An aircraft, such as a rotary-wing aircraft, may be selectably fitted with power modules that may be installed in or removed from corresponding openings in the aircraft fuselage. The power modules may be interchangeable with other power modules, The power modules may utilize different technologies or thermodynamic cycles to generate power, including electrical batteries, fuel cells, a turbine powered generator, a reciprocating engine-powered generator, a turbine engine, a reciprocating engine, or other electrical or mechanical sources of power. The power modules may transfer electrical or mechanical power to the aircraft to maintain the aircraft in flight or to provide propulsion to the aircraft. An aircraft control system may detect the installed power modules and adjust inceptors and displays to correspond to the installed power modules.

An aircraft, such as a rotary-wing aircraft, may be selectably fitted with power modules that may be installed in or removed from corresponding openings in the aircraft fuselage. The power modules may be interchangeable with other power modules, The power modules may utilize different technologies or thermodynamic cycles to generate power, including electrical batteries, fuel cells, a turbine powered generator, a reciprocating engine-powered generator, a turbine engine, a reciprocating engine, or other electrical or mechanical sources of power. The power modules may transfer electrical or mechanical power to the aircraft to maintain the aircraft in flight or to provide propulsion to the aircraft. An aircraft control system may detect the installed power modules and adjust inceptors and displays to correspond to the installed power modules.

A propulsor fan array having reduced noise emission is disclosed. The propulsor fan array includes a plurality of propulsor fans that collectively generate thrust. Each of the propulsor fans include a blade fan having a plurality of blades. The plurality of blades are tensioned at tips of the plurality of blade fans such that a pitch of the blades during thrust generation is substantially the same as a pitch of the blades at rest. By tensioning the tips of the blades, an angle of the blades is maintained during operation of the propulsor fan thereby reducing noise that may result from changes in the angle of the blades.

A propulsor fan array having reduced noise emission is disclosed. The propulsor fan array includes a plurality of propulsor fans that collectively generate thrust. Each of the propulsor fans include a blade fan having a plurality of blades. The plurality of blades are tensioned at tips of the plurality of blade fans such that a pitch of the blades during thrust generation is substantially the same as a pitch of the blades at rest. By tensioning the tips of the blades, an angle of the blades is maintained during operation of the propulsor fan thereby reducing noise that may result from changes in the angle of the blades.

An aircraft includes an aircraft heat source; a propulsion system including an electric propulsion engine, the electric propulsion engine including an electric motor and a fan rotatable by the electric motor, the electric propulsion engine further defining a fan air flowpath; a thermal management system including a heat source exchanger in thermal communication with the aircraft heat source, a heat sink exchanger in thermal communication with the fan air flowpath of the electric propulsion engine, and a thermal distribution bus extending from the heat source exchanger to the heat sink exchanger; and a control system operably connected to the thermal management system for selectively thermally coupling the heat sink exchanger with the heat source exchanger.

An aircraft includes an aircraft heat source; a propulsion system including an electric propulsion engine, the electric propulsion engine including an electric motor and a fan rotatable by the electric motor, the electric propulsion engine further defining a fan air flowpath; a thermal management system including a heat source exchanger in thermal communication with the aircraft heat source, a heat sink exchanger in thermal communication with the fan air flowpath of the electric propulsion engine, and a thermal distribution bus extending from the heat source exchanger to the heat sink exchanger; and a control system operably connected to the thermal management system for selectively thermally coupling the heat sink exchanger with the heat source exchanger.

A propulsion system for an aircraft is provided that includes an electric generator, a compressor, an internal combustion (IC) engine, a turbine, an electric power storage unit, and an electric motor. The compressor is configured to selectively produce a flow of compressor air at an air pressure greater than an ambient air pressure. The IC engine is configured to selectively intake compressor air during operation and produce an exhaust gas flow during operation. The turbine, powered by exhaust gas flow, is in communication with and configured to power the compressor and the electric generator. The electric power storage unit is in communication with the electric generator. The electric motor is in communication with the IC engine. The electric motor is powered by the electrical power produced by the electric generator, and the electric motor is configured to selectively provide motive force to the IC engine.

The present disclosure provides a thermoelectric power system including one or more thermoelectric power devices for generating power. An example thermoelectric power device includes a thermoelectric generator, a first plate, and a second plate. A first side of the thermoelectric generator is at a higher temperature than a second, opposite, side of the thermoelectric generator. The first plate is disposed on the first side of the thermoelectric generator and includes a first surface coating that affects a heat absorption of the first plate. The second plate is disposed on the second side of the thermoelectric generator and includes a second surface coating that affects a heat absorption of the second plate.

The present disclosure provides a thermoelectric power system including one or more thermoelectric power devices for generating power. An example thermoelectric power device includes a thermoelectric generator, a first plate, and a second plate. A first side of the thermoelectric generator is at a higher temperature than a second, opposite, side of the thermoelectric generator. The first plate is disposed on the first side of the thermoelectric generator and includes a first surface coating that affects a heat absorption of the first plate. The second plate is disposed on the second side of the thermoelectric generator and includes a second surface coating that affects a heat absorption of the second plate.

Aspects described herein may relate to aerial structures such as aircraft. An aerial structure may include a fuselage, a wing attached to the fuselage, and a plurality of propulsion systems configured to generate thrust. A propulsion system may include a plurality of propulsors, such as propulsor fans. A propulsor fan may be configured to be actuated between a conventional take-off and landing (CTOL) flight mode, a short take-off and landing (STOL) flight mode, and a vertical take-off and landing (VTOL) flight mode.