An integrated mobility system includes at least one road module, at least one railway module adapted to contain a plurality of road modules therein, and a plurality of loading/unloading infrastructures arranged in a plurality of boarding and unboarding stations scattered over a territory to allow operations for boarding/unboarding the road modules from the railway module. The railway module can be a two-story high-speed railway module. The boarding/unboarding stations are equipped with the loading/unloading infrastructures arranged so that the operations for boarding/unboarding the road module with respect to the railway module are always possible regardless of the position occupied by the road module inside the railway module, and regardless of simultaneous boarding and unboarding of other road modules. The road module and the railway module are arranged to be automatically interconnected to each other in the condition in which the road module is received inside the railway module.

A rail vehicle includes a roof structure that configures an upper face, a side structure that configures a side face, a gable end structure that configures an end face in a longitudinal direction, and an underframe that configures a lower face. The underframe is configured from a hollow shaped member formed from two face plates and a rib that connects the face plates to each other. The hollow member that configures the underframe includes a first upper side face plate arranged at a central portion in a widthwise direction of the underframe, a first lower side face plate arranged at the central portion in the widthwise direction of the underframe, a second upper side face plate arranged at an end portion in the widthwise direction of the underframe and positioned below the first upper side plate, a second lower side face plate arranged at the end portion in the widthwise direction of the underframe and positioned below the first lower side face plate, a third upper side face plate that connects the first upper side plate and the second upper side plate to each other, and a third lower side face plate that connects the first lower side face plate and the second lower side face plate to each other. A space is provided below the first lower side face plate, and a closing plate that connects adjacent end portions of a pair of the second lower side face plates to each other is arranged in the space.

A system and method are for managing the energy supplied to a transport vehicle. A first and a second source of energy provide electrical energy to power at least one piece of consumer equipment of the vehicle. An intermediate energy transmission system receives electrical energy provided by at least one of the two sources of energy and transfers it to the at least one piece of consumer equipment. An energy conversion-control system applies, at the input of the intermediate energy transmission system, the electrical energy to be provided, adjusted depending on the operational state of the first source of energy and on an input signal indicative of an operational state of the second source. The first source of energy includes an internal combustion engine connected to a permanent-magnet alternator that is placed between the internal combustion engine and the energy conversion-control system.

A floor panel (100) for transport means, in particular for trains, ships or boats, the floor panel (100) comprising a metal plate (1); at least one heating cable (2, 3) adapted to generate heat when it is crossed by electric current; a net (4) provided with a plurality of meshes (41); wherein said at least one heating cable (2, 3) is arranged between the net (4) and the metal plate (1). wherein said at least one heating cable (2, 3) is in contact with the metal plate (1).

A system is described comprising a first compressor for generating compressed air to feed a main tank and a main brake pipe of the railway vehicle through an air drying unit and a second compressor for compressing a refrigerant gas for an air conditioning system. The system comprises a single electric motor for generating a mechanical torque to be selectively supplied to the first compressor, or to the second compressor, or simultaneously to the first and second compressors, as a function of a) a first electrical signal generated by a pressure measurement device and indicative of a pressure present in the main brake pipe, or in the main tank, and b) at least a second electrical signal coming from the air conditioning system and indicative of a temperature or pressure or humidity value, and at least a third electrical signal indicative of a temperature of an environment.

A system is described comprising a first compressor for generating compressed air to feed a main tank and a main brake pipe of the railway vehicle through an air drying unit and a second compressor for compressing a refrigerant gas for an air conditioning system. The system comprises a single electric motor for generating a mechanical torque to be selectively supplied to the first compressor, or to the second compressor, or simultaneously to the first and second compressors, as a function of a) a first electrical signal generated by a pressure measurement device and indicative of a pressure present in the main brake pipe, or in the main tank, and b) at least a second electrical signal coming from the air conditioning system and indicative of a temperature or pressure or humidity value, and at least a third electrical signal indicative of a temperature of an environment.

A railcar floor structure includes: a plurality of floor panels arranged over an entire length of a passenger room of a railcar in a car longitudinal direction and including respective electric heaters; a wiring duct extending in the car longitudinal direction and arranged between a side bodyshell and car width direction end portions of the floor panels; an electricity supply cable arranged at the wiring duct, electric power being supplied to the electric heaters through the electricity supply cable; and a wire insertion opening formed at a side wall portion of the wiring duct, the side wall portion being located close to the floor panels and extending along the car longitudinal direction, the electricity supply cable passing through the wire insertion opening.

A refrigerated railcar system that is configured to have a plurality of reefers operably coupled thereto wherein the present invention provides improved electrical coupling of the reefers. The refrigerated railcar system of the present invention includes a plurality of railcars that are operable to have secured thereto reefers ranging from twenty to fifty-three feet. The railcars have a first end and a second end with an electrical junction box present at each end. A generator railcar is present in the system and is electrically coupled to an adjacent railcar present on opposing ends thereof. The generator railcars include subpanel modules and a wiring harness that are operable to electrically couple to electrical junction boxes present at opposing ends of the generator railcars. A platform is coupled to the container of the generator railcar and is configured to have the wiring harness secured underneath thereto.

An assembly-type car body and a rail vehicle. A roof, an underframe, side roofs and side walls of the assembly-type car body are separately formed by assembling double-layer pultruded profiles, and each double-layer pultruded profile comprises an outer plate, an inner plate and cavities formed by separating an interlayer between the outer plate and the inner plate using ribs; the upper edge and the lower edge of each side roof are respectively connected to an edge of the roof and the upper edge of a side wall by means of lapping joints, and the lower edge of each side wall is connected to an edge of the underframe by means of a side wall connector; each side wall connector is a double-layer pultruded profile unit, the upper edge of the side wall connector is connected to the lower edge of the side wall by a plug joint.

The vehicle air conditioning apparatus comprises at least one physical condition information sensor which detects information on physical conditions of passengers in a vehicle as physical condition information. The vehicle air conditioning apparatus selectively executes an outside-air circulation control for discharging air from an interior of the vehicle to outside of the vehicle and introducing outside air to the interior of the vehicle from the outside of the vehicle and an interior-air circulation control for taking the air from the interior of the vehicle and returning the taken air to the interior of the vehicle. The vehicle air conditioning apparatus executes the outside-air circulation control when the electronic control unit determines that at least one of the passengers has an infection, based on the physical condition information.