Passive safety systems have garnered significant attention, particularly in situations where active systems fail. The comprehension of natural circulation phenomena plays a vital role in the advancement of passive cooling systems in nuclear power plants. The objective of this study is to examine the flow patterns under steady state conditions and assess the Grashof number. The experimental approach involved maintaining temperature differences of 60°C, 70°C, 80°C, and 90°C for a duration of 3 hours, with 3 replications. Alterations in temperature have an impact on the physical properties of water, such as density, viscosity, and specific heat. The calculations indicate that the minimum Grashof number occurs at 60°C (2.49×10¹²), while the maximum is observed at 90°C (9.42×10¹²), with an R² value of 0.96533. Turbulent flow patterns were observed during each temperature fluctuation, which aligns with previous research on the Re_ss value of Gr_m/N_G.

1. Jabbari M., Hadad K., Pirouzmand A. Re-assessment of Station Blackout Accident in VVER-1000 NPP with Additional Measures Following Fukushima Accident Using Relap/Mod3.2. Annals of Nuclear Energy. 2019. 129:316–30.

2. Anhar Riza Antariksawan, Mulya Juarsa Nuclear Reactor Safety: Basic Design Accidents and Severe Accidents (in Indonesian Language). First ed. Jakarta: BRIN; 2023.
3. J. Ahn, C. Carson, M. Jensen, K. Shinya, and N. Satoru, Reflections on the Fukushima Daiichi Nuclear Accident Toward Social-Scientific Literacy and Engineering Resilience, 2015.
4. Juarsa M., Antariksawan A.R., Kusuma M.H., Haryanto D., Putra N. Estimation of Natural Circulation Flow Based on Temperature in The FASSIP-02 Large-Scale Test Loop Facility. IOP Conference Series: Earth and Environmental Science. 2018. 105(1)
5. Lesmana R.S., Juarsa M., Waskita A.A. Numerical Analysis Model on SinglePhase Natural Circulation in Fassip-01 Mod.1 Rectangular Loop Based on Heater Position (in Indonesian Language). Sigma Epsilon. 2019. 23(2):70–8.
6. Juarsa M., Purba J.H., Kusuma H.M., Setiadipura T., Widodo S. Preliminary Study on Mass Flow Rate in Passive Cooling Experimental Simulation During Transient Using NC-Queen Apparatus. Atom Indonesia. 2014. 40(3):141–7.
7. 7. Tjahjono H. Comprehensive Prediction of Thermosyphon Characteristics in Reactor Passive Cooling System Simulation Loop FASSIP-01. Atom Indonesia. 2017. 43(3):157–66.
8. Andrea S.A.A. Analysis of Changes in Thermal Energy Based on Water Temperature Variations in the Heating Tank of FASSIP-02 Test Loop (in Indonesian Language).Universitas Andalas; 2022.
9. Haryanto D., Budiman A.A., Putra M.G., Setiawan P.H., Juarsa M. Investigation of Heat Exchanger Performance in The Heating Tank Section of Loop FASSIP 03 NT. Jurnal Teknologi. 2024. 16(1):41.
10. Yuliaji D., Waluyo R., Pramono G.E., Setiawan P.H., Juarsa M. The Commissioning Test Facility of Passive Simulation System 04 Version 2 (FASSIP 04 VER.2) for Passive Cooling Capability Study on Nuclear Reactor Safety System (in Indonesian Language). Jurnal Ilmiah Teknik Mesin. 2023. 9(1):57–63.
11. 11. Adrian H., Roswandi I., Gunawan H.A., Sukarno R., Syaka D.R.B., Juarsa M. Estimated Calculation of Natural Circulation Flow Rate in the of Fassip-05 Pressurized Test Loop (In Indonesian Language). Jurnal Ilmiah Teknik Mesin. 2023. 9(2):86–92.
12. Roswandi I., Gunawan H.A., Budiman A.A., Adrian H., Sanda, Juarsa M. Reliability Investigation of Heater and Cooler of Passive System Simulation Facility-05 (FASSIP-05) Based on Initial Commissioning Phase (in Indonesian Language). Jurnal Teknik Mesin Indonesia. 2023. 18(2):15–20.
13. Basu D. N., Bhattacharyya S., and Das P. K , "A review of modern advances in analyses and applications of single-phase natural circulation loop in nuclear thermal hydraulics," Nuclear Engineering and Design, 2014.
14. ToolBox T.E. Volumetric (Cubic) Thermal Expansion [Accessed: 30 April 2024]. Available from: https://www.engineeringtoolbox.com/volumetric-temperature-expansion-d_315.html.
15. F.A. Sánchez-Cruz, D. de la Rosa-Urbalejo, H.G. Ramírez-Hernández, L.F. Rua-Mojica, H.D. García-Lara, and S. Martínez-Martínez, "Heat transfer study of natural circulation serpentine-shaped loops," Applied Thermal Engineering, vol. 236, pp. 121485, 2024.
16. Vijayan P.K. Experimental Observations on The General Trends of The Steady State and Stability Behaviour of Single-Phase Natural Circulation Loops. Nuclear Engineering and Design. 2015. 215(1–2):139–52.
17. Siddiqui O. K, Shuja S. Z, and Zubair S. M., "Assessment of thermo-fluid analogies for different flow configurations: the effect of Prandtl number, and laminar-to-turbulent flow regimes," International Journal of Thermal Sciences, vol. 129, pp. 145–170, 2018.
18. Srivastava A.K., Saikrishna N., Maheshwari N.K. Steady State Performance of Molten Salt Natural Circulation Loop With Different Orientations of Heater and Cooler. Applied Thermal Engineering. 2023. 218(September 2022):119318.
19. Kumar N., Doshi J.B., Vijayan P.K. Investigations on The Role of Mixed Convection and Wall Friction Factor in Single-Phase Natural Circulation Loop Dynamics. Annals of Nuclear Energy. 2014. 38(10):2247–70.
20. Hariyanto D., Permana S., Waris A., Mustari A.P.A., Kinoshita M., Aji I.K., et al. Irregular Pentagon Loop for Nuclear Reactor Natural Circulation System Test Apparatus. Nuclear Engineering and Design. 2024. 416(November 2023):112753.
21. Naveen K., Iyer K.N., Doshi J.B., Vijayan P.K. Investigations on Single-Phase Natural Circulation Loop Dynamics. Part 2: Role of Wall Constitutive Laws. Progress in Nuclear Energy. 2014. 75:105–16.