Resumen

El presente trabajo describe una metodología para modelar y simular un componente plástico bajo condiciones de fluencia lenta (Creep). Se modela el comportamiento mecánico del material polipropileno (PP) por medio de la Ley de Norton, cuyos parámetros B y n fueron obtenidos a través de una caracterización experimental del material plástico en función del tiempo (1000 horas); reproduciendo el comportamiento de las probetas a través de una simulación del fenómeno de fluencia lenta para el mismo periodo de tiempo usando un software comercial, obteniendo una diferencia entre los resultados experimentales y la simulación menor al 14%. Esto sugiere que en las simulaciones realizadas para componentes fabricados con PP existirá la confianza para obtener resultados próximos a la realidad. Se presenta un caso de estudio.

Palabra(s) Clave: Fluencia lenta, Ley de Norton, Simulación de fluencia lenta.

MODELING AND SIMULATION OF PLASTIC COMPONENT SUBJECTED TO SLOW FLUENCY

Abstract

The present work describes a methodology for modeling and simulating a plastic component under creep conditions. The mechanical behavior of the plastic material is modeled by Norton's Law, whose parameters B and n were obtained through an experimental characterization of the polypropylene (PP) as a function of time (1000 hrs); reproducing the behavior of the specimens through a simulation of the creep phenomenon for the same period of time using commercial software, obtaining a difference between the experimental results and the simulation of less than 14%. This suggests that in the simulations performed for components made with PP there will be the confidence to obtain results close to reality. One case study is presented.

Keywords: Creep, Norton’s Law, Simulation creep.

ANSYS. (2015). Rate dependent creep. En ANSYS Mechanical Advanced Nonlinear Materials .

ASTM. (s.f.). ASTM E 646- 00. Uniated states.

Callister, W. D. (2007). Material science an engineering. Utah: John Wiley & sons, Inc.

Dwayne, R. (2009). transient and steady-state creep in a sn-ag-cu lead-free solder alloy: experiments and modeling. Toronto: Departament of materials science & engineering.

Chaturvedi, M. C., & Han, Y. (1989). Creep Deformation Of Alloy 718. Institute of Aeronautical Materials.

Mabe, C. (2015). Cuidado de la ropa: http://www.mabe.com.co/glosario

Martin, J., David, H., & David, E. (2003). Developing an ANSYS Creep Model for Polypropylene from Experimental Data.

Mata, M., Ballesteros, L., & Zavala, J. (2016). Nuevo Método para Evaluar Fluencia Lenta en Materiales Plásticos. Academia Journals, 6.

Shell181. (2016). Sharcnet: https://www.sharcnet.ca/Software/Ansys/16.2.3 /en-us/help/ans_elem/Hlp_E_SHELL181.html.

Solid187. (2016). Sharcnet: https://www.sharcnet.ca/Software/Ansys/17.0 /en-us/help/ans_elem/Hlp_E_SOLID187.html.

Steinberger, R., Vezer, S., Major, Z., & Lang, R. (s.f.). Testing System Development for Creep Characterization of Polymers. Leoben.

Tsou, C., Li, H., Lai, T., Hsu, C., & Feng, W. (2007). Bending characterization of electroplated nickel microbeams. S & M.

Xu, B., Yu, Z., & Eggeler, G. (2007). A numerical procedure for retrieving material creep properties from bending creep test. Acta MATERIALIA.

Zhuang, F., Tu, G., Zhou, Y., & Wang, Q. (2014). A small cantilever beam test for determination of creep properties of materials. FFEMS, 11.