Disclosed is a method of and control system for operating a circuit arrangement, in particular a circuit arrangement of an electric vehicle for inductive power transfer to the vehicle. The circuit arrangement includes at least one phase line with at least one field receiving arrangement and at least one compensating arrangement with a variable reactance, wherein at least one current-dependent cost function is evaluated, wherein the reactance is varied such that the cost function is optimized.

Systems and methods for charging an electric bus having a charging interface on its roof may include determining that an approaching bus is supposed to be charged at the charging station, lowering the charging head of the charging station to land on the roof of the bus, and moving the bus with the charge head on its roof to engage the charging head with the charging interface.

A circuit arrangement, in particular a circuit arrangement of an electric vehicle for inductive power transfer to the vehicle includes a pick-up arrangement and at least one variable compensating arrangement. The variable compensating arrangement includes a capacitive element, a first switching element and a second switching element. The first switching element and the second switching element are connected in series, and the series connection of the first and the second switching element is connected in parallel to the capacitive element of the variable compensating arrangement. Also disclosed is a method of operating the circuit arrangement and a method of manufacturing the circuit arrangement of the electric vehicle and the electric vehicle.

Systems and methods for charging an electric bus having a charging interface on its roof may include determining that an approaching bus is supposed to be charged at the charging station, lowering the charging head of the charging station to land on the roof of the bus, and moving the bus with the charge head on its roof to engage the charging head with the charging interface.

The first power converter is connected with a circuit connected with an overhead line, and an intermediate link, and mutually converts power. The second power converter is connected with the intermediate link, and a circuit electrically connected with an induction motor, and mutually converts power. The auxiliary power-supply device receives power from the intermediate link, and supplies power to a load. The operation controller controls the operation/deactivation of the first power converter based on acceleration and speed of a vehicle, auxiliary source power, and a restriction value for regenerative power to the overhead line in such a way that the power to be supplied to the auxiliary power-supply device becomes equal to or larger than the auxiliary source power, and the regenerative power flowing to the overhead line 105 becomes equal to or smaller than the restriction value.

An electric drive vehicle is provided with first and second slider plates contacting a trolley line on the high-voltage side and on the ground side, respectively. A camera has a photographing range of the whole of the second slider plate held in contact with the trolley line on the ground side and a part of the trolley line residing around the second slider plate. A controller controls a display of a monitor, wherein the controller includes a relative distance calculation section that calculates a relative distance between the trolley line on the ground side and a reference position of the second slider plate, and a bird's eye view image data generation section that generates bird's eye view image data reflecting the relative distance calculated by the relative distance calculation section and that outputs the bird's eye view image data to the monitor.

Systems and methods for charging an electric bus having a charging interface on its roof may include determining that an approaching bus is supposed to be charged at the charging station, lowering the charging head of the charging station to land on the roof of the bus, and moving the bus with the charge head on its roof to engage the charging head with the charging interface.

A cart charging station includes a supporting member, a power transmission device, and an engaging member. The power transmission device is coupled to the supporting member such that a power transmission surface thereof faces a power receiving surface of a power reception device mounted on a cart at the cart charging station. The power transmission device is configured to transmit electric power to the power reception device in a non-contact manner. The engaging member is configured to engage with the power reception device of the cart and restrict movement of the power reception device in a frontward direction and the width directions of the cart.

A resistor includes an elongated cylindrical body having nodes and elongated members. The elongated members interconnect the nodes to form openings between the nodes and the elongated members for the flow therethrough of a cooling fluid. The body is configured to receive electric current from a powered system and to conduct and provide electric resistance to the electric current to dissipate at least part of the electric current as heat from the body. The body may be coupled with at least one other resistor of the powered system in one or more of a parallel or series arrangement in an electric circuit.

A system and method for operating a transport refrigeration system including: a trailer system including a vehicle connected to a transport container; an electric generation device operably connected to a wheel axle of the trailer system, the electric generation device configured to rotate at an operating frequency, and to generate electrical power from the rotational energy of the wheel axle for charging an energy storage device when the electric generation device is activated; an energy management system for providing power to the transportation refrigeration unit of the trailer system, the energy management system including an energy controller in communication with at least one of the electric generation device and the energy storage device, wherein the energy controller is configured to modify the operation of the electric generation device when the operating frequency of the electric generation device is equal to or less than an energy controller operating limit.