A logistic monorail transportation system. The logistic monorail transportation system comprises a logistic track beam system, a logistic vehicle system, a logistic turnout system, a logistic handling system, and a logistic signal system. The logistic track beam system is set up on the road, in the field, or in the streets in the form of single-column pier studs or frame-type pier shads. The technical solution of the present application solves the problems of short distance, high costs, and low speed of existing transportation systems, and the purpose of long-distance, low-cost, and high-speed logistic monorail transportation is achieved.

A high-speed transportation system, the system including at least one transportation path having at least one track, at least one transportation vehicle configured for travel along the at least one transportation path, a propulsion system adapted to propel the at least one transportation vehicle along the at least one transportation path; and a levitation system adapted to levitate the transportation vehicle along the at least one transportation path. The at least one transportation vehicle additionally comprises wheels for at least intermittently supporting the transportation vehicle on the at least one track.

Embodiments related to a rail system for use with a personal rapid transit system are disclosed. In some embodiments, a railway may include a first rail configured to engage and support a bogie of a vehicle and a lift rail may be configured to engage and support the bogie of the vehicle. The lift rail, which may be a lift arm including a short section of rail that is attached at one end to a lift, may be configured to change a position of the lift rail to transition the vehicle between different desired positions. In another embodiment, a railway may include a first pair of main rails intersecting a second pair of main rails, where the second pair of main rails are divided by the first pair of main rails and a portion of the second pair of main rails are configured to hold one or more stationary vehicles.

An anomaly determination device includes a changeover force measurement unit that measures a changeover force output by a driving device, the driving device outputting a changeover force for switching a direction of a branch rail whose direction is variable, a voltage measurement unit that measures a voltage supplied to the driving device, a current measurement unit that measures a current flowing through the driving device, and an anomaly determination unit that determines whether or not there is an anomaly in the branch rail, there is an anomaly in the driving device, and there is an anomaly in power supplied to the driving device on the basis of the magnitude of the changeover force, the magnitude of the voltage, and the magnitude of the current.

A system and method to ensure a sufficient amount of electrical energy is supplied to a cable-drawn vehicle of a transportation device. Electrical loads of the vehicle are supplied with power outside a station by an electrical energy store of the vehicle or by both an electrical energy store and the generator during a first movement phase, in which the vehicle is accelerated to a limit speed or, conversely, decelerated from a limit speed into a station. In a subsequent second movement phase, the vehicle is supplied with electrical energy by the generator while the vehicle moves at a speed that is greater than the limit speed.

The present invention relates to an operating and locking mechanism for diamond crossings of central rail-guided vehicles, comprising: a sliding plate (2A) fixed to a fixed part (2) of the diamond crossing forming a channel in its central area in the direction of the X axis, a guide block (10) fixed to the sliding plate (2A) comprising four guide grooves (10A, 10B, 10C, 10D) in the form of circular sectors located on the main plane of the guide block (10), the geometric center of which coincides with a theoretical pivoting point (17) of a moving panel (6) of the diamond crossing, where the sliding plate (2A) and the guide block (10) form a rectangular section groove (2F) the axis of which is parallel to the direction of the X axis, four shafts (12A, 12B, 13A, 13B) fixed to the moving panel (6) symmetrically with respect to a guide rail (7) of said moving panel (6) and perpendicular to the main plane of the moving panel (6), comprising respective rollers (12E, 12F, 13E, 13F) that can be moved and rolled respectively within the guide grooves (10A, 10B, 10C, 10D), and a cam plate (14) sliding in the longitudinal direction within the groove (2F) formed by the sliding plate (2A) and the guide block (10).

A switch is described. The switch is for interconnecting a first rail providing a first portion of a running surface for a wheel and a second rail providing a second portion of the running surface wherein a first end of the first rail and an opposed second end of the second rail are axially mutually spaced apart by a first spacing. The switch comprises a set of rail segments including a first rail segment, having a first end, a second end and a first length therebetween correlating with the first spacing. The switch is arrangeable in a first configuration, wherein the first rail segment is arranged to interconnect the first rail and the second rail, thereby providing an interconnecting portion of the running surface between the first portion and the second portion. The switch is arrangeable in a second configuration, wherein the first rail segment is transversely spaced apart from the first rail and/or the second rail. The switch is arranged to move from the first configuration to the second configuration by a first transverse movement of the first rail segment.

Controlling a level crossing of a railway track by providing a train having an onboard processor communicating with a wayside processor associated to a level crossing, said train having a forward end and a rear end; moving the train forward along the railway track lowering down gates of the level crossing when train is at a predetermined distance upon detection of the train approaching the level crossing; when the forward end passes over a first reference point defining the beginning of an island area of the level crossing, sending a first message from the onboard safety processor towards the wayside processor informing that the train is approaching the level crossing; maintaining down gates; when the rear end passes over a second reference point defining the end of the island area, sending a second message from the onboard safety processor to the wayside processor informing that the train has left the level crossing; and lifting the gates.

The present aspects refer to a method for prioritizing railway crossing flows comprising: defining residence location nodes, daily-activity location nodes and level crossing nodes within a zone of influence; generating a graph comprising the residence location nodes, daily-activity location nodes and level crossing nodes and a set of edges, wherein said edges connect the residence location nodes, daily-activity location nodes and level crossing nodes, generating a connected component containing residence location nodes, daily-activity location nodes and level crossing nodes; and obtaining a vector comprising the level crossing nodes in descending order of the value assigned to each level crossing node. The present aspects also refer to a memory storage medium comprising computer-executable instructions for implementing a method for prioritizing railway crossing flows.

In order to provide a cable car that enables an operation as autonomous as possible with the highest possible safety for persons, it is provided that in at least one cable car station a detection apparatus is provided for detecting a measurement variable of an airborne sound, that a classification unit is provided that is designed for this purpose, to identify at least one defined safety-relevant sound event from the measurement variable or a variable derived therefrom, and in that the control unit is designed to operate the cable car in a defined safety operating mode when a defined safety-relevant sound event is identified.