References
- R. W. MOIR, R. L. BIERI and X. M. CHEN et al, “HYLIFE-II: A molten-salt inertial fusion energy power plant design - final report,” Fusion Technol., 25, 5, (1994).
- M. A. ABDOU, THE APEX TEAM and A. YING et. al., “On the Exploration of Innovative Concepts for Fusion Chamber Technology,” Fusion Eng Des, 54, 181 (2001).
- A. SAGARA, H. YAMANISHI and S. IMAGAWA et al, “Design and Development of the Flibe Blanket for Helical-Type Fusion Reactor FFHR,” Fusion Eng. Des., 49-50, 661, (2000).
- R. A. GARDNER and P. S. LYKOUDIS, Magneto-fluid-mechanic pipe flow in a transverse magnetic field Part 2. Heat transfer, J. Fluid Mech. 48, 129 (1971).
- H. C. JI and R. A. GARDNER, Numerical analysis of turbulent pipe flow in a transverse magnetic field, Int. J. Heat Mass Transfer, 40, No.8, 1839 (1997).
- E. Ya. BLUM, Effect of a magnetic field on heat transfer in the turbulent flow of conducting liquid, High Temperature, 5, 68 (1967).
- J. TAKEUCHI, S. SATAKE and N. B. MORLEY et al, “PIV Measurements of Turbulence Statistics and Near-Wall Structure of Fully Developed Pipe Flow at High Reynolds Number,” Proc. 6th International Symposium on Particle Image Velocimetry, Pasadena, CA, USA, Sept 21-23, (2005).
- J. TAKEUCHI, S. SATAKE and R. MIRAGHAIE et al, “Study of Heat Transfer Enhancement/Suppression for Molten Salt Flows in a Large Diameter Circular Pipe: Part One - Benchmarking,” Fusion Eng Design, 81, 601, (2006).
- J. G. M. EGGELS, F. UNGER and J. WEISS et al, “Fully Developed Turbulent Pipe Flow: A Comparison between Direct Numerical Simulation and Experiment,” J. Fluid Mech., 268, 175, (1994).
- S. SATAKE, T. KUNUGI and R. HIMENO, “High Reynolds Number Computation for Turbulent Heat Transfer in Pipe Flow,” In: M. VALERO et al, Ed., Lecture Notes in Computer Science 1940, Springer-Verlag, Berlin-Heidelberg, (2000).
- B. A. KADER, “Temperature and Concentration Profiles in Fully Turbulent Boundary Layers,” Int. J. Heat Mass Transfer, 24, No.9, 1541 (1981).