An automatic dock servicing system can monitor status of dock stations and/or dock station components, analyze the status to determine whether it satisfies a service condition for one or more service actions and, when service conditions are satisfied, cause the corresponding service actions to be performed. In some embodiments, a control panel can track a number of trailer loading/unloading cycles at the dock station. When the number of cycles reaches a threshold for performing a service on the dock station, the control panel can automatically initiate the service action. Some service actions that can be initiated by placing a maintenance or part request, sending control signals to a control panel or to dock station components, and/or sending messages or providing remote controls to other personnel.

An automatic dock servicing system can monitor status of dock stations and/or dock station components, analyze the status to determine whether it satisfies a service condition for one or more service actions and, when service conditions are satisfied, cause the corresponding service actions to be performed. In some embodiments, a control panel can track a number of trailer loading/unloading cycles at the dock station. When the number of cycles reaches a threshold for performing a service on the dock station, the control panel can automatically initiate the service action. Some service actions that can be initiated by placing a maintenance or part request, sending control signals to a control panel or to dock station components, and/or sending messages or providing remote controls to other personnel.

A middle mounted implement tractor utilizes a movable frame design in order to provide for middle mounting of implements on a tractor that can drive up to the implement, raise its front portion in the air, drive forward over the implement, and then lower the front portion to the ground and attach the middle mounted implement. This is accomplished utilizing a front frame assembly pivotably connected to a mounting frame assembly which mounts the implement; a frame mover mechanism that lifts the front frame and mounting frame; a middle frame which connects the cab, frame mover mechanism and related components; and a rear frame which attaches rear wheels, caster wheels, engine, etc. The front wheels can turn one hundred and eighty degrees and the tractor can easily interchange consumables via a carriage system that allows simple loading and unloading of tanks, etc.

A military deployable ramp system assembled from sectional modules and used to load/unload heavy wheeled and tracked vehicles on/off rail cars and other transport platforms. The design of the system affords potential to handle such vehicles in a wide range of environments, particularly at remote train track locations. The assembled modular ramp consists of two main parallel load-bearing ramp tracks, connected to each other via central bridging supports. Sections slide together vertically and connect using structural angles which are retained in opposing guide channels, eliminating the need for fixing hardware. Once assembled the ramp can be dismantled by lifting off each section clear of the others in order. The ramp sections independently find their own level relative to each other on unprepared ground. Additional restraint is provided by integrated lashing points for sections to be tethered together to enhance its assembled rigidity.

A method for preventing drive off of a refrigerated transport unit includes detecting whether an electrical power system of the refrigerated transport unit is electrically connected to a utility power source, and performing an action when the electrical power system is electrically connected to the utility power source includes. A drive off protection system includes a refrigerated transport unit including an electrical power system and a controller that monitors the electrical power system. The controller configured to perform an action when the electrical power system is electrically connected to the refrigerated transport unit.

A method for preventing drive off of a refrigerated transport unit includes detecting whether an electrical power system of the refrigerated transport unit is electrically connected to a utility power source, and performing an action when the electrical power system is electrically connected to the utility power source includes. A drive off protection system includes a refrigerated transport unit including an electrical power system and a controller that monitors the electrical power system. The controller configured to perform an action when the electrical power system is electrically connected to the refrigerated transport unit.

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.

An autonomous cargo handling system having a sensor self-calibration system may comprise a sensing agent configured to monitor a sensing zone, and a system controller in electronic communication with the first sensing agent. The system controller may be configured to receive structural cargo deck data from the first sensing agent, generate a real-time cargo deck model, identify a cargo deck component in the real-time cargo deck model, and determine a position of the sensing agent relative to the cargo deck component.

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.

A control panel is configured to operate one or more dock devices in a loading dock environment. The control panel can be supported at least in part by a bollard disposed in the loading dock environment. In one form, the bollard is configured to contain portions of the control panel and dock devices including sensors, lights, and the like. In one form, the control panel and one or more dock devices are mounted to a preexisting bollard to add functionality to the loading dock environment.