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On the evaluation of non-Fourier effects in heat pulse experiments

Anna Fehér, Róbert Kovács

2021International Journal of Engineering Science41 citationsDOIOpen Access PDF

Abstract

The heat pulse (flash) experiment is a well-known and widely accepted method to measure the thermal diffusivity of a material. In recent years, it has been observed that the thermal behavior of heterogeneous materials can show deviation from the classical Fourier equation, resulting in a different thermal diffusivity and requiring further thermal parameters to identify. Such heterogeneity can be inclusions in metal foams, layered structure in composites, or even cracks and porous parts in rocks. Furthermore, the next candidate, the Guyer–Krumhansl equation is tested on these experiments with success. However, these recent evaluations required a computationally intensive fitting procedure using countless numerical solutions, even when a good initial guess for the parameters is found by hand. This paper presents a Galerkin-type discretization for the Guyer–Krumhansl equation, which helped us find a reasonably simple analytical solution for time-dependent boundary conditions. Utilizing this analytical solution, we developed a new evaluation technique to immediately estimate all the necessary thermal parameters using the measured temperature history.

Topics & Concepts

Thermal diffusivityLaser flash analysisDiscretizationFourier transformThermalMaterials scienceHeat equationGalerkin methodBoundary value problemMechanicsPorosityPulse (music)Measure (data warehouse)Mathematical analysisComputer scienceThermodynamicsMathematicsPhysicsOpticsComposite materialFinite element methodDetectorDatabaseThermoelastic and Magnetoelastic PhenomenaThermal properties of materialsThermography and Photoacoustic Techniques
On the evaluation of non-Fourier effects in heat pulse experiments | Litcius