Numerical modeling and experimental validation of new energetic materials in favor of photovoltaic modules

Numerical modeling and experimental validation of new energetic materials in favor of photovoltaic modules

  IJETT-book-cover  International Journal of Engineering Trends and Technology (IJETT)          
  
© 2020 by IJETT Journal
Volume-68 Issue-11
Year of Publication : 2020
Authors : Khadija Ezzouitine, Mustapha Jammoukh, Abdelilah Hachim, Abdelkader Boulezhar
DOI :  10.14445/22315381/IJETT-V68I11P219

Citation 

MLA Style: Khadija Ezzouitine, Mustapha Jammoukh, Abdelilah Hachim, Abdelkader Boulezhar "Numerical modeling and experimental validation of new energetic materials in favor of photovoltaic modules" International Journal of Engineering Trends and Technology 68.11(2020):145-149. 

APA Style:Khadija Ezzouitine, Mustapha Jammoukh, Abdelilah Hachim, Abdelkader Boulezhar. Numerical modeling and experimental validation of new energetic materials in favor of photovoltaic modules  International Journal of Engineering Trends and Technology, 68(11),145-149.

Abstract
A photovoltaic module consists of grouping photovoltaic cells in series or parallel to allow their use at practical voltages and currents while ensuring their electrical insulation and their protection against external factors as humidity, rain, snow, etc. dust, corrosion, or mechanical shock.
In this perspective, we plan to establish a numerical Modeling and experimental validation of new material such as S355 steel in favor of photovoltaic panels` framework given its energy potential.
To this end, our work will be focused on numerical modeling by finite elements of a double notch tensile test specimen using the CAST3M 2009 calculation code. We will analyze the evolution of the maximum stress along the axis of the l. test specimen and the stress concentration factor with the crack length and the applied stress.

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Keywords
Notch, finite elements, photovoltaic, maximum stress, stress concentration factor, nominal stress.