A telescopic plate includes a sliding rail structure (10), a rotation structure (20), a drive structure (30) including a motor (31), a circulation structure (40) including an upper connection member (41) and a lower connection member (42), and a support frame (50) mounted on the telescopic sliding rail. The sliding rail structure includes a fixed sliding rail (11) and a telescopic sliding rail (12); the rotation structure including a double-groove wheel (21) mounted at one end of the motor; the upper and lower connection members are wound on the double-groove wheel and extend into the fixed sliding rail to fix with the telescopic sliding rail; a positioning bolt (111) is provided on an inner wall at the tail end of the fixed sliding rail; a positioning groove (1211) is provided at the front end of the telescopic sliding rail; the upper and lower connection members pull the telescopic sliding rail to implement sliding of the support frame in the fixed sliding rail; the positioning bolt and the positioning groove are cooperative so that the telescopic sliding rail rotates around the positioning bolt. A motor is used for controlling to slide and rotate the support frame; a rotation angle can be adjusted by means of a remote-control operation so as to meet user requirements.

In one aspect, a method is provided for controlling access to a facility including a movable barrier and a plurality of loading docks. The method includes receiving, from a user device associated with a vehicle, a check-in communication that includes a check-in identifier. The method includes receiving a verification communication that verifies a presence of the vehicle relative to a sensor associated with the movable barrier. The method further includes causing a movable barrier operator associated with the movable barrier to move the movable barrier between closed and open positions in response to the check-in identifier indicating authorization to access the facility and in response to receiving the verification communication. Further, the method includes selecting a particular loading dock from the plurality of loading docks and communicating a loading dock identification representative of the particular loading dock to the user device to direct the vehicle to the particular loading dock.

A momentum arresting ramp that includes a plurality of steps that each includes a slider receiving surface and a transition surface. The steps may enable a device with wheels to be moved down the ramp by a user, without inconvenient gravity building momentum of the device down the ramp. For example, the steps may be spaced apart along a first axis such that a first slider of the device is never in contact with one of the transition surfaces when a second slider of the device is in contact with another one of the transition surfaces. The configuration of the steps and the sliders may enable the device (e.g., a device heavy enough to typically require two users to unload using a planar ramp) to be easily and conveniently unloaded by a single user.

Unloading conveyor systems are provided. Some embodiments have a transport configuration and an operating configuration.

A telescopic plate includes a sliding rail structure (10), a rotation structure (20), a drive structure (30) including a motor (31), a circulation structure (40) including an upper connection member (41) and a lower connection member (42), and a support frame (50) mounted on the telescopic sliding rail. The sliding rail structure includes a fixed sliding rail (11) and a telescopic sliding rail (12); the rotation structure including a double-groove wheel (21) mounted at one end of the motor; the upper and lower connection members are wound on the double-groove wheel and extend into the fixed sliding rail to fix with the telescopic sliding rail; a positioning bolt (111) is provided on an inner wall at the tail end of the fixed sliding rail; a positioning groove (1211) is provided at the front end of the telescopic sliding rail; the upper and lower connection members pull the telescopic sliding rail to implement sliding of the support frame in the fixed sliding rail; the positioning bolt and the positioning groove are cooperative so that the telescopic sliding rail rotates around the positioning bolt. A motor is used for controlling to slide and rotate the support frame; a rotation angle can be adjusted by means of a remote-control operation so as to meet user requirements.

A system for allowing a chassis for an intermodal shipping container having fittings and a floor to be secured to a loading dock is provided. The system is capable of being stowed away into the chassis when not in use, and moveable to a locking position for interfacing with the dock's restraining system when the chassis is to be secured to the loading dock.

Loading ramp for loading platforms, including a bridge plate which at its loading platform side rotatably is connected to the loading platform and at its front side is provided with a lip, which lip, from a retracted position, in which the lip is taken up underneath the bridge plate, is extendible from the front side of the bridge plate forward into an extended position, in which extended position a foremost lip part, being provided to the front side of the lip, is intended to rest upon the loading floor of a vehicle, whereby underneath the bridge plate, completely or partly, a layer of insulating material is provided, wherein in the extended position underneath the lip a further layer of insulating material is present.

A temperature control docking system (TCDS) is configured for providing temperature controlled air for circulation within one or more freight trailers. The freight trailers are engaged with corresponding control docks of the TCDS, each control dock additionally defining a docking door configured between a closed configuration and an open configuration. The docking door separates the interior of the TCDS from an exterior thereof (and from the freight trailer). Upon engaging the freight trailer with the control dock, the docking door is configured to an open configuration, and a temperature maintenance unit positioned within the interior of the TCDS and corresponding with the control dock provides temperature controlled air for circulation within the interior of the freight trailer so as to maintain a desired temperature within the freight trailer.

A temperature control docking system (TCDS) is configured for providing temperature controlled air for circulation within one or more freight trailers. The freight trailers are engaged with corresponding control docks of the TCDS, each control dock additionally defining a docking door configured between a closed configuration and an open configuration. The docking door separates the interior of the TCDS from an exterior thereof (and from the freight trailer). Upon engaging the freight trailer with the control dock, the docking door is configured to an open configuration, and a temperature maintenance unit positioned within the interior of the TCDS and corresponding with the control dock provides temperature controlled air for circulation within the interior of the freight trailer so as to maintain a desired temperature within the freight trailer.

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.