A rack and lifter system and method is described. The system includes a rack having at least a first engagement opening, and a lifter having at least a first engagement member and at least a first vertical extension member, wherein in use the at least a first engagement member interlocks with the at least a first engagement opening of the rack, and the at least a first vertical extension member extends to lift the interlocked lifter and rack, wherein the at least a first vertical extension member includes means for movement. The lifter may include a guiding-and-lifting member which lifts the lifter and guides the lifter into an interior space of the rack. The lifter may include a towing machine connection member which connects the lifter to a towing machine which positions the lifter within the rack and tows the connected lifter and rack.

A breakaway system for use with a decking system may include a bracket that is configured to be capable of sliding along a track and a carrier that is releasably coupled to the bracket. The bracket and the carrier may be configured to be separated when an upward force is applied upon the bracket and not upon the carrier.

A breakaway system for use with a decking system may include a bracket that is configured to be capable of sliding along a track and a carrier that is releasably coupled to the bracket. The bracket and the carrier may be configured to be separated when an upward force is applied upon the bracket and not upon the carrier.

A vehicle lift includes a lift platform which can be selectively moved in a range between one or more raised positions which are level from the front to the rear and a lowered position where the lift platform is tilted for loading and unloading. A vehicle may be supported on the lift platform. The vehicle lift may be arranged in a trailer.

A road plate moving system and method is disclosed that makes it easier, safer, and more economical to move road plates. A frame detachably attaches to a road plate at the centre of the road plate, and the frame is detachably attached to a vehicle, and the frame is attached to rollers that straddle the road plate and are configured to move in the desired direction of travel. Each roller has a lifting mechanism to adjust the height of the frame relative to the bottom of the rollers. In use, the frame is attached to the road plate, and the road plate is lifted off the ground by the rollers lifting the frame, and the frame and road plate are pulled forward or backwards by the vehicle to move the road plate, which is then lowered to the ground. In a second embodiment, the road plate is lifted by a lifter located above the centre of the road plate.

A road plate moving system and method is disclosed that makes it easier, safer, and more economical to move road plates. A frame detachably attaches to a road plate at the centre of the road plate, and the frame is detachably attached to a vehicle, and the frame is attached to rollers that straddle the road plate and are configured to move in the desired direction of travel. Each roller has a lifting mechanism to adjust the height of the frame relative to the bottom of the rollers. In use, the frame is attached to the road plate, and the road plate is lifted off the ground by the rollers lifting the frame, and the frame and road plate are pulled forward or backwards by the vehicle to move the road plate, which is then lowered to the ground. In a second embodiment, the road plate is lifted by a lifter located above the centre of the road plate.

A road plate moving system and method is disclosed that makes it easier, safer, and more economical to move road plates. A frame detachably attaches to a road plate at the centre of the road plate, and the frame is detachably attached to a vehicle, and the frame is attached to rollers that straddle the road plate and are configured to move in the desired direction of travel. Each roller has a lifting mechanism to adjust the height of the frame relative to the bottom of the rollers. In use, the frame is attached to the road plate, and the road plate is lifted off the ground by the rollers lifting the frame, and the frame and road plate are pulled forward or backwards by the vehicle to move the road plate, which is then lowered to the ground. In a second embodiment, the road plate is lifted by a lifter located above the centre of the road plate.

A method may comprise attaching a spool support frame to a forward bogie and an aft bogie, lifting the cargo, supported by a spool support frame with a forward hydraulic arm and an aft hydraulic arm. A transportation system may comprise a forward bogie, an aft bogie, and a spool support frame. The forward bogie may include a plurality of axel groups configured to operate independently of each other, a forward arm attached to the forward bogie through a swivel connection, and a forward hydraulic arm attached to the forward arm through a rod. The aft bogie may include a plurality of aft axel groups configured to operate independently of each other, an aft arm attached to the aft bogie through an aft swivel connection, and an aft hydraulic arm attached to the aft arm through an aft rod.

A method may comprise attaching a spool support frame to a forward bogie and an aft bogie, lifting the cargo, supported by a spool support frame with a forward hydraulic arm and an aft hydraulic arm. A transportation system may comprise a forward bogie, an aft bogie, and a spool support frame. The forward bogie may include a plurality of axel groups configured to operate independently of each other, a forward arm attached to the forward bogie through a swivel connection, and a forward hydraulic arm attached to the forward arm through a rod. The aft bogie may include a plurality of aft axel groups configured to operate independently of each other, an aft arm attached to the aft bogie through an aft swivel connection, and an aft hydraulic arm attached to the aft arm through an aft rod.

Robotic vehicle and use thereof for displacing a holder for goods, which is for instance loaded with goods, which vehicle can be operated in an empty position and a loaded position, comprising of (1) moving the robotic vehicle to a position under the holder in a first direction, wherein the robotic vehicle is in the empty position, wherein a holding means is countersunk in a body of the vehicle; (2) lifting the holder, wherein the robotic vehicle lifts the holder by performing a vertical movement of the holding means relative to the wheels of the vehicle, such that the holding means comes into contact with an underside of the holder, wherein the robotic vehicle transfers to the loaded position; (3) rotating driven wheels of the robotic vehicle from the first direction to the second direction without the body of the vehicle being rotated, and (4) displacing the robotic vehicle in the loaded position in a second direction, wherein the first and second direction enclose a mutual angle of between 60 and 120 degrees, preferably 75 and 105 degrees, more preferably 85 and 95 degrees, such as a substantially right angle.