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The Energy Finite Element Analysis(EFEA) is a recent development for high frequency vibro-acoustic analysis, and constitutes an evolution in the area of high frequency computations. The EFEA is a wave based approach, while the SEA is a modal based approach. In this paper the similarities in the theoretical development of the two methods are outlined. The main scope of this paper is to establish the validity of the EFEA by analyzing several complex structural-acoustic systems. The EFEA solutions are compared successfully to SEA results and to solutions obtained from extremely dense conventional FEA models.

The use of die cast magnesium for automobile transmission cases offers promise for reducing weight and improving fuel economy. However, the inferior creep resistance of magnesium alloys at high temperature is of concern since transmission cases are typically assembled and joined by pre-loaded bolts. The stress relaxation of the material could thus adversely impact the sealing of the joint. One means of assessing the structural integrity of magnesium transmission cases is modeling the bolted joint, the topic of this paper. The commercial finite element code, ABAQUS, was used to simulate a well characterized bolt joint sample. The geometry was simulated with axi-symmetric elements with the exact geometry of a M10 screw. Frictional contact between the male and female parts is modeled by using interface elements. Material creep is described by a time hardening power law whose parameters are fit to experimental creep test data.

Adhesive joining is a common autobody subassembly technique especially for outer panels, where visible spot welding is objectionable. To accommodate mass production with the use of certain adhesives very high thermal gradient usually exists, which may result in panel dimensional distortion and variation. The temperature distribution over location and over time are monitored, and its impact to panel dimension is investigated. Experimental results on the effect of the distance between panel and induction coil on the panel temperature is obtained. The thermal induced shape distortion is simulated with a simplified FEA model. The approach to improvement of the induction curing process is discussed.

In this paper, an analytical method is proposed for determining the stress distributions in steering knuckle/tapered stud assemblies. The method is based on solutions of the plane stress thick cylinder interference fit problem with modifications to account for the effects of stud taper and dissimilar component materials. The analytical solutions are applied to knuckle/tapered stud assemblies. The results from the analytical solutions are compared to those from a finite element analysis. It is shown that the analytical and FEA results are in good agreement for several load and frictional conditions, and the hoop and radial stress solutions presented in this paper are good engineering solutions to the knuckle/tapered stud problem where the draw distance is provided.

Engineering productivity and customer-focused outcomes are ongoing concerns for managers. In order to be effective, engineering departments need to be challenging, satisfying, and productive places to work. Attracting and keeping talented engineers are constant worries in an era of uncertainty caused by competitiveness, downsizing, and restructuring. Design for the Workplace: A Manager's Guide focuses on providing maximum management support and encouragement. Engineering managers can use several strategies to create an effective workplace, including temporary job assignments, work teams, communication, training and career development, and motivation. Thoughtful planning and careful implementation are necessary for any strategy to be viable.

An assessment of Body-In-White quality and launch preparedness occurs at many intervals. This paper will focus on dimensional control activities that take place during the first pre-production pilot phase known as P0. (P-zero occurs approximately 35 weeks before volume production.) Two Process Assurance Body Build Systems (Tooling Build and Plate Build) have been used at Chrysler and the results have been documented. The Plate Build and Tooling Build activities provide the opportunity to uncover and resolve Product Design and Part Quality Issues. In addition, the Tooling Build process has proven to be an objective method of identifying and correcting tooling, gaging and process issues during the P0 Vehicle Build Program.

Rapid change is a way of life in Chrysler. Facing increasing competition, we realize that the traditional practices are no longer sufficient. Accordingly, a new process using simultaneous engineering (SE) teams in conjunction with reliability tools has been used to design and develop a new family of Chrysler engines. These SE teams include representatives from engine engineering, vehicle platform engineering, electrical engineering, manufacturing, reliability & service engineering, finance and suppliers. The SE teams maximize the use of up-front engineering tools, such as Finite Element Analysis (FEA), Digital Model Assembly (DMA), Variation Simulation Analysis (VSA) and Rapid Prototyping with StereoLithography (SLA), Laminated Object Manufacturing (LOM), etc. The new process combines these up-front engineering activities and the appropriate reliability testing as an integral part of the reliability growth process. It enhances the design decisions made with reliability.

The shape and topology optimization method using a homogenization method is a powerful design tool because it can treat topological changes of a design domain. This method was originally developed in 1988 [1] and have been studied by many researchers. However, their scope of application in real vehicle design works has been limited where a design domain and boundary conditions are very complicated. The authors have developed a powerful optimization system by adopting a general purpose finite element analysis code. A method for treating vibration problems is also discussed. A new objective function corresponding to a multi-eigenvalue optimization problem is suggested. An improved optimization algorithm is then applied to solve the problem. Applications of the optimization system to design the body and the parts of a solar car are presented.

A new turbocharged 2.2 liter engine has been developed by Chrysler Corporation. It is derived from the Chrysler 2.2 liter naturally aspirated four cylinder powerplant. A number of new and redesigned components were required to yield a durable, high performance production engine. The compact installation includes a watercooled turbocharger and multi-point fuel injection. Electronic controls are used to satisfy the demanding performance and durability requirements unique to the turbocharged powerplant.

The development of the first fully molded, plastic, passenger car door trim panel is discussed in this paper. From the initial styling concept, an attempt is made to explain the various factors that lead to the choice of materials and final part overall design. Special consideration of the interaction of part shape and attachment methods is given. There is also a description of the mold and the molding conditions, and the quality control test procedures established to insure quality production. A prediction of concept acceptability is made in the Summary Section. Also, a suggestion for further developments of plastic surface coatings is made.