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New generation light commercial vehicles are expected to have lower steering effort, high self centering and less turning circle diameter covering large variety of wheelbases from 2.8 m to 4.5 m even with mechanical steering and keeping same number of total turns of steering wheel compared to old generation light commercial vehicles. To address above requirements, below parameters related to steering and rigid front axle were studied. 1 Caster angle of front axle 2 Steering compliance and Steering ball joint articulation angle 3 Front axle kingpin axial play 4 Steering gearbox ratio 5 Pitman arm length The effect of above parameters was studied in isolation and combination. This optimization has resulted in least steering effort and least turning circle diameter in light commercial vehicles with mechanical steering and option of power steering could be eliminated for cost reduction.

Recent infrastructural developments and emerging automotive market in India has given an impetus to the transportation industry and has led to high end research activities in synchronization with growing customer demands and competition especially in last decade. Since average speeds in India has gone up from 50 kmph in the year 2000 to almost 100 kmph in 2011, even the Light Commercial Vehicles (5 to 9.6T) are gradually experiencing a shift from low speed to high speed goods carrier. These new age vehicles are developed with a driver centric outlook towards safety and comfort. They are better optimized and equipped to the changing needs of the consumer and road conditions. Increase in vehicle speed poses many challenges in terms of occupant safety and control. In view of this, refinement of different vehicle handling parameters with respect to steering system compliance becomes far more critical.

Subject paper focuses primarily on non uniform tire wear problem of front steered wheels in a pickup model. Cause and effect analysis complemented with field vehicle investigations helped to identify some of the critical design areas. Investigation revealed that steering geometry of the vehicle is undergoing huge variations in dynamic condition as compared to initial static setting. Factors contributing to this behavior are identified and subsequently worked upon followed by a detailed simulation study in order to reproduce the field failures on test vehicles. Similar evaluation with modified steering design package is conducted and results are compared for assessing the improvements achieved. In usual practice, it is considered enough if Steering Geometry parameters are set in static condition and ensured to lie within design specifications.