The present disclosure relates to high-voltage circuits. The teachings thereof may be embodied in a circuit apparatus for detecting a state of an interlock loop monitoring a high-voltage component. The apparatus may include a power connection to a voltage source; a ground connection; a positive connection to a line end of the electrical interlock loop; a negative connection to a second line end of the interlock loop; a measuring arrangement for a voltage potential at the negative connection when two mutually different currents flow from the power connection via the negative connection to the ground connection; and a detector arrangement comparing the two potential measurements at the two respective currents with two predefined potential reference values and ascertaining, based on the comparison results of the comparison unit, whether the negative connection is electrically short-circuited with the positive connection, the power connection, or the ground connection, or with none of these connections.

The present disclosure relates to a device for monitoring a high-voltage contactor in a vehicle. In one implementation, the high-voltage contactor has a coil with an anchor, the coil is energized with a coil current or a coil voltage to switch the high-voltage contactor, and the high-voltage contactor is switched by a motion of the anchor, thus also changing the inductivity of the coil. The device may include an interface for reading in a measurement value function for the generated coil voltage and/or for the generated coil current during the switching cycle of the high-voltage contactor; an analysis device for determining a motion information representing a travel distance of the anchor based on the measurement value function; and a comparison device for comparing the motion information with a threshold value information. A fault signal is generated when the motion information falls below the threshold information.

A vehicle system includes an instructing portion that issues open/close instructions for a charging disconnector, a discharging disconnector, and a pair of contactors. A diagnosis start determination portion determines a diagnosis start timing before entering a trolleyless section. A remaining battery capacity checks whether a battery unit has a battery capacity necessary in a trolleyless section travel. A relay operation check portion checks operability of a charging disconnector, the discharging disconnector, and the pair of contactors based on certain open/close states of a plurality of relays depending on the open/close instructions. An abnormality determination portion determines trolleyless section travel is not allowed when the relay operation check portion is incapable of checking operability or necessary remaining battery capacity, the remaining battery capacity check portion, the relay operation check portion, and the abnormality determination portion being operated when the diagnosis start determination portion determines that it is diagnosis start timing.

A double-sided LCC compensation network and a tuning method are proposed for a wireless power transfer system. With the proposed topology, the resonant frequency is independent of coupling coefficient and load conditions. The parameter values are tuned to realize zero voltage switching (ZVS) for the sending side switches. A wireless charging system with up to 7.7 kW output power was designed and built using the proposed topology and achieved 96% efficiency from DC power source to battery load.

The electric vehicular connector includes: a connection terminal block including a primary power transmission terminal to be electrically connected to a first power terminal of a power converter; a plug including a secondary power transmission terminal to be electrically connected to a second power terminal of an inlet of an electric vehicle; a breaker which is connected between the primary power transmission terminal and the secondary power transmission terminal and has a closed state of electrically interconnecting the primary power transmission terminal and the secondary power transmission terminal and an open state of electrically separating the primary power transmission terminal and the secondary power transmission terminal from each other; and a breaker controller configured to set the connector-side breaker in the closed state during a normal state and to set the connector-side breaker in the open state during an abnormal state in which abnormality occurs in the electric vehicle.

In an operation mode for heating battery air, a refrigerant passage switching portion switches over to a first refrigerant passage in which a refrigerant including gas refrigerant flowing out of an interior condenser flows into an auxiliary heat exchanger through a first pipe having a relatively large passage cross-sectional area and a liquid refrigerant flowing out of the auxiliary heat exchanger flows to an inlet of an exterior heat exchanger through a second pipe having a relatively small passage cross-sectional area. Meanwhile, in an operation mode for cooling the battery air, the refrigerant passage switching portion switches over to a second refrigerant passage in which a liquid refrigerant flowing out of the exterior heat exchanger flows into the auxiliary heat exchanger through the second pipe and a gas refrigerant flowing out of the auxiliary heat exchanger flows to a suction port of a compressor through the first pipe.

A multi-input charging system and method using a motor driving system can prevent relay fusing or cutting in a motor and damage of a neutral point capacitor provided in a charging power input stage in a process of receiving external charging power through a neutral point of the motor and charging a battery.

A plug connector part for connection to a mating plug connector part includes: at least one electrical contact element for carrying an electrical current and establishing electrical contact with at least one other contact element of a mating plug connector part; and a temperature sensor device for recording an increase in temperature of the plug connector part, the temperature sensor device including at least one sensor element, which is designed to detect infrared radiation emitted by the at least one electrical contact element.

An electric vehicle controller includes an inverter that drives a motor by receiving power supplied from an overhead line, a brake chopper circuit that includes a switching device and a braking resistor and is connected in parallel with the inverter, a voltage detector that detects a bus voltage applied to DC buses, and a control unit that performs power consumption control of causing the braking resistor to consume regenerative power supplied from the motor and overvoltage suppression control of suppressing the bus voltage from being excessive. The control unit controls the switching device such that a second duty ratio used at the time of performing the overvoltage suppression control is lower than a first duty ratio used at the time of performing the power consumption control.

A heat exchange system includes a first thermal circuit, a second thermal circuit, and a controller. A first thermal circuit includes a first device, a first pump, and a first flow path and a second flow path configured to cool the first device. A second thermal circuit includes a second device, a second pump, and a third flow path and a fourth flow path configured to cool the second device. A controller is configured to switch, when the controller switches a flow path of the first thermal circuit from the first flow path to the second flow path and switches a flow path of the second thermal circuit from the fourth flow path to the third flow path, the fourth flow path to the third flow path and the first flow path to the second flow path.