A hybrid drive system and associated methods are described that include an internal combustion engine, an electric motor, and a liquid cooling system. In one example, the liquid cooling system includes an oil circulation system that cools selected components, and lubricates selected components.

An object is to reduce a discharging time required for discharging residual charges of a capacitor. A power conversion device according to the present invention includes: an inverter circuit unit; a step-up circuit unit; a smoothing capacitor; and a step-up circuit control unit which controls the step-up circuit unit, wherein the step-up circuit unit has a first switching element, a second switching element connected electrically in series to the first switching element, and a reactor having a conducting current controlled by switching operation of the first switching element and the second switching element, and the step-up circuit control unit has a first control mode of controlling the switching operation of the first switching element and the second switching element by changing a duty command value and outputting a stepped up voltage from the step-up circuit unit, and a discharge control mode of discharging electric charges stored in the smoothing capacitor into the reactor, with the duty command value fixed to a predetermined value.

A power-electronics system includes a plurality of power modules each having a power stage and defining a side pocket. The power stages are stacked in an array such that the side pockets are interleaved with the power stages. A dummy module defines a first coolant pocket and is disposed within the array such that the first coolant pocket cooperates with one of the side pockets to define a coolant chamber.

A bridge rectifier having AC voltage terminals, two DC voltage terminals, and a number of half-bridges corresponding to the number of AC voltage terminals. Each half-bridge has two activatable switching elements, connected in series between the DC voltage terminals and between which one of the AC voltage terminals is connected in each case. Each half-bridge includes a control circuit configured to detect an output voltage applied between the DC voltage terminals and switch a first switching element of the two switching elements of the particular half-bridge to be conductive by activation using a first control signal until the output voltage falls below a lower threshold value, after it has previously exceeded an upper threshold value, and to activate it in a clocked manner by activation using a second control signal, until the output voltage exceeds the upper threshold value, after it has previously fallen below the lower threshold value.

This application discusses various ways to adjust the performance of a variable input control in accordance with previous use data. In some embodiments, the previous use data can be associated with particular users of the variable input control. In this way, a response provided by the user input control can be adjusted to accommodate particular patterns of use on a user by user basis. In some embodiments, the variable input control can take the form of an accelerator pedal of a vehicle. Performance of the accelerator pedal can be adjusted by changing an amount of engine power provided for a particular accelerator pedal position. The adjustment can arrange commonly utilized power settings in the middle of the accelerator pedal range of motion to make manipulation of the accelerator pedal more comfortable and convenient for each user of the accelerator pedal.

A vehicle may include a battery and a controller programmed to set a bus voltage threshold such that during a next charging event a voltage of the battery achieves a desulfation value. The controller may set the bus voltage threshold in response to charge acceptance of the battery falling below a predetermined sulfation value. The controller may be programmed to lower the threshold such that the voltage of the battery falls below the desulfation value. The controller may lower the threshold in response to the charge acceptance exceeding the predetermined sulfation value during the event.

An on-board electrical system for a vehicle comprising: a first energy store; a second energy store; a DC/DC converter bidirectionally transferring energy between the first energy store and the second energy store; and two switching devices for coupling a first terminal of the second energy store to a first terminal of the first energy store via a first node, a second node, and a third node. The system further comprises: four current determining units for: a first current flowing between the first terminal of the first energy store and the first node, a second current flowing via the first switching device and the second switching device, a third current flowing between the first terminal of the second energy store and the second node, and a fourth current flowing between the third node and the DC/DC converter; an electrical resistor couplable to the first terminal of the second energy store by means of a third switching device; a voltage determining unit determining a first voltage value of the second energy store if the electrical resistor is electrically isolated from the first terminal of the second energy store and a second voltage value of the second energy store if the electrical resistor is electrically coupled to the first terminal of the second energy store; and an internal resistance determining unit for characterizing an internal resistance of the second energy store on the basis of determined first voltage and the second voltage and for classifying the determined resistance value on the basis of the determined first, second, third, and fourth current values.

A system for using a solar cell includes a solar cell module configured to convert sunlight into electric energy, an engine operating circuit configured to convert mechanical energy generated by an engine operation of a vehicle into electric energy and provide the electric energy, a solar cell circuit configured to provide the electric energy generated through the solar cell module, a battery configured to be charged by electric energy provided by the solar cell circuit or the engine operating circuit, a load, and a controller of a vehicle. The controller is configured to control a connection of the circuits to the battery or to the load depending on a measured state of charge of the battery, driving of the vehicle, and acceleration of the vehicle. A method for using a solar cell is also disclosed.

In a method for recharging an electrical energy storage device of a hybrid vehicle, the hybrid vehicle includes an internal combustion engine, first and second electric machines, and a drive shaft, the internal combustion engine and the first electric machine are directly mechanically coupled, the second electric machine and the drive shaft are directly mechanically coupled, and the internal combustion engine and the drive shaft are variably mechanically coupled by a gear device. A drive unit for a hybrid vehicle includes an electrical energy storage device, an internal combustion engine, first and second electric machines, and a drive shaft, wherein the internal combustion engine and the first electric machine are directly mechanically coupled, the second electric machine and the drive shaft are directly mechanically coupled, and the internal combustion engine and the drive shaft are variably mechanically coupled by a gear device. A hybrid vehicle can includes the drive unit.

The present disclosure provides an apparatus with a prime mover coupled to a generator that is directly electrically coupled to an electric motor. A propeller or fan may be coupled to and driven by the electric motor. A bi-directional power converter may be coupled to the generator and further coupled to an energy storage device. The energy storage device may be selectively coupled to the electric motor. Methods of using the apparatus are also provided.