An improving loading dock bumper system having a pair of telescoping bumpers positioned on either side of the loading dock. The bumpers may be extended longitudinally to contact a vehicle having an abnormally shaped rear end further from the loading dock to prevent vehicular damage or damage the loading dock.

Systems and methods for automatically controlling loading dock equipment, such as in response to a trailer approaching and docking at a docking station, are disclosed. The systems and methods can provide scanning devices and scanning operations which assist with, for example, properly aligning a trailer at a docking station and/or checking an interior area in front of the dock door for obstructions. The systems and methods can also transmit messages between components of the system and/or to users of the system regarding the status of components of the systems and/or the status of the overall docking process.

Systems and methods for automatically controlling loading dock equipment, such as in response to a trailer approaching and docking at a docking station, are disclosed. The systems and methods can provide scanning devices and scanning operations which assist with, for example, properly aligning a trailer at a docking station and/or checking an interior area in front of the dock door for obstructions. The systems and methods can also transmit messages between components of the system and/or to users of the system regarding the status of components of the systems and/or the status of the overall docking process.

A cargo vehicle includes a cargo area configured to receive a load of cargo for transport, and a plurality of wheels configured to support the cargo area above a road surface while the plurality of wheels roll along the road surface. A rear structure of the cargo vehicle includes a rear cross member located at a rear edge of the cargo area, and a first light array is located in the rear cross member. A first dock bumper is placed directly over a first lamp of the first light array on a first lateral side of the rear cross member, the first dock bumper including a through hole accommodating the first lamp to visually mark a first outboard edge of the cargo vehicle.

Bumpers for loading docks are disclosed. An example rear impact guard (RIG) bumper includes a casing, a compressible body in the casing, a rod through the casing, and a lip-supporting plate associated with the casing and positioned above the compressible body, where the lip-supporting plate is to move with the casing in reaction to an impact from a vehicle.

The invention provides an underground container logistics loading and unloading system based on a deep underground passage. The underground container logistics loading and unloading system comprises an automatic container wharf, a logistics park and the deep underground passage. The automatic container wharf is connected with the logistics park through the deep underground passage, and the deep underground passage internally comprises an area where shuttle vehicles run; and the deep underground passage comprises a main body layout area and accessory equipment. By applying the embodiment of the invention, through a vertical loading and unloading mode and an underground container logistics transportation mode, cargo transportation is realized, and transportation of ground container trucks is shunted to a certain extent, so that the ground transportation pressure of a port city is relieved, the transportation distance between the container wharf and the out-of-city logistics park is shortened.