The helical steam generator is connected to an HTGR-type nuclear reactor called PeLUIt-40 for steam production. Steam is used to generate electricity and hydrogen. A once-through helical tube bundle was employed because of its ability to endure mechanical stress due to thermal expansion, high resistance to flow-induced vibrations, and better thermal performance compared to a straight tube one. To produce the targeted steam, a design analysis of the once-through helical steam generator needs to be conducted. A quick evaluation method was used to predict the preliminary specifications required for steam production. Simple thermodynamic calculations combined with empirical heat transfer coefficients covering convective and boiling processes at constant pressure were used to carry out the analysis. Two scenarios were conducted to evaluate the design choice based on the previous design of RDE-10.

1. T. Taryo, Rokhmadi, S. Bakhri, and G.R. Sunaryo, "The On-Going Progress of Indonesia's Experimental Power Reactor 10 MW and Its National Research Activities," Prosiding Seminar Nasional Teknologi Energi Nuklir (Makasar, Indonesia: SENTEN), p. 57–67, 2017.
2. F. Gou, F. Chen, and Y. Dong, " Dynamic Response of the HTR-10 Under the Control Rod Withdrawal Test Without Scram," Energy Procedia. 2017. 127:247–254.
3. Z. Zuoji, Y. Dong, F. Li, Z. Zhang, H. Wang, X. Huang, H. Li, B. Liu, X. Wu, H. Wang, X. Diao, H. Zhang, and J. Wang, " The Shandong Shidao Bay 200 MWe High-Temperature Gas-Cooled Reactor Pebble-Bed Module (HTR-PM) Demonstration Power Plant: An Engineering and Technological Innovation," Engineering. 2016. 2(1):112–118.
4. C. Fang, X. Bao, C. Yang, Y. Yang, and J. Cao, “The R&D of HTGR High Temperature Helium Sampling oop: From HTR-10 to HTR-PM,” Nuclear Engineering and Design. 2016. 306: 192 - 197.
5. S. Ding, C. Fubing, X. Bing, S. Lei, "Simulation of the HTR-10 Operation History With the PANGU Code," Frontiers in Energy Research. Vol. 9, Art. No. 704116, 2021. doi.org/ 10.3389/fenrg.2021.704116.
6. Y. Inaba, and T. Nishihara, "Development of fuel temperature calculation code for HTGRs," Annals of Nuclear Energy. 2017. 101:383–389.
7. Z. Zhang, P. Ye, X.T. Yang, H.M. Ju, S.Y. Jiang, J.Y. Tu, "Supercritical Steam Generator Design and Thermal Analysis Based on HTR-PM," Annals of Nuclear Energy. 2019. 132: 311-321.
8. W. Scheuermann, N. Haneklaus, and Fütterer M., editor(s), K. Kugeler, H. Nabielek, and D. Buckthorpe, "The High Temperature Gas-cooled Reactor: Safety considerations of the (V) HTR-Modul," EUR 28712 EN, Publications Office of the European Union, Luxembourg, 2017, ISBN 978-92-79-71311-8, doi:10.2760/270321, JRC107642.
9. J. Riznic, "Steam Generators for Nuclear Power Plants," Woodhead Publishing Series in Energy, p. 35 - 53, 2017.
10. J. Sun, R. Zhang, M. Wang, J. Zhang, S. Qiu, W. Tian, G.H. Su, "Multi-objective Optimization of Helical Coil Steam Generator in High Temperature Gas Reactors with Genetic Algorithm and Response Surface Method," Energy, Vol. 259, Art. No. 124976, 2022. doi.org/10.1016/j.energy.2022.124976.
11. M. Wang, J. Sun, J. Zhang, W. Tian, S. Qiu, and G. Su, "Thermal-hydraulic Characteristics Analysis Method of Helical Coil Steam Generator in High Temperature Gas Reactor," Atomic Energy Science and Technology. 2022. 56(11): 2262-2271.
12. B.W. Riyandwita, M. Awwaludin, Krismawan, P. Zacharias, E. Siswanto, P.H. Setiawan and A. Nugroho, "Analytical Design of Helical Coil Steam Generator for Hot Temperature Gas Reactor," Journal of Physics: Conference Series. , Vol. 1198, No. 4, 2019. dx.doi.org/ 10.1088/1742-6596/1198/4/042014.
13. M.A. Bergant, A.A. Yawny, J.E.P. Ipiña, " Structural Integrity Assessments of Steam Generator Tubes using the FAD Methodology," Nuclear Engineering and Design. 2015. 295: 457-467.