Computational modeling of viscoelastic backsheet materials for photovoltaics

TL;DR

This paper experimentally characterizes and computationally models the viscoelastic response of backsheet materials in photovoltaic modules, proposing and validating two models to improve durability predictions.

Contribution

It introduces and compares Prony-series and Fractional Calculus viscoelastic models based on extensive experimental data for PV backsheets.

Findings

Models show good agreement with experimental data

Comparative analysis highlights advantages of each model

Enhanced simulation accuracy for PV module durability

Abstract

The viscoelastic response of backsheet materials significantly affects the durability of the photovoltaic (PV) module. In this study, the viscoelastic response of commercially available backsheet materials is experimentally characterized and computationally modeled. An extensive viscoelastic experimental study on backsheet materials is carried out, considering the temperature-dependent properties for characterizing the mechanical properties. Based on an experimental campaign, small-strain viscoelastic models based on the Prony-series (PS) and Fractional Calculus (FC) Models are proposed here. The form of the constitutive equations for both models is summarized, and the finite element implementation is described in detail. Following identifications of relevant material parameters, we validate the model with the experimental data that shows good predictability. A comparative study of model responses under different loading conditions is also reported to assess the advantages and disadvantages of both models. Such an extensive experimental study and constitutive modeling will help design and simulate a more comprehensive modeling of PV modules, as illustrated by the benchmark problems.