Systems, methods, and aircraft for managing center of gravity (CG) while transporting large cargo are described. Management of CG is achieved in many ways. In some instances, the aircraft itself is designed to assist in managing CG by providing fuel tanks that minimize the impact of fuel on the net CG of the aircraft. The fuel tanks utilize only a small amount of available volume in the wings for fuel. Disclosures related to properly managing CG while loading wind turbines onto cargo aircraft are also provided. The CG management techniques provided for herein allow for the transportation of wind turbine blades via aircraft, running counter to the typical rail or truck transportation of the same. One such management technique includes accounting for how a rotation of the blades when loading impacts the CG of the blades, and thus taking this into account when placing the blades in the aircraft.

A cargo restraint system includes a driveshaft having a plurality of drive pins and a plurality of first restraints each configured to actuate between a lowered position and a raised position. Each of the plurality of first restraints includes a head to actuate between the lowered position and the raised position, a drive disk rotatably coupled to the head and having a notch to receive a respective drive pin of the plurality of drive pins, and a locking disk to be received by the drive disk in response to the head being in the raised position. The cargo restraint system further includes a handle coupled to the driveshaft and configured to translate the driveshaft and to actuate such that the respective drive pin is received by the notch of the respective first restraint to move the respective first restraint between the lowered position and the raised position.

Coupler assemblies are described that removably couple sides of an auxiliary fuel tank in a cargo area of an aircraft. In one embodiment, a first coupler of the coupler assemblies includes a first attachment member that supports a body with a hollow channel having a centerline disposed longitudinally in the fuselage between a first end and a second end, and a slot between an outer surface of the body and the hollow channel. A second coupler of the coupler assemblies includes an engagement member, a second attachment member, and an arm extending between the engagement member and the second attachment member. The engagement member is slidably received within the hollow channel from the first end, and fits slidably within the hollow channel to engage with the body of the first coupler, with the arm extending through the slot.

An inflatable pod assembly for an aircraft includes an expandable exoskeleton. The expandable exoskeleton defines a leading edge and a trailing edge of the inflatable pod assembly, and the expandable exoskeleton includes first and second portions selectively attachable to each other. The inflatable pod assembly also includes an internal cargo area configured to receive cargo, and the first and second portions are configured to selectively enclose the internal cargo area when the first and second portions are attached to each other. The inflatable pod assembly further includes an internal inflation chamber configured to selectively receive an inflation fluid for expanding the exoskeleton to thereby transition the inflatable pod assembly from a deflated state to an inflated state.

An integral floor module for a cargo deck comprising: a first and second support section for (planar) support on support sections of perforated rail device, wherein the support sections extend in a longitudinal direction and define a support plane; a flat functional device receiving section, which is formed (centrally) between the support sections, wherein the functional device receiving section extends in a longitudinal direction and defines a (lower) receiving plane; wherein the floor module is designed in such a way that the receiving plane is clearly spaced apart (downwards) from the support plane. The floor module can be used in a cargo loading system, including with a latch element, and a method for converting a passenger deck into a cargo deck.

Systems, methods, and vehicles for loading and unloading cargo into or out of a large transport vehicle, such as an aircraft, utilizing a curved path are described. The systems and methods include one or more support structures disposed, either permanently or removably, within a cargo bay of the transport vehicle to form a curved path extending into an aft portion of the cargo bay. During loading, the payload can move in the aft direction while concurrently rotating about a center point of an arc. In some embodiments, the cargo bay can include a kinked portion disposed between a proximal and aft portions of the cargo bay, with the curved path extending at least through the kinked portion and into the aft portion. Methods, systems, and components thereof for assembling a cargo, unloading cargo from a large transport vehicle, and disassembling a cargo are also provided.

A cargo system for an aircraft may include one or more of the following: a cargo deck configured for the receipt of bulk cargo, the cargo deck including at least one deck panel; and a cargo transport system including a track for moving a cargo container; and at least one floor fixture exposed on the cargo deck, where the cargo transport system includes an installed state and an uninstalled state, the track being secured to the floor fixture when the cargo transport system is in the installed state and the track being displaced from the cargo deck when the cargo transport system is in the uninstalled state.

Systems and methods for removeably adding a cargo bay floor to the interior cargo bay of cargo aircraft bay are disclosed. The system includes a rail disposed in a cargo bay of a cargo aircraft with the rail extending longitudinally along both a length of a forward portion and an aft portion of the fuselage. The system includes a cargo floor segment configured to be removeably attached to the rail. When attached, the cargo floor segment can transform between a first arrangement with the cargo floor segment translatable along the rail, and a second arrangement with the cargo floor segment fixedly secured to a location along the rail. The cargo floor segment is configured to, when secured to the rail, define a section of a floor of the cargo bay of the cargo aircraft. Multiple floor segments can be used together to form a continuous floor for the aircraft.

Systems, methods, and vehicles for loading and unloading cargo into or out of a large transport vehicle, such as an aircraft, utilizing a curved path are described. The systems and methods include one or more support structures disposed, either permanently or removably, within a cargo bay of the transport vehicle to form a curved path extending into an aft portion of the cargo bay. During loading, the payload can move in the aft direction while concurrently rotating about a center point of an arc. In some embodiments, the cargo bay can include a kinked portion disposed between a proximal and aft portions of the cargo bay, with the curved path extending at least through the kinked portion and into the aft portion. Methods, systems, and components thereof for assembling a cargo, unloading cargo from a large transport vehicle, and disassembling a cargo are also provided.

A unit load device (ULD) for aircraft cargo loading, the ULD including a container having a cargo portion and a ledge extending from the cargo portion. The ledge is configured to interface with a floor latch. A first latch sensor is disposed on the ledge. The first latch sensor is configured to detect a closed latch contact. A controller is electrically connected to the first sensor, and is configured to automatically perform an action in response to the first latch sensor detecting the closed latch contact.