Product Distribution and Deactivation of Y-zeolite Based Catalyst in the Catalytic Cracking of Biomass Pyrolysis Oil

Q3 Chemical Engineering

Chemical engineering transactions Pub Date : 2021-06-15 DOI:10.3303/CET2186145

Beatriz Valle, J. Bilbao, A. Aguayo, A. Gayubo

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Abstract

The valorization of bio-oil by catalytic cracking is a promising route for producing hydrocarbon fuels as an alternative to oil. This work addresses the cracking of bio-oil over HY zeolite catalyst (Si/Al = 15) in a continuous reaction system composed of two-step on line (thermal + catalytic). The effect that temperature has on the bio-oil conversion and the distribution of reaction products is studied. The catalyst was synthetized by agglomerating the zeolite powder with inert filler and binder, and the raw bio-oil was stabilized by adding 20 wt% MeOH. Operating condition were: 500 oC (thermal unit); 400-500 oC and space-time, 0.7 gcatalysth/gfeed (fluidized bed reactor). Attention is also paid to the catalyst deactivation, analyzing the spent catalyst samples by different techniques (N2 adsorption-desorption, adsorption/cracking/desorption of t-BA, and TGA-TPO). The results evidence a significant influence of temperature on the yield and composition of products. Although the LPG (C3-C4) hydrocarbons are the main products at 400 oC, the increase in temperature notably promotes the conversion of oxygenates into C5+ hydrocarbons, which are the majority products above 450 oC. Operation at 500 oC has the advantages of both maximizing the production of a liquid fuel composed of 74 % C5-C12 gasoline fraction (rich in 1-ring aromatics and C6-C7 cycloalkanes), and also attenuating the catalyst deactivation. Furthermore, the catalyst deactivation at 400 oC and 450 oC is faster than that observed at 500 oC, despite the lower formation of coke. This fact is explained by the different nature and location of the coke deposited in the porous structure of the catalyst.

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生物质热解油催化裂化过程中y型沸石基催化剂的产物分布及失活

催化裂化生物油是一种很有前途的替代石油的烃类燃料生产途径。研究了HY沸石催化剂(Si/Al = 15)在热+催化两步在线连续反应系统上裂解生物油的问题。研究了温度对生物油转化及反应产物分布的影响。催化剂由沸石粉与惰性填料和粘结剂团聚而成，原料油通过加入20 wt%的甲醇进行稳定。运行工况为:500℃(热单位);400-500℃和时空，0.7 gcatalyst /gfeed(流化床反应器)。对催化剂失活进行了研究，采用不同的技术(N2吸附-脱附、t-BA吸附/裂解/脱附、TGA-TPO)对废催化剂样品进行了分析。结果表明，温度对产物的收率和组成有显著的影响。虽然在400℃时主要产物是LPG (C3-C4)烃，但温度的升高显著促进了含氧化合物向C5+烃的转化，而C5+烃是450℃以上的主要产物。在500℃下操作的优点是，既可以最大限度地生产由74%的C5-C12汽油馏分(富含1环芳烃和C6-C7环烷烃)组成的液体燃料，也可以减轻催化剂的失活。此外，在400℃和450℃时，催化剂的失活速度比在500℃时更快，尽管焦炭的形成较低。这一事实可以用沉积在催化剂多孔结构中的焦炭的不同性质和位置来解释。

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

Chemical engineering transactions Chemical Engineering-Chemical Engineering (all)

CiteScore

1.40

自引率

0.00%

发文量

审稿时长

6 weeks

期刊介绍： Chemical Engineering Transactions (CET) aims to be a leading international journal for publication of original research and review articles in chemical, process, and environmental engineering. CET begin in 2002 as a vehicle for publication of high-quality papers in chemical engineering, connected with leading international conferences. In 2014, CET opened a new era as an internationally-recognised journal. Articles containing original research results, covering any aspect from molecular phenomena through to industrial case studies and design, with a strong influence of chemical engineering methodologies and ethos are particularly welcome. We encourage state-of-the-art contributions relating to the future of industrial processing, sustainable design, as well as transdisciplinary research that goes beyond the conventional bounds of chemical engineering. Short reviews on hot topics, emerging technologies, and other areas of high interest should highlight unsolved challenges and provide clear directions for future research. The journal publishes periodically with approximately 6 volumes per year. Core topic areas: -Batch processing- Biotechnology- Circular economy and integration- Environmental engineering- Fluid flow and fluid mechanics- Green materials and processing- Heat and mass transfer- Innovation engineering- Life cycle analysis and optimisation- Modelling and simulation- Operations and supply chain management- Particle technology- Process dynamics, flexibility, and control- Process integration and design- Process intensification and optimisation- Process safety- Product development- Reaction engineering- Renewable energy- Separation processes- Smart industry, city, and agriculture- Sustainability- Systems engineering- Thermodynamic- Waste minimisation, processing and management- Water and wastewater engineering