Systems and methods for monitoring components of a loading dock station that implement a remote monitoring and authorization system are disclosed. The systems and methods can provide information regarding the status of various components of the loading dock station to a remote monitoring and authorization control unit, where a supervisor or the like is capable of reviewing real time information regarding the status of the components and progress through and adherence to a workflow protocol. The systems and methods can also provide for authorization requests to be sent to the remote monitoring and authorization control unit, such as requests to override certain components of the docking station. The user at the remote monitoring and authorization control unit can then grant or deny requests based on status information and other data provided at the remote monitoring and authorization control unit.

Rear headers for dock levelers. An example dock leveler includes a deck movable between a stored position and an operating position; and a rear header coupled to the deck, the rear header including a hinge lug; a mounting plate to couple to the hinge lug, the mounting plate defining a first sloped surface oriented toward a rear surface of the deck when the dock leveler is in the stored position; and a tilt plate coupled to the mounting plate, the tilt plate defining a second sloped surface oriented away from the rear surface of the deck when the dock leveler is in the stored position.

Methods and apparatus for monitoring a dock leveler are disclosed herein. One example dock leveler system for use at a doorway of a loading dock, where a body is sometimes present at the loading dock, includes a deck movable between a raised position and a lowered position. The example dock leveler system also includes a sensor having a field of view extending over the deck when the deck is in the lowered position. The sensor is in a normal state when the deck is in the lowered position while the body is off the deck, the sensor is in a triggered state when the deck is in the lowered position while the body is on the deck interrupting the field of view, and the sensor is in the triggered state when the deck is in the raised position with the deck interrupting the field of view regardless of whether the body is on or off the deck.

A telescoping ramp may include first and second ramp sections such that the second ramp section may be received within the first ramp section and translated between an extended position and a retracted position. The telescoping ramp may include a locking mechanism that extends between at least one of pairs of rails of the first and second ramp sections. The locking mechanism may include a pair of locking pins that is selectively engageable with the first and second ramp sections. In one embodiment, the pair of locking pins may include handle portions that may be disposed between the at least one of the pairs of rails. In such embodiment, an axial movement of the handle portions along a common axis of the pair of locking pins may lock the second ramp section relative to the first ramp section.

A barrier rail system is used with a truck well or drive-through truck bay, in which a truck, such as a flatbed trailer is positioned. The truck well has a floor and opposing upstanding side walls and at least one stanchion positioned on a surface adjacent to and outboard of one of the upstanding side walls. The barrier rail system includes a barrier rail having at least one upright post and at least one post mounted transverse to the upright post. A movable link is mounted to the upright post and mountable to the stanchion. The barrier rail is movable from a stowed position in which the barrier rail is adjacent the upstanding sidewall to a deployed position in which the barrier rail is moved away from the upstanding sidewall and the stanchion and over the well. The system can also be used on drive-through truck bays.

A protective panel for shielding a dock pad while loading and unloading cargo includes a protective panel, a plurality of mounting holes, and a plurality of panel fasteners. The protective panel is mounted to a metallic door jamb of a loading dock via the plurality of panel fasteners. The plurality of mounting holes in turn allow the plurality of panel fasteners to attach to the protective pad. The protective panel includes a flat body and a curved body. The flat body protects the side of the dock pad, whereas the curved body protects the edge of the dock pad. As such, the flat body is connected adjacent to the curved body. Finally, each of the plurality of panel fasteners is attached to a corresponding hole from the plurality of mounting holes. Thus, the number of panel fasteners can be adjusted depending on the size and weight of the protective pad.

A system and method are provided for automated engaging of a truck trailer at a loading dock. Sensors measure a distance and an angle of alignment between the incoming trailer and a wall of the loading dock. An outside lighting system guides a truck driver backing the trailer toward the dock door. A vehicle restraint system fixates the trailer within the loading dock in response to signals from the sensors. An overhead dock door opens once the trailer is successfully fixated by the vehicle restraint system. A dock leveler deploys after the overhead dock door opens. An inside dock light indicates to dock personnel that the trailer is ready to be serviced. Once servicing of the trailer is finished, an automated release of the trailer from the loading dock may be initiated by PLC communication.

The invention discloses a method, system and related device of implementing vehicle automatic loading and unloading, so as to achieve the automatic loading and unloading of the unmanned vehicle. The method includes: controlling, by a vehicle controller, a vehicle to drive automatically and stop at a loading and unloading position; obtaining, by a loading and unloading control apparatus corresponding to the loading and unloading position, vehicle identification information of the vehicle; verifying the vehicle identification information and controlling a loading and unloading machine to load and unload when the verification succeeds; sending a loading and unloading completion indication to the vehicle controller after the loading and unloading is completed; and controlling, by the vehicle controller, the vehicle to leave the loading and unloading position when receiving the loading and unloading completion indication.

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.

An example system includes pedestrian sensors to monitor a first pedestrian zone and a second pedestrian zone in front of a dock face of a loading dock. A first vehicle detector is to attempt to detect a vehicle near the first pedestrian zone and a second vehicle detector is to attempt to detect the vehicle near the second pedestrian zone. A sensor manager is to disable the first pedestrian zone when the first vehicle detector detects the vehicle approaching the first pedestrian zone and the at least one pedestrian sensors does not detect the pedestrian in the first pedestrian zone. The sensor manager is to disable the second pedestrian zone when the second vehicle detector detects the vehicle approaching the second pedestrian zone and at least one of the at least pedestrian sensors does not detect the pedestrian in the second pedestrian zone.