Approaches to conditioning of vegetable oil feedstock for hydrotreating to produce renewable diesel

[Display omitted] •The hydrotreating process can be disrupted by impurities in vegetable oils.•Tailored pretreatment for vegetable oils ensures contaminant reduction.•Reduction of phospholipids is crucial for hydrotreating of vegetable oils.•The two-stage hydrotreating process softens deoxygenation...

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Bibliographic Details
Published in:Fuel (Guildford) 2025-03, Vol.383, p.133897, Article 133897
Main Authors: Pérez-Rangel, Nelly, Coronado, Christian, Ancheyta, Jorge
Format: Article
Language:English
Subjects:
Hydrotreating
Pretreatment
Renewable diesel
Vegetable oil
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Summary:[Display omitted] •The hydrotreating process can be disrupted by impurities in vegetable oils.•Tailored pretreatment for vegetable oils ensures contaminant reduction.•Reduction of phospholipids is crucial for hydrotreating of vegetable oils.•The two-stage hydrotreating process softens deoxygenation conditions. The hydrotreating (HDT) process is increasingly implemented due to its versatility in producing renewable diesel and its flexibility with various raw materials. Impurities in vegetable oils can disrupt the HDT process, necessitating a pretreatment stage to ensure optimal performance, catalyst and equipment preservation, and achieve high yields. While laboratory-scale studies often overlook pretreatment due to minimal impacts on production costs and the use of pre-refined oils, industrial processes are designed and tailored to optimize the purification step for efficiency and cost-effectiveness. This study discusses the effect of impurities such as phospholipids, metals, and free fatty acids (FFA) on HDT and outlines effective pretreatment methods. Removing impurities is critical as they can deactivate sulfur-based catalysts, promote coke formation, and initiate oligomerization. The introduction of dimethyl disulfide (DMDS) and co-processing with sulfur-containing petroleum fractions are examined for their effectiveness in mitigating catalyst deactivation. The two-stage HDT, or pre-HDT, which is emphasized for lowering coke formation and increasing hydrogen availability, is also covered. The study emphasizes the importance of tailored pretreatment strategies for different raw material, including used cooking oil (UCO), to enhance HDT efficiency and extend catalyst life.
ISSN:0016-2361
DOI:10.1016/j.fuel.2024.133897