eprintid: 20097 rev_number: 2 eprint_status: archive userid: 1 dir: disk0/00/02/00/97 datestamp: 2024-06-04 14:19:50 lastmod: 2024-06-04 14:19:50 status_changed: 2024-06-04 14:16:35 type: article metadata_visibility: show creators_name: Bin Abdullah, A.Z.A. creators_name: Muhammad, M.D. creators_name: Gilani, S.I.U.-H. creators_name: Ali, M. creators_name: Al-Kayiem, H.H. title: Thermal Analysis of Evacuated Tube Receiver for Solar Power Tower by Transient Simulation ispublished: pub keywords: Computer software; Flow rate; Free energy; Quality control; Reaction rates; Solar heating; Solar thermal energy; Steam generators; Thermoanalysis, Direct steam generation; Evacuated tube receiver; Evacuated tubes; Fluid flow rates; Heat transfer fluids; Heliostat; Power towers; Solar power tower; Steam quality; Thermolib, Steam note: cited By 0; Conference of International Conference on Renewable Energy and E-mobility, ICREEM 2022 ; Conference Date: 1 December 2022 Through 2 December 2022; Conference Code:309409 abstract: Solar thermal power is a promising and rapidly expanding source of carbon-free energy. Analysis and design techniques for solar thermal power generation for the Solar Power Tower (SPT) systems are currently mathematically difficult. We simulated a model of a SPT that advances the simulation of SPT performance by modelling them in Thermolib software. The model in this study simulates SPT with a direct steam generation system with design variables of 0.04 kg/s heat transfer fluid (HTF) flow rate at 6 bar operating pressure using water as HTF. The reaction to varied operating pressure, fluid flow rates, and insolation input has been analysed. The simulation results show that steam will be produced at 1â��3 bar with maximum steam quality of 0.06, 0.02 and 0.0015, respectively. Lowering the HTF flow rates to 0.02 and 0.03 kg/s will produce steam with maximum quality of 0.15 and 0.028, respectively. Increasing the amount of heliostat from 15 to 20 in staggered formation results in a 14.5 increase in power received by the receiver, resulting in a maximum steam quality produced of 0.029. The analysis shows that high quality of steam can be achieved with a lower HTF flow rate and pressure, but it compromises the useful energy generated by turbine. © Institute of Technology PETRONAS Sdn Bhd (Universiti Teknologi PETRONAS) 2024. date: 2024 publisher: Springer Science and Business Media Deutschland GmbH official_url: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85188754408&doi=10.1007%2f978-981-99-5946-4_13&partnerID=40&md5=cba03b3fdc337b43b0e2d21d8a26d87a id_number: 10.1007/978-981-99-5946-4₁₃ full_text_status: none publication: Lecture Notes in Mechanical Engineering pagerange: 147-160 refereed: TRUE isbn: 9789819959457 issn: 21954356 citation: Bin Abdullah, A.Z.A. and Muhammad, M.D. and Gilani, S.I.U.-H. and Ali, M. and Al-Kayiem, H.H. (2024) Thermal Analysis of Evacuated Tube Receiver for Solar Power Tower by Transient Simulation. Lecture Notes in Mechanical Engineering. pp. 147-160. ISSN 21954356