A charging system for an electric vehicle has an elongate enclosure having a plurality of sides and an at least partially open side. The enclosure defines a hollow interior. The charging system further includes a conductor rail disposed in the hollow interior and that is accessible through the at least partially open side of the enclosure. The conductor rail may be placed in electric communication with an electrical power source and thereby may be selectively placed in electrical communication with an electrical connector of an electric vehicle. The charging system may conduct electric current from the electrical power source to an electric power supply of the electric vehicle.

A charging module for an electric vehicle includes an enclosure having a plurality of sides and an at least partially open top, the enclosure defining a hollow interior; a conductor rail disposed in the at least partially open top of the enclosure, the conductor rail being configured to be placed in electric communication with an electrical power source; and at least one external insulator disposed in the at least partially open top of the enclosure adjacent to the conductor rail. The at least one external insulator is disposed between the conductor rail and at least one of the sides of the enclosure. The conductor rail is configured to transmit electrical energy from the electrical power source to the electric vehicle.

A charging module for an electric vehicle includes an enclosure having a plurality of sides and an at least partially open top, the enclosure defining a hollow interior; a conductor rail disposed in the at least partially open top of the enclosure, the conductor rail being configured to be placed in electric communication with an electrical power source; and at least one external insulator disposed in the at least partially open top of the enclosure adjacent to the conductor rail. The at least one external insulator is disposed between the conductor rail and at least one of the sides of the enclosure. The conductor rail is configured to transmit electrical energy from the electrical power source to the electric vehicle.

A non-contact power supply control system includes: an electric transmission pad connected to a power source unit; a control unit controlling current supply to the electric transmission pad; a living body detecting means detecting a living body present around the electric transmission pad; a power receiving pad magnetically coupled to the electric transmission pad to excite power, when current is supplied from the power source unit to the electric transmission pad; and a power storage unit storing power excited by the power receiving pad. The living body detecting means are arranged on the road surface side, and the control unit, when determining that no living body is present around the electric transmission pad on the basis of a result from the living body detecting means, controls the power supply unit to supply power to the power storage unit.

A non-contact power supply control system includes: an electric transmission pad connected to a power source unit; a control unit controlling current supply to the electric transmission pad; a living body detecting means detecting a living body present around the electric transmission pad; a power receiving pad magnetically coupled to the electric transmission pad to excite power, when current is supplied from the power source unit to the electric transmission pad; and a power storage unit storing power excited by the power receiving pad. The living body detecting means are arranged on the road surface side, and the control unit, when determining that no living body is present around the electric transmission pad on the basis of a result from the living body detecting means, controls the power supply unit to supply power to the power storage unit.

The invention relates to a safety system for an inductive power transfer system for transferring power to a vehicle on a surface of a route, wherein the primary unit comprises at least one primary winding for generating an electromagnetic primary field for the inductive power transfer, wherein a charging surface of the route is assigned to the primary winding. The safety system comprises at least one inductive sensing system, wherein the inductive sensing system comprises multiple detection windings wherein the multiple detection windings are arranged in an array structure, and wherein the array structure covers the charging surface at least partially. Furthermore, the invention relates to a method of operating such a safety system and a method of building such a safety system.

The invention relates to a safety system for an inductive power transfer system for transferring power to a vehicle on a surface of a route, wherein the primary unit comprises at least one primary winding for generating an electromagnetic primary field for the inductive power transfer, wherein a charging surface of the route is assigned to the primary winding. The safety system comprises at least one inductive sensing system, wherein the inductive sensing system comprises multiple detection windings wherein the multiple detection windings are arranged in an array structure, and wherein the array structure covers the charging surface at least partially. Furthermore, the invention relates to a method of operating such a safety system and a method of building such a safety system.

A method is for maintenance of a ground-level power supply for a transport vehicle. The device includes: a power supply rail, a detector of spatial coordinates of a vehicle; and a power supply shoe. The device and the shoe equip the same vehicle. The supply shoe includes a vibration sensor. The method includes measuring vibrations of the shoe and simultaneously detecting spatial coordinates of the vehicle during the movement of the vehicle along the rail, followed by comparing measured vibrations of the shoe with a threshold value, and determining spatial coordinates corresponding to vibrations above the threshold value.

The invention relates to a safety system for an inductive power transfer system for transferring power to a vehicle on a surface of a route, wherein the primary unit comprises at least one primary winding for generating an electromagnetic primary field for the inductive power transfer, wherein a charging surface of the route is assigned to the primary winding. The safety system comprises at least one capacitive sensing system, wherein the capacitive sensing system comprises multiple detection capacitors, wherein the multiple detection capacitors are arranged in an array structure, and wherein the array structure covers the charging surface at least partially. A method of operating the safety system and a method of building the safety system is proposed.

The invention relates to a safety system for an inductive power transfer system for transferring power to a vehicle on a surface of a route, wherein the primary unit comprises at least one primary winding for generating an electromagnetic primary field for the inductive power transfer, wherein a charging surface of the route is assigned to the primary winding. The safety system comprises at least one capacitive sensing system, wherein the capacitive sensing system comprises multiple detection capacitors, wherein the multiple detection capacitors are arranged in an array structure, and wherein the array structure covers the charging surface at least partially. A method of operating the safety system and a method of building the safety system is proposed.