کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
---|---|---|---|---|
646531 | 1457158 | 2014 | 10 صفحه PDF | دانلود رایگان |
• A numerical investigation is presented using computational fluid dynamics (CFD), of melting with internal heat generation for a vertical cylindrical geometry.
• An experiment was performed to produce such data using resistive, or Joule, heating as the internal heat generation mechanism.
• The numerical results are compared against the experimental results and showed favorable correlation.
• Uncertainties in the numerical and experimental analysis are discussed.
• Based on the numerical and experimental analysis, recommendations are made for future work.
There have been significant efforts by the heat transfer community to investigate the melting phenomenon of materials. These efforts have included the analytical development of equations to represent melting, numerical development of computer codes to assist in modeling the phenomena, and collection of experimental data. The understanding of the melting phenomenon has application in several areas of interest, for example, the melting of a Phase Change Material (PCM) used as a thermal storage medium as well as the melting of the fuel bundle in a nuclear power plant during an accident scenario. The objective of this research is two-fold. First a numerical investigation, using computational fluid dynamics (CFD), of melting with internal heat generation for a vertical cylindrical geometry is presented. Second, to the best of authors knowledge, there are very limited number of engineering experimental results available for the case of melting with Internal Heat Generation (IHG). An experiment was performed to produce such data using resistive, or Joule, heating as the IHG mechanism. The numerical results are compared against the experimental results and showed favorable correlation. Uncertainties in the numerical and experimental analysis are discussed. Based on the numerical and experimental analysis, recommendations are made for future work.
Journal: Applied Thermal Engineering - Volume 67, Issues 1–2, June 2014, Pages 587–596