A method for controlling a vehicle brake system for a heavy duty vehicle including a primary brake system and an auxiliary brake system. The method includes configuring a wheel slip magnitude limit, obtaining a requested auxiliary brake torque, engaging the primary brake system at a torque determined in dependence of the requested auxiliary brake torque, while monitoring a wheel slip value, determining an allowable auxiliary brake torque in dependence of the requested auxiliary brake torque and the wheel slip value, and engaging the auxiliary brake system at the allowable auxiliary brake torque.

Systems and methods are provided for controlling operation of a trailer brake system associated with an agricultural vehicle-trailer combination, including: determining a trailer brake temperature; comparing the determined trailer brake temperature with one or more temperature thresholds to determine a temperature level condition for the trailer brake; and controlling the trailer brake system in dependence on the determined temperature level condition.

Towed vehicles can be extremely heavy. Accordingly, it is too much of a burden to the braking system of a towing vehicle to not have brakes on the towed vehicle. Controlling the brakes of the towed vehicle must be accurately applied otherwise undesirable conditions can be created. There is a need for a method for controlling braking of a towed vehicle. This method comprises receiving a first signal via a communication bus of a towing vehicle, the first signal relating to at least one operating condition of at least one the towing vehicle and a towed vehicle, sending a second signal to brakes of the towed vehicle, the second signal based on said first signal.

A vehicle brake system includes a brake control device, a vehicle acceleration sensor, and a trailer brake controller. The trailer brake controller outputs an initial trailer brake torque demand based on an input received from the brake control device and adjusts the initial trailer brake torque demand to converge a signal from the vehicle acceleration sensor to an expected negative acceleration value correlated with the input from the brake control device.

A method and system for braking a trailer with a trailer braking system including receiving, at a controller, a brake request from a vehicle. The controller receives wheel speed signals from wheel speed sensors on the trailer. The controller determines a velocity of the trailer based on the wheel speed signals and determines a wheel speed based on one of the wheel speed signals. The controller compares the velocity of the trailer to the wheel speed to obtain a difference value. The controller determines that one of the wheels is unstable when the difference value exceeds a threshold. When unstable and when the brake request is received, the controller generates a braking signal to reduce the braking force on the one of the plurality of wheels.

An electro-pneumatic tractor protection valve assembly (8) including a trailer supply input (84) for receiving a supply pressure, a trailer service output (87) for delivering a trailer supply pressure, a first supply input (81) for receiving a primary driver brake pressure, a second supply input (82) for receiving a secondary driver brake pressure, a dual brake valve (14) actuated by a brake pedal (10) and supplying the brake control pressures, a vent opening (86) for venting an internal conduit, a first electrically controlled pneumatic valve (92) to receive a first electric control signal for trailer assistance braking, and a trailer control output (85) for delivering a trailer brake control pressure. The valve assembly includes one single casing (8a) accommodating the first supply input (81), the second supply input (82), the trailer supply input (84), the trailer control output (85), the vent opening (86) and the trailer service output (87).

Disclosed is a method for automatically controlling brakes in a trailer vehicle having antilock control, wherein wheel rotational speeds are continuously monitored and evaluated at wheels having antilock control. According to the method, lateral acceleration and longitudinal acceleration of the trailer vehicle are determined. If a predefined, critical lateral acceleration is exceeded, an automatic braking process occurs. A control unit and trailer vehicle are also disclosed in connection with the inventive method.

An electronically controllable pneumatic brake system for a utility vehicle has an electronic service brake control unit and a brake pressure modulator which modulates a service brake pressure at a service brake pressure port in accordance with service braking signals provided by the electronic service brake control unit. The brake pressure modulator has a ventilation port. The brake system furthermore has an electronic redundancy control unit and at least one redundancy pressure modulator which modulates a redundancy brake pressure at a redundancy brake pressure port in accordance with redundancy braking signals that are provided by the electronic redundancy control unit. The redundancy pressure modulator has a redundancy ventilation port. Provision is made for the redundancy brake pressure port to be connected to the ventilation port such that the redundancy brake pressure can be modulated, via a ventilation path of the brake pressure modulator, at the service brake pressure port.

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.

System, method, and devices related to a wheel speed sensor that includes a wireless communication device and a motion sensor. The motion sensor includes an accelerometer. The wireless communication device and motion sensor are disposed in a housing. The housing is attached to an attachment member. The attachment member is selectively attached to a wheel of a towed vehicle.