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ABSTRACT
The need of assessing physical performances of a product before manufacturing is very common in engineering design. Hence, since they rely on a virtual model of behaviour, numerical simulation software are of great importance. Finite Elements based software are probably the most common ones. Using such simulation technics in a design process falls into one of three categories that are first presented, as well as the main stakeholders to these activities. Stating that a good knowledge of the method and limitations is required for relevant using, the theoretical principles are briefly presented in a second part of the article. Finally, the third part gives some description of the main steps for implementing the method in an engineering design process.
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Franck POURROY: Senior Lecturer, G-SCOP Laboratory – University of Grenoble Alpes, Grenoble (France)
INTRODUCTION
Design is a complex creative process. It consists of developing a product or system in accordance with a customer's requirements, and in compliance with certain rules or standards, or the availability of certain materials, components or means of production, which amounts to limiting the product's creative scope. It must also guarantee the company's financial profitability.
Drawing up a functional specification (CdCF, see
When it comes to the mechanical behavior of a product, the engineer or designer has a wide range of methods at his or her disposal, including :
methods based on "professional" knowledge such as abacuses, empirical laws, databases, etc. ;
simplified calculation methods such as strength of materials ;
more elaborate calculation methods, generally supported by computer tools, with the finite element method (FEM) being the most widely used;
optimization methods.
The relevant implementation and use of these methods, and in particular the finite element method, are discussed in this article. The stakes are high, since in a highly competitive industrial context, the aim is to :
reduce costs (optimize shapes and material volumes, choose materials, reduce the number of prototypes, etc.);
reduce lead times (limit the number of iterations in the design process, propose viable solutions directly from a behavioral point of view, better target testing, etc.);
improve quality (ensure compliance with various functions and constraints in terms of reliability, comfort, ergonomics, etc.).
The field of application of finite element methods is vast. They have proven...
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KEYWORDS
finite elements | simulation | computer aided design | numerical simulation
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The contribution of finite elements to mechanical design
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Bibliography
Websites
The keywords listed below are intended to facilitate access to the main websites devoted to finite element software and the finite element method in general:
finite elements ;
FEA (finite elements analysis) ;
FEM (finite elements method) ;
CAE (computer aided engineering)...
Standards and norms
"Guide de validation des progiciels de calcul de structures" published by AFNOR 1990 (ISBN 2-12-486611-7).
CA2582058
Directory
Manufacturers – Suppliers – Distributors (non-exhaustive list)
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ALTAIR. Publisher of a software suite for numerical simulation (HyperMesh, Optistruct, Radioss, Inspire, etc.). https://altairengineering.fr/
ANSYS. Publisher of a software suite for numerical simulation (Mechnical, Fluent, LS-DYNA...).
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