Turbulence, Coherent Structures, Dynamical Systems and SymmetryP. Holmes, J. L. Lumley, G. Berkooz, and C. W. Rowley, 2nd ed., Cambridge University Press, Cambridge, England, U.K., 2012, 386 pp., $90

https://bura.brunel.ac.uk/bitstream/2438/14401/3/FullText.pdf

Heat pipe based systems - Advances and applications

Experimental investigation of the effect of graphene nanofluids on heat pipe thermal performance

Heat transfer mechanisms in heat pipes using nanofluids-A review

The main purpose of this research was to investigate the efficiency of artificial neural networks in modeling thermal conductivity data of water–EG (40–60 %) nanofluid with aluminum oxide nanoparticles (with average diameter of 36 nm). The measured data as modeling input data are in six volume fractions from 0 to 1.5 % and different temperatures from 20 to 60 °C. In order to optimize the network, different numbers of neurons with different transfer functions have been tested and after preprocessing and normalizing the data, the optimum network structure with one hidden layer and six neurons was obtained. This structure simulated the experimental data with very high precision. The measured thermal conductivity was compared with the two models that calculated thermal conductivity for mixtures. The results indicated that Hamilton–Crosser and Lu–Lin models failed in estimating the thermal conductivity of Alumina–water–EG nanofluid in different temperatures and concentration. Finally, a new correlation was presented based on experimental data with regression coefficient of 0.9974.

Designing artificial neural network on thermal conductivity of Al2O3–water–EG (60–40 %) nanofluid using experimental data

Comparison of thermal performances of water-filled, SiC nanofluid-filled and SiC nanoparticles-coated heat pipes

Hybrid heat pipe based passive in-core cooling system for advanced nuclear power plant

Flow visualization and heat transfer performance of annular thermosyphon heat pipe

Hybrid heat pipe based passive cooling device for spent nuclear fuel dry storage cask

Dynamic mode decomposition for the stability analysis of the Molten Salt Fast Reactor core

Yeong Shin Jeong

Papers

Comparison of thermal performances of water-filled, SiC nanofluid-filled and SiC nanoparticles-coated heat pipes

Hybrid heat pipe based passive in-core cooling system for advanced nuclear power plant

Flow visualization and heat transfer performance of annular thermosyphon heat pipe

Hybrid heat pipe based passive cooling device for spent nuclear fuel dry storage cask

Dynamic mode decomposition for the stability analysis of the Molten Salt Fast Reactor core