Advancing Indonesia’s Energy Transition: Coal-to-Nuclear (C2N) Simulation Study

Advancing Indonesia’s Energy Transition: Coal-to-Nuclear (C2N) Simulation Study

Indonesia’s ambitious net-zero emissions (NZE) target for 2060 necessitates a transformative shift from coal-dependent power systems to nuclear energy sources. Although previous studies have explored various aspects of energy transitions, limited attention has focused on the possibility of replacing...

Full description

Saved in:
Bibliographic Details
Main Authors: Irfan Eko Budiyanto, Sinta Uri El Hakim
Format: Article
Language:English
Published: Universitas Gadjah Mada 2025-05-01
Series:Jurnal Nasional Teknik Elektro dan Teknologi Informasi
Subjects:
nuclear energy transition
power plant simulation
coal-to-nuclear conversion
coal-fired boilers
nuclear reactors
Online Access:https://jurnal.ugm.ac.id/v3/JNTETI/article/view/17426
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Indonesia’s ambitious net-zero emissions (NZE) target for 2060 necessitates a transformative shift from coal-dependent power systems to nuclear energy sources. Although previous studies have explored various aspects of energy transitions, limited attention has focused on the possibility of replacing existing coal-fired boilers with nuclear reactors while maintaining the input and output parameters of the current infrastructure. This paper presents an approach to facilitating Indonesia’s nuclear energy transition by a coal-to-nuclear (C2N) simulation study. Specifically, the focus is on the 400 MW coal-fired power plant (CFPP), which relies on coal combustion. This study was designed to model the conversion process of the coal combustion system to a modular nuclear reactor setup while preserving the existing steam turbine and generator infrastructure. The foundation of this study was that the replacement of the nuclear reactor-based heat source must meet the requirements of the pre-existing water and steam cycle design. Various configurations for substituting the current boiler with a nuclear reactor were analyzed in this study, by considering engineering, operational, and modeling aspects. Results from model simulations for nine different operating conditions showed a deviation of the main-steam temperature of about 3% of the design value, starting at 120 MWe and above. Nevertheless, all other parameters of the conversion simulation results demonstrated a very small deviation. The deviation was close to the actual existing operational conditions of the previous CFPP. This paper highlights how the simulation demonstrated a promising integration of legacy infrastructure with emerging nuclear technology.
ISSN:2301-4156
2460-5719

Similar Items