Finite Element Modelling to Predict Equivalent Stiffness of 3D Space Frame Structural Joint Using Circular Beam Element

Mohd Shukri Yob; Shuhaimi Mansor; Razali Sulaiman

doi:10.4028/www.scientific.net/AMM.431.104

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 431Finite Element Modelling to Predict Equivalent...

Finite Element Modelling to Predict Equivalent Stiffness of 3D Space Frame Structural Joint Using Circular Beam Element

Abstract:

In automotive industry, thin walled beam is widely used to build vehicles structure. Vehicle structure is built by joining thin walled beams using various welding techniques. The usage of thin walled structure in automotive is important to improve vehicle performance by offering better strength-to-weight ratio. However the application of thin walled structure will cause few drawbacks to vehicle structure. When thin walled beam or structure is loaded with compression load, at certain limit it will undergo local or global buckling. Another problem is when thin walled beam is joined to other thin walled beams, it will show unexpected deformation which called joint flexibility. Both phenomena will cause numerical and analytical model to predict stiffness of structure tend to deviate from experimental result. In vehicle structure fabrication 3D space frame is used a lot. As a case study for this application, area around car bulkhead where cross member, side sill and A pillar are connected to each other at right angle is studied. The intention of this research work is to produce validated finite element model to predict equivalent stiffness of 3D space frame structural joint. Finite element, shell element is most common technique used to model the joined structure. However it is known that shell model cannot produce good result. In this result work, modelling of equivalent stiffness for 3D space frame structural joint is presented. The result shows, using this model the accuracy is about 65%. New modelling technique is proposed to increase the accuracy based on solid model. By introducing circular beam elements at welding area, it is found that accuracy improves up to 90%.

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Periodical:

Applied Mechanics and Materials (Volume 431)

Pages:

104-109

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.431.104

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Online since:

October 2013

Authors:

Mohd Shukri Yob*, Shuhaimi Mansor, Razali Sulaiman

Keywords:

3D Space Frame, Finite Element, Joint Modelling, Thin Walled Structure

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* - Corresponding Author

References

[1] American Iron and Steel Institute, Automotive Steel Design Manual. (2002).

Google Scholar

[2] Christian Spencer, Katy Vartanian and Mechael White. Light truck frame joint Stiffness Study. Altair Engineering and DaimlerChrysler Corporation. SAE. (2003).

DOI: 10.4271/2003-01-0241

Google Scholar

[3] Donald E. Malen. Fundamentals of Automobile Body Structure Design. 400 Commonwealth Warreendale, PA 15096-0001 USA. (2011).

Google Scholar

[4] Ferdinand P. Beer, E. Russell Johnston, Jr., John T. Dewolf and David F. Mazurek. Mechanics of Materials. (5th Edition), McGraw-Hill, New York. (2009).

Google Scholar

[5] Mohd Shukri Yob, Shuhaimi Mansor and Razali Sulaiman, Modelling of Equivalent Stiffness of Thin walled structural Joint. ICMAAE 2013 Conference.

Google Scholar

[6] Shiunn-Jang Wang, Sam Errera and Douglas G, Prince. Determine Member Strength of Automotive Steel Components Considering Local Buckling Effect. Desktop Engineering Int'l Inc and U. S steel , a unit of USX Corp. SAE. (2002).

DOI: 10.4271/2000-01-2708

Google Scholar

[7] Yasuaki Tsurumi, Hidekazu Nishigaki, Toshiaki Nakagawa, Tatsuyuki Amago And Katsuya Furusu. First Order Analysis for Automotive Body Structure Design, Part 2: Joint Analysis Considering Nonlinear Behavior, Toyota Central R&D Lab, Inc, University Of Michigan. SAE. (2004).

DOI: 10.4271/2004-01-1659

Google Scholar