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Evaluating the effect of tolerances on the functionalrequirements of assemblies

Published online by Cambridge University Press:  12 June 2013

Mehdi Tlija
Affiliation:
LGM, ENIM, University of Monastir, Av. Ibn Eljazzar, 5019 Monastir, Tunisia
Borhen Louhichi*
Affiliation:
LGM, ENIM, University of Monastir, Av. Ibn Eljazzar, 5019 Monastir, Tunisia LIPPS, ÉTS, 1100 Notre-Dame Ouest, Montréal, H3C1K3 Québec, Canada
Abdelmajid BenAmara
Affiliation:
LGM, ENIM, University of Monastir, Av. Ibn Eljazzar, 5019 Monastir, Tunisia
*
a Corresponding author:[email protected]
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Abstract

In order to improve digital mock-up, a tolerancing phase should be integrated in thegeometric models. However, in CAD software, tolerances are represented by annotations,which are neglected as well as the tolerance impact. Thus, the system malfunction isgenerated. For these reasons, in this paper a tolerancing phase is integrated in thenumerical model to form a realistic model, where worst case configurations of assembliesare determined from the tolerances assigned to the nominal model. The proposed modelincorporates tolerances on CAD models in the case of planar face, cylindrical face andplanar face with non quadratic loop. In addition, the model ability to respect the maximummaterial condition (MMC) and the requirement of datum priority order in the CAD models isshown. Finally, functional requirement of a linear guide mechanism is inspected by usingthe proposed model.

Type
Research Article
Copyright
© AFM, EDP Sciences 2013

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References

G. Ameta, P. Hoffmann, Ontological model of tolerances for interoperability in product lifecycle, Ontological Model of Tolerances for Interoperability in Product Life Cycle, Chapt. 26, in: M. Giordano, L. Mathieu, F. Villeneuve (eds.), Geometric Variations within Product Lifecycle management (Selected Papers from the 11th CIRP International Conference on Computer-Aided Tolerancing, held at Université de Savoie, Annecy, France, 26–27 March 2009) ISTE, HERMES publishers, London, Uk, 2010, pp. 455–468
J.C. Tsai, Stiffness variation of compliant devices due to geometric tolerancing, Proceedings of International Seminar on Computer-Aided Tolerancing 10th CIRP, Erlangen, Germany, 2007
M. Tlija, B. Louhichi, A. BenAmara, Integration of tolerances in the mechanical product process, Proceedings of International conference on Innovative Methods in Product Design, Venice, Italy, 2011
J. Dufaure, D. Teissandier, Geometric tolerancing from conceptual to detail design, Proceedings of CIRP Seminar on Computer-Aided Tolerancing, 2003, pp. 176–186
Anselmetti, B., Louati, H., Generation of manufacturing tolerancing with ISO standards, Int. J. Mach. Tools Manuf. 45 (2005) 11241131 CrossRefGoogle Scholar
Clement, A., Riviere, A., Serre, P., The TTRS: a common declarative model for relative positioning, tolerancing and assembly, International journal of CAD/CAM and computer graphics 11 (1996) 149164 Google Scholar
Desrochers, A., Ghie, W., Laperriere, L., Application of a unified Jacobian-Torsor model for tolerance analysis, J. Comput. Inf. Sci. Eng. 3 (2003) 214 CrossRefGoogle Scholar
F. Germain, M. Giordano, A new approach for three-dimensional statistical tolerancing, Proceedings of CIRP Conference on Computer Aided Tolerancing, Erlanger, Germany, 2007
J.Ph. Petit, S. Samper, Tolerancing analysis and functional requirement, Proceedings of the 5th International Conference on Integrating Design and Manufacturing in Mechanical Engineering, Bath, UK, 2004
P. Bourdet, E. Ballot, Geometrical Behavior Laws for Computer-aided Tolerancing, Computer-aided Tolerancing, in: Chapman and Hill, F. Kimura (ed.), Proceedings of the 4th CIRP Design Seminar The University of Tokyo, Tokyo, Japan, 1995, pp. 119–131
S. Tichadou, O. Legoff, J.-Y. Hascoët, 3D Geometrical Simulation of Manufacturing, Compared approaches between integrated CAD/CAM system and small displacement torsor model, Advances in Integrated Design and Manufacturing in Mechanical Engineering, Kluwer Academic Press, 2005, pp. 446–456.
F. Vignat, F. Villeneuve, A numerical approach for 3D manufacturing tolerances synthesis, Proceedings of CIRP Conference on Computer Aided Tolerancing, Erlangen, Germany, 2007
R. Benea, G. Cloutier, C. Fortin, Process plan validation including process deviations and machine-tool error, Geometric Product Specification and Verification: Integration of Functionality, Kluwer Academic Publishers, Netherlands, 2003, pp. 197–206
Chang, M., Gossard, D.C., Modeling the assembly of compliant non-ideal parts, Comput. Aided Des. 29 (1997) 701708 CrossRefGoogle Scholar
Ballu, A., Falgarone, H., Chevassus, N., Mathieu, L., A new design method based on functions and tolerance specifications for product modelling, CIRP annals – Manufactoring Technology 55 (2006) 139142 CrossRefGoogle Scholar
A. Ballu, L. Mathieu, Choice of functional specifications using graphs within the framework of education, Proceedings of 6th CIRP Seminar on Computer Aided Tolerancing, Enschede (The Netherlands), Kluwer Academic Publishers, 1999, pp. 197–206
D. Buysse, M. Socoliuc, A. Rivière, A new specification model for realistic assemblies simulation, Proceedings of International Seminar on Computer-Aided Tolerancing 10th CIRP, Erlangen, Germany, 2007
G. Mandil, A. Desrochers, A. Rivière, Framework for the monitoring of functional requirements along the product life cycle, Proceedings of CPI’2009, Fes, Morocco, 2009
Pillet, M., Adragn, P-A., Germain, F., Inertial Tolerancing: The Sorting Problem, Journal of Machine Engineering: Manufacturing Accuracy Increasing Problems, Optimization 6 (2006) 95102 Google Scholar
M. Giordano, S. Samper, J.P. Petit, Tolerance analysis and synthesis by means of deviation domains, axi-symmetric cases, in: J.K. Davidson (ed.), Models for Computer Aided Tolerancing in Design and Manufacturing 2007, Proceedings of the 9th CIRP International Seminar on Computer-Aided Tolerancing, held at Arizona State University, Tempe, Arizona, USA, 2005, pp. 85–94
J.P. Petit, Spécification géométrique des produits: méthode d’analyse de tolérances. Application en conception assistée par ordinateur, Mechanical Ph.D. Thesis, Engineering High School of Annecy, 2004
Lahanas, M., Kemmerer, T., Milickovic, N., Karouzakis, K., Baltas, D., Zamboglou, N., Optimized bounding boxes for three-dimensional treatment planning in brachytherapy, Med. Phys. J. 27 (2000) 23332342 CrossRefGoogle ScholarPubMed
Béchet, E., Cuillière, J.C., Trochu, F., Generation of a Finite Element Mesh from Stereolithography (STL) Files, Comput. Aided Des. 34 (2002) 117 CrossRefGoogle Scholar
Louhichi, B., Tlija, M., BenAmara, A., François, V., Reconstruction d’un modèle CAO à partir d’un maillage : application dans le cas de grands déplacements, Mécanique & Industries 10 (2009) 477486 CrossRefGoogle Scholar
Samper, S., Adragna, P.-A., Favreliere, H., Pillet, M., Modeling of 2D and 3D Assemblies Taking Into Account Form Errors of Plane Surfaces, J. Comput. Inf. Sci. Eng. 9 (2009) 041005 CrossRefGoogle Scholar
Louhichi, B., Benamara, A., Francois, V., Intégration CAO/Calcul par reconstruction des modèles CAO à partir des résultats de calcul, Revue internationale d’ingénierie numérique 1 (2005) 926 Google Scholar
B. Louhichi, Intégration CAO/Calcul par reconstruction du modèle CAO à partir des résultats éléments finis, Ph.D. Thesis, National Engineering School of Monastir, Tunisia, 2008