FULL CORE MODELLING OPTIMIZATION OF PB-BI COOLED CANDLE REACTOR FOR STARTUP AND EQUILIBRIUM STATE USING PARALLEL COMPUTATION MCNP6 CODE
The CANDLE Reactor (Constant Axial Shape of Neutron Flux, Nuclide Densities, and Power Profile during the Life of Energy Production) is a Generation IV reactor with a unique fuel-burning pattern resembling a candle that burns from the top down or vice versa. This reactor can operate using natural...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/87087 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The CANDLE Reactor (Constant Axial Shape of Neutron Flux, Nuclide Densities,
and Power Profile during the Life of Energy Production) is a Generation IV reactor
with a unique fuel-burning pattern resembling a candle that burns from the top
down or vice versa. This reactor can operate using natural uranium during the
equilibrium state. At startup, the fuel composition is assumed to be based on the
spent fuel from an APWR reactor. The objective of this research is to determine the
initial fuel composition at startup to ensure the reactor remains critical until it
reaches the equilibrium state, analyze various neutronic characteristics, and
evaluate the effects of thermal power variation and core size on neutronic
calculations. The reactor design was then optimized to achieve a lower excess
reactivity compared to the initial design. Neutronic calculations were conducted
using the Monte Carlo method with MCNP6, referencing the Evaluated Nuclear
Data File (ENDF/B-VII.1). Preliminary results show that for core designs with
thermal power variations from 400 MWth to 800 MWth, criticality can be
maintained for 80 years of burnup . Burning wave velocity can be calculated from
the shifting of power peak position for several thermal power core designs. After
optimization, a minimum of 4 assembly layers with around 240 fuel pins per
assembly was achieved. The optimized design resulted in reactivity below 2%.
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