The control device for a hybrid vehicle includes: a mechanical power source; an electric motor to be used when the mechanical power source is started; a first clutch arranged between the mechanical power source and a first transmission mechanism including a plurality of gear shift stages; a second clutch arranged between the mechanical power source and a second transmission mechanism including a plurality of gear shift stages; an electrical power source coupled to an input shaft of the first transmission mechanism; and a control unit for controlling a torque of at least one of the second clutch or the electric motor so as to compensate a braking force decreased upon a gear shift in the electrical power source when a gear shift request for shifting the gear shift stage of the first transmission mechanism is made during a regeneration travel of the electrical power source.

A control device for electric motor vehicle configured to decelerate by a regenerative braking force of the motor detects an accelerator operation amount, calculates a motor torque command value and controls the motor on the basis of the calculated motor torque command value. Further, a speed parameter proportional to a traveling speed is detected, and a feedback torque for stopping the electric motor vehicle is calculated on the basis of the detected speed parameter. Furthermore, the speed parameter is estimated in accordance with a state of the electric motor vehicle, and a feedforward torque is calculated on the basis of the estimated speed parameter. When accelerator operation amount is not larger than a predetermined value and the electric motor vehicle stops shortly, the motor torque command value is converged to zero on the basis of the feedback torque and the feedforward torque with a reduction in the traveling speed.

A control device for a hybrid vehicle carries out, when a vehicle travels in a downhill control section or a congestion control section, pre-charge/discharge control of changing a target state of charge (SOC) SOCcntr from a standard SOC SOCcntr-n to a specific SOC, and is within a permissible range, in a period in which the vehicle travels from a control start point (Ds) to at least a start point (Dk) of a subject downhill section or a subject congested section. Further, the control device is configured to inhibit, when return control is carried out while the pre-charge/discharge control is being carried out, the pre-charge/discharge control from a start time point (D5) of the return control to a time point (D9) at which the vehicle has passed through the control section. As a result, fuel efficiency can be improved when the return control is carried out during the pre-charge/discharge control.

A method for operating a motor vehicle, which is driven by an electric motor. The motor vehicle has a high-voltage power system, to which the electric motor is connected, with a high-voltage battery that is operated in an operating temperature range, for which purpose, a temperature control mechanism utilizing a circulating coolant, and having a heating mechanism for the coolant and a cooling mechanism for the coolant is assigned to the high-voltage battery, to satisfy a power deficiency which indicates that a braking power required by recuperation of the electric motor exceeds the on-demand power currently in the high-voltage power system that can be demanded for charging the high-voltage battery.

An exemplary method includes applying both friction braking and powertrain braking when decelerating a vehicle to a stop, the applying in response to a driver lifting off an accelerator pedal. An exemplary assembly includes a powertrain brake, a friction brake, and a braking controller configured to command the powertrain brake to apply powertrain braking and the friction brake to apply friction braking to stop a vehicle in response to a driver lifting off an accelerator pedal.

The present disclosure provides a shifting control method for hybrid vehicles to reduce the occurrence of a clutch releasing phenomenon due to an excessive change in input torque of a transmission during shifting of the vehicle, including: an entering step of performing, by a controller, a control to enter a torque hand over control in response to power off down shifting; and a rising control step of controlling, by the controller, an engagement side clutch torque to rise to correspond to a changed input torque of a transmission when a change rate in input torque of the transmission is equal to or more than a reference value during the torque hand over process.

A utility vehicle with regenerative braking is disclosed. The utility vehicle includes a power bus, a battery coupled to the system power bus, and at least one electric drive motor to generate power through regenerative braking and supply the generated power onto the power bus. The utility vehicle includes a power regulation controller configured to direct the generated power to the battery to recharge the battery when the battery is not fully charged, direct the generated power to at least one power sink to consume the generated power when the battery is fully charged and the generated power is less than or equal to a power consumption limit, and reduce a maximum travel speed to reduce an amount of power generated by the at least one electric drive motor through regenerative braking when the battery is fully charged and the generated power is greater than the power consumption limit.

A method is provided for scheduling regenerative braking torque, comprising: sensing a position of an accelerator pedal; generating a torque request value in response to the sensed accelerator pedal position; determining a speed of operation of a motor/generator; determining a torque limit in response to the torque request value and the determined speed of the motor/generator; generating a regenerative braking command in response to the torque limit; and outputting the regenerative braking command to the motor/generator.

When a brake is turned on during travel of a hybrid vehicle, a required braking force required for a drive shaft is set based on a brake depression amount, a base rotation speed of an engine is set based on the required braking force, a shift stage is set based on the base rotation speed and a vehicle speed, a target rotation speed of the engine is set based on the shift stage and the vehicle speed, and the engine, the first motor, and the second motor are controlled such that the engine operates at the target rotation speed and the required braking force acts on the drive shaft.

A driveline for a vehicle includes a set of electric machines with variable regeneration efficiency level. The driveline includes a cooling system connected to each electric machine to remove heat generated by each electric machine. The driveline includes a control system adapted to receive status information of a current status of the driveline and for at least one, preferably each one, of the electric machines: receive braking torque information indicative of a requested braking torque to be produced by the electric machine; in response to the braking torque and the status information, determine a target relation between the electric energy and the thermal energy produced by the electric machine; control the electric machine to obtain the requested braking torque and the determined target relation between electric energy and thermal energy, and control the cooling system in response to the determined target relation between electric energy and thermal energy.