Dryout heat flux for core debris bed. (I) Effects of system pressure and particle size.:Effects of System Pressure and Particle Size
スポンサーリンク
概要
- 論文の詳細を見る
For gaining basic data on decay heat coolability of debris bed in the post-accident heat removal, measurement of dryout heat flux was made, with stagnant water as coolant, in a 50 mm I. D. pyrex glass cylinder vessel. The fuel debris bed subjected to decay heat was simulated by steel ball particles which were inductively heated with a power supply of 20 kHz and 30 kW. The bed was made of homogeneous size particles. An emphasis was placed on the influence of system pressure and particle size. The experiment covered the ranges over the steel ball diameters of 0.34.0 mm and the system pressure of 0.020.5 MPa.<BR>The experimental results, as a whole, agreed fairly well with the prediction based on Lipinski's 0-D model with respect to the dependence of dryout heat flux both on pressure and on particle size. In detail, however, the dryout heat flux deviates toward a lower value at a higher pressure while to a higher value for a smaller size particle bed. Comparison of the results between the free and fixed beds suggests that the deviation to the higher side will be attributed to the channeling and/or levitation.
- 一般社団法人 日本原子力学会の論文
著者
-
Yamaoka Nobuo
Department Of Nuclear Engineering Graduate School Of Engineering Osaka University
-
Miyazaki Keiji
Department Of Nuclear Engineering Graduate School Of Engineering Osaka University
-
INOUE Shoji
Department of Electric, Information and Energy Engineering, Graduate school of Engineering, Osaka Un
-
OHAMA Toshihiro
Department of Nuclear Engineering, Faculty of Engineering, Osaka University
-
OHAMA Toshihiro
Department of Nuclear Engineering, Faculty of Engineering,Osaka University
-
MURAI Kenji
Department of Nuclear Engineering, Faculty of Engineering,Osaka University
-
YAMAOKA Nobuo
Department of Nuclear Engineering, Faculty of Engineering,Osaka University
-
MURAI Kenji
Department of Nuclear Engineering, Faculty of Engineering, Osaka University
関連論文
- Forced Convection Heat Transfer and Temperature Fluctuations of Lithium under Transverse Magnetic Fields
- Magnetically Guided Free Surface Annular Nak Flow Experiment
- Thinning Improves Surface-Soil Physical Properties of Coniferous Forest Plantations
- Magnetically Guided Free Surface Annular Nak Flow Experiment
- Heat transfer and temperature fluctuation of lithium flowing under transverse magnetic field.
- Temperature fluctuation of sodium in annular flow channel heated by single-pin with blockage.
- Dryout heat flux for core debris bed. III Mixture of intact fuel and particulated clad.:Mixture of Intact Fuel and Particulated Clad
- Film boiling characteristics of potassium droplets on heated plate.
- Thermal interaction of water droplet with molten tin.
- Natural convection heat transfer of liquid lithium under transverse and parallel magnetic fields.
- Cavitation in cylindrical liquid metal shell imploded for axial magnetic flux compression.
- Dryout heat flux for core debris bed. (I) Effects of system pressure and particle size.:Effects of System Pressure and Particle Size
- Pressure Transient and Bubble Growth in Incipient Boiling of Superheated Potassium
- Experimental Studies on Characteristics of Pressure Attenuation and Recovery to Saturation for Decompressive Disturbances in Low Pressurized Water
- Influence of Void and Velocity Variations on Two-Phase Liquid Metal MHD Induction Converter Characteristics
- Influence of Void and Flow Regime on Liquid Metal MHD Induction Generator Using Two-Phase Flow
- Incipient boiling of sodium in an annular channel heated by a single-pin with blockage.
- Dryout heat flux for core debris bed. (II) Effects of particle size mixing and coolant flow.:Effects of Particle Size Mixing and Coolant Flow
- Intensity and Propagation Velocity of Compression Shock Pulses in Low Pressure Steam-Water Medium
- Analysis of Two-Phase Liquid Metal MHD Induction Converter
- Redistribution of gaseous phase of liquid metal two-phase flow in a strong magnetic field.