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The human factor in licensing and operating the next generation of nuclear plants
As human factors specialists working at the intersection of human performance and nuclear operations, we are witnessing one of the nuclear sector’s most significant transitions in decades. The emergence of small modular reactors, microreactors, and other advanced designs is reshaping the industry’s landscape. Digital instrumentation and controls, passive safety systems, and increased automation are creating opportunities for greater safety margins and more flexible operation. These same features also fundamentally redefine what it means to “operate” a nuclear plant. Interactions among human roles, automation, and passive systems shape how people maintain awareness, exercise judgment, and intervene when necessary. These developments affect both operational realities and the regulatory foundations on which nuclear safety is built.
Eung Soo Kim, Chang Ho Oh, Hee Cheon No
Nuclear Technology | Volume 164 | Number 2 | November 2008 | Pages 278-285
Technical Paper | Materials for Nuclear Systems | doi.org/10.13182/NT08-A4026
Articles are hosted by Taylor and Francis Online.
A number of experiments were carried out to investigate the effect of moisture - which is always present in environmental air - on the graphite oxidation rate. A porous metal with 10-m pores was used to enhance the humidification at the outlet of the vertical column that is full of water and is designed to increase the moisture on the helium gas when it is passed through the porous media located at the bottom of the water column. The relative humidity (RH) of the mixture was controlled between 0 and 70% by a humidity sensor. The experiment was performed at temperatures ranging from 873 to 1573 K, mole fractions of oxygen from 0.09 to 0.17, and RH from 0 to 70% at the normal condition.Assuming that the effect of moisture affects only the mass transfer, we derived a theoretical model for mass transfer that included the fast homogeneous CO combustion reaction. The present model shows that the mass transfer rate of humid air is half of the mass transfer rate for dry air. The predictions by the model agree with experimental data within 17%.