A loading system includes one or more adjusting mechanisms configured to adjust a position of the container held by the container holder, a controller configured to control operation of the one or more adjusting mechanisms, a transfer mechanism configured to move a loadable object into a holding space of the container with the container held by the container holder to transfer the loadable object to the container, and one or more position detectors. The one or more position detectors are located to detect a relative position of a loadable object when the loadable object is held by the transfer mechanism and is in the holding space. The controller is configured to perform an adjusting control in which the position of the container is adjusted to place the container in a proper position with respect to the loadable object, the adjusting control being performed based on detected information from the one or more position detectors, and being performed during at least a portion of a process of transferring the loadable object by the transfer mechanism, and being completed before the loadable object becomes supported by the container.

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.

A trailer stabilizing device for stabilizing a parked freight trailer comprising a frame having mounted thereto at least a right side wheel and a left side wheel, the frame also including a hitch, a fifth wheel, and at least one of a repositionable wheel chock and a repositionable hook, the trailer stabilizing device further including a repositioning device in order to reposition at least one of the repositionable wheel chock and the repositionable hook. The present disclosure also includes a method of stabilizing a parked trailer at a loading dock, the method comprising: (a) positioning a wheeled trailer stabilizer underneath a parked freight trailer at a loading dock while landing gear of the parked freight trailer are deployed and a kingpin of the parked trailer is accessible; (b) securing the kingpin of the parked freight trailer to a fifth wheel of the wheeled trailer stabilizer; and, (c) deploying a repositionable hook operatively coupled to the frame of the wheeled trailer stabilizer so the repositionable hook couples to a cleat mounted to the ground, where deployment of the hook is operative to exert a pulling force on the kingpin.

Example vehicle restraints with a barrier having rotational and translational motion are described. An example vehicle restraint includes a carriage frame movable vertically relative to the dock. A drive shaft is supported by the carriage frame. A drive unit is to rotate the drive shaft about a shaft axis and relative to the carriage frame. A hub is connected to rotate with the drive shaft about the shaft axis, the hub having an outer diameter surface that is radially off center relative to the shaft axis. A barrier defines a bore that encircles the outer diameter surface of the hub. The barrier is movable selectively to an extended position and a retracted position. The barrier being connected to move selectively to the extended position and the retracted position in response to relative rotation between the outer diameter surface of the hub and the bore of the barrier.

The present invention is an impact vehicle restraint with a hook and auxiliary securing/locking mechanism that combine to secure the RIG bar of a trailer to a loading dock. A motor rotates the hook between retracted and extended positions. When extended, the hook secures and holds the RIG bar to the dock. When the hook is extended, the auxiliary securing/locking mechanism is also extended to and held at a set position by a biasing mechanism. When the hook is blocked by an obstruction, forward movement of the trailer causes the RIG bar and the obstruction to slide into engagement with the auxiliary securing/locking mechanism, which accepts the RIG bar and obstruction and moves to a locked position to secure the RIG bar. The retraction of the hook by the motor overpowers the biasing mechanism and causes the retraction of the auxiliary securing/locking mechanism.

Pedestrian-Vehicle safety systems for loading docks are disclosed. An example system includes a first sensor system to determine a position of a vehicle relative to a pedestrian zone adjacent a dock wall of a loading dock and a second sensor system to monitor the pedestrian zone. The second sensor system to attempt to detect a pedestrian in the pedestrian zone, the second sensor system responsive to signals from the first sensor system to enable the second sensor system to dynamically change a sensing area of the pedestrian zone to maintain a delta threshold between the vehicle and the pedestrian zone in response to the vehicle moving toward a dock wall of the loading dock.

A docking plate apparatus is provided for motorized floor conveyor vehicles, such as conveyance tuggers, that is particularly structured to provide tactile feedback at a determined stop position for improved docking and/or stopping placement. The docking plate apparatus has a structure and dimensions to ensure that the motorized floor conveyor vehicle is docked exactly in a determined stop position that is deemed most optimal for interaction with a delivery system. The docking plate apparatus can comprise body, which is a flat panel structure, and a docking aperture that is structured in a portion of the body. The docking aperture receiving at least one wheel of a motorized floor conveyor vehicle to dock the motorized vehicle in a determined stop position for interaction with the delivery system.

The present magnet holder and magnetic sensor bracket provide a robust, easily repaired magnet-and-sensor system. The axle extending through the holder and bracket is easily aligned in a shaft collar in the holder by an interlocking keyway. A slot extending through the collar allows deformation of the split collar to accommodate over-rotation without damage to the collar. The magnet assembly in the holder is held in place based on magnetic attraction, allowing both easy assembly and replacement. Likewise, the potential sensor attachment methods allow easy, rapid fabrication and replacement using assemblies with split sensor channels and retaining rings.

A blocking device (11) for a truck (2) is provided. The blocking device (11) includes at least one height-adjustable blocking arm (24), wherein the at least one blocking arm (24) includes a telescopable plunger (29). The plunger (29) is movable from below the truck (2) against a truck underride guard (5), whereby a rolling-away or driving-away of the truck is prevented.

Systems and associated methods for controlling operation of loading dock equipment are disclosed herein. In some embodiments, the system and associated methods can be used to control operation of loading dock equipment (e.g., a vehicle restraint, a dock door, a dock leveler, etc.) according to a preset sequence of operations. The system can include a display screen that sequentially presents a series of graphical control elements (e.g., touch-sensitive buttons) that enable operation of the loading dock equipment in an appropriate sequence. Additionally, the visual appearance and/or sequence of presentation of the graphical control elements indicate the proper sequence of selection to the user, thereby reducing user confusion and simplifying the operation of the loading dock equipment.