Local buckling strength of steel foam sandwich panels

Structural Stability Research Council Annual Stability Conference 2012

Volumn , Issue , 2012, Pages 620-637

  Szyniszewski, S ^a   Smith, B H ^b   Hajjar, J F ^c   Arwade, S R ^b   Schafer, B W ^a  

^a JOHNS HOPKINS UNIVERSITY   (United States)

^b UNIVERSITY OF MASSACHUSETTS   (United States)

^c NORTHEASTERN UNIVERSITY   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ANALYTICAL EXPRESSIONS; BRICK ELEMENTS; CIVIL ENGINEERING APPLICATIONS; CLOSED FORM; CORE CONFIGURATION; DEFORMATION CAPACITY; DESIGN METHOD; DESIGN METHODOLOGY; EFFECTIVE WIDTH; ELASTIC BUCKLING; ENGINEERING DOMAINS; FACE SHEETS; FINITE ELEMENT SIMULATIONS; FOAM CORE; INTERNAL VOIDS; LOCAL BUCKLING; LOCAL STABILITY; MATERIAL CHARACTERIZATIONS; OPTIMAL BALANCE; OPTIMAL TARGET; PARAMETRIC STUDY; PLAIN STEELS; SANDWICH PANEL; SINGLE PARAMETER; STEEL CORE; STEEL FACE; YIELDING BEHAVIOR;

CIVIL ENGINEERING; DESIGN; ENERGY DISSIPATION; HONEYCOMB STRUCTURES; OPTIMIZATION; SANDWICH STRUCTURES; STABILITY;

STEEL TESTING;

EID: 84866286056     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: None     Document Type: Conference Paper

References (29)

1. American Iron and Steel Institute (2007). Cold-formed steel design manual: specification for the design of cold- form steel structural members, New York.
2. Allen HG (1969). Analysis and Design of Structural Sandwich Panels, Pergamon, Oxford.
3. Ashby MF, Evans T, Fleck NA, Gibson NA, Hutchinson JW, Wadley HNG (2000). Metal Foams: A Design Guide, Butterworth-Heinemann.
4. Banhart J, Seeliger H (2008). Aluminum foam sandwich panels: manufacture, metallurgy and applications. Advanced Engineering Materials 10:793-802.
5. Bao HQ, Han BK (2009), Transmission loss of metallic foams for the local resonance, in: 3rd International Conference on Bioinformatics and Biomedical Engineering, iCBBE.
6. Cardoso E, Oliveira BF (2010), Study of the use of metallic foam in a vehicle for an energy - economy racing circuit. Materialwissenschaft Und Werkstofftechnik 41;257-264.
7. Coquard R, Rochais D, Baillis D (2010). Conductive and Radiative Heat Transfer in Ceramic and Metal Foams at Fire Temperatures - Contribution to the Special Issue "Materials in Fire" Guest Editor K. Ghazi Wakili.
8. Deshpande V, Fleck NA (2000). Isotropic constitutive models for metallic foams, Journal of the Mechanics and Physics of Solids 48:1253-1283.
9. Hallquist J (2006). LS-DYNA: theory manual, Livermore, California: Lawrence Software Technology Corporation.
10. Hanssen A, Hopperstad O, Langseth M, Ilstad H (2002). Validation of constitutive models applicable to aluminium foams, International Journal of Mechanical Sciences 44:359-406.
11. Hipke T (2011), Fraunhofer Institute, Chemnitz, Germany, personal communication.
12. Hohe J, Librescu L (2004). Advances in the Structural Modeling of Elastic Sandwich Panels. Mechanics of Advanced Materials and Structures 11:395-424.
13. Kardomateas GA (2010). An elasticity solution for the global buckling of sandwich beams/wide panels with orthotropic phases, Journal of Applied Mechanics, Transactions ASME 77:1-7.
14. von Kármán T, Sechler EE, Donnell LH (1932). Strength of Thin Plates in Compression, Trans. A.S.M.E, Vol.54,No.APM-54-5,pp.53-57.
15. Kremer K, Liszkiewicz A and Adkins J (2004). Development of Steel Foam Materials and Structures, US DOE and AISI final report DE-FC36-97ID13554, Fraunhofer USA - Delaware Center for Manufacturing and Advanced Materials, Newark, DE.
16. Lefebvre LP, Banhart J, Dunand DC (2008). Porous Metals and Metallic Foams: Current Status and Recent Developments. Advanced Engineering Materials 10:775-787.
17. Losito O, Barletta D, Dimiccoli V (2010). A wide-frequency model of metal foam for shielding applications. IEEE Transactions on Electromagnetic Compatibility 52:75-81.
18. Lu T, Chen C (1999). Thermal transport and fire retardance properties of cellular aluminium alloys, Acta Materialia 47:1469-1485.
19. Miller RE (2000). A continuum plasticity model for the constitutive and indentation behaviour of foamed metals, International Journal of Mechanical Sciences 42:729-754.
20. Neugebauer R, Hipke T, Hohlfeld J, and Thümmler R (2004). Metal foam as a combination of lightweight engineering and damping. Cellular Metals and Polymers. Singer RF, Koerner C, Alstaedt V, Muenstedt H (eds.) pp. 13-18.
21. Plantema JF (1966). Sandwich Construction, John Wiley and Sons, New York.
22. Reyes A (2003). Constitutive modeling of aluminum foam including fracture and statistical variation of density, European Journal of Mechanics A/Solids 22:815-835.
23. Schafer BW, Grigoriu M, Peköz T (1998). A probabilistic examination of the ultimate strength of cold-formed steel elements, Thin-Walled Structures, 31:271-288.
24. Xu S, Bourham M, Rabiei A (2010). A novel ultra-light structure for radiation shielding. Materials and Design 31:2140-2146.
25. Winter G (1947). Strength of thin steel compression flanges. Engineering Experiment Station bulletin, no. 35, pt. 3. Ithaca, N.Y. : Cornell University.
26. Reprint from: Transactions of American Society of Civil Engineers Vol. 112, with an appendix not contained in the original publication.
27. Vieira LCM Jr, Shifferaw Y, Schafer BW (2011). Experiments on sheathed cold-formed steel studs in compression, Journal of Constructional Steel Research 67:1554-1566.
28. Vinson JR (1999). The Behavior of Sandwich Structures of Isotropic and Composite Materials, Technomic, Lancaster, PA.
29. Ziemian RD (2010). Guide to Stability Design Criteria for Metal Structures, Chapter 4, 6th ed., Wiley.