An amphibious air cushion vehicle includes an air cushion supported hull configured for travel on water and smooth land; a deck supported by the hull; and a dual-rail cargo system having tracks arranged longitudinally on along the hull cargo deck from an aft end. The tracks include (1) guide rails and rollers providing for guided sliding movement of palletized cargo along the tracks, and (2) locks for locking pallets in position during transport, The track is configured at the aft end for an unloading operation in which the locks are disengaged and the palletized cargo slides off the aft end onto underlying land as the vehicle is moving forward thereon. The track may be the one track of a single-track variant, or one of a pair of tracks in a two-track variant.

Disclosed is method including receiving digital vehicle data for a fleet of vehicles like trucks, trains, planes, drones, etc., the digital vehicle data being one or more of GPS/location-based data, image data or radar data and combining one or more of pieces of data. The method includes inferring, based on the first combined data or based on incomplete data, a loaded/empty status of a vehicle. The method includes combining other data to yield second combined data, receiving data regarding one or more of supply, demand, and amount of available cargo to yield third combined data, generating information relating to a supply of vehicles available to load at a specified dock and/or deliver a cargo to a specified dock, in each case within a specified period of time and generating suggestions for one or more vehicles regarding future routes based on the data.

A deck hook having the capability 1) to accept loading force in wide space angles of multiple directions, and 2) to distribute loading forces over increased deck/socket surface areas thereby increasing durability of the deck elements built from non-steel materials.

A deck hook having the capability 1) to accept loading force in wide space angles of multiple directions, and 2) to distribute loading forces over increased deck/socket surface areas thereby increasing durability of the deck elements built from non-steel materials.

A transport frame having a longitudinal, lateral and upright extent for receiving a tip portion of a wind turbine blade is disclosed. The frame is stackable with identical frames and has a tip saddle assembly including a saddle with a support surface shaped to receive a blade tip, and a clamping mechanism having a hinged clamping arm operable between an open position and a closed position, the clamping arm, when open, allowing a blade tip to be lowered into the saddle, and when closed, securely restraining the blade tip against upward movement. The tip saddle assembly further includes a preventer serving to maintain the clamping arm in the closed position over a blade. A method of using the transport frame to clamp a wind turbine blade is also disclosed.

A transport frame having a longitudinal, lateral and upright extent for receiving a tip portion of a wind turbine blade is disclosed. The frame is stackable with identical frames and has a tip saddle assembly including a saddle with a support surface shaped to receive a blade tip, and a clamping mechanism having a hinged clamping arm operable between an open position and a closed position, the clamping arm, when open, allowing a blade tip to be lowered into the saddle, and when closed, securely restraining the blade tip against upward movement. The tip saddle assembly further includes a preventer serving to maintain the clamping arm in the closed position over a blade. A method of using the transport frame to clamp a wind turbine blade is also disclosed.

A modular system for transporting wind turbine blades in at least two different spatial arrangements comprising two or more root end transport frames having a height H for supporting the root end, wherein H<D (D=bolt circle diameter), and two or more first tip end transport frames having a height H1 for supporting the blade towards the tip end, each first tip end transport frame has a base frame and a support bracket provided on top of the base frame, wherein each first tip end transport frame is stackable on top of a root end transport frame and vice versa, so the system is operable to stack successive blades in an alternating root end to tip end arrangement. The first tip end transport frame is replaceable with a second end transport frame that increase the inter-blade spacing, or with a tip end or a root end distance piece.

A modular system for transporting wind turbine blades in at least two different spatial arrangements comprising two or more root end transport frames having a height H for supporting the root end, wherein H<D (D=bolt circle diameter), and two or more first tip end transport frames having a height H1 for supporting the blade towards the tip end, each first tip end transport frame has a base frame and a support bracket provided on top of the base frame, wherein each first tip end transport frame is stackable on top of a root end transport frame and vice versa, so the system is operable to stack successive blades in an alternating root end to tip end arrangement. The first tip end transport frame is replaceable with a second end transport frame that increase the inter-blade spacing, or with a tip end or a root end distance piece.

A system includes a coil contacting base. The coil contacting base includes a radially curved outer surface with a radius of curvature less than or equal to a coil radius of curvature of an interior channel of a coil of spoolable pipe, and the coil contacting base includes a length greater than or equal to an axial dimension of the coil. The system also includes a side wall coupled to an inner surface of the coil contacting base. The side wall is configured to block circumferential movement of a coil restraint. The system also includes a passage disposed between the coil contacting base and the side wall. The coil restraint is configured to be disposed in the passage.

A system includes a coil contacting base. The coil contacting base includes a radially curved outer surface with a radius of curvature less than or equal to a coil radius of curvature of an interior channel of a coil of spoolable pipe, and the coil contacting base includes a length greater than or equal to an axial dimension of the coil. The system also includes a side wall coupled to an inner surface of the coil contacting base. The side wall is configured to block circumferential movement of a coil restraint. The system also includes a passage disposed between the coil contacting base and the side wall. The coil restraint is configured to be disposed in the passage.