A brake light sensor module includes: a retainer which is provided to move together with an operation element of a master cylinder in response to a depression of a brake pedal; an operation rod which is connected to the retainer so as to move together with the retainer; an elastic member which is installed in the master cylinder; a signal transmitting element which is installed in the master cylinder, one end of the signal transmitting element being elastically supported by the elastic member, and the other end of the signal transmitting element being supported by the operation rod; and a sensor which is installed in the master cylinder so as to be operated by the signal transmitting element.

A braking control system of a vehicle includes a pressure control device that regulates brake fluid flow to a brake caliper of a wheel from a brake fluid cylinder. A pressure sensor measures a pressure of the brake fluid applied to the brake caliper. A filter module filters the measured pressure based on a rotational frequency of the wheel. The filtering produces a filtered pressure of the brake fluid applied to the brake caliper. A target pressure module sets a target pressure for the brake fluid for application to the brake caliper. A difference module determines a pressure difference between the filtered pressure and the target pressure. A pressure control module actuates the pressure control device based on the pressure difference.

A brake boost assist system for use with a master cylinder of a motor vehicle braking system, includes an inductive sensing system. The inductive sensing system has sensing devices carried on an input member and an output member, where the input and output members are coupled to respective ones of an input rod and an output rod of the brake boost assist system. Movement of the input and output members relative to one another, and relative to a fixed element of the inductive sensing system positioned within the brake boost assist system, enables an accurate estimation of the distance of a pedal gap which separates faces of the input and output rods. The accurate estimation of the pedal gap distance enables a more accurate determination to be made of the braking force required for any given pedal stroke input by an operator of the vehicle during a braking action.

A vehicle brake mechanism that includes a pedal, a piston attached to the pedal, a spring associated with the piston and exerting a longitudinal force on the piston in a direction opposite the braking direction in order to bring the pedal to a resting position, and an autonomous brake module. A manual braking force on the pedal causes a longitudinal movement of the piston and displaces a transmitter element integrally joined to the piston. The autonomous brake module causes a movement of an intermediate plate that displaces the transmitter element and the piston, exerting a longitudinal force on the piston in the braking direction. The brake mechanism determines the force in the direction opposite the braking direction using a sensor situated on or in the intermediate plate and/or the transmitter element.

Disclosed herein are an electromechanical brake system and a control method thereof. In accordance with one aspect of the present disclosure, there is provided an electromechanical brake system including electromechanical brakes respectively provided on four wheels of a vehicle, a sensor part that outputs a signal which corresponds to or is capable of estimating whether each of the electromechanical brakes is normal and a driver demand braking torque generated based on the speed and lateral acceleration of the vehicle and a brake pedal operation of a driver, and a controller that estimates a demand braking torque based on the signal received from the sensor part and determines whether the electromechanical brakes are normal, wherein the controller performs a braking control as much as the demand braking torque based on the determination that the electromechanical brakes are normal, and performs a braking control by distributing, within a range of the demand braking torque, braking torques based on the lateral acceleration of the vehicle to the respective other electromechanical brakes except the electromechanical brake determined to malfunction based on the determination that there is a malfunction of any one among the electromechanical brakes.

A brake pedal module for a brake-by-wire braking system of a vehicle is disclosed, with a carrier component for attaching the brake pedal module to the vehicle, a brake pedal mounted pivotably on the carrier component, a feedback unit which, to generate a resistance on actuation of the brake pedal, is mechanically coupled at one end to the brake pedal and at the other end to the carrier module, and a sensor unit for detecting a braking request of a driver and having at least one sensor for detecting an actuation travel. The sensor unit is attached to the carrier component at the side of the brake pedal such that the sensor is arranged on a pivot bearing of the brake pedal.

An industrial vehicle includes a controller. The controller sets a first upper deceleration limit as a set upper deceleration limit, if a first condition is satisfied, to perform first deceleration limiting. The first condition is satisfied when at least one of a high lifting height of the industrial vehicle, a material weight equal to or greater than a threshold, and an empty driver seat is detected. The controller sets a second upper deceleration limit as the set upper deceleration limit, if a second condition is satisfied, to perform second deceleration limiting. The second condition is satisfied when a distance between the industrial vehicle and an obstacle is less than a threshold. The controller performs priority control if the first condition and the second condition are satisfied so that the first upper deceleration limit is set as the set upper deceleration limit in preference to the second upper deceleration limit.

A brake system includes four sensors and at least two electronic control units. The four sensors are a first sensor, a second sensor, a third sensor, and a fourth sensor. The first sensor transmits a sensor output signal generated therein to a predetermined electronic control unit among the at least two electronic control units. The second sensor transmits a sensor output signal generated therein to other electronic control unit that is different from the predetermined electronic control unit among the at least two electronic control units. The third sensor transmits a sensor output signal generated therein to at least one of the predetermined electronic control unit and the other electronic control unit. The fourth sensor transmits a sensor output signal generated in its own sensor to both of the predetermined electronic control unit and the other electronic control unit.

A brake system for a motor vehicle includes an electrohydraulic partial brake system with hydraulically actuated wheel brakes and an electromechanical partial brake system with electromechanically actuated wheel brakes. The brake system includes two control units and two energy supplies which are independent of one another, a first one of the control units being configured to control the electromechanical partial brake system, and a second one of the control units being configured to control the electrohydraulic partial brake system. The first control unit is supplied with energy exclusively by way of a first one of the energy supplies and the second control unit is supplied with energy exclusively by way of a second one of the energy supplies.

A second control unit controls a pump of a P system and a pump of an S system according to a stroke of a brake pedal that is detected by a stroke sensor in a state that a fluid level of brake fluid in a reservoir tank falls below a predetermined fluid surface level.