HELIUM GAS-COOLED FAST REACTOR DESIGN STUDY USING URANIUM CARBIDE â THORIUM CARBIDE MIXTURE FUEL WITH AXIAL MODIFIED CANDLE SCHEME
As we know, human need of energy increase time to time. In order to fulfill human necessity of energy, in unison with the urge to provide long term clean energy for earth sustainability, building Nuclear Power Plant (NPP) seems to be the right answer. In the effort to support non-proliferation tr...
Saved in:
| Main Author: | |
|---|---|
| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/41939 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | As we know, human need of energy increase time to time. In order to fulfill human
necessity of energy, in unison with the urge to provide long term clean energy for
earth sustainability, building Nuclear Power Plant (NPP) seems to be the right
answer. In the effort to support non-proliferation treaty, scientist had been
developing fast reactor burning scheme design CANDLE (Sekimoto, 2010) which
uses natural Uranium as its fuel. The Modified CANDLE (MCANDLE) as the
modification of the previous CANDLE scheme has become the object of this research.
Modified CANDLE divide the burning core into several discreet regions. This
research uses Natural Uranium-Carbide and Natural Thorium-Carbide as fuel and
Helium gas as coolant which was applied to an axial MCANDLE scheme reactor.
The core size has been varied to optimize the design. Neutronic analysis has been
applied to this research with burn up level, effective multiplication factor (k eff),
infinite multiplication factor (k inf), and conversion ratio (CR) as observed
parameter. Uranium percentage in fuel has been varied to reduce undesired power
peaking. Neutronic calculation has been calculated using SRAC while the core design
was calculated using FI-ITB-CH1 program. Combination of Uranium Carbide and
Uranium Carbide – Thorium Carbide mixture fuel has reduced the power peaking
factor of the reactor. Optimization has been reached as the radial length of the
reactor set to 180cm and the axial length to 303cm.
|
|---|