The predictions of composite materials responses in fire environments are important in terms of safety. This reality problem can be simplified as a thermal fluidstructure interaction problem in terms of mathematical modelling. The thermofluid model is used to simplify the physical properties of fire. The classical continuum mechanics has difficulty in predicting crack propagations because of the singularities of differential equations at discontinuities. Therefore, the peridynamic theory which uses the integral governing equations is a good choice to predict the damage in composite materials. It will bring convenience to simulate the composite response in fire environments using a monolithic methodology. Consequently, in the current study, both thermofluid modelling for fire and thermomechanical damage modelling in composites are simulated by using peridynamic theory. Therefore, the following models are developed step by step to achieve the final target.;Firstly, a fully coupled thermomechanical ordinary statebased peridynamic model is developed for isotropic materials. Both the deformation effect on the temperature field and the temperature effect on deformation are taken into consideration. Then the fully coupled ordinary statebased peridynamic model for isotropic materials is extended to laminated composites. Besides, a bondbased peridynamic laminate model was applied to predict the responses of a 13ply composite under a pressure shock loading. Secondly, regarding the fluid model to represent fire, a peridynamic model is developed for Newtonian singlephase fluid low Reynold's number laminar flow. The high temperature should also be considered which is one of the typical properties of fire. Therefore, the heat transfer is incorporated into the fluid model to represent the thermal properties of fire. Based on the singlephase fluid peridynamic model, peridynamic model for multiphase fluid flows is also developed.;The NavierStokes equations including the surface tension forces are reformulated into their integral forms. Thirdly, by combining the developed singlephase fluid peridynamic model and the ordinary statebased peridynamic solid model, a fluidstructure interaction model is developed for the simulation of weakly compressible viscous fluid and elastic structure interactions. Subsequently, the heat transfer is incorporated into the fluidstructure interaction model to predict the composite response under a fire scenario. The ISO temperaturetime curve is utilized to present the high temperature which is induced by fire. The thermal degradation properties of the composite materials are also included in the numerical peridynamic composite model. Finally, the composite response underfire scenario is predicted.
Date of Award  28 Jul 2020 

Original language  English 

Awarding Institution   University Of Strathclyde


Sponsors  University of Strathclyde 

Supervisor  Selda Oterkus (Supervisor) & Erkan Oterkus (Supervisor) 
