Disclosed is an interconnected transportation network system, wherein same is related to the field of transportation facilities and control, and comprises a main transportation system, a transfer system and an entry/exit system. The main transportation system is formed of a closed annular rail vehicle, and the annular train moves continuously on a T-shaped track to fulfil a passenger transportation task by means of multi-point drive. The transfer system (intercommunication) is of the same structure as that of the main transportation system, and the passengers transfer between main transportation lines by means of the transfer system. The entry/exit system (terminal) is formed of an annular buffer vehicle system and a stepping speed control system, and the passengers enter or exit the main transportation lines in a self-service manner by means of the entry/exit system.

A vacuum pipeline magnetic levitation conveying device is provided, the device includes: multiple sites sequentially connected through the vacuum pipeline; three fixed tracks parallel to each other, are disposed in the vacuum pipeline, and extend along an extension direction of the vacuum pipeline, where the three fixed tracks determine a circumscribed circle, and the three fixed tracks are evenly distributed on the circumscribed circle; the train disposed in the vacuum pipeline, where a body of the train is provided with three moving tracks, the three moving tracks are evenly distributed around the train and are parallel to each other; three fixed tracks, where the three moving tracks correspond to the three fixed tracks one by one, and the three moving tracks are coupled with the fixed tracks in a magnetic levitation manner, which makes a guiding running of the train inside the vacuum pipeline safer and more stable.

A vacuum pipeline magnetic levitation conveying device is provided, the device includes: multiple sites sequentially connected through the vacuum pipeline; three fixed tracks parallel to each other, are disposed in the vacuum pipeline, and extend along an extension direction of the vacuum pipeline, where the three fixed tracks determine a circumscribed circle, and the three fixed tracks are evenly distributed on the circumscribed circle; the train disposed in the vacuum pipeline, where a body of the train is provided with three moving tracks, the three moving tracks are evenly distributed around the train and are parallel to each other; three fixed tracks, where the three moving tracks correspond to the three fixed tracks one by one, and the three moving tracks are coupled with the fixed tracks in a magnetic levitation manner, which makes a guiding running of the train inside the vacuum pipeline safer and more stable.

A passenger carrier of a transportation system includes a main body to carry a first group of passengers, a detachable departure compartment, detachably coupled to the main body, to carry a second group of passengers, and a processing device to issue a control signal to trigger a decoupling between the departure compartment and the main body, allowing the main body to travel along a first path without stop at a station and allowing the departure compartment to travel along a second path to enter and stop at the station.

A passenger carrier of a transportation system includes a main body to carry a first group of passengers, a detachable departure compartment, detachably coupled to the main body, to carry a second group of passengers, and a processing device to issue a control signal to trigger a decoupling between the departure compartment and the main body, allowing the main body to travel along a first path without stop at a station and allowing the departure compartment to travel along a second path to enter and stop at the station.

A device for transporting freight articles in a ground or rail haul operations comprises a hollow housing including four corner sections, side walls, two center sections defining four openings each disposed between one edge of a center section and an edge of a respective corner section, a bottom portion and a top portion, wherein the two center portions are manufactured from see through or clear material. A door is mounted to selectively open and close a respective opening and swinging outwardly and towards a respective corner portion to selectively open the respective opening. Two channels are provided in the bottom portion, each in open communication with opposite sides of the bottom portion. Four feet or wheels are mounted on the bottom portion. Four receptacles are provided in the top portion, each sized and shaped to receive a foot therewithin.

A roadway conduit system includes a roadway conduit section that includes a floor portion with roadway surface configured to receive traveling vehicles, a ceiling portion, and at least one sidewall portion coupled to the floor portion and the ceiling portion such that the floor, ceiling, and at least one sidewall portions define a roadway conduit volume through which the traveling vehicles traverse the roadway conduit section. The roadway conduit section includes at least two fixedly connected preformed segments. The roadway conduit system also includes a roadway conduit ingress coupled to a first location of the roadway conduit section; a roadway conduit egress coupled to a second location of the roadway conduit section; and at least one air mover configured to circulate an airflow in the roadway conduit volume in a direction of at least one of the traveling vehicles.

A roadway conduit system includes a roadway conduit section that includes a floor portion with roadway surface configured to receive traveling vehicles, a ceiling portion, and at least one sidewall portion coupled to the floor portion and the ceiling portion such that the floor, ceiling, and at least one sidewall portions define a roadway conduit volume through which the traveling vehicles traverse the roadway conduit section. The roadway conduit section includes at least two fixedly connected preformed segments. The roadway conduit system also includes a roadway conduit ingress coupled to a first location of the roadway conduit section; a roadway conduit egress coupled to a second location of the roadway conduit section; and at least one air mover configured to circulate an airflow in the roadway conduit volume in a direction of at least one of the traveling vehicles.

The present invention relates to a system, server, and method for automatically calculating a platform dwell time of a train. The system includes a passenger detection device configured to determine the number of passengers who board or deboard a train entering a station; an operation control server configured to calculate an appropriate dwell time of the train by using the number of passengers, which is received from the passenger detection device; and an ATO device configured to control a dwell time of the train by using the appropriate dwell time, which is received from the operation control server.

The present invention relates to a system, server, and method for automatically calculating a platform dwell time of a train. The system includes a passenger detection device configured to determine the number of passengers who board or deboard a train entering a station; an operation control server configured to calculate an appropriate dwell time of the train by using the number of passengers, which is received from the passenger detection device; and an ATO device configured to control a dwell time of the train by using the appropriate dwell time, which is received from the operation control server.