A power supply system 1 includes: a variable voltage power supply 7 that outputs power of a variable voltage E1 from a pair of secondary-side input/output terminals 72p and 72n; a first power line 21 and a second power line 22 that connect the pair of secondary-side input/output terminals 72p and 72n and a load 4; a first switch unit 31 that is provided on the first power line 21; a third power line 23 that connects both ends of the first switch unit 31; and a bypass line 25 that connects the pair of secondary-side input/output terminals 72p and 72n, a first DC power supply 33 is provided on the third power line 23 to output DC power, and a bypass diode 33a is provided on the bypass line 25 to allow an output current of the first DC power supply 38.

A drive control system controls travel of an electric vehicle, the drive control system including a plurality of induction motors, one inverter that drives the plurality of induction motors, and a controller that controls the inverter. The controller includes a coupling disconnection detecting unit that calculates an estimated torque value on the basis of a total current and a voltage command value at the start of the induction motors, and detects disconnection of a coupling provided between the induction motors and a drive mechanism of the electric vehicle on the basis of the estimated torque value calculated and a torque command value.

An intermediate circuit adaptation device for a vehicle. The intermediate circuit adaptation device includes a DC intermediate circuit with at least two phases and a control unit. The control unit is configured to change the intermediate circuit voltage and/or the number of phases of the intermediate circuit on the basis of the current operating point.

An electric work vehicle includes a battery, a motor positioned under the battery and drivable on electric power supplied by the battery, a travel device drivable by the motor, an inverter positioned under the battery and forward of the motor to convert direct-current electric power from the battery into alternating-current electric power and supply the alternating-current electric power to the motor, and a transmission positioned backward of the battery to transmit a driving force of the motor to the travel device, wherein the motor and the inverter are arranged in a front-back direction of a machine body.

An electronic power converter to control at least one electric motor of a vehicle and having at least one group of power modules, each designed to power with an alternating current one single phase of the electric motor; two lateral plates, which are arranged on opposite sides of the group so as to form a pile; a hydraulic circuit, which is configured to cause a cooling liquid to circulate inside the plates; and a clamping system, which applies a clamping force to the pile in order to keep the pile compressed and has elastic elements, which are deformed in order to apply a compression force of elastic origin to the pile.

The disclosure relates to an inverter device, including: an inverter circuit including a plurality of switching elements and a capacitor; an active discharge circuit including a first discharge resistor and a discharge switch connected in series, and connected between a positive electrode and a negative electrode of the capacitor; and a control circuit including a controller respectively connected to the switching elements and the discharge switch. The controller controls the switching elements and the discharge switch. The controller turns on the discharge switch to discharge the capacitor when the controller receives a discharge command from outside the inverter device and an electric motor is rotating.

The present disclosure provides a capacitor module including: a capacitor; a first housing having a hexahedron shape and having an inner space in which the capacitor is disposed, the first housing including a pair of cooling parts recessed inwards from a pair of parallel surfaces among outer side surfaces thereof such that a refrigerant flows, a pair of cooling channels disposed inside opposite side surfaces perpendicular to the surfaces of the pair of cooling parts such that the pair of cooling parts communicate with each other, and a through-hole configured to connect each of the cooling channels to the outside such that the refrigerant is introduced or discharged therethrough; and a cooling plate coupled to the first housing so as to seal the cooling parts.

A vehicle inverter circuit includes a first inverter and a second inverter connected to a motor, a mode conversion switching element configured to short-circuit or open the first inverter and the second inverter based on a switching operation to drive the motor in one of a Y-winding driving mode and an open-end winding driving mode, and a controller configured to control a switching operation of the mode conversion switching element.

In at least one embodiment, a vehicle battery charger is provided. The charger includes at least one transformer, a first active bridge, a second active bridge, and at least one controller. The first active bridge includes a first plurality of switching devices being positioned with the primary. The second active bridge includes a second plurality of switching devices being positioned with the secondary to generate. The controller is configured to activate the first plurality of switching devices based on a primary control signal and to activate the second plurality of switching devices based on a secondary control signal. The controller is configured to generate the secondary control signal in accordance to a first control variable. The controller is further configured to generate a second control variable that corresponds to a phase shift between the primary control signal and the secondary control signal.

This invention embodies a system and a method for charging electric vehicles comprising, a solar canopy over selected parking spaces, and control equipment and software to maximize the use of solar energy, minimize demand charges and allow for ancillary services to the grid. The capacity of the solar canopy is such that it is capable of providing the energy needed to operate the vehicle both for commuting and for all other uses except for trips over 2-300 miles, as provided by the control software. The system can include features for allowing access only to authorized users, for measuring the amount of energy used by each, and for monthly billing.