Partial upgrading of bitumen with supercritical water— liquid products characteristics, gas composition and coke morphology

IF 3.4 3区工程技术 Q2 CHEMISTRY, PHYSICAL

Journal of Supercritical Fluids Pub Date : 2024-05-27 DOI:10.1016/j.supflu.2024.106319

Hadi Bagherzadeh, Devjyoti Nath, Mabkhot Bin Dahbag, Hassan Hassanzadeh

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Abstract

The study aimed to investigate the partial upgrading of bitumen in the absence of water (non-water) and the presence of supercritical water (SCW). Partial upgrading experiments were conducted at the target temperature of 420 °C, with the reaction time varying from zero to 60 min in a batch reactor. The liquid products were analyzed for density, viscosity, composition, total acid number (TAN), olefin content, and elemental analysis. The gas composition and morphology of solid products were also studied. The experimental results revealed that while partial upgrading of bitumen with SCW could accelerate improvement in oil quality, particularly in terms of API and viscosity, it concurrently led to elevated gas and coke formation levels. Moreover, the difference in the distribution of oil fractions between the two environments (absence and presence of SCW) tends to diminish with an extended residence time. Additionally, as the residence time increases, the efficiency of TAN reduction under SCW conditions is less pronounced compared to the non-water conditions. Liquid products obtained in an SCW environment exhibited higher olefin content (between 3 and 4 wt %) compared to non-water conditions (between 1.8 and 2.7 wt %). In both environments, the olefin content was initially increased up to a residence time of 20 min and then decreased. Regarding heteroatoms, the sulphur (S) and nitrogen (N) contents decreased up to 36 % and 72 %, respectively, while a greater reduction was observed in the presence of SCW. More non-hydrocarbon gases (H₂S, CO₂ and CO) were produced in the presence of SCW. SEM images showed that an extended residence time led to a shift in coke morphology towards a more uniform and compact structure, regardless of the upgrading environment. However, the porous structures of coke samples obtained under SCW are distinguished from those formed without water, which is attributed to the phase inversion of precursors. The findings of this study confirm that SCW plays a beneficial role as a solvent in the partial upgrading of bitumen, expediting the process. However, the increased level of coke formation and olefin contents suggest that it may not function effectively as a hydrogen donor in the process.

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用超临界水部分提纯沥青--液体产品特征、气体成分和焦炭形态

该研究旨在探讨沥青在无水（非水）和有超临界水（SCW）的情况下的部分升级。在目标温度为 420 °C、反应时间为零至 60 分钟的间歇式反应器中进行了部分升级实验。对液体产品进行了密度、粘度、成分、总酸值（TAN）、烯烃含量和元素分析。还研究了气体成分和固体产品的形态。实验结果表明，用 SCW 对沥青进行部分提质可以加快油质的改善，特别是在 API 和粘度方面，但同时也会导致气体和焦炭形成水平的升高。此外，随着停留时间的延长，两种环境（无 SCW 和有 SCW）下油馏分分布的差异也会减小。此外，随着停留时间的延长，与无水条件相比，在 SCW 条件下降低 TAN 的效率也会降低。与无水条件下的烯烃含量（1.8-2.7 wt %）相比，在 SCW 环境下获得的液体产品的烯烃含量更高（3-4 wt %）。在这两种环境中，烯烃含量最初在停留时间为 20 分钟时有所增加，随后有所减少。在杂原子方面，硫（S）和氮（N）的含量分别降低了 36% 和 72%，而在有 SCW 的情况下，降低幅度更大。有 SCW 存在时，会产生更多的非碳氢化合物气体（HS、CO 和 CO）。扫描电子显微镜图像显示，无论升级环境如何，停留时间的延长都会导致焦炭形态向更均匀、更紧凑的结构转变。然而，在 SCW 条件下获得的焦炭样品的多孔结构有别于无水条件下形成的焦炭样品，这归因于前驱体的相反转。本研究的结果证实，在沥青的部分升级过程中，SCW 作为溶剂发挥了有益的作用，加快了升级过程。然而，焦炭形成和烯烃含量的增加表明，在这一过程中，它可能无法有效发挥氢供体的作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Supercritical Fluids 工程技术-工程：化工

CiteScore

7.60

自引率

10.30%

发文量

236

审稿时长

56 days

期刊介绍： The Journal of Supercritical Fluids is an international journal devoted to the fundamental and applied aspects of supercritical fluids and processes. Its aim is to provide a focused platform for academic and industrial researchers to report their findings and to have ready access to the advances in this rapidly growing field. Its coverage is multidisciplinary and includes both basic and applied topics. Thermodynamics and phase equilibria, reaction kinetics and rate processes, thermal and transport properties, and all topics related to processing such as separations (extraction, fractionation, purification, chromatography) nucleation and impregnation are within the scope. Accounts of specific engineering applications such as those encountered in food, fuel, natural products, minerals, pharmaceuticals and polymer industries are included. Topics related to high pressure equipment design, analytical techniques, sensors, and process control methodologies are also within the scope of the journal.