A vehicle includes an electric machine, friction brakes, a drivetrain, and a controller. The electric machine is configured to recharge a battery during regenerative braking. The friction brakes are configured to apply torque to wheels of the vehicle to slow the vehicle. The controller is programmed to, in response to and during an anti-locking braking event, generate a signal indicative of a total torque demand to brake the vehicle based on a difference between a desired wheel slip ratio and an actual wheel slip ratio, adjust a regenerative braking torque based on a product of the signal and a regenerative braking weighting coefficient, adjust a friction braking torque based on a product of the signal and a friction braking weighting coefficient, and further adjust the regenerative braking torque based on a closed-loop control of an estimated regenerative braking torque feedback.

A method of controlling braking of a vehicle is provided. When a disconnector is disconnected and an auxiliary drive wheel is separated from a driving system, vehicle braking is performed with regenerative braking by a primary drive wheel motor during braking. Subsequently, the disconnector is connected based on a vehicle stability state, and then, braking is performed simultaneously on the auxiliary drive wheel and a primary drive wheel.

The invention relates to a method for operating a hydraulic brake system (10) in a motor vehicle with regenerative braking function. In the method, if a generator braking force of an electric machine (50) is present or incipient, a hydraulic connection (80) between a brake cylinder (16) and a wheel brake (28) is opened before a hydraulic fluid is displaced in the direction of the wheel brake (28) by means of the brake cylinder (16). The invention furthermore relates to a hydraulic brake system (10) for a motor vehicle with regenerative braking function, and to a method for controlling a hydraulic brake system (10) with regenerative braking function. The invention also encompasses a computer program product, a control unit and a motor vehicle.

A vehicle includes: two front wheels which are front right and left wheels and two rear wheels which are rear right and left wheels; a brake system capable of applying a braking force to only one of (a) the two front wheels and (b) two rear wheels, independently of each other utilizing a friction force; and a drive system configured to drive at least the other of (a) the two front wheels and (b) the two rear wheels by a force of electric, motors, each as a drive source, respectively corresponding to the other of (a) the two from wheels and (b) the two rear wheels, the drive system being capable of applying a braking force to at least the other of (a) the two front wheels and (b) the two rear wheels, independently of each other utilizing regeneration by the electric motors.

An apparatus and method control regenerative braking torque of an electric vehicle on which an anti-lock brake system (ABS) is mounted. The apparatus and method can compensate the regenerative braking torque of the driving motor based on the behavior model of the electric vehicle, such that the ABS is prevented from entering an operating range to the maximum limit to maximize the energy recovery rate through regenerative braking. The apparatus includes a disturbance extractor that extracts a disturbance in a specific frequency band from a difference between a behavior model and an actual behavior of the electric vehicle. The apparatus includes a torque compensator that compensates for the regenerative braking torque based on the disturbance extracted by the disturbance extractor.

In the vehicle control system, a controller may perform first regenerative control that causes a motor generator to perform regeneration so as to apply a braking force to a vehicle when the accelerator is off and, when the accelerator is off and a steering is turned, perform second regenerative control that causes the motor generator to perform regeneration so as to apply a braking force to the vehicle in order to control the vehicle attitude by generating a deceleration that corresponds to a steering angle in the vehicle in addition to the first regenerative control.

An electric vehicle according to an example of the present application includes a battery, a regenerative brake, a friction brake, and a controller. The regenerative brake imparts regenerative braking torque to drive wheels. The friction brake imparts frictional braking torque to the drive wheels and non-drive wheels. The controller execute a slip control when the slip of the drive wheels is expected. The controller controls, during the execution of slip control, the regenerative and the friction brakes so that; the total of the frictional and the regenerative braking torque imparted to the drive wheels is less than or equal to upper limit torque set within a range that the drive wheels do not slip; the power of the regenerative power generation is not to exceed an acceptable charging power set according to a state of charge of the battery; and the regenerative braking torque is smaller than the regenerative braking torque before the start of the slip control.

A regenerative braking control method of a vehicle, may include a first operation of determining a driving risk of a road surface on the basis of a status of the road surface while driving; a second operation of determining whether an accelerator pedal is released while driving; a third operation of determining whether a brake pedal is operated while driving; and a fourth operation of performing no regenerative braking when the accelerator pedal is determined as being released, the driving risk of the road surface is determined as being high, and when the brake pedal is determined as not being operated.

A method of controlling braking of a vehicle having a transfer case disposed between a driving motor and a plurality of driving wheels including a main driving wheel and an auxiliary driving wheel includes determining a first required braking amount of the main driving wheel and a second required braking amount of the auxiliary driving wheel, comparing the first required braking amount with a regenerative brake available amount of the driving motor, and, as a result of the comparing, when the first required braking amount is equal to or greater than the regenerative brake available amount, distributing regeneration capability of the driving motor only to the main driving wheel, and when the first required braking amount is less than the regenerative brake available amount, distributing the regeneration capability to both the main driving wheel and the auxiliary driving wheel.

A regenerative braking system and method include: a regenerative braking determination unit configured to determine whether or not a vehicle satisfies an entry condition for regenerative braking based on information collected by the vehicle; a calculation unit configured to calculate a hydraulic braking torque according to a pressure of a master cylinder and a target amount of a regenerative braking torque varied according to the pressure of the master cylinder, if the vehicle satisfies the entry condition; and a controller configured to perform braking of the vehicle based on the target amount of the regenerative braking torque and the hydraulic braking torque.