A forklift active braking control method based on power shift transmission, comprising the following steps: step 1: obtaining forklift state parameters, if the current state of the forklift is an active braking state, performing step 2; step 2: inputting a current speed signal of the forklift, and obtaining duty ratio parameters that are impact-free and can produce a maximum braking force at the current speed, and outputting proportional solenoid valve control parameters of the transmission according to the obtained duty ratio parameters; step 3: using the proportional solenoid valve control parameters to control the proportional solenoid valve of the transmission to take action, and controlling the forklift power system to output a driving force opposite to a current movement direction of the forklift to drive the forklift to actively brake; step 4: exiting the active braking of the forklift when the forklift speed is detected to be zero.

A system for braking a vehicle includes an operator interface that transmits a brake command signal when actuated by a vehicle operator. When the interface is not actuated and does not transmit the signal, a controller receives signals indicative of whether the vehicle is in an active or inactive state from two different sources and determines that the vehicle is in the inactive state if both of the signals indicate the vehicle is in the inactive state. The controller receives another signal indicative of a speed of the vehicle and determines whether the speed of the vehicle meets a predetermined condition relative to a predetermined speed of the vehicle. The controller generates a control signal to apply a wheel parking brake on the vehicle after determining that the vehicle is the inactive state and determining that the speed of the vehicle meets the predetermined condition relative to the predetermined speed.

The present invention relates to a braking arrangement for a vehicle, the braking arrangement comprising an electric machine electrically connectable to an electric power source, a brake compressor positioned in an air flow conduit, the brake compressor being configured to pressurize a flow of air and to exhaust the pressurized flow of air, and a compressor shaft mechanically connecting the electric machine and the brake compressor to each other, wherein the electric machine is configured to generate a torque on the compressor shaft for operating the brake compressor to pressurize the flow of air, the braking arrangement further comprising an air bearing arrangement, the air bearing arrangement being fluidly connectable to a pressurized brake air tank of the vehicle via an air bearing conduit, wherein the air bearing arrangement is suspending the compressor shaft to at least one of the electric machine and the brake compressor.

The present invention provides a vehicle control device that enhances safety in an event of a collision of a vehicle. The vehicle control device includes: a speed calculator that calculates a vehicle speed at a time of collision when the collision of the vehicle is detected by the collision detection sensor, and a driving assist controller that performs automatic brake control based on the vehicle speed at the time of collision calculated by the speed calculator, wherein when a brake pedal is depressed at the time of collision of the vehicle, the speed calculator calculates the vehicle speed at the time of collision based on a highest of respective detected values by the wheel speed sensors for a plurality of wheels.

A system and method are provided for disabling a retarder during a gearshift at low speeds for improved driver comfort. These embodiments recognize that power flow is interrupted during a shifting process and use that opportunity to disable the retarder at low speeds, thereby eliminating an additional, uncomfortable jolt to the driver. Several embodiments are provided.

This disclosure provides systems and methods for deceleration control during emergency braking using control algorithm override. An embodiment of the present disclosure provides a computer-implemented method for deceleration by a controlling device of an autonomous driving vehicle (ADV). The method includes engaging a braking system of the ADV to decelerate the ADV using a first deceleration algorithm. When an onset of discrepancy between a velocity of the ADV and a corresponding wheel speed of the ADV is detected, a processing device, based on the discrepancy, overrides an output of the first deceleration algorithm using a second deceleration algorithm that prioritizes in reducing the discrepancy between the velocity of the ADV and the corresponding wheel speed of the ADV over a target rate of deceleration computed by the first deceleration algorithm.

An autonomous emergency braking apparatus is provided for a host vehicle having one or more sensors providing one or more sensor signals indicative of status of at least one vehicle adjacent to the host vehicle. The autonomous emergency braking apparatus comprises a vehicle controller arranged to (i) monitor the one or more sensor signals indicative of the status of the at least one vehicle adjacent to the host vehicle, and (ii) provide at least one control signal for controlling extent of deceleration of the host vehicle based upon the status of the at least one vehicle adjacent to the host vehicle in the event of the host vehicle colliding with a vehicle in front of the host vehicle.

A redundancy dynamic braking system may include: a main braking force adjusting device configured to control a hydraulic braking device of a vehicle; a receiving unit configured to receive driving information of the vehicle; an electronic control braking device configured to be operated electrically to generate braking force; and an auxiliary braking force adjusting device configured to control the hydraulic braking device and the electronic control braking device, in an event of a failure in the main braking force adjusting device, wherein the auxiliary braking force adjusting device is configured to control the electronic control braking device by adjusting a magnitude and an application time of a current applied to the electronic control braking device based on an estimated target pressure using the driving information.

A method and device for improving trailer brake response during a hard braking event by identifying unnecessary attenuation of a trailer braking signal, and responding by boosting the trailer braking signal.

A method for operating a motor vehicle, which includes a drive system, including an electric drive machine, a friction braking system and an actuating element. The actuating element is continuously movable between a first end state and a second end state, a position of the actuating element in the first end state corresponding to a percentage value of 0%, and the position of the actuating element in the second end state corresponding to a percentage value of 100%. An acceleration torque for the motor vehicle is predefined if the positon has a percentage value that is greater than a predefined threshold value, and a deceleration torque for the motor vehicle being predefined if the position has a percentage value that is less than the threshold value. The friction braking system is activated in such a way that the friction braking system generates at least partially the predefined deceleration torque.