分析核电在荷兰净零能源系统转型中的技术经济作用

IF 13 Q1 ENERGY & FUELS Advances in Applied Energy Pub Date : 2022-09-01 DOI:10.1016/j.adapen.2022.100103
Amirhossein Fattahi , Jos Sijm , Machteld Van den Broek , Rafael Martínez Gordón , Manuel Sanchez Dieguez , André Faaij
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引用次数: 2

摘要

为了分析核电在综合能源系统中的作用,我们使用了IESA-Opt-N成本最小化模型,重点关注四个关键主题:核电的全系统影响、不确定的技术成本、灵活发电和跨境电力贸易。我们证明,LCOE(电力平准化成本)不应该单独用来证明发电技术的经济可行性。例如,在默认的技术经济假设下,特别是5%的贴现率和外生电力贸易潜力,荷兰到2050年投资9.6 GWe的核电装机容量是成本最优的。然而,其LCOE比海上风电高34欧元/兆瓦时。此外,我们发现核电投资可以在短期内减少对可变可再生能源的需求,并在长期内降低能源独立性(即减少天然气,生物质和电力的进口)。此外,投资核电可以在2040年和2050年将荷兰能源系统的减排成本分别降低1.6%和6.2%,到2050年将全国二氧化碳价格降低25%。然而,考虑到核电融资成本上升和建设时间延长的可能性,这种成本降低并不显著。此外,在3%的利率价值(例如,欧盟分类法支持)下,即使是高成本的核电(100亿欧元/吉瓦)在荷兰也可以具有成本效益。总之,在本研究的具体假设下,从技术经济的角度来看,核电可以在支持荷兰能源转型方面发挥互补作用(与风能和太阳能并举)。
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Analyzing the techno-economic role of nuclear power in the Dutch net-zero energy system transition

To analyze the role of nuclear power in an integrated energy system, we used the IESA-Opt-N cost minimization model focusing on four key themes: system-wide impacts of nuclear power, uncertain technological costs, flexible generation, and cross-border electricity trade. We demonstrate that the LCOE (levelized cost of electricity) alone should not be used to demonstrate the economic feasibility of a power generation technology. For instance, under the default techno-economic assumptions, particularly the 5% discount rate and exogenous electricity trade potentials, it is cost-optimal for the Netherlands to invest in 9.6 GWe nuclear capacity by 2050. However, its LCOE is 34 €/MWh higher than offshore wind. Moreover, we found that nuclear power investments can reduce demand for variable renewable energy sources in the short term and higher energy independence (i.e., lower imports of natural gas, biomass, and electricity) in the long term. Furthermore, investing in nuclear power can reduce the mitigation costs of the Dutch energy system by 1.6% and 6.2% in 2040 and 2050, and 25% lower national CO2 prices by 2050. However, this cost reduction is not significant given the odds of higher nuclear financing costs and longer construction times. In addition, with 3% interest rate value (e.g., EU taxonomy support), even high cost nuclear (10 B€/GW) can be cost-effective in the Netherlands. In conclusion, under the specific assumptions of this study, nuclear power can play a complementary role (in parallel to the wind and solar power) in supporting the Dutch energy transition from the sole techno-economic point of view.

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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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