Disclosed is a method for controlling the position relatively to a platform of a floor of a carriage including a bogie including a chassis, a primary suspension, and a secondary suspension, the method including the steps: measuring the height of the secondary suspension; and adjusting the height of the secondary suspension, according to the height of the platform for positioning the floor at the height of the platform. This method includes a step for estimating the height of the top of the chassis, the adjustment of the height of the secondary suspension being achieved according to the estimated height of the top of the chassis.

Disclosed is a method for controlling the position relatively to a platform of a floor of a carriage including a bogie including a chassis, a primary suspension, and a secondary suspension, the method including the steps: measuring the height of the secondary suspension; and adjusting the height of the secondary suspension, according to the height of the platform for positioning the floor at the height of the platform. This method includes a step for estimating the height of the top of the chassis, the adjustment of the height of the secondary suspension being achieved according to the estimated height of the top of the chassis.

A force analysis system and method include a truck assembly that is configured to travel along a track having rails. The truck assembly includes a first side frame, a second side frame, a bolster extending between the first side frame and the second side frame, a first wheel set coupled to the first side frame and the second side frame, a second wheel set coupled to the first side frame and the second side frame, and one or more load cells disposed within the first side frame and/or the second side frame. The load cell(s) are configured to detect forces exerted in relation to the first side frame, the second side frame, and/or the bolster.

A railcar bogie includes a bogie frame including a cross beam and supports, the supports disposed at respective car width direction end portions of the cross beam. There are a plurality of axle boxes to accommodate a plurality of bearings supporting a pair of axles, a plate spring extending in a car longitudinal direction and supported by a pair of the axle boxes which are away from each other in the car longitudinal direction among the plurality of axle boxes. The plate spring supports the cross beam while being pressed by the corresponding support from above such that the pressing member is separable from the plate spring. Elastic walls are at both respective sides of the supports in the car longitudinal direction and sandwiched between a lower surface of the bogie frame and an upper surface of the plate spring so as to be compressed.

A railcar bogie includes a bogie frame including a cross beam and supports, the supports disposed at respective car width direction end portions of the cross beam. There are a plurality of axle boxes to accommodate a plurality of bearings supporting a pair of axles, a plate spring extending in a car longitudinal direction and supported by a pair of the axle boxes which are away from each other in the car longitudinal direction among the plurality of axle boxes. The plate spring supports the cross beam while being pressed by the corresponding support from above such that the pressing member is separable from the plate spring. Elastic walls are at both respective sides of the supports in the car longitudinal direction and sandwiched between a lower surface of the bogie frame and an upper surface of the plate spring so as to be compressed.

A truck assembly of a rail vehicle includes a side frame including a spring seat below an opening. The spring seat includes a locating pocket. An end guide system is coupled to the side frame. The end guide system includes a central base configured to be received and retained by the locating pocket. At least one end guide extends outwardly and upwardly from the central base.

A truck assembly of a rail vehicle includes a side frame including a spring seat below an opening. The spring seat includes a locating pocket. An end guide system is coupled to the side frame. The end guide system includes a central base configured to be received and retained by the locating pocket. At least one end guide extends outwardly and upwardly from the central base.

A railway vehicle condition monitoring apparatus includes a detection device for detecting vehicle information represented by a wheel load or the like of a wheel included in a railway vehicle running on a railroad track, and a determination device including a classifier to which the vehicle information detected by the detection device is input and which outputs a vehicle condition such as the presence or absence of an abnormality of the railway vehicle. The classifier is generated by means of machine learning that uses training data of a railway vehicle of which the vehicle condition is known, the training data being the vehicle information and the vehicle condition which is known, the machine learning being performed so that when the vehicle information of the training data is input to the classifier, the classifier outputs the vehicle condition of the training data.

A stabilizing arrangement for a tilting running gear of a non-rail-borne vehicle is disclosed. The stabilizing arrangement includes a balance beam configured to have each end coupled to a respective suspension side of a multi-track running gear axle of the tilting running gear. A pivot bearing is connected to a frame or body of the vehicle and defines a stationary axis of rotation. The pivot bearing rotatably supports the balance beam about the stationary axis of rotation. At least one stabilizing element is connected to the balance beam and is supported with respect to a frame or body of the vehicle. The at least one stabilizing element is configured to provide a reaction force to counteract a tilting moment of the vehicle. A non-rail-borne vehicle comprising the stabilizing arrangement also is disclosed.

A stabilizing arrangement for a tilting running gear of a non-rail-borne vehicle is disclosed. The stabilizing arrangement includes a balance beam configured to have each end coupled to a respective suspension side of a multi-track running gear axle of the tilting running gear. A pivot bearing is connected to a frame or body of the vehicle and defines a stationary axis of rotation. The pivot bearing rotatably supports the balance beam about the stationary axis of rotation. At least one stabilizing element is connected to the balance beam and is supported with respect to a frame or body of the vehicle. The at least one stabilizing element is configured to provide a reaction force to counteract a tilting moment of the vehicle. A non-rail-borne vehicle comprising the stabilizing arrangement also is disclosed.