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A web based software program has been developed to do a Finite Element (FE) analysis of a simplified driveline system. In the past, an expert analyst had to make a Finite Element Model, analyze and then report results. It has been observed that this process is time consuming besides the difficulties of doing quick parametric studies, geographical location of designers, analysts, etc. The web-based software program aims to solve these issues. The designer could get analytical & Finite element results anywhere around the world (where the designer has access to the web) without any expertise in FE modeling. This software is a joint effort of Engineering and Information Technology (IT) software groups. It is based on Active Server Page (ASP) technology and MSC/NASTRAN technologies combined. Input data deck is prepared from user inputs and submitted over the internet to a remote system, solved and results are retrieved and plots shown in minutes, instead of days earlier.

A case study of the application of optimization techniques to the design of rear-axles-connecting-linkage of heavy trucks with only two rear axles has been presented. The rear axles are made to move in tandem by designing a linkage connecting the two at each of its ends. The linkage locations are determined by the inter-axle-drive shaft, which is a telescopic tube. The drive-shaft is mounted with U-Joints on the two rear axles and follows the bumps and rebounds of the roads with minimal rotation about the lateral axis. Optimization techniques were applied to a planar ADAMS Model to minimize the drive shaft rotation.

The aim of this analysis is to study the effects of flexibility of the suspension components like upper control arm, lower control arm and knuckle on the suspension forces as experienced by a vehicle. An independent front suspension, which was being proposed for a vehicle, has been used for this analysis. A rigid body quasi-static analysis was first performed. Later a finite-element model of the suspension first with rigid elements and later with flexible elements was analyzed using non-linear large deflection and compared with the rigid body results. It is found that flexibility of the suspension components only have a local effect and not much of a global effect.

A fuel filter system essentially consists of a center tube, which is screwed on to a head and rests against a bowl. A thin circular plate, called end-cap, slides inside the bowl with spline teeth. The fuel filter material is inside the bowl and rests on the end-cap. When the bowl is tightened an input torque is transferred to the center tube and on to the head. It is required to estimate the stresses of the various components when a maximum tightening torque is applied to the bowl. A non-linear large deflection contact analysis of the fuel filter system needs to be performed. A number of contacts between the different deformable bodies, i.e. head and bowl, end-cap and center tube, etc. are resolved for equilibrium.

A case study of an application of shape optimization techniques in the design of an upper control arm of an automotive suspension system has been presented. An existing design of an upper control arm was taken as a starting design point. The designer's inputs as to the various possible changes, constraints of movements etc. were built into the optimizer as shape variables and constraints. Shape optimization was then performed using approximate direct linearization method of MSC/Nastran software. A number of design directions were obtained. The weight of the upper control arm was reduced by 15% and at the same time the maximum stresses were also reduced by 29%.

Automotive drive shafts, which transmit power from the transmission unit to the rear axle are in general straight round tubes. An attempt has been made to explore other possible cross-sectional shapes to improve NVH (Noise Vibration and Harshness) performance. The first natural frequency is a very good indicator of the NVH performance. First, finite element based topology optimization and later topography optimizations were tried out. A number of design solutions were obtained from the study and a comparison has been made. A round drive shaft with a bulge at the center has been proposed for stiffenening the drive shaft to improve the first natural frequency.