Methods, apparatus, systems, and articles of manufacture to monitor and manage loading docks and facility operations are disclosed. An example apparatus includes processor circuitry to: identify a first occurrence of a safety event based on outputs of sensors associated with at least one of doors or docks, the event associated with a first event type of a plurality of event types; determine a time of day different instances of the event occurred within a given period of time; determine a number of at least one of different doors or different docks associated with the different instances of the event; select a particular corrective action based on the time of day of the different instances of the event and based on the number of the at least one of the different doors or the different docks; and cause an output device to output an indication of the particular corrective action.

A modular loading dock with a mobile base includes an adjustable front section with front opposing adjustable leg members and middle opposing adjustable leg members, two adjustable feet connect each front leg member to a middle leg member, as well as an adjustable back section connected to the adjustable front section and including opposing rear adjustable leg members each having a grade plate. The mobile base has top and bottom surfaces, the top surface has an opening to receive a dock leveler into such opening, the dock leveler includes a lower end and an upper end, the upper end abuts a preexisting structure and the lower end has a lower edge having a lip, the lip being able to be activated between an extended/engaged position to contact a truck bed and a retracted/disengaged position.

In a load handling system, a load handling operation is performed between a platform and the inside of a container of a container truck. A load handling device that performs the load handling operation includes a mobile robot including, on an unmanned transport vehicle, a robot with a robot arm capable of handling a load. A proper position display unit is installed outside the mobile robot and displays a proper position of the mobile robot relative to a position of the container of the truck. After aligning the mobile robot to the proper position, the mobile robot autonomously travels.

Loading dock systems for detecting trailer door status and/or trailer cargo status and operating loading dock equipment accordingly are disclosed herein. In some embodiments, a loading dock station can include one or more sensors for detecting whether a trailer door is in an open or closed position, and/or whether trailer cargo is loaded in an end load condition, when the trailer is present at the loading dock station. Sensor targets containing, e.g., QR codes, barcodes, and other machine-readable indicia, etc., as well as reflective targets, can be positioned on trailer doors and/or in trailer cargo areas to facilitate detection and acquisition of related door and/or cargo information. In some embodiments, the systems disclosed herein can activate a sequence of automated dock operations in response to determining the status of the trailer doors and/or the trailer cargo.

The invention relates to a goods storage trailer including connection means to allow the trailer to be connected to a tractor unit and a plurality of wheels which allow the trailer to be moved along a surface. The trailer is formed by a base, opposing sidewalls, opposing end walls, a roof and a deck located intermediate the roof and base so as to define two storage areas within the cavity of the trailer. At one of the ends, there is provided a door assembly which is movable between open and closed positions to allow access to the cavity and the base is formed by a plurality of portions at different heights with respect to said support surface and the floor of the base and the upper deck are used to locate goods thereon.

There is an access ramp system for access between a first and a second object. The second object is elevated with respect to the first object. The system includes a supporting frame mountable to the first object; a casing box mounted to the supporting frame; a sliding ramp installed to slide inside the casing box; and a deployment mechanism for automatically moving the sliding ramp between a stand-by and a fully deployed position. In the deployed position, a nose of the sliding ramp is raised to a height equal with the second object and is engaged with the second object. In the deployed position, the sliding ramp and casing box extend across a vertical gap and a horizontal gap between the first and second objects. An upper surface of the sliding ramp and casing box defines a support surface for supporting people or objects moving between the first and second objects.

In a load handling system, a load handling operation is performed between a platform and the inside of a container of a container truck. A load handling device that performs the load handling operation includes a mobile robot including, on an unmanned transport vehicle, a robot with a robot arm capable of handling a load. A proper position display unit is installed outside the mobile robot and displays a proper position of the mobile robot relative to a position of the container of the truck. After aligning the mobile robot to the proper position, the mobile robot autonomously travels.