The primary objective of control rod management is to ensure the safe, reliable and
optimum use of the nuclear fuel in the reactor, while remain within the limits imposed
by the design of the fuel assembly and reactor w.r.t the safety analysis. In numerous
reactors, the control rods perform the function of reactivity control, both globally and
locally, latter also control the power distribution of the core. Most control rods are
completely withdrawn from the core during operations and fully inserted during
shutdown of the reactor. This are the prove of an investigative study into optimization
of the heterogeneous control rods, the safety management of an additional safety rod,
and control rod drop hydrodynamic analysis which will be able to provide an efficient
and maximum safety procedure for emergency shut down system in the reactor. It is
also will be very important safety features of the reactor. To design the additional
safety rod at the inner irradiation sites with boron carbide (absorber material) and
stainless steel (clad) and also to design a simple heterogeneous control rod design to
analyse the effects of geometry self-shielding, the Monte Carlo Neutron Particle Code,
version 5 (MCNP5) was used. By simulating the unsteady flow field around the control
rod, the hydrodynamic analysis of the control rod can be analysed. A correlation based
on the achieved data was proposed to provide useful information on the safety
management during the research.
Muhammad Adil Khattak, Muhammad Zulhelmi Mahadi, Nurlaila Syamsul Bahri, Hor, Yen Tiu, Khairulnadzmi Jamaluddin, Muhammad Faiz Farhan Noorizhab, et al.
The objective of this review paper is to summarize the current state of understanding
on a topic ‘Nuclear spent fuel storage and facilities’. This review paper surveys and
summarizes previously published studies, rather than reporting new facts or analysis.
It is importance to case study this issue since the number of spent fuel are increasing
in which a typical nuclear power plant in a year generates almost 20 metric tons of
used nuclear fuel. In which the nuclear industry generates a total of about 2,000 - 2,300
metric tons of used fuel per year and for the last 40 years produced 76,430 metric tons
of nuclear spent fuel. Future understanding and attention need to be accomplished
since spent fuel can cause harm due to its high radioactive level and also the ability to
reprocess the fuel to be used as MOX fuel.