基于钙基吸收强化技术(CaL-SEP)实现低碳甲醇生产的过程分析与评价
ID:161 View Protection:PUBLIC Updated Time:2023-04-03 18:33:06 Hits:1840 Oral Presentation

Start Time:2023-04-07 16:30(Asia/Shanghai)

Duration:15min

Session:S5 分会场五:其他化学链体系 » S5-1其他化学链体系 1

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Abstract
Methanol is an important basic chemical, but its production generates a significant amount of CO2 not only because it is an energy-intensive process but also the raw material for methanol synthesis is fossil energy. Here, a sorption-enhanced process (SEP) technology was constructed and simulated using Aspen Plus based on the four processes of coal-to-methanol (CTM), natural gas-to-methanol (NTM), biomass-to-methanol (BTM), and biomass-to-methanol with biochar (BTMC). Using the life cycle assessment (LCA) method established fossil energy demand (FED) and global warming potential (GWP) indicators to analyze the fossil energy consumption and CO2 emissions of four processes. Compared to conventional routes, the SEP effectively reduced FED and GWP due to the reaction coupling, in-situ CO2 capture, and syngas upgrade in a reactor. In particular, the co-product of biochar and methanol process (BTMC) attained the best FED and GWP, which were -17.085 MJ/kg-methanol and -2.457 kgCO2-eq/kg-methanol, respectively. Additionally, this work investigated the impacts of CO2 capture, co-production, green energy (GE), and raw material substitution on FED and GWP. The best carbon effect (-5.793 kgCO2-eq/kg-methanol) was achieved using the BTMC&CC&GE process. And the BCH4-TM&GE process had the lowest FED (-75.498 MJ/kg-methanol). Thus, the work suggests that while CO2 capture effectively avoided CO2 emissions, GE and raw material substitution were the long-term development strategies. Thus, the work suggests that while CO2 capture effectively avoided CO2 emissions, GE and raw material substitution were the long-term development strategies.
 
Keywords
Biomass-to-methanol, Sorption-enhanced process, CO2 capture, Life cycle assessment, calcium looping
Speaker
蒋鹏
博士生 南京工业大学

蒋鹏 南京工业大学 化学工程与技术专业博士研究生,主要研究方向是生物质热解过程建模与生物质精炼过程评价(技术经济分析、生命周期评价),目前已经在该领域发表学术论文7篇,其中包括:Bioresource Technology、Green Energy & Environment、Applied Energy等。

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Important Date
  • Conference Date

    Apr 06

    2023

    to

    Apr 08

    2023

  • Apr 04 2023

    Contribution Submission Deadline

  • Apr 15 2023

    Registration deadline

  • Apr 30 2023

    Draft paper submission deadline

Sponsored By
昆明理工大学
Organized By
昆明理工大学
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