Systems and methods for brake cable adjustment are disclosed herein. In this regard, a gage block tool for adjusting a brake cable may comprise a body comprising, a first member extending in a first direction, the first member having a first length and a first thickness, and a second member extending in a second direction, the second member having a second length and a second thickness. At least one of the first member or the second member may be sized and configured to be placed between a stop and a lever of a brake valve, the brake cable connected between the lever and a brake handle being properly adjusted when the gage block sandwiched between the lever and the stop contacts both the lever and the stop while the brake handle is in a park lock position.

An electro-pneumatic braking system including a pneumatic pressure supply pipe, a generator for generating a vehicle load signal, a weighting system designed to supply a weighted pressure which defines a maximum braking pressure, limited as a function of the load signal, and braking control units connected to the weighting system and having a relay valve connected between the pipe and at least one brake cylinder, to cause the application to this cylinder of a controllable braking pressure, equal to or less than the weighted pressure. The weighting system includes an electro-pneumatic drive assembly, interposed between the pipe and the drive inlet of the relay valve and is connected to the pipe through a pressure limiter, and an electronic weighting control unit which controls this drive assembly as a function of the load signal, so as to modulate in predetermined ways the pressure at the drive inlet of the relay valve.

A controller determines a load weight associated with a plurality of pneumatically independent circuits of a vehicle suspension system. The controller is adapted to receive an electronic pressure signal, at a controller electronic input port, based on a single pneumatic signal representative of respective pneumatic pressures in the plurality of pneumatically independent circuits. The controller is also adapted to determine the load weight based on the electronic pressure signal and control an operation of a function of an associated vehicle based on the load weight.

A controller determines a load weight associated with a plurality of pneumatically independent circuits of a vehicle suspension system. The controller is adapted to receive an electronic pressure signal, at a controller electronic input port, based on a single pneumatic signal representative of respective pneumatic pressures in the plurality of pneumatically independent circuits. The controller is also adapted to determine the load weight based on the electronic pressure signal and control an operation of a function of an associated vehicle based on the load weight.

A braking control apparatus performs right and left wheel independent control to approach a slip rate of a rear-right wheel and a rear-left wheel to a target slip rate as an average of slip rates of a front-right wheel and a front-left wheel. In a high-speed range, right and left wheel independent control is started when a deceleration is equal to or larger than a start value that is smaller than a start value used in a low-speed range. In right and left wheel independent control started in the high-speed range, when there is a demand to increase braking pressures of both the rear-right wheel and the rear-left wheel, the braking pressure of the rear wheel located on the outside during the occurrence of deflection of the vehicle resulting from braking is increased, and the braking pressure of the rear wheel located on the inside is prohibited from increasing.

A braking control apparatus performs right and left wheel independent control to approach a slip rate of a rear-right wheel and a rear-left wheel to a target slip rate as an average of slip rates of a front-right wheel and a front-left wheel. In a high-speed range, right and left wheel independent control is started when a deceleration is equal to or larger than a start value that is smaller than a start value used in a low-speed range. In right and left wheel independent control started in the high-speed range, when there is a demand to increase braking pressures of both the rear-right wheel and the rear-left wheel, the braking pressure of the rear wheel located on the outside during the occurrence of deflection of the vehicle resulting from braking is increased, and the braking pressure of the rear wheel located on the inside is prohibited from increasing.

An exemplary embodiment of the present disclosure provides an electronic brake system, which includes different first and second hydraulic circuits configured to transmit hydraulic pressure, which is discharged in a low-pressure pressing mode state or a high-pressure pressing operation mode state of a hydraulic pressure supply device, to a wheel cylinder provided on at least one vehicle wheel, the electronic brake system including a plurality of valves provided in hydraulic pressure flow path that connects the hydraulic pressure supply device and the first and second hydraulic circuits, the plurality of valves being configured to regulate hydraulic pressure, a volume detection part configured to detect an input volume value of a pressure chamber produced when a motor piston is moved by a rotational force of a motor corresponding to a pedal effort measured by a pedal displacement sensor, and compute and detect, as a circuit volume value, a pressure value of the second hydraulic circuit measured by a pressure sensor, a determination part configured to compare the circuit volume value with the input volume value detected by the volume detection part, determine whether a predetermined condition is satisfied, and determine whether a leakage occurs in the second hydraulic circuit, and a control part configured to perform control to stop the low-pressure pressing mode, switch the mode to the high-pressure pressing operation mode, and detect a leakage occurrence valve among the plurality of valves when the determination part determines that a leakage occurs.

An electronically controlled brake system to automatically or remotely control the braking of a towed vehicle from a towing vehicle comprising a towing vehicle module including a microcontroller having logic and circuitry to generate a braking signal in response to braking of the towing vehicle fed through an automotive vehicle self-diagnostic device port and vehicle control unit interface to the brake system of the towed vehicle and a towed vehicle includes a microcontroller having logic and circuitry to generate a brake control signal fed to the brake system on the towed vehicle through a vehicle control unit interface and automotive self-diagnostic port to electronically actuate the towed vehicle brakes.

A hydraulic brake system, including: a brake operation member; a brake device; a master cylinder; a communication switching valve; a low-pressure-source shut-off valve; a high-pressure source; a regulator; a pressure adjuster; and a controller, wherein, when a pressurizing state of the master cylinder is switched from a first pressurizing state to a second pressurizing state after initiation of an operation on the brake operation member, the controller executes a pressurizing-state switching control in which switching of a state of the low-pressure-source shut-off valve from an open state to a closed state and switching of a state of the communication switching valve from a closed state to an open state are carried out after a pressure-regulating state of the regulator has been switched from a first pressure-regulating state to a second pressure-regulating state by controlling the pressure adjuster to increase a second pilot pressure while the first pressurizing state is maintained.

A braking distance control device employed for an electrically driven work vehicle includes a safety vehicle speed calculation unit that calculates a safety vehicle speed at which a braking distance provided by use of an electric brake device becomes less than or equal to a threshold value, based on gradient information, payload information, road surface friction information, vehicle speed information, and a braking torque characteristic of electric motors: a critical vehicle speed for deceleration calculation unit that calculates a critical vehicle speed for deceleration at which deceleration provided by use of the electric brake device becomes less than or equal to a threshold value; and an operation judgment unit 14 that judges a setting of notification, based on pedal operation amounts.