Accurate empirical formulas for the evaluation of origin intensity factor in singular boundary method using time-dependent diffusion fundamental solution

•The empirical formulas of the origin intensity factor in singular boundary method are presented.•The time-dependent diffusion fundamental solution is employed.•The proposed SBM more fast, straightforward, and efficient. This paper presents the simple empirical formulas for the accurate evaluation o...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2016-12, Vol.103, p.360-369
Main Authors: Wang, Fajie, Chen, Wen
Format: Article
Language:English
Subjects:
Empirical formulas
Origin intensity factor
Singular boundary method
Time-dependent fundamental solutions
Transient diffusion problems
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Summary:•The empirical formulas of the origin intensity factor in singular boundary method are presented.•The time-dependent diffusion fundamental solution is employed.•The proposed SBM more fast, straightforward, and efficient. This paper presents the simple empirical formulas for the accurate evaluation of the origin intensity factor in singular boundary method (SBM) when the time-dependent diffusion fundamental solution is employed. These new formulas makes the SBM more fast, straightforward, and efficient for transient diffusion problems while being truly meshless, integration-free and easy-to-implement. Three benchmark examples are tested to demonstrate the accuracy and efficiency of the proposed scheme. It is shown that the SBM using these empirical formulas works well especially for one and two-dimensional transient diffusion problems. In the three-dimensional case, we have obtained the SBM empirical formula of the origin intensity factors at initial time, and numerical experiments on benchmark problems have verified its efficiency and accuracy. It is worth noting that we need to two different formulas for a specific dimensionality. However, the empirical formula with time variation in three-dimensional case is not available and still under investigation.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2016.07.035