A dock apparatus includes a plurality of loading dock components. An identification system is coupled with the plurality of loading dock components. A control panel is in signal communication with the plurality of loading dock components via the identification system. The identification system automatically cooperates with the control panel to define an operating sequence of the plurality of loading dock components. A power module is in signal communication with the control panel and an installed component of the plurality of loading dock components. The control panel provides instructions to the power module according to the operating sequence and the power module delivers a predetermined electrical current to the installed components of the plurality of loading dock components in a sequential pattern defined by the operating sequence.

There is provided herein an endoscope assembly comprising at least one front-pointing viewing element on a front end of a distal section of the endoscope assembly, at least one side-looking viewing element on at least one side wall of the distal section of the endoscope assembly, a working channel configured for insertion of a medical tool towards the distal section, and a system for regulating the direction of exit of medical device wherein said system enables the medical device to exit at multiple angles to the long dimension of the endoscope device either from the front end or through side walls of the distal section of the device.

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.

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.

The device includes a first portion which has a leading edge and a trailing edge, the trailing edge is disposed further from the driveway than the leading edge. The embodiment also includes a second portion which has a leading edge and a trailing edge, the leading edge of the second portion is removably attached to the trailing edge of the first portion and the leading edge of the second portion is disposed further from the driveway than the trailing edge of the second portion. The device also includes an extension portion and opposing side portions, the opposing side portions extend the length of and contact the second portion and extension portion. The opposing side portions include at least one light which is controlled by a sensor adjacent to a door.

Tracking and digitization method and system for warehouse inventory management is provided to greatly increase the visibility of the events at a warehouse, provide a comprehensive cataloging of every single event, compare that event against the expected event, and report any discrepancies immediately so that they can be fixed prior to causing costly mistakes. Further, it reduces the need for costly quality control personnel in the warehouse. Embodiments of this invention greatly enhance the accuracy of inventory, at a vastly reduced cost. In an indoor environment, GPS cannot be used to track the location of the forklifts or vehicles in the warehouse because most warehouses have metal constructions and present a “GPS denied” environment. Hence one must resort to vision, lidar, or inertial, or a combination of such sensors to accurately track location.

Aspects of unbinding apparatus, methods, and systems are disclosed. One aspect disclosed herein is an apparatus for unbinding a stacked load of logs. For example, the apparatus may comprise: a plurality of support arms movable toward a plurality of side surfaces of the stacked load, each support arm of the plurality of support arms comprising a guide surface and being: adjustable to abut against one or more side surfaces of the plurality of side surfaces; and independently movable relative to the plurality of support arms in one or more directions responsive to a physical shape of the one or more side surfaces to establish a formfitting abutment between the plurality of support arms and the plurality of side surfaces. In this example, once the formfitting abutment is established, the guide surfaces of the plurality of support arms may be positioned and operative to guide a log released from the stacked load along an escape path over and away from an unbinding area adjacent the stacked load. Aspects of related methods and systems also are disclosed herein.

A system and method for remotely controlling loading dock components is disclosed that includes a distribution center having at least one dock station for exchanging materials and a dock component configured to in at least two operational states. An actuator is included that is configured to change the operational state of the dock component in response to an activation signal. A mobile remote control is configured to generate the activation signal to cause the actuator to change the operational state of the dock component and at least one predefined non-activation zone is included such that changing of operational state of the dock component is inhibited when the mobile remote control is located within the at least one predefined non-activation zone.

The vehicle leveler includes a first portion which has a leading edge and a trailing edge, the trailing edge is disposed further from the driveway than the leading edge. The embodiment also includes a second portion which has a leading edge and a trailing edge, the leading edge of the second portion is attached to the trailing edge of the first portion and the leading edge of the second portion is disposed further from the driveway than the trailing edge of the second portion. The device has opposing side portions and a walkway. The opposing side portions include at least one or more lights which illuminate the leveler and the walkway.

A system and method for operation of an autonomous vehicle (AV) yard truck is provided. A processor facilitates autonomous movement of the AV yard truck, and connection to and disconnection from trailers. A plurality of sensors are interconnected with the processor that sense terrain/objects and assist in automatically connecting/disconnecting trailers. A server, interconnected, wirelessly with the processor, that tracks movement of the truck around and determines locations for trailer connection and disconnection. A door station unlatches/opens rear doors of the trailer when adjacent thereto, securing them in an opened position via clamps, etc. The system computes a height of the trailer, and/or if landing gear of the trailer is on the ground and interoperates with the fifth wheel to change height, and whether docking is safe, allowing a user to take manual control, and optimum charge time(s). Reversing sensors/safety, automated chocking, and intermodal container organization are also provided.