Experiments based analysis of thermal decomposition kinetics model. Case of carbon fibers PolyPhenylene Sulfide composites

Considering their increasing use in high-temperature aeronautical applications, thermoplastic-based laminates have to meet certification requirements in terms of critical service conditions (e.g. aircraft engine's fire). This work is aimed at identifying the most relevant approach to model the isothermal decomposition of C/PPS composites. The first step in the understanding of the thermal decomposition of these materials relies on TGA and MT-TGA tests. They can be conducted in isothermal and anisothermal conditions to characterize the thermal decomposition kinetics taking place in a fire scenario. The experimental database obtained from these tests is of major importance to identify input parameters of pyrolysis kinetics models. The predictive capabilities of three different approaches (model-fitting, isoconversional/model-fitting and model-free) is discussed based on statistical analyses (Fisher's test). For C/PPS laminated composites, these approaches are virtually statistically equivalent. Model-fitting methods result in relatively accurate predictions of the TGA curves at a given heating rate. However, this type of approaches is not fully satisfactory especially when it is used to predict the thermal decomposition of polymer-matrix composites under anisothermal conditions. Finally, the model-free approach is identified as the most relevant from a physical point of view to account for the thermal decomposition of C/PPS composites under isothermal conditions. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This study aimed to identify the most relevant approach to model the isothermal decomposition of C/PPS composites, with experimental databases obtained from TGA and MT-TGA tests. Three different modeling approaches were discussed, with model-fitting methods providing relatively accurate predictions of TGA curves. The model-free approach was identified as the most physically relevant method for capturing the thermal decomposition of C/PPS composites under isothermal conditions.