A system includes a computer including a processor and a memory, the memory storing instructions executable by the processor to actuate a vehicle brake according to a specified brake torque, receive user input to exceed the specified brake torque, and actuate a brake fluid valve to attain a brake fluid pressure to maintain the specified brake torque.

A controller and a control method of a motorcycle brake system capable of meeting requests of downsizing, cost cut, simplification, and the like, and a motorcycle brake system including such a controller are obtained.

In the controller and the control method of the motorcycle brake system and the motorcycle brake system according to the invention, a positive gradient G that corresponds to a lean angle A obtained during turning of a motorcycle is set, and, when an initiation reference is satisfied, a braking force suppression operation to increase braking forces, which are generated by wheel braking mechanisms, in the positive gradient G is initiated.

A vehicle braking system for a vehicle combination includes a first brake axle including a first actuatable brake, a second brake axle including a second actuatable brake, a third brake axle including a third actuatable brake, a first valve controlling actuation of the first actuatable brake and actuation of the second actuatable brake, and a second valve controlling actuation of the second actuatable brake and actuation of the third actuatable brake.

The embodiments of the present application disclose a stability control system and a stability control method for a four-wheel drive electric vehicle and the four-wheel drive electric vehicle. In the stability control system, when the lateral acceleration is equal to or greater than an acceleration threshold, at least one of a first braking force signal, a second braking force signal, a first logic signal and a second logic signal is obtained. When the first logic signal is obtained, the body of the electric vehicle is controlled to keep stable. When the first braking force signal and the second logic signal are obtained, a motor is controlled to apply braking force to an outside front wheel. When the second braking force signal and the second logic signal are obtained, motors are controlled to apply braking force to the outside front wheel and an inside rear wheel.

A modular braking device for a hydraulic motor vehicle brake system, which is optimized for remote actuation, including a hydraulic booster stage with a booster housing, a main brake cylinder mounted thereon, a booster piston which is displaceable therein and delimits a pressure chamber which is supplied directly with pressure medium by a motor pump unit.

A wheel speed detection device according to one aspect of the present disclosure is installable on a wheel bearing which comprises an outer ring and an inner ring coupled to a rotating shaft and relatively rotated relative to the outer ring about the rotating shaft. The wheel speed detection device comprises a first target concentrically coupled to the rotating shaft, a second target disposed along an outer circumference of the inner ring, a cap coupled to the outer ring to cover the first target and the second target, a first sensor disposed in the cap and configured to detect a variation in magnetic field of the first target due to a rotation of the rotating shaft, and a second sensor disposed in the cap and configured to detect a variation in magnetic pole of the second target due to a rotation of the inner ring.

In a method for generating braking power by actuating at least one electric braking motor in a vehicle parking brake comprising two control devices, in the event of a failure of a first control device/braking motor unit, braking power is generated automatically via a second control device/braking motor unit if the vehicle speed is lower than a threshold value and/or if a characteristic value in the vehicle (e.g. the ignition status) indicates that the vehicle is at or is about to come to a standstill, but preferably only once a defined time interval has elapsed.

In a method for generating braking power by actuating at least one electric braking motor in a vehicle parking brake comprising two control devices, in the event of a failure of a first control device/braking motor unit, braking power is generated automatically via a second control device/braking motor unit if the vehicle speed is lower than a threshold value and/or if a characteristic value in the vehicle (e.g. the ignition status) indicates that the vehicle is at or is about to come to a standstill, but preferably only once a defined time interval has elapsed.

A parking lock in a vehicle transmission includes a locking mechanism for locking and releasing a parking interlock gear (1) and an actuating unit. The actuating unit is coupled via a coupling mechanism to the locking mechanism in order to actuate the locking mechanism between an interlock position and a release position of the parking interlock gear (1). The parking lock is arranged on an intermediate plate (2) in a housing of the vehicle transmission.

A method for controlling a vehicle deceleration depending on a differential slip between two vehicle axles in a vehicle with an ABS brake system includes detecting at least one of a target vehicle deceleration specified by the driver and an actual vehicle deceleration; and controlling a braking pressure on wheel brakes of a vehicle axle to be controlled by actuation of ABS brake valves in such a way that the braking pressure on the wheel brakes of the vehicle axle to be controlled is controlled depending on a detected actual differential slip, so that the actual differential slip corresponds to a target differential slip. The actual differential slip indicates a difference in a rotational behavior of the vehicle axle to be controlled relative to a further vehicle axle. The target differential slip is dependent on at least one of the detected actual vehicle deceleration and the detected target vehicle deceleration.