A body (1) for a rail vehicle (100) comprising a control panel (4) for controlling the rail vehicle (100). The control panel (4) has a rest position and an operational position and, in the rest position, is located in a control panel holder (41) while, in the operational position, is at least partially located outside the control panel holder (41) such that control elements (42) are accessible for operation.

A driver's cab for an interoperable rail vehicle has a front window and a seat arrangement with two seats for operating personnel. A standard field of view is defined for each of the seats. The standard fields of view overlap at least partially in the projection thereof onto the front window. There is also described a rail vehicle.

A driver's cab for an interoperable rail vehicle has a front window and a seat arrangement with two seats for operating personnel. A standard field of view is defined for each of the seats. The standard fields of view overlap at least partially in the projection thereof onto the front window. There is also described a rail vehicle.

Conventional APUs for diesel-electric locomotives may include an AC electric generator and typically require additional hardware to be installed to convert the AC power output by the generator to DC power that can power electrical systems or charge batteries in the locomotive. According to some embodiments, there is provided an auxiliary power unit (APU) or system for operation in cooperation with a primary engine. The APU includes a secondary engine; a primary engine coolant heating system, or a primary engine lubricant heating system; a control system that automatically shuts down the primary engine and starts the secondary engine responsive to a predetermined condition; and a Direct Current (DC) power generator that generates an output voltage, the DC power generator being driven by the secondary engine.

Conventional APUs for diesel-electric locomotives may include an AC electric generator and typically require additional hardware to be installed to convert the AC power output by the generator to DC power that can power electrical systems or charge batteries in the locomotive. According to some embodiments, there is provided an auxiliary power unit (APU) or system for operation in cooperation with a primary engine. The APU includes a secondary engine; a primary engine coolant heating system, or a primary engine lubricant heating system; a control system that automatically shuts down the primary engine and starts the secondary engine responsive to a predetermined condition; and a Direct Current (DC) power generator that generates an output voltage, the DC power generator being driven by the secondary engine.

A modular foot platform for a driver's cab of a rail vehicle includes at least a base frame having a height adjustment mechanism, an intermediate frame mounted on the base frame, and a step plate lying on the intermediate frame. The height adjustment mechanism includes at least one operating element, which is disposed at least partially in a region on or above the top side of the step plate, which top side faces away from the base frame. A rail vehicle having a driver's cab and a modular foot platform disposed therein is also provided.

A modular foot platform for a driver's cab of a rail vehicle includes at least a base frame having a height adjustment mechanism, an intermediate frame mounted on the base frame, and a step plate lying on the intermediate frame. The height adjustment mechanism includes at least one operating element, which is disposed at least partially in a region on or above the top side of the step plate, which top side faces away from the base frame. A rail vehicle having a driver's cab and a modular foot platform disposed therein is also provided.

A transformer holding device for an electric locomotive having a transformer, includes at least one transformer support which is configured in such a way that the transformer can be displaced on an underframe of the electric locomotive during a maintenance operation so that the electric locomotive attains a predetermined center of gravity position. The transformer is fixed to the underframe of the electric locomotive during operation. A transformer arrangement for an electric locomotive and an electric locomotive are also provided.

A transformer holding device for an electric locomotive having a transformer, includes at least one transformer support which is configured in such a way that the transformer can be displaced on an underframe of the electric locomotive during a maintenance operation so that the electric locomotive attains a predetermined center of gravity position. The transformer is fixed to the underframe of the electric locomotive during operation. A transformer arrangement for an electric locomotive and an electric locomotive are also provided.

An electrically operated vehicle includes a braking resistor in a heat sink cover. The heat sink cover has an air throughflow body having vent openings and an air throughflow direction perpendicular to a direction of travel of the vehicle. The heat sink cover includes an inlet flap on an air inflow side and an outlet flap on an air outflow side. An opening mechanism opens and closes the flaps. In the closed state, the flaps are oriented along the direction of travel and obliquely to the air throughflow direction. In a plan view of the vent openings, the vent openings are at least 90% covered by the flaps in the closed state and at most 60% covered by the flaps in the opened state. The flaps are disposed symmetrically to a vehicle center axis, and the vent openings are oriented parallel to side surfaces of the vehicle.