A control device for performing start assist control for an internal combustion engine includes: a first start assist processing unit that executes a first start assist process that brings a first engagement device into slip engagement at a first engagement pressure while increasing a torque generated by a rotating electrical machine; and a second start assist processing unit that increases, when the first start assist process fails to start the internal combustion engine, an engagement pressure of the first engagement device to a second engagement pressure higher than the first engagement pressure while increasing the torque generated by the rotating electrical machine. The second start assist processing unit determines the second engagement pressure on the basis of a rotational speed of the internal combustion engine in the first start assist process.

A helicopter may include a hybrid engine system including an internal combustion engine (e.g., a turbine engine) and an electric engine. The internal combustion engine and the electric engine being coupled to the rotor system and configured to separately or collectively operate the rotor system in response to a triggering event. In one aspect, a method for operating a rotor system of a helicopter may include receiving an indicator of a triggering event and actuating a non-active engine, one of the internal combustion engine or the electric engine, in response to receiving the triggering event.

A vehicle includes a motor serving as a driving source configured to run the vehicle, and a high-power and high-capacity assembled batteries, each of the assembled batteries being formed to include secondary batteries configured to supply an electric power to the motor, the secondary batteries of the assembled batteries being housed in different cases. The high-power and high-capacity assembled batteries are arranged around a luggage space located in a rearward portion of the vehicle. The high-power assembled battery is chargeable and dischargeable with a current larger than a current in the high-capacity assembled battery. The high-capacity assembled battery has an energy capacity larger than an energy capacity of the high-power assembled battery. The high-capacity assembled battery is arranged above or below the high-power assembled battery in the vehicle, and at least a portion of the high-capacity assembled battery protrudes from the high-power assembled battery rearward in the vehicle.

A vehicle drive device that includes a rotary electric machine that serves as a drive force source for wheels; a speed change mechanism; a pump motor that serves as a drive force source for an electric pump that generates a hydraulic pressure to be supplied to a servo mechanism for the speed change mechanism; a case that accommodates the speed change mechanism; and a first inverter that controls the rotary electric machine and a second inverter that controls the pump motor, the first inverter and the second inverter being connected to a common DC power source, wherein: the first inverter and the second inverter are disposed in the case; and a first wiring member that extends from the DC power source is branched in the case to be connected to each of the first inverter and the second inverter.

Vehicle to project concrete, including a truck provided with a main motor to move the truck using a movement unit, a unit to project the concrete equipped with a pumping device configured to feed the concrete along a pipe, where the vehicle includes a unit to generate and feed electric energy configured to selectively feed one or more of either the movement unit of the truck, the concrete projection unit and the pumping device.

This hybrid vehicle (10) has an HV mode and an EV mode, creates a predetermined traveling plan in a manner so as to switch between HV mode and EV mode on the basis of map information, and performs mode switching control on the basis of the traveling plan. The hybrid vehicle (10) limits the execution of mode switching control that is on the basis of the traveling plan in the case of a predetermined state such that the power that can be output by a battery (28) that is the storage battery connected to a second MG (24) that is a rotary electric machine driven during execution of the EV mode is limited.

The present disclosure discloses a vehicle and a coasting feedback control method for the same. The coasting feedback control method includes the following steps: detecting the current speed of a vehicle, the depth of a braking pedal of the vehicle, and the depth of an accelerator pedal; and when the current speed of the vehicle is greater than a preset speed, both the depth of the braking pedal and the depth of the accelerator pedal are 0, and the current gear of the vehicle is gear D, when the vehicle is not in a cruise control mode and an anti-lock braking system of the vehicle is in a non-working state, controlling the vehicle to enter a coasting feedback control mode, where when the vehicle is in the coasting feedback control mode, a coasting feedback torque of a first motor generator and a coasting feedback torque of a second motor generator are distributed according to a selected coasting feedback torque curve of the vehicle.

A method according to an exemplary aspect of the present disclosure includes, among other things, controlling a power supply system to avoid an over-voltage event across one or more switching devices of the power supply system, the controlling step based on switching overlap information that includes instructions for either advancing or retarding a switching signal associated with at least one of the switching devices.

A method manages a power train of a motor vehicle including a heat engine and an electric motor electrically linked to a power battery. The method includes controlling a heating system for heating the power battery according to at least one measurement of a temperature representative of an operation of the heat engine.

If a vehicle speed is less than a predetermined value when a hybrid control mode is a series mode and a charge mode is selected (S10-S14), it is determined whether an SOC of a high voltage battery is less than a predetermined value or not (S16), and when the SOC of the high voltage battery is less than the predetermined value, ignition timing is corrected to be retarded (S18).