An arm-airframe connecting structure and an unmanned aerial vehicle are provided by embodiments of the present disclosure. The arm-airframe connecting structure is configured to movably connect an airframe and an arm, and the arm is switchable between an unfolded position and a housed position with respect to the airframe. The arm-airframe connecting structure includes: at least one arm matching part provided on the arm; and at least one airframe matching part provided on the airframe. The at least one arm matching part and the at least one airframe matching part are configured to be bonded with each other so as to maintain at least one of the unfolded position and the housed position of the arm with respect to the airframe.

An arm-airframe connecting structure and an unmanned aerial vehicle are provided by embodiments of the present disclosure. The arm-airframe connecting structure is configured to movably connect an airframe and an arm, and the arm is switchable between an unfolded position and a housed position with respect to the airframe. The arm-airframe connecting structure includes: at least one arm matching part provided on the arm; and at least one airframe matching part provided on the airframe. The at least one arm matching part and the at least one airframe matching part are configured to be bonded with each other so as to maintain at least one of the unfolded position and the housed position of the arm with respect to the airframe.

An aerial vehicle includes a hull containing the main processor, energy storage, support components such as sensors, wireless communication, and landing gear. Attached to the hull are at least three thrust or propulsion units each with two degrees of freedom from the hull allowing them to orient independently in any direction and apply thrust independently from the hull or any other thrust or propulsion unit. In some embodiments, a mount for auxiliary attachments is included or the auxiliary system is built into the hull. Components like the energy storage, auxiliary attachments, and/or propulsion units may also be replaceable as required.

An aerial vehicle includes a hull containing the main processor, energy storage, support components such as sensors, wireless communication, and landing gear. Attached to the hull are at least three thrust or propulsion units each with two degrees of freedom from the hull allowing them to orient independently in any direction and apply thrust independently from the hull or any other thrust or propulsion unit. In some embodiments, a mount for auxiliary attachments is included or the auxiliary system is built into the hull. Components like the energy storage, auxiliary attachments, and/or propulsion units may also be replaceable as required.

A compound rotorcraft comprises a fuselage, a rotor coupled to the fuselage and a wing mounted to the fuselage. The rotorcraft further comprising a first outboard propeller, a first inboard propeller, a second outboard propeller, and a second inboard propeller. The first outboard propeller having a propeller body and propeller blades, the body mounted to a first wing-half at a first incidence angle. The first inboard propeller having a propeller body and propeller blades, the body mounted to the first wing-half between the first outboard propeller and the fuselage at a second incidence angle. The second outboard propeller having a propeller body and propeller blades, the body mounted to a second wing-half at a third incidence angle. The second inboard propeller comprising a propeller body and propeller blades, the body mounted to a second wing-half between the second outboard propeller in the fuselage at a fourth incidence angle.

A compound rotorcraft comprises a fuselage, a rotor coupled to the fuselage and a wing mounted to the fuselage. The rotorcraft further comprising a first outboard propeller, a first inboard propeller, a second outboard propeller, and a second inboard propeller. The first outboard propeller having a propeller body and propeller blades, the body mounted to a first wing-half at a first incidence angle. The first inboard propeller having a propeller body and propeller blades, the body mounted to the first wing-half between the first outboard propeller and the fuselage at a second incidence angle. The second outboard propeller having a propeller body and propeller blades, the body mounted to a second wing-half at a third incidence angle. The second inboard propeller comprising a propeller body and propeller blades, the body mounted to a second wing-half between the second outboard propeller in the fuselage at a fourth incidence angle.

In a flying object, a PCU has a plurality of operation modes in which an engine and/or a motor generator is used as a driving source for a pusher propeller. In accordance with the state of the flying object, the PCU controls the engine, a first clutch, the motor generator, and a second clutch in one of the operation modes.

In a flying object, a PCU has a plurality of operation modes in which at least one of an engine, a first motor generator, and a second motor generator is used as a driving source for a pusher propeller. In accordance with the state of the flying object, the PCU controls the engine, the first motor generator, a clutch, and the second motor generator in one of the operation modes.

In a flying object, a PCU has a plurality of operation modes in which at least one of an engine, a first motor generator, and a second motor generator is used as a driving source for a pusher propeller. In accordance with the state of the flying object, the PCU controls the engine, the first motor generator, a clutch, and the second motor generator in one of the operation modes.

A novel crash-resistant aircraft includes a fuselage and an aircraft base connected together via a movable fastener, and said fuselage comprises a cockpit, a cabin and an empennage. The aircraft base comprises a belly hold cargo bay, a fuel tank, an undercarriage, a power unit and wings. The empennage is also connected to the tail end of said fuselage via a movable fastener. A crash-resistant propeller system capable of bringing said fuselage upward is set up at the top of said cabin, a crash-resistant recoil devices set up beneath said cabin. The crash-resistant aircraft also comprises a control system disposed in said cockpit, and when said aircraft is in an accident in midair, said control system releases said movable fastener to abandon said aircraft base and said empennage. Also disclosed is a crash-resistant operation method of the crash-resistant aircraft.