Ş. Galusnyak, L. Petrescu, Dora-Andreea Chisalita, C. Cormos
{"title":"Life Cycle Assessment of Bio-methanol Derived from Various Raw-materials","authors":"Ş. Galusnyak, L. Petrescu, Dora-Andreea Chisalita, C. Cormos","doi":"10.3303/CET2186112","DOIUrl":null,"url":null,"abstract":"Bio-methanol production from biomass or from carbon dioxide and hydrogen, generated using renewable electricity, are considered to be sustainable routes nowadays. The aim of the present study consists on the environmental evaluation of bio-methanol production using Life Cycle Assessment (LCA) methodology. Two different bio-methanol production processes such as bio-methanol production from an external CO2 stream and H2 from water electrolysis, electricity being produced using various sources (i.e. biomass, solar, wind, and hydro or mix electricity) as well as woody biomass gasification for syngas production, syngas being further transformed into bio-methanol, are considered in the current study. The processes were simulated using computer aided design tools (i.e. ChemCAD and Aspen Plus process simulators). The environmental assessment is carried out using GaBi software. The LCA is a cradle-to-gate study with the following system boundaries: a) upstream processes (i.e. biomass, solvent and electricity supply chains, H2 production, catalysts production and transportation); b) main processes: bio-methanol production through direct gasification and from CO2 hydrogenation and c) downstream processes: solvent degradation and disposal of wastes. The production of one ton of bio-methanol was considered as functional unit in the present investigation. ReCIPe method was chosen as life cycle impact assessment method. Purities higher than 99% are obtained for the main product. Significant environmental impact categories (i.e. Global Warming Potential, Human Toxicity Potential, Fossil Depletion Potential) are discussed and the influence of various sub-processes is investigated. For instance, the best result in terms of Human Toxicity Potential, 12.30 kg 1,4-DB eq./tMeOH, was obtained in the case of hydroelectric sources, while the same indicator was at least two times higher for other scenarios. From the environmental point of view, the scenario which relies on hydroelectric power performed better in six out of nine environmental impact categories as compared to other scenarios, being succeeded by the one considering wind power as electricity source.","PeriodicalId":9695,"journal":{"name":"Chemical engineering transactions","volume":"145 1","pages":"667-672"},"PeriodicalIF":0.0000,"publicationDate":"2021-06-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Chemical engineering transactions","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3303/CET2186112","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Chemical Engineering","Score":null,"Total":0}
引用次数: 1
Abstract
Bio-methanol production from biomass or from carbon dioxide and hydrogen, generated using renewable electricity, are considered to be sustainable routes nowadays. The aim of the present study consists on the environmental evaluation of bio-methanol production using Life Cycle Assessment (LCA) methodology. Two different bio-methanol production processes such as bio-methanol production from an external CO2 stream and H2 from water electrolysis, electricity being produced using various sources (i.e. biomass, solar, wind, and hydro or mix electricity) as well as woody biomass gasification for syngas production, syngas being further transformed into bio-methanol, are considered in the current study. The processes were simulated using computer aided design tools (i.e. ChemCAD and Aspen Plus process simulators). The environmental assessment is carried out using GaBi software. The LCA is a cradle-to-gate study with the following system boundaries: a) upstream processes (i.e. biomass, solvent and electricity supply chains, H2 production, catalysts production and transportation); b) main processes: bio-methanol production through direct gasification and from CO2 hydrogenation and c) downstream processes: solvent degradation and disposal of wastes. The production of one ton of bio-methanol was considered as functional unit in the present investigation. ReCIPe method was chosen as life cycle impact assessment method. Purities higher than 99% are obtained for the main product. Significant environmental impact categories (i.e. Global Warming Potential, Human Toxicity Potential, Fossil Depletion Potential) are discussed and the influence of various sub-processes is investigated. For instance, the best result in terms of Human Toxicity Potential, 12.30 kg 1,4-DB eq./tMeOH, was obtained in the case of hydroelectric sources, while the same indicator was at least two times higher for other scenarios. From the environmental point of view, the scenario which relies on hydroelectric power performed better in six out of nine environmental impact categories as compared to other scenarios, being succeeded by the one considering wind power as electricity source.
利用可再生电力从生物质或二氧化碳和氢气中生产生物甲醇,目前被认为是可持续的路线。本研究的目的是利用生命周期评价(LCA)方法对生物甲醇生产进行环境评价。目前的研究考虑了两种不同的生物甲醇生产工艺,如从外部CO2流中生产生物甲醇和从水电解中生产氢气,利用各种来源(即生物质、太阳能、风能和水力或混合电力)生产电力,以及木质生物质气化生产合成气,合成气进一步转化为生物甲醇。使用计算机辅助设计工具(即ChemCAD和Aspen Plus过程模拟器)对过程进行模拟。环境评价采用GaBi软件进行。LCA是一个从摇篮到门的研究,具有以下系统边界:a)上游过程(即生物质、溶剂和电力供应链、H2生产、催化剂生产和运输);b)主要工艺:通过直接气化和二氧化碳加氢生产生物甲醇;c)下游工艺:溶剂降解和废物处理。本研究以生产一吨生物甲醇为功能单元。选择配方法作为生命周期影响评价方法。主要产品的纯度高于99%。讨论了重要的环境影响类别(即全球变暖潜力,人类毒性潜力,化石枯竭潜力),并调查了各种子过程的影响。例如,在水力发电的情况下,人体毒性潜力的最佳结果为12.30 kg 1.4 db当量/tMeOH,而在其他情况下,同样的指标至少高出两倍。从环境的角度来看,与其他情景相比,依赖水力发电的情景在9个环境影响类别中的6个方面表现更好,其次是将风力发电作为电力来源的情景。
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
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