Encapsulated OSB Energy Absorption Potential

A Preliminary Analysis

Autores/as

DOI:

https://doi.org/10.15392/2319-0612.2022.1874

Palabras clave:

Shock absorbers, Wood, LS-DYNA, Finite Elements Method, Cellular Solids

Resumen

The transport of radioactive substances is, in many ways, necessary in the context of the nuclear fuel cycle that aims to generate energy or radioisotopes. In the event of a possible accident, the shock-absorbing parts reduce the mechanical stresses on the other components of the transport packaging, since a large part of the kinetic energy is absorbed by the shock absorber. To standardize the design of the research reactor spent fuel assembly transport devices by numerical analysis, a set of dynamic simulations of a benchmark was conducted to representatively capture the phenomena found in the drop tests used in project qualifications. This study aims to present a comparison of different ways of applying wood and wood composites as a useful and accessible impact-absorbing material. The necessary numerical modelling characteristics are validated and the phenomena present in non-isotropic materials are discussed. This study demonstrates the application of material models where energy absorption is the main structural function. In this case, the orientation of the wood fibers became sensitive with an approximate difference of 10% more in the impact absorption potential, without considerable variation in the duration interval of the maximum deceleration.

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Referencias

NEUMANN, M. Investigation of the Behavior of Shock-Absorving Structural Parts of Transport Casks Holding Radioactive Substances in Terms of Design Testing and Risk Analysis. BAM-Dissertation Series, Volume 45, Berlin, Germany, 2009.

Ove Arup and Partners International (OAPIL); Gesellschaft für Nuklear-Behälter mbH (GNB). Evaluation of Codes for Analyzing the Drop Test Performance of Radioactive Material Transport Containers. European Commission DG 17, United Kingdom, Germany, March 1998, Report Ref: 53276/02.

GIBSON L.J.; ASHBY. M.F. Cellular solids Structure and properties. Cambridge University Press, London, England, 1997.

NAIRN, J. A. Numerical Modeling of Wood or Other Anisotropic, Heterogeneous and Irregular Materials. 4th MPM Workshop, Salt Lake City, Utah United States of America, March, 2008.

DING, Y.; Et al. Dynamic crushing of cellular materials: A unique dynamic stress-strain state curve. Mechanics of Materials vol. 100 (2016) pp. 219-231 September, 2016.

LSTC - Livermore Software Technology Corporation. LS-DYNA Keyword User’s Manual R11. Volume 1, Version 10580, 2018. Available at: <https://www.dynasupport.com/manuals/ls-dyna-manuals>. Last accessed: 10 Jul. 2020.

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CHI-FUNG TSO, Arup, UK e R. HÜGGENBERG. Evaluation of Finite Element Codes for Demonstrating the Performance of Radioactive Material Packages in Hypothetical Accident Drop Scenarios. 14th International Symposium on the Packaging and Transportation of Radioactive Materials (PATRAM 2004), Berlin, Germany, September 20-24, 2004.

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Publicado

2022-10-29

Número

Vol. 10 Núm. 3A (Suppl.) (2022): XXII ENFIR / VII ENIN

Sección

INAC 2021_XXII ENFIR_VII_ENIN

Licencia

Derechos de autor 2022 Brazilian Journal of Radiation Sciences (BJRS)

Creative Commons License

Esta obra está bajo una licencia internacional Creative Commons Atribución 4.0.

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Cómo citar

Encapsulated OSB Energy Absorption Potential: A Preliminary Analysis. Brazilian Journal of Radiation Sciences (BJRS), Rio de Janeiro, Brazil, v. 10, n. 3A (Suppl.), 2022. DOI: 10.15392/2319-0612.2022.1874. Disponível em: https://bjrs.org.br/revista/index.php/REVISTA/article/view/1874. Acesso em: 16 jul. 2025.