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Structural durability of the vehicle components is one of the key factors in design and development. This helps in understanding the capability of structures or components to withstand the loads encountered in service over a specified period of use. Durability assessment for vehicle structures requires load inputs. These load inputs can be in form of force, acceleration and displacement and typically generated from road load profiles in the testing lab or by the load groups. But if a program is in its early stage when design data is immature or lab facility is limited then acquiring these load inputs takes time and sometimes not feasible also. In this scenario, we can predict the durability load inputs from road load profiles virtually using dynamic transient simulation. The objective of this work is to predict the durability input signals from road profiles using finite element model by modal transient approach.

A vehicle fitted with a sunroof has structural challenges due to the mountings of the assembly with the Body-In-White parts. The major challenges include water leakage, noise and durability issues. This results in warranty issues and cost penalties for the Original Equipment Manufacturer. The focus of this paper is to address the challenges due to the mounting issues in the sunroof. The clinching process of the sunroof panels results in the reduction of the contact area for the clamping process. This reduction could result in bolt slippage either during the assembly of the vehicle or during the operating conditions. The sunroof module is also prone to cracks and bulging, due to bolt slippage. The Virtual engineering simulation used in this study represents the clinching process and the variations in the surface of the body panels. In addition, the clamping of the Body-In-White to the sunroof module is represented for the assembly torque considering the frictional characteristics.

Roof is one of the major subsystems of the Body-In-White Structure, which significantly affects the vehicle strength and durability performance criteria. The roof structure should meet the functional targets under the standard operating conditions. Roof design considering various parameters in the initial phase is beneficial in reducing the product timeline for the OEM. The first-time right approach provides an opportunity for Optimization and Cost benefits in the longer term. This paper provides the use of Design for Six Sigma techniques to arrive at a robust and optimum design for the standard roof structure. The roof structure is designed to meet the operating conditions for durability. Roof finite element models are developed with control factors that affect the structure design. Virtual Analysis is performed on the Standard roof structure models.

The wheel impact test evaluates wheel structural performance for a typical lateral curb impact event occurring in passenger cars and light trucks. This test which is as per SAE J -175 standard has a striker dropped from a specified height on to a fixture mounted wheel-tire assembly. This impact test performance is critical to meeting overall structural performance for the wheel. There are many processes and methods available to simulate impact tests using FE analysis and in this study, certain existing methods are fine tuned to facilitate improved correlation with aforementioned lab test. Abaqus explicit is used in the simulation process and FE analysis-test correlation is achieved within 3% (strain gauge measurements). The improved method closely captures the behavior of the wheel during and after impact including capturing the variation of bolt pretension during the impact test. The wheel width before and after impact is another parameter used to compare analysis and test results.