A method of managing torque at a vehicle standstill includes outputting torque from a powertrain to satisfy a driver torque demand. The method also includes, in response to a nonzero torque demand resulting in vehicle standstill, applying a friction brake to maintain the vehicle standstill and substantially reducing output torque of the powertrain during friction brake application. The method further includes satisfying driver torque demand using the powertrain and releasing the friction brake in response to the driver torque demand deviating from the nonzero torque demand by more than a predetermined amount.

A method for carrying out a driver-independent brake force holding function in a motor vehicle when the motor vehicle is at a standstill on a roadway that is inclined in the vehicle longitudinal direction. The brake force, maintained independently of the driver, is reduced when a release condition is met. In the method, the uphill distance, which corresponds to the spacing or the distance from the neighboring vehicle in the uphill direction, is ascertained with the aid of a first distance sensor system. If the uphill distance falls below a predetermined limiting value, the brake force is reduced before the release condition is met, so that the motor vehicle moves.

A method for operating a braking device of a drive train of a vehicle, the drive train including an automatic gearbox of a vehicle, and the vehicle further having a gear-side parking lock, a service brake, and a parking brake that can be operated independently from the service brake. When a parking condition occurs, the parking lock may be engaged by a control device if the vehicle is protected from rolling away by a service brake that can be operated independently from the parking brake. The parking lock may then be configured to remain engaged until a driving condition occurs for the vehicle. This may optimize the parking lock operation in such a way that reliably prevents a disengagement impulse when the parking lock is disengaged, preventing the vehicle from rolling when entering or leaving a parked state.

A valve system includes an isolation check valve delivering pneumatic fluid as a supply pressure, a double-check valve adapted to deliver a braking demand control signal of the pneumatic fluid based on a higher of a first braking demand in a first pneumatic braking circuit and a second braking demand in a second pneumatic braking circuit, and a control module. The control module is adapted to receive the supply pressure as a control module supply pressure of the pneumatic fluid, receive a control module control pressure of the pneumatic fluid based on the braking demand control signal, and deliver a control module delivery pressure of the pneumatic fluid based on the control module supply pressure and the control module control pressure. A tractor protection module delivers the pneumatic fluid at the control module delivery pressure based on a trailer park brake pressure of the pneumatic fluid.

A valve system includes an isolation check valve delivering pneumatic fluid as a supply pressure, a double-check valve adapted to deliver a braking demand control signal of the pneumatic fluid based on a higher of a first braking demand in a first pneumatic braking circuit and a second braking demand in a second pneumatic braking circuit, and a control module. The control module is adapted to receive the supply pressure as a control module supply pressure of the pneumatic fluid, receive a control module control pressure of the pneumatic fluid based on the braking demand control signal, and deliver a control module delivery pressure of the pneumatic fluid based on the control module supply pressure and the control module control pressure. A park control module selectively transmits the pneumatic fluid at the supply pressure based on a park brake control signal.

A device for preventing a parked vehicle, such as an electric or hydraulic vehicle, from rolling away. The device includes a blocking device, which can be activated by electronic actuation, for immobilizing a movement of the vehicle. The device also includes a determination device configured to determine whether the vehicle is moving or not, and a control device configured to determine whether the blocking device has been activated or not. If the blocking device has been activated, the control device prompts the determination device to determine whether the vehicle is moving or not. If the determination device determines that the vehicle is moving, the control device actuates an electric motor of the vehicle for driving the vehicle to stop the movement of the vehicle and maintain the stopped state of the vehicle.

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.

Provided is a control method for a vehicle including an internal combustion engine as a driving source, the control method for the vehicle including: executing automatic stop control of automatically stopping the internal combustion engine when a predetermined stop condition is satisfied, and executing automatic restart control of automatically restarting the internal combustion engine when a predetermined restart condition is satisfied during execution of the automatic stop control; performing brake holding control of applying a braking force to wheels to maintain a vehicle stop state during the execution of the automatic stop control; and automatically restarting the internal combustion engine when the restart condition is satisfied, and releasing the brake holding control when a predetermined period elapses since the restart condition is satisfied. Particularly, in this control method, the predetermined period is varied according to an engine revolution speed at a time when the restart condition is satisfied.

There is provided with an automatic transmission (2) having a clutch (32) and a brake device (6) which holds a brake force during a stop of an engine (1). There is provided with an engine control section (11) which performs an automatic stop of the engine and a re-start of the engine and a release control section (14) which releases a holding of the brake force during the re-start of the engine. The release control section (14) releases the holding of the brake force when an engagement state of the clutch (32) is a predetermined state in case where an accelerator off state occurs until the engagement state of the clutch (32) becomes the predetermined state and releases the holding of the brake force when the engagement state of the clutch (32) is an engagement state weaker than the predetermined state, during a re-start of the engine (1).

A vehicle control method includes, by a controller, while an engine is auto-stopped and an electric parking brake is engaged, auto-starting the engine without releasing the electric parking brake responsive to application of an accelerator pedal less than a predefined amount, and auto-starting the engine and releasing the electric parking brake responsive to application of the accelerator pedal greater than the predefined amount. The method also includes comprising auto-stopping the engine and engaging the electric parking brake responsive to vehicle speed being less than a predefined threshold speed.