工业脱碳的高技术和时间分辨率集成能源系统建模

IF 13 Q1 ENERGY & FUELS
Sánchez Diéguez Manuel , Taminau Floris , West Kira , Sijm Jos , Faaij André
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引用次数: 5

摘要

由于该部门的复杂性,工业活动通常在综合能源系统模型中以有限的技术分辨率表示。在本研究中,我们在综合能源系统分析优化(IESA-Opt)模型中丰富了工业活动的技术描述,这是一个同行评审的能源系统优化模型,可以同时为所有综合部门的每小时运行提供最佳容量规划。我们使用这个丰富的模型来分析荷兰工业脱碳的四个关键活动:高价值化学品、碳氢化合物、氨和钢铁生产。所进行的分析包括:1)探索参考场景中的最优性;2)探索生物基工业、氢基工业、全电气化工业以及将现有资产改造为碳捕获利用和封存的四种不同技术原型的极端工业案例的可行性和意义;3)对进口生物质、氢气和天然气价格、碳储存潜力、技术学习和烯烃需求等关键主题进行敏感性分析。这项研究的结果表明,对于能源系统来说,拥有一个完全基于生物基、氢基、完全电气化和改造的行业来实现完全脱碳是可行的,同时允许最佳技术组合产生至少10%的廉价转型。我们还表明,由于燃料成分在工业产品的平均成本中占很高的优势,绿色技术的隔夜投资成本的大幅减少对其采用的影响有限。最后,我们发现,根据目前(2022年)的能源价格,能源转型是具有成本效益的,到2050年化石燃料可以完全取代工业和国家结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
High technical and temporal resolution integrated energy system modelling of industrial decarbonisation

Owing to the complexity of the sector, industrial activities are often represented with limited technological resolution in integrated energy system models. In this study, we enriched the technological description of industrial activities in the integrated energy system analysis optimisation (IESA-Opt) model, a peer-reviewed energy system optimisation model that can simultaneously provide optimal capacity planning for the hourly operation of all integrated sectors. We used this enriched model to analyse the industrial decarbonisation of the Netherlands for four key activities: high-value chemicals, hydrocarbons, ammonia, and steel production. The analyses performed comprised 1) exploring optimality in a reference scenario; 2) exploring the feasibility and implications of four extreme industrial cases with different technological archetypes, namely a bio-based industry, a hydrogen-based industry, a fully electrified industry, and retrofitting of current assets into carbon capture utilisation and storage; and 3) performing sensitivity analyses on key topics such as imported biomass, hydrogen, and natural gas prices, carbon storage potentials, technological learning, and the demand for olefins. The results of this study show that it is feasible for the energy system to have a fully bio-based, hydrogen-based, fully electrified, and retrofitted industry to achieve full decarbonisation while allowing for an optimal technological mix to yield at least a 10% cheaper transition. We also show that owing to the high predominance of the fuel component in the levelled cost of industrial products, substantial reductions in overnight investment costs of green technologies have a limited effect on their adoption. Finally, we reveal that based on the current (2022) energy prices, the energy transition is cost-effective, and fossil fuels can be fully displaced from industry and the national mix by 2050.

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来源期刊
Advances in Applied Energy
Advances in Applied Energy Energy-General Energy
CiteScore
23.90
自引率
0.00%
发文量
36
审稿时长
21 days
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