A park brake system for adjusting a tension in a brake cable that is coupled to a park brake. The park brake system can include a driver that is communicatively coupled to a microcontroller, and an actuator that is rotatably displaceable by operation of the driver. An equalizer assembly can be linearly displaced along the rotating actuator to adjust a tension in the brake cable. The microcontroller can monitor a current being drawn by the driver as the driver is operated, and generate instructions to cease operation of the driver upon the current reaching a predetermined current threshold that corresponds a maximum force that is to be applied by the park brake. The microcontroller can also, when the park brake is being released from a set position, count pulses outputted by an encoder in connection with determining whether the park brake has reached a running clearance position.

A vehicle behavior stabilization apparatus 10 as a vehicle control system includes: a selector position sensor 28 configured to detect a selector position selected in accordance with an operation of a selector lever 52, and wheel velocity sensors 30, 31 configured to measure a direction of travel and a traveling velocity |V| of a vehicle 40, and an ESP-ECU 12 configured to execute velocity reducing control that applies a braking force with wheel cylinders 36 in a case where the measured direction of travel is different from a tendency of behavior corresponding to the detected selector position and the measured traveling velocity |V| is larger than a threshold value Vth.

A valve module is provided for enabling a vehicle to control an autonomous event of the vehicle. The valve module comprises a relay valve, a first solenoid valve, and a second solenoid valve. A first control pressure can be delivered through the first solenoid valve and applied to a control port of the relay valve. In one embodiment, a second control pressure can be delivered through the second solenoid valve and combined with the first control pressure. The combined first and second control pressures are applied to the control port of the relay valve. In another embodiment, a second control pressure can be delivered through the second solenoid valve only when no first control pressure is delivered through the first solenoid valve.

In a method for providing the clamping force generated by a parking brake, the roadway incline is measured and in the case that the roadway incline exceeds a threshold value, a reengagement process is carried out after a defined time period has elapsed.

A method for detecting a movement of a vehicle that has been shut down in a parked state, including: detecting a movement variable which describes a movement of the vehicle, integrating the movement variable, in a manner dependent on a movement direction of the vehicle, to obtain a movement travel, and, if the movement travel meets a predetermined condition, making a decision on the movement for detection.

A brake assistant control system for a vehicle includes one or more sensors, to detect a movement state of the vehicle. The one or more sensor includes a g-sensor to detect acceleration of a movement of the vehicle, a braking force control unit to adjust a braking force of the vehicle, and a brake assistant control module. The brake assistant control module is coupled to all the sensors and can receive signals from all the sensors. When the motion sensor detects the vehicle is in a stationary state and the g-sensor detects acceleration of the vehicle, the brake assistant control module can increase braking force to slow the speed of the vehicle, through the braking force control unit.

Some embodiments relate to apparatus for enhancing vehicle performance along an inclined surface. The apparatus can include a brake modulator that is controllable to reduce or limit the vehicle speed. A controller can control the brake modulator to selectively operate in a hill start assist mode. In the hill start assist mode, the controller can control the brake modulator to hold the vehicle stationary after the vehicle is initially stopped while traveling along the inclined surface, until an acceleration input member is manually operated to control a power source to propel the vehicle. The controller can control the brake modulator to release fluid pressure at the friction members at a pressure release rate that is based on a current position of the acceleration input member.

A Hill Start Assist (HSA) system for an off-road type vehicle includes a brake system for producing a braking force sufficient to maintain the vehicle in a stopped condition, and a control unit in communication with the brake system for controlling a brake modulator of the brake system to maintain the braking force when a manual brake actuator of the brake system is in a released position. The HSA system is operable in a ready state where the brake modulator is in an open condition and the braking force is not maintained, an activated state and a hold state where the brake modulator is in a closed condition and the braking force is maintained. The HSA system is only in the ready state upon determination by the control unit that predetermined vehicle conditions are satisfied.

The invention relates to a method of controlling a heavy-duty vehicle in a slope when the vehicle has come to a standstill due to service brakes of the vehicle having applied a service brake force, the method comprising determining a total brake force required for maintaining the vehicle at standstill, activating at least one park brake for providing a park brake force, gradually increasing the park brake force, and, while the park brake force is gradually increased, gradually reducing the service brake force while maintaining the sum of the service brake force and the park brake force at least equal to the determined total brake force.

An axle drive for a vehicle comprising at least one drivable vehicle axle comprises a drive shaft that extends along a longitudinal direction of the vehicle, starting from a first side of the axle drive, to a second side of the axle drive and that is configured to receive drive power from an electric motor arranged at the first side and to output said drive power at the second side to a driven shaft that extends at the second side of the axle drive offset from the drive shaft and that is configured to output drive power to the vehicle axle via a bevel gear facing towards the first side. The axle drive further comprises a brake, in particular a parking brake, comprising a brake disk that is arranged at the second side of the axle drive, in a manner facing away from the first side, at the drive shaft or at the driven shaft.