Conversion of lignin-derived ketonic intermediate to biofuel products: Syngas-assisted vs. Conventional hydrotreating

IF 7.2 2区 工程技术 Q1 CHEMISTRY, APPLIED Fuel Processing Technology Pub Date : 2024-03-19 DOI:10.1016/j.fuproc.2024.108077
Ali Bakhtyari , Adele Sakhayi , Mohammad Reza Rahimpour , Adolfo Iulianelli
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Abstract

A new strategy for the transformation of an intermediate of the lignin conversion process, namely cyclohexanone, to fuel-grade products is assessed in this study. In this regard, the conventional hydrodeoxygenation process (with pure hydrogen) was compared to an innovative one with a simulated lignin-derived syngas stream in a wide range of reaction conditions (300–400 °C, 1–15 bar, and small-to-large feed-to-catalyst ratios) and over commercial molybdenum-based (nickle‑molybdenum (NiMo) and cobalt‑molybdenum(CoMo)) catalysts. Cyclohexanone conversion, product distribution, deoxygenation efficacy, and heating value were compared in each case. Cyclohexanone was transformed into cyclohexane, cyclohexene, benzene, cresols, phenol, toluene, and bi-cyclic compounds, which are beneficial in jet-fuel processing. Increasing the reaction temperature and pressure intensified the conversion of cyclohexanone (up to 87.8% conversion at 400 °C and 15 bar over both NiMo and CoMo catalysts), whereas increasing the feed-to-catalyst ratio reduced it. Operating conditions and the reducing gas (pure hydrogen or syngas) had major impacts on the conversion of cyclohexanone, deoxygenation efficiency, product distribution, and the heating value of the final product blend. The results of this study claim that cyclohexanone conversion to fuel-grade hydrocarbons (up to 97.61% over NiMo and 74.71% over CoMo catalysts) is a beneficial route and the conventional hydrodeoxygenation process can be replaced with the syngas-assisted one with a small change in production capacity, still large positive impact on the sustainability and environmental footprints of lignin conversion to biofuels.

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将木质素衍生酮中间体转化为生物燃料产品:合成气辅助加氢处理与传统加氢处理的比较
本研究评估了将木质素转化过程的中间产物(即环己酮)转化为燃料级产品的新策略。在这方面,将传统的加氢脱氧工艺(使用纯氢)与创新的加氢脱氧工艺(使用模拟木质素衍生合成气流)进行了比较,后者在多种反应条件下(300-400 °C、1-15 巴、进料与催化剂的比例由小到大),在商用钼基(镍钼(NiMo)和钴钼(CoMo))催化剂上进行。对每种情况下的环己酮转化率、产品分布、脱氧效率和热值进行了比较。环己酮被转化为环己烷、环己烯、苯、甲酚、苯酚、甲苯和双环化合物,这些化合物有利于喷气燃料的加工。提高反应温度和压力可提高环己酮的转化率(镍钼催化剂和钴钼催化剂在 400 °C 和 15 巴条件下的转化率可达 87.8%),而提高原料与催化剂的比例则会降低转化率。操作条件和还原气体(纯氢气或合成气)对环己酮的转化率、脱氧效率、产品分布和最终混合产品的热值有很大影响。这项研究的结果表明,环己酮转化为燃料级碳氢化合物(在镍钼催化剂上转化率高达 97.61%,在钴钼催化剂上转化率高达 74.71%)是一条有益的途径,传统的加氢脱氧工艺可由合成气辅助工艺取代,但产能变化不大,对木质素转化为生物燃料的可持续性和环境足迹仍有很大的积极影响。
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来源期刊
Fuel Processing Technology
Fuel Processing Technology 工程技术-工程:化工
CiteScore
13.20
自引率
9.30%
发文量
398
审稿时长
26 days
期刊介绍: Fuel Processing Technology (FPT) deals with the scientific and technological aspects of converting fossil and renewable resources to clean fuels, value-added chemicals, fuel-related advanced carbon materials and by-products. In addition to the traditional non-nuclear fossil fuels, biomass and wastes, papers on the integration of renewables such as solar and wind energy and energy storage into the fuel processing processes, as well as papers on the production and conversion of non-carbon-containing fuels such as hydrogen and ammonia, are also welcome. While chemical conversion is emphasized, papers on advanced physical conversion processes are also considered for publication in FPT. Papers on the fundamental aspects of fuel structure and properties will also be considered.
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