Dynamic Control of Braking-Force Distribution as Turning Braking

Dong Sheng Xia; Yan Yu; Hui He

doi:10.4028/www.scientific.net/AMM.607.431

Paper Titles

Real-Time Semi-Physical Simulation of Industry Design System Based on Virtual Reality Technology
p.413

Mixing Analysis of Laminar Flow in Static Mixers with Circle Grid Fractal Perforated Plate Elements
p.417

Research on the Static and Dynamic Characteristics of the Sliding Rail Joint Surfaces of the Fe-Based Porous Oily Material
p.422

The Thermal Structure Coupling Analysis of Hydrostatic Motorized Spindle in Ultra-Precision Grinding Machine
p.427

Dynamic Control of Braking-Force Distribution as Turning Braking
p.431

The Design of Dynamic Model of Engineering Material Arresting System
p.435

Slip Enhancement in Continuously Variable Transmission (CVT) by Using Adaptive Fuzzy Logic and LQR Controller
p.440

The Application of Safety Membranes in Hydropower Plant
p.449

Screw Fixing Fracture and Fatigue Failure on Particleboard Surface Using Different Style of Screw Insertion Technique
p.454

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 607Dynamic Control of Braking-Force Distribution as...

Dynamic Control of Braking-Force Distribution as Turning Braking

Abstract:

The Braking-force distribution on the left and right wheels is a key factor influencing the braking performance of vehicles at a corner. To promote the braking stability and the control ability at the turning-braking process, a new method based on the steering-angle feedforward control principle was proposed to realize dynamic braking-force distribution on the left and right wheels. A vehicle model of three wheels with two freedom degrees was established. Computer simulation of the turning-braking process with dynamic distribution control was carried out. The simulated results show that the difference between the actual yaw rate and the ideal one is significantly reduced at the period of braking being effective. It is validated that the method can effectively improve the braking stability and the control ability of vehicles at the turning-braking process.