The two stackable loading level pallet makes it possible to transport one or two stacked cars in a container or airplane pallet. Said pallet is non-motorized, capable of being folded flat, stackable, and capable of being opened out by a forklift truck. In a lower position, the top support structure of said pallet, which is framed and has a completely free central space, fits into the bottom support structure of said pallet, and the top and rear front wheel support devices of the top support structure are inserted onto or in alignment with the bottom wheel support assembly of the bottom support structure and thus form all or part of a lower rolling path that makes it possible to load a motor vehicle onto the top support structure of said pallet via the own movement thereof and without an access ramp.

A novel logistic panel is disclosed. The logistic panel is adapted for use within cargo containers and enables vertical mounting tracks of a cargo beam and decking system to be located at various desired centers, or intervals, along the length of the container wall, even if the locations of the logistic posts do not coinside with the desired locations of the vertical mounting tracks. The logistic panel comprises a plurality of recessed channels for receiving complementary sized vertical mounting tracks. The mounting tracks and the recessed channels of the logistic panel are sized and configured such that the tracks do not substantially project into the interior of the cargo container and to therefore minimize the risk of the mounting tracks being damaged during loading and unloading operations.

A fastening tip for connecting a cargo support beam to a track, which comprises a first side plate, a second side plate, a stopping plate, a torsional spring and a lining plate, wherein the top surface of the top portion of the stopping plate is flat, and the stopping plate has an operating fin exposed outside; he lining plate engages the stopping plate when the top portion of the stopping plate tightly resists against the edge of the positioning hole. In the present invention, the damage due to the extrusion of cargos or by an external force is effectively prevented from; in addition, the manual operation space is increased, and the operation is more convenient.

A cargo carousel system for shipping containers is provided that can include a frame configured to fit within a shipping container and a cargo carousel mechanism in the frame that can move cargo pod platforms, configured for holding cargo pods, in a continuous loop path in the frame. The system can further include two frames side-by-side in the shipping, each frame with its own cargo carousel system.

A clamping device secures an equipment rack during shipping. The clamping device includes a gripping portion having first and second surfaces positionable along opposing sides of a respective one of a front and rear lateral logistic bar. The clamping device also includes a clamp mechanism attached to the gripping portion for movement between a disengaged position and an engaged position to selectively engage the first and second surfaces to the opposing sides of the respective one of the front and rear lateral logistic bars positioned adjacent to an equipment rack within a carrier shipping enclosure. A mounting feature is attached to the gripping portion to hold one end of a longitudinal logistic bar positioned along a lateral side of the equipment rack.

The present disclosure provides a load-securement apparatus and a method of installing the load-securement apparatus to secure a load in a shipping container. In one embodiment, the load-securement apparatus includes a first non-rigid anchor member, a second non-rigid anchor member, a first non-rigid load restrainer, and a second non-rigid load restrainer. In one embodiment, the method of installing the load-securement apparatus comprises attaching the first load restrainer to the first anchor member, attaching the first anchor member to the shipping container adjacent a side wall, attaching the second load restrainer to the second anchor member, attaching the second anchor member to the shipping container adjacent another side wall, attaching the first load restrainer to the second load restrainer such that part of the first load restrainer and part of the second load restrainer both contact the load, and tensioning the attached first and second load restrainers to a designated tension.

The present invention is modular offset mounting apparatus for use in efficiently and densely removeably mounting objects comprising a structure having a plurality of spring E-fittings on a first side and an E-track section on a second side. The modular offset mounting apparatus is adapted such that the spring E-fittings of the modular offset mounting apparatus may be removeably engaged to a section of E-track that is fastened to a structure such as a truck bed and such that at least one spring E-fitting such as a spring E-fitting connected to a wheel chock is removeably engaged to the length of E-track of the modular offset mounting apparatus. By so mounting the modular offset mounting apparatus, objects such as motorcycles may be more densely positioned and mounted such as in a bed of a pickup truck.

The present invention provides a removable frame system for transporting vehicles in a container. The frame system is be assembled in the container, the vehicles are loaded on the frame system, the container is shipped to the location, the vehicles are unloaded from the frame system, and the frame system is disassembled and returned to the manufacture or stored for later use.

The invention relates to a transportation system (100) for transportation of large items (2), such as flanges, wherein said transportation system comprises: a frame (4) having an extension in a longitudinal direction (X), in a transversal direction (Y) and in a vertical direction (Z); wherein said frame comprises two longitudinal girders (6,6), which are connected to a plurality of pairs of transversal primary support beams (8,8, 10,10); wherein said primary support beams preferably are being arranged on an upper part of said longitudinal girders (6,6); wherein said longitudinal girders comprise a lower surface (12) and an upper surface (14); wherein said transversal primary support beams comprise an upper surface (16); wherein the area between two transversal primary support beams defines a storage area (18) for said large items; wherein free access in a downward direction is provided in the storage area (18) for the large items; wherein the lower part of the frame (4) is having dimensions and locking mechanisms corresponding to a freight container; thereby allowing the transportation system to be arranged and locked in place safely on top of a freight container.

A cargo carousel system for shipping containers is provided that can include a frame configured to fit within a shipping container and a cargo carousel mechanism in the frame that can move cargo pod platforms, configured for holding cargo pods, in a continuous loop path in the frame. The system can further include two frames side-by-side in the shipping, each frame with its own cargo carousel system.