Abstract: A passive control system can be implemented that converts an active control system on a multi-rotor unmanned aerial vehicle (UAV) to a passive control system. In the event that a system health of an active control system on the UAV is compromised, or in other instances, a passive control mechanism can be deployed to restore at least some in-flight stability. In various examples, the passive control system can monitor UAV attitude, velocity, and position to determine an active control system health. In other examples, the passive control system may receive an indication from the active control system itself. In some examples, the passive control mechanisms may include increasing an offset of a center of thrust and the center of gravity of the UAV. In other examples, the passive control mechanisms may include deploying control surfaces that induce a drag force that impedes translational and rotational movement.

Abstract: A stowage carousel for handling cargo aboard an aircraft is provided including a revolving conveyor having an inner ring facing a passenger cabin of the aircraft and an outer ring facing a fuselage of the aircraft. Stowage compartments are associated with the revolving conveyor. The stowage compartments are configured to receive the cargo. The stowage compartments are rotatable within the aircraft with the revolving conveyor. The revolving conveyor is situated within the aircraft partially in the passenger cabin and partially in at least one of an upper crown and a lower lobe of the aircraft.

Abstract: A battery containment pod including a body formed of a lightweight material. The body has an aerodynamic exterior shape and an interior cavity formed in the lightweight material, the size and shape of the interior cavity designed to accommodate one or more battery packs. A smooth exterior coating covers the exterior shape of the body, and an attachment structure formed in or on the body allows the body to be coupled to a flight vehicle. Other implementations are disclosed and claimed.

Abstract: A toggle assembly includes a first joint member having a first lug and a second lug, a second joint member, and a third joint member. The second joint member has a first arm that receives a first rolling element, a second arm that receives a second rolling element, a third arm, and a fourth arm. The second joint member is pivotally connected to the first joint member via a first pin that extends through the first lug, the first rolling element, the second rolling element, and the second lug. The third joint member has a third lug and a fourth lug disposed opposite the third lug. The third joint member is pivotally connected to the second joint member via a cross rod pin that extends through the third lug, the third arm and the fourth arm.

Abstract: A system and method for determining length of load sling assembly in an aircraft, includes receiving, with a processor, information via one or more sensors regarding a load length during a delivery and descent state, the load length comprising length of a load sling assembly and a load height; controlling, with the processor, a minimum altitude of operation of the aircraft that ensures that the load does not touch the ground or obstacles during one or more of a flight plan, during decent, or during delivery; determining, with the processor, when a load has touched a ground in response to the receiving of the load length information; and releasing, with the processor, the load from the load sling assembly when the processor determines that the load has touched the ground.

Abstract: Certain exemplary embodiments can provide a system, machine, device, manufacture, circuit, composition of matter, and/or user interface adapted for and/or resulting from, and/or a method and/or machine-readable medium comprising machine-implementable instructions for, activities that can comprise and/or relate to, providing a guided descent from a release zone and toward an entry zone.

Abstract: A method and apparatus for handling cargo. A cargo handling system may be positioned relative to the cargo. The cargo handling system may comprise a frame structure and an engagement system. The frame structure may be configured to change in a number of dimensions to encompass the cargo. The engagement system may be configured to engage the cargo. The number of dimensions of the frame structure may be adjusted to encompass the cargo. The cargo may be engaged with the engagement system.

Abstract: An unmanned aerial vehicle (UAV) is disclosed that includes a retractable payload delivery system. The payload delivery system can lower a payload to the ground using an assembly that secures the payload during descent and releases the payload upon reaching the ground. The assembly can also include a bystander communication module for generating cues for bystander perception. While the assembly securing the payload is being lowered from the UAV, the bystander communication module can generate an avoidance cue indicating that bystanders should avoid interference with the assembly. The assembly also includes sensors that generate data used, at least in part, to determine when the descending assembly is at or near the ground, at which point the assembly releases the payload. The bystander communication module can then cease the avoidance cue and the UAV can retract the assembly.

Abstract: An apparatus includes a multifunction shelf rotatably coupled to a chassis at one or more pivot points. The chassis includes a sub-chassis mounted in a first end of the chassis and connected to one or more connectors within the chassis. The multifunction shelf includes one or more first lever arms extending away from a pivot point. The multifunction shelf also includes one or more second lever arms, each second lever arm connecting to a first lever arm and extends in a direction at a first angle to the connected first lever arm. The multifunction shelf also includes one or more camming features each coupled to a second lever arm and the sub-chassis. Rotating the one or more first lever arms away from the chassis applies a force through each corresponding camming feature to the sub-chassis to disconnect the sub-chassis from the chassis.

Abstract: Methods and apparatus are disclosed for persistent deployment of aerial vehicles. The present application discloses a mission control system that is configured to control and manage one or more aerial vehicles for deployment to and from one or more docking stations. The one or more docking stations may be configured with a battery swapping device for removing the depleted battery from an aerial vehicle and for refilling a charged battery into the aerial vehicle. The mission control system may be configured to generate a priority list used to determine the recharging order of the one or more aerial vehicles.

Abstract: A method and apparatus for deploying a space structure. The space structure is secured to a base with release mechanisms that engage features of the space structure when the base is in a first position. The base is moved from the first position to a second position to deploy the space structure. The release mechanisms are moved at substantially a same time to disengage from the features and release the space structure from the base without imparting a transverse load to the space structure when the base moves from the first position towards the second position to deploy the space structure.

Abstract: A method to load stores on an aircraft, the method may be controlled by one or more controller and may include one or more acts of loading stores onto corresponding lift portions; determining a relative position of the aircraft; positioning the stores relative to the determined position of the aircraft; and securing the stores to corresponding hardpoints (HPs) of the aircraft.

Abstract: An apparatus to aerially dispense payload containers from an aircraft is provided. The apparatus includes an outer portion, including an opening to allow a payload container to leave the apparatus when the payload container is in alignment with the opening. The apparatus also includes an inner portion, configured to rotate within the outer portion. The inner portion has one or more cutouts that retain the payload container. The apparatus further includes an actuator, coupled to the inner portion, and a processor circuit. The processor circuit commands the actuator to rotate the inner portion to cause the payload container to align with the opening.

Abstract: An aircraft store ejector systems and subsystems thereof. Embodiments can include a two-reservoir re-pressurization system wherein a remote reservoir is used to maintain desired pressure in a local ejector reservoir. The system can include a release valve having a vent valve and valve piston. The release valve can control release of pressurized gas to a pitch control valve. The pitch control valve can be configured to distribute the pressurized gas between two or more ejector piston assemblies. One or more of the ejector piston assemblies can include multiple concentric piston stages and piston chambers, the piston chambers configured to contain a volume of gas. The ejector piston assemblies can be configured to compress the volume of gas within the piston chambers as the piston stages are extended out from the aircraft. Such compression can provide a return force to the piston stages.

Abstract: A canisterized satellite dispenser includes one or more of: a pair of guide rails that eliminate the requirement of a rectangular profile for the satellite; a preload system that secures the canisterized satellite during transport and launch, and releases to deploy the canisterized satellite; a constant-force spring to provide a uniform and predictable dispensing force; an external rectangular profile in each dimension; and internal support surfaces that simplify the design of canisterized satellites, particularly those with deployable components. Each canisterized satellite includes a pair of opposing flanges on a lower portion of the satellite that ride in a channel formed by the dispenser's guide rails and restraining flanges; no other support constraints are imposed. During travel and launch, the satellite flanges are held against the restraining flanges, rigidly fixing the satellite to the dispenser until the satellite is deployed.

Abstract: An aircraft includes a fuselage, a wing, and a decoupled joint interconnecting the fuselage and the wing. The decoupled joint can be an active suspension system. A method of adapting an aircraft to attenuate forces between a main wing and a fuselage thereof includes providing a plurality of sensors upon the aircraft, configured for sensing motion and/or mechanical stress of the main wing and/or the fuselage and producing signals indicative thereof, and providing a plurality of active suspension elements interconnecting the wing and the fuselage, the active suspension elements being configured to move at least in response to the signals to adjust a position of the wing with respect to the fuselage.

Abstract: The bottom surface of an aircraft, such as an Osprey V-22 propeller driven aircraft, has at least four distributed hook attachment points. A load suspension apparatus is attached to the four attachment points with elongated slings. The load suspension apparatus includes an upper rigid frame and a lower rigid frame of lesser dimensions. The lower frame is suspended from the upper frame with V-shaped slings. A cargo load is attached to the lower frame. The load suspension apparatus provides stable attachment of loads to tilt wing and rotary wing aircraft at high aircraft speeds, at transitions between high and low speeds and through aircraft turns.

Abstract: The present invention is a stratospheric-airship-assisted orbital payload launching system that features with high reusability ratio, low cost, short launch-preparation time and robust reliability. The system consists of an airship-based stratospheric launch platform (1), a stratospheric-launched suborbital shuttle (2, SLSS) and an upper stage (3, a modified version of conventional upper stage or a spaceplane). The airship-based stratospheric launch platform (1) employs hydrogen and helium to provide buoyancy in its ascent and high-altitude cruise stages. Given the substantially lower ambient pressure, the usage of hydrogen at high altitude is much safer than on the ground. The SLSS (2) is mounted beneath the platform (1), and an assembly of payload (4) and upper stage (3) is loaded in the cargo bay (2B) of SLSS (2).

Abstract: A multi-purpose helicopter pendant hook assembly is provided. The pendant hook assembly allows cargo load attachment by a ground crewman from positions either on the load itself or standing on the ground next to the load. In both cases, a stand-off from the helicopter improves safety for the ground crewmen. The hook assembly combines the capability to pick up cargo and personnel, or both, simultaneously. This multi-purpose feature reduces the need for more than one helicopter during recovery operations. The pendant has multiple D-rings for attachment of personnel and has a communications link for ground crew to pilot communications. The hook assembly also has a flange and hook configuration which allows release of the cargo load while retaining the cargo net.

Abstract: Device for engaging and ejecting a load suspended below an aircraft, comprising at least two ejection pistons (4, 5) which are connected, on the one hand, to the load to be engaged/ejected and, on the other hand, to a control circuit (1) which comprises a pneumatic circuit (2, 3, 8), further comprising for supplying each ejection piston (4, 5) a hydraulic circuit (6, 7, 41, 51) which is interposed between the pneumatic circuit and the ejection pistons (4, 5).

Abstract: An aircraft store ejector systems and subsystems thereof. Embodiments can include a two-reservoir re-pressurization system wherein a remote reservoir is used to maintain desired pressure in a local ejector reservoir. The system can include a release valve having a vent valve and valve piston. The release valve can control release of pressurized gas to a pitch control valve. The pitch control valve can be configured to distribute the pressurized gas between two or more ejector piston assemblies. One or more of the ejector piston assemblies can include multiple concentric piston stages and piston chambers, the piston chambers configured to contain a volume of gas. The ejector piston assemblies can be configured to compress the volume of gas within the piston chambers as the piston stages are extended out from the aircraft. Such compression can provide a return force to the piston stages.

Abstract: A payload cut-down mechanism having a pathway member having a first end and a second end attached to a balloon envelope, a line extending within the pathway member having first and second ends extending from the pathway member, where the first end of the line is releasably secured to a first actuated release mechanism attached to a payload, and a second end of the line releasably secured to a second actuated release mechanism attached to the payload, and wherein at least one of the first and second actuated release mechanisms are operable, upon receiving a signal, to release the first or second end of the line from one of the actuated release mechanisms and cause the payload to separate from the payload.

Abstract: A method for retrieving personnel is provided. The method includes receiving a radio signal indicating a real-time position of personnel to be retrieved, deploying an unmanned aerial vehicle to the real-time position, receiving an indication that the personnel to be retrieved is on-board the unmanned aerial vehicle, and operating the unmanned aerial vehicle to move the personnel to a different location.

Abstract: An air vehicle having a bilaterally asymmetric configuration for reducing wave drag may include a body having a longitudinal axis. The air vehicle may further include longitudinally offset engine nacelles, asymmetrically lengthened engine nacelles, and/or longitudinally offset protruding aerodynamic surfaces for reducing wave drag.

Abstract: A method of releasing cargo suspended from at least one cargo hook release pendant in a suspension system coupled to a cargo hook release system includes receiving a voltage release signal at a cargo hook control interface and a cargo release harness assembly; receiving an energizing voltage signal at the cargo release harness assembly; energizing a relay in response to receiving the energizing voltage signal, the relay being electrically coupled to the cargo release harness assembly; automatically transmitting the voltage release signal from the cargo release harness assembly to at least one cargo hook release pendant in response to energizing the relay; and automatically releasing the cargo from at least one cargo hook release pendant in response to automatically transmitting the voltage release signal. Also, the cargo hook release system includes the cargo hook control interface, the cargo release harness assembly, and at least one cargo hook release pendant.

Abstract: A suspension system (10) of an aircraft (1). The suspension system (10) comprises a fastener device (15) including a coupling member (20) suitable for carrying a load (5) with a sling (21). The suspension system (10) has a return device (30) that comprises a linkage (40) provided with a plurality of bars (41, 42, 43) hinged in pairs to apply a non-linear force to the coupling device (15), said linkage (40) being suitable for fastening to a load-carrier structure (2) of an aircraft (1). In addition, the return device (30) includes a tie (35) connecting said linkage (40) to the coupling device (15), as well as a spring member (36) fastened to a bar (41) of the linkage (40) and suitable for being connected to an aircraft (1).

Abstract: An aircraft (1) having an airframe (2) extending along an anteroposterior plane of symmetry (P1) in elevation transversely separating a first side (11) of said aircraft (1) from a second side (12) thereof, said aircraft (1) being provided with hoist means (20) including a winch (21) provided with a drum for winding a hoist cable (22), said hoist means (20) including a beam (30) for guiding said cable, said beam (30) extending from a first end (31) constituting an inlet end for said cable (22) to a second end (32) constituting an outlet end for said cable (22). The hoist means (20) have a counterweight (23), said counterweight including said winch (21) that is fastened to said first end (31), said second end (32) being located on said second side (12) while said winch (21) and said first end (31) are located on said first side (11).

Abstract: A flying vehicle comprises an elongated airfoil having a first end and a second end defining a longitudinal axis, the first and second ends further defining an interior opening extending therebetween and terminating at an outlet port proximal the second end; a solid fuel engine includes a fuel combustion chamber proximal the first end of the airfoil; a first manifold is coupled to the fuel combustion chamber and configured to convey a pressurized gas generated by combustion of a solid fuel; wherein the interior opening conveys the pressurized gas from the first manifold to the outlet port proximal the second end and wherein the pressurized gas is exhausted at the outlet port substantially perpendicular to the longitudinal axis of the elongated airfoil, thereby producing thrust which imparts a rotational motion to the airfoil about a center of mass proximal to the first end, for thereby defining a rotor disk.

Abstract: An aircraft store ejector systems and subsystems thereof. Embodiments can include a two-reservoir re-pressurization system wherein a remote reservoir is used to maintain desired pressure in a local ejector reservoir. The system can include a release valve having a vent valve and valve piston. The release valve can control release of pressurized gas to a pitch control valve. The pitch control valve can be configured to distribute the pressurized gas between two or more ejector piston assemblies. One or more of the ejector piston assemblies can include multiple concentric piston stages and piston chambers, the piston chambers configured to contain a volume of gas. The ejector piston assemblies can be configured to compress the volume of gas within the piston chambers as the piston stages are extended out from the aircraft. Such compression can provide a return force to the piston stages.

Abstract: Attachable/detachable segmented ordnance dispenser systems and methods are presented. A control module targets, fuses, and releases ordnance, and at least one ordnance dispenser segment comprises a rack mount ordnance assembly and a segment enclosure. The rack mount ordnance assembly mounts and releases ordnance under control of the control module, and the segment enclosure comprises a segment door that opens under control of the control module. An aerodynamic shell aerodynamically enhances and protects the ordnance dispenser segment and the control module, and can be coupled to a vehicle.

Abstract: A fastener device (10) provided with attachment means (20) for attaching an external load (5) and with fastener means (30) provided with a support beam (40) and with anchor means (50) for anchoring said support beam (40). A first mechanical coupling (60) connects said support beam (40) to the anchor means (50) so as to enable the support beam (40) to pivot about a first pivot axis (AX1). In addition, coupling means (70) are hinged to the support beam (40) so as to make pivoting possible about a second pivot axis (AX2), the attachment means (20) being hinged to the coupling means (70) to make pivoting possible about a third pivot axis (AX3). This fastener device (10) includes automatic folding means (100).

Abstract: Embodiments related to mounting a sensor pod mount to an aircraft fuselage are disclosed. In one example embodiment, a sensor pod mount comprises a sensor pod mounting body where the sensor pod mounting body includes a mounting region for removably mounting the sensor pod mount to the fuselage using a coupling that joins a strut to the fuselage.

Abstract: A deployment system includes a spring-driven linkage for deploying one or more kicker feet, to push a device to be deployed away from the deployment system. The kicker feet may include fore and aft kicker feet that push the deployed device to obtain a desire pitch in the launch, an example being a minimal or substantially zero pitch. The release of the kicker feet may be controlled by a pair of actuator, such as electrical solenoid actuators, both of which must be actuated to deploy the device. An electrical connection may allow positional float to account for tolerances in the positioning of the device relative to the deployment system.

Abstract: Methods and systems for aerial delivery utilize expendable materials. An expendable aerial delivery system comprises wood, textile and/or other expendable materials, for example materials suitable for disposing via burning or crushing in a forward area. In this manner, valuable and/or expensive metal platforms can be eliminated from airdrops, thus preventing insurgent repurposing of these platforms into improvised explosive devices and other implements of warfare.

Abstract: The present invention relates to a removable support (10) for optional equipment (6) on an aircraft (1). The support (10) comprises an elongate beam (20) fitted with at least one attachment point for a piece of equipment and extending from a first end portion (21) to a second end portion (22), and the support (10) is provided with first fastener means (30) provided with a first fastener arm (31) connected to a first link arm (32) that is releasably fastened to the first end portion (21), and with second fastener means (40) provided with a second fastener arm (41) connected to a second link arm (42) that is releasably fastened to the second end portion (22), a first support rod (34) also connecting the first fastener arm (31) to the first link arm (32), and a second support rod (44) also connecting the second fastener arm (41) to the second link arm (42).

Abstract: Particular embodiments comprise a non-dedicated, temporarily installed, airborne special mission payload mounting system which is mechanically interfaced to the Air Deployment System (ADS) rails of a host cargo aircraft. An Adaptive Mounting Plate (AMP) is placed over an ADS rail section and restrained in position. Once the AMP is secured, an articulated or fixed position strut can be attached to it through the opened side doorway without removing the original door. Once the fixed position or articulated strut is bolted to the AMP, a one piece or segmented two piece pressurized door plug indented along its lower periphery to accommodate the protruding form factor of the fixed position or articulated strut is installed within the vacant doorway above the strut providing an airtight seal and thereby permitting pressurization of the aircraft.

Abstract: Sensor pod attachment assemblies are provided for attaching a sensor pod containing airborne sensor equipment to an aircraft fuselage. The sensor pod assemblies may include fore and aft pairs of attachment pylon assemblies each having a lower end attached to the aircraft fuselage and an upper end attached to the sensor pod. The fore pair of attachment pylon assemblies can include port and starboard pylon structures, and a cross-support base connected to upper ends of the port and starboard pylon structures. The aft pair of attachment pylon assemblies may include a lengthwise adjustable spar assembly.

Abstract: An emergency pod configured for use with a rotary wing aircraft is provided including a rigid, generally hollow shell. The shell includes a movable portion configured to move between a closed position and an open position. An inflatable raft is arranged within an interior portion of the hollow shell. The life raft is coupled to an inflation mechanism. A first activation device and a second activation device are operably coupled to the inflation mechanism. The first activation device and the second activation device are configured to operate the inflation mechanism to initiation inflation of the life raft when a force is applied thereto.

Abstract: A mounting set for use in mounting an external stores to a mounting station of an aerospace vehicle includes a mounting bracket arrangement and a strap arrangement. The bracket arrangement is configured for selective reversible engagement with respect to the mounting station and for cooperating with the strap arrangement. The strap arrangement is configured for securing the bracket arrangement to the stores in load bearing abutment therewith to enable transfer of loads between the stores and the mounting station via said bracket arrangement, in operation of said mounting set. A mounting system is also provided for mounting an external stores to an aerospace vehicle having two or more mounting stations, including a mounting set for each mounting station. Mounting methods are also provided.

Abstract: A locking apparatus for an object that is lockable on a rail is provided such that the object may be undone in a single manual operating step. The apparatus may be used in a passenger aircraft in which it is necessary to slide seats or other built-in devices. The apparatus includes at least one first base body, at least one first locking body, and at least one first operating element. The at least one first base body is designed to be placed on top of the rail. The at least one first locking body is movably held to the at least one first base body, and is shaped to be placed into the rail. The at least one first operating element is connected to the at least one first locking body for moving the at least one first locking body in the direction of the interior of the rail.

Abstract: One embodiment of the present invention is a unique aircraft. Another embodiment is a unique external pod for an aircraft. Other embodiments include apparatuses, systems, devices, hardware, methods, and combinations for aircraft and external pods for aircraft. Further embodiments, forms, features, aspects, benefits, and advantages of the present application will become apparent from the description and figures provided herewith.

Abstract: Under-wing pylon for an aircraft which has on the upper side a pin (2) for attaching to the fuselage or to the wings of the aircraft itself, and a connector (3) for connecting the pylon to the aircraft. The pylon has a monolithic framework made with stratified unidirectional and/or woven carbon fibres, impregnated with epoxy resin.

Abstract: A dispenser pod, which includes a dispenser chassis with a first chassis end, a second chassis end and a chassis chamber, a first chassis end cover for covering the first chassis end, a second chassis end cover for covering the second chassis end, a launch system, and at least one sway brace. The first chassis end cover has at least one expendable passageway for accepting an expendable launch canister such that the expendable launch canister can enter the chassis chamber. The launch system is for expelling the expendable launch canister from the chassis chamber and through the expendable passageway. The at least one sway brace is for securing the expendable launch canister within the chassis chamber.

Abstract: A method of automatically jettisoning cargo suspended from a suspension system coupled to an auto jettison system, includes receiving an initial load value from at least one attachment point of the suspension system, the receiving of the initial load value in response to attaching the cargo to the suspension system; receiving an instantaneous load value of the cargo suspended on an attachment point, the attachment point being coupled to the cargo; predicting a rate of change of the instantaneous load value at a predetermined future time period; combining the predicted rate of change of the instantaneous load value with the initial load value to create a predicted load value; comparing the predicted load value to a threshold value for the attachment point; and jettisoning the cargo from the attachment point if the predicted value is greater than the threshold value.

Abstract: The invention relates to a device for limiting the deflection of a door (1), particularly a hatch or a freight door, arranged in a fuselage cell (3) of an aircraft, having at least one holding element (5) arranged preferably in the region of a door jamb (4) or in the region of a door leaf edge (7). In order to ensure deflection limitation for doors, hatches and freight doors in aircraft which can be triggered manually independently of an actuation of the normal locking system, it is proposed according to the invention that the at least one holding element (5) can, if there is a sufficient pressure difference ?p between the internal pressure pi prevailing in the fuselage cell (3) and the outside air pressure pa prevailing outside of the fuselage cell (3), be brought into engagement with at least one abutment (6) arranged in the region of the door leaf edge (7) or the door jamb (4).

Abstract: An aircraft store ejector systems and subsystems thereof. Embodiments can include a two-reservoir re-pressurization system wherein a remote reservoir is used to maintain desired pressure in a local ejector reservoir. The system can include a release valve having a vent valve and valve piston. The release valve can control release of pressurized gas to a pitch control valve. The pitch control valve can be configured to distribute the pressurized gas between two or more ejector piston assemblies. One or more of the ejector piston assemblies can include multiple concentric piston stages and piston chambers, the piston chambers configured to contain a volume of gas. The ejector piston assemblies can be configured to compress the volume of gas within the piston chambers as the piston stages are extended out from the aircraft. Such compression can provide a return force to the piston stages.

Abstract: A deployment system includes a spring-driven linkage for deploying one or more kicker feet, to push a device to be deployed away from the deployment system. The kicker feet may include fore and aft kicker feet that push the deployed device to obtain a desire pitch in the launch, an example being a minimal or substantially zero pitch. The release of the kicker feet may be controlled by a pair of actuator, such as electrical solenoid actuators, both of which must be actuated to deploy the device. An electrical connection may allow positional float to account for tolerances in the positioning of the device relative to the deployment system.

Abstract: A load lifting apparatus for a helicopter has a cable, including a supply length in a cable store. The cable is secured at one end to the helicopter and has a free end. A load-bearing element, on which a load to be raised can be secured, is arranged on the cable. The cable can be removed from the cable store in order to lower the load-bearing element downwards from the helicopter. As the load-bearing element is lowered or pulled upwards, the cable acts at a force-introduction location on the helicopter. The load-bearing element is arranged on the cable such that it can move along the cable. At least one cable-attachment location is present on the helicopter, and is spaced apart from the force-introduction location and has, or can have, the free end of the cable secured on it.

Abstract: An external hook system for a rotary-wing aircraft includes a lower frame interface which accommodates longitudinal and lateral loads and an upper frame interface. A tension member is mountable between the lower frame interface and the upper frame interface to transfer tension loads between the lower frame interface and the upper frame interface.

Abstract: A detachable connecting arrangement for fitting launchable external loads to an aircraft, having a hook-like connecting element fitted to the external load and a holding element fitted to the aircraft for the hook-like connecting element. The hook-like connecting element includes a lower supporting surface and an upper supporting surface. The holding element has a first opposing supporting surface that interacts with the lower supporting surface, and a second, upper opposing supporting surface that interacts with the upper supporting surface. The lower supporting surface and the first opposing supporting surface are designed to support mass forces of the external load directed away from the aircraft, and the upper supporting surface and the upper opposing supporting surface are designed to support mass forces of the external load directed towards the aircraft.