An overpass structure with vertical interchange arrangement for crossroads includes a transverse roadway at a bottom level, a pedestrian walkway in the middle level and a longitudinal road bridge at an upper level. The vehicle roadways on and under the bridge are connected by two ramp units. The pedestrian walkway is a pedestrian platform with an interchange platform provided on top. The interchange platform is located between and connected to two roadways of opposite directions on the longitudinal road bridge in the upper level. The leftmost lane along a forward moving direction of vehicle on the bridge in the longitudinal road bridge is defined as a universal lane of the longitudinal road bridge. The rightmost lane along a forward moving direction of vehicle under the bridge in the transverse roadway is defined as a universal lane of the transverse roadway. The interchange platform is connected to four universal lanes.

An overpass structure with vertical interchange arrangement for crossroads includes a transverse roadway at a bottom level, a pedestrian walkway in the middle level and a longitudinal road bridge at an upper level. The vehicle roadways on and under the bridge are connected by two ramp units. The pedestrian walkway is a pedestrian platform with an interchange platform provided on top. The interchange platform is located between and connected to two roadways of opposite directions on the longitudinal road bridge in the upper level. The leftmost lane along a forward moving direction of vehicle on the bridge in the longitudinal road bridge is defined as a universal lane of the longitudinal road bridge. The rightmost lane along a forward moving direction of vehicle under the bridge in the transverse roadway is defined as a universal lane of the transverse roadway. The interchange platform is connected to four universal lanes.

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.

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 railroad train marshaling system or method includes a railroad train with cars within a platform area. Door-free cars are connected with the cars within platform area at both ends or one end and made up of at least one car with no side door for passengers to get on and off the train. When the railroad train stops at the platform, the cars within the platform area are arranged to stop within the area of the platform or corresponding to the platform. The door-free car is arranged to stop beyond platform area and passengers in the door-free car will get to the platform directly from the car within platform area. The sum of length of door-free car and cars within platform area is more than a length of the platform.

A railroad train marshaling system or method includes a railroad train with cars within a platform area. Door-free cars are connected with the cars within platform area at both ends or one end and made up of at least one car with no side door for passengers to get on and off the train. When the railroad train stops at the platform, the cars within the platform area are arranged to stop within the area of the platform or corresponding to the platform. The door-free car is arranged to stop beyond platform area and passengers in the door-free car will get to the platform directly from the car within platform area. The sum of length of door-free car and cars within platform area is more than a length of the platform.

A high-carrying-capacity non-stop rail transit system, wherein, comprising a main passage, a main rail arranged in the main passage, an exit and entrance passage and independent small compartments, wherein, the independent small compartment is provided with a connecting device, the exit and entrance passage is provided with a rail change structure, the connecting device realizes transfer and rail change between the main passage and the exit and entrance passage through the rail change structure, the main rail is used to place the independent small compartment and drive the independent small compartment to move. The system adopts the independent small compartment mode, so every passenger has a seat and the non-stop purpose is realized; stable and continuous kinetic energy for advancing are provided; and the independent small compartments have no relative displacement and can reach a high speed under high density.

A high-carrying-capacity non-stop rail transit system, wherein, comprising a main passage, a main rail arranged in the main passage, an exit and entrance passage and independent small compartments, wherein, the independent small compartment is provided with a connecting device, the exit and entrance passage is provided with a rail change structure, the connecting device realizes transfer and rail change between the main passage and the exit and entrance passage through the rail change structure, the main rail is used to place the independent small compartment and drive the independent small compartment to move. The system adopts the independent small compartment mode, so every passenger has a seat and the non-stop purpose is realized; stable and continuous kinetic energy for advancing are provided; and the independent small compartments have no relative displacement and can reach a high speed under high density.

A railroad train marshaling system or marshaling method is disclosed. The railroad train includes cars within platform area which are made up of several cars; door-free cars which are connected with the cars within platform area at both ends or one end and made up of at least one car with no side door for passengers to get on and off the train. When the railroad train stops at the platform, the cars within platform area are arranged to stop within the area of platform or corresponding to the platform, the door-free car is arranged to stop beyond platform area and passengers in the door-free car will get to the platform directly from the car within platform area. The sum of length of door-free car and cars within platform area is more than that of the platform.