TY - JOUR VL - 355 UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85175562772&doi=10.1016%2fj.fuel.2023.129456&partnerID=40&md5=33cf8d8a54133e06700a98ed77ed8a3d ID - scholars20274 N2 - Trickle bed reactors (TBRs) are commonly used in various chemical and associated processes. The selection of a proper back pressure regulator (BPR) is crucial for maintaining the system's upstream pressure. In this study, we investigate the impact of BPR selection on deoxygenation reaction in a TBR with two typical types of BPR, including gas-phase type back pressure regulator (Gas-BPR) and multiphase type back pressure regulator (Multi-BPR). Notably, Gas-BPR introduces interruptions and pressure drops during the sampling step, impacting the hydrogen flow rate, while Multi-BPR ensures more consistent hydrogen flow. To examine the performance of BPR systems, hydrotreating experiments were conducted at 330 °C, 50 bar of hydrogen over Ni/γ-Al2O3 catalyst using crude Pongamia pinnata oil as a feedstock and refined palm olein as a benchmark. Insignificant difference in the reaction performance between Multi-BPR and Gas-BPR systems was observed when using refined palm olein. Interestingly, there was a significant difference between the two systems when feeding with crude Pongamia pinnata oil. The multi-BPR system demonstrated superior performance, achieving 100 conversion of the feedstock over a prolonged period compared to the interrupted hydrogen flow in the Gas-BPR system. Further characterization of fresh and spent catalysts using N2 sorption, XRD, SEM-EDS and TGA-DTG-DSC techniques revealed that a gum and coke formation was a reason for the rapid catalyst deactivation. Furthermore, the interrupted flow in the Gas-BPR system led to substantial gum production, ultimately causing a blockage in the reactor bed. Consequently, for feedstocks with high impurities, a robust continuous flow of hydrogen is essential. Thus, the study strongly recommends selecting Multi-BPR for continuous operation in TBRs to enhance efficiency and avoid catalyst deactivation. © 2023 Elsevier Ltd TI - Biofuel upgrading via catalytic deoxygenation in trickle bed reactor: Crucial issue in selection of pressure regulator type Y1 - 2024/// AV - none N1 - cited By 0 A1 - Pongsiriyakul, K. A1 - Kiatkittipong, W. A1 - Lim, J.W. A1 - Najdanovic-Visak, V. A1 - Wongsakulphasatch, S. A1 - Kiatkittipong, K. A1 - Srifa, A. A1 - Eiad-ua, A. A1 - Boonyasuwat, S. A1 - Assabumrungrat, S. JF - Fuel KW - Benchmarking; Chemical reactors; Diesel engines; Feedstocks; Gases; Nickel; Palm oil KW - Back pressure regulators; Bio-hydrogenated diesel; Catalysts deactivation; Gas-phases; Multiphases; Nickel catalyst; Reactor configuration; Regulator systems; Renewable energies; Tricklebed reactors KW - Catalyst deactivation ER -