end is coupled to the superior surface and the inferior surface. The rotor arm has a proximal end and a distal end. A motor and rotor system is coupled to the distal end of the rotor arm. The rotor arm joint is coupled to the proximal end of the rotor arm, and the rotor arm joint further comprises an outer shell; and a plurality of quick release latches coupled to the outer shell and configured to coule the rotor arm joint to a plurality of corresponding latch receivers positioned.