Coupling Variable Renewable Electricity Production to the Heating Sector through Curtailment and Power-to-heat Strategies for Accelerated Emission Reduction

Q1 Engineering
V. Arabzadeh, Sannamari Pilpola, P. Lund
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引用次数: 25

Abstract

The Paris Climate Accord and recent IPCC analysis urges to strive towards carbon neutrality by the middle of this century. As most of the end-use energy in Europe is for heating, or well above 60%, these targets will stress more actions in the heating sector. So far, much of the focus in the emission reduction has been on the electricity sector. For instance, the European Union has set as goal to have a carbon-free power system by 2050. Therefore, the efficient coupling of renewable energy integration to heat and heating will be part of an optimal clean energy transition. This paper applies optimization-based energy system models on national (Finland) and sub-national level (Helsinki) to include the heating sector in an energy transition. The models are based on transient simulation of the energy system, coupling variable renewable energies (VRE) through curtailment and power-to-heat schemes to the heat production system. We used large-scale wind power schemes as VRE in both cases. The results indicate that due to different energy system limitations and boundary conditions, stronger curtailment strategies accompanied with large heat pump schemes would be necessary to bring a major impact in the heating sector through wind power. On a national level, wind-derived heat could meet up to 40% of the annual heat demand. On a city level, the use of fossil fuel in combined heat and power production (CHP), typical for northern climates, could significantly be reduced leading even close to 70% CO2 emission reductions in Helsinki. Though these results were site specific, they indicate major opportunities for VRE in sectoral coupling to heat production and hence also a potential role in reducing the emissions.
将可变可再生电力生产与供暖部门耦合,通过削减和电力换热战略加速减排
《巴黎气候协定》和IPCC最近的分析敦促努力在本世纪中叶实现碳中和。由于欧洲的大部分最终用途能源用于供暖,或远高于60%,这些目标将强调供暖行业的更多行动。到目前为止,减排的重点大多集中在电力部门。例如,欧盟设定了到2050年实现无碳电力系统的目标。因此,可再生能源整合与供暖和供暖的有效耦合将是最佳清洁能源转型的一部分。本文在国家(芬兰)和次国家(赫尔辛基)层面应用基于优化的能源系统模型,将供暖部门纳入能源转型。该模型基于能源系统的瞬态模拟,通过限功率和功率-热量方案将可变可再生能源(VRE)耦合到供热系统。在这两种情况下,我们都使用了大型风电方案作为VRE。结果表明,由于不同的能源系统限制和边界条件,有必要采取更强有力的削减策略,同时采用大型热泵方案,通过风电对供暖行业产生重大影响。在国家层面上,风能可以满足高达40%的年热需求。在城市层面上,化石燃料在热电联产(CHP)中的使用(典型的北方气候)可以显著减少,从而使赫尔辛基的二氧化碳排放量减少近70%。尽管这些结果是针对特定地点的,但它们表明了VRE在部门与热量生产耦合方面的主要机会,因此也在减少排放方面发挥了潜在作用。
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
Future Cities and Environment
Future Cities and Environment Engineering-Architecture
CiteScore
3.10
自引率
0.00%
发文量
7
审稿时长
17 weeks
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