Guest editorial

IF 2.4 Q2 BUSINESS, FINANCE
Awad Elsayed Awad Ibrahim, Khaled Hussainey
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引用次数: 0

Abstract

ENERGY Systems Integration (ESI) is the process of coordinating the operation and planning of energy systems across multiple pathways and/or geographical scales to deliver reliable, cost-effective energy services with minimal impact on the environment. Energy systems have evolved from individual systems with little or no dependencies into a complex set of integrated systems at scales that include customers, cities, and regions. This evolution has been driven by political, economic, and environmental objectives. As we try to meet the globally recognized imperative to reduce carbon emissions through the deployment of large renewable energy capacities while also maintaining reliability and competitiveness, flexible energy systems are required. This flexibility can be attained through integrating various systems: by physically linking energy vectors, namely electricity, heat, and fuels; by coordinating these vectors across other infrastructures, namely water, data, and transport; by institutionally coordinating energy markets; and, spatially, by increasing market footprint with granularity all the way down to the customer level. Smart grids and ESI are related, in particular, the coupling between electricity, consumers, data and transport. This special section focuses on the aspects of ESI where electricity is coupled to water, heat and fuels and where this coupling brings challenges and/or opportunities. The seven papers in this special section originate from Europe, Asia, North America and Australasia and several of the papers had multiple authors spread across the globe illustrating the international importance of ESI and the collaborations that have developed. The papers cover nearly the full range of ESI sub themes including the coupling between electricity with fuels, heat, gas; the coupling across scales and coupling with other infrastructures (e.g., water). Coupling between electricity and transport is a missing theme but not surprising considering the attention this topic has had in the past decade in the literature. Optimization at a planning and/or an operational time frame is central to nearly all the papers. The energy hub concept introduced over a decade ago by Geidl et al. at ETH Zurich features strongly in the literature survey sections of many of the papers, highlighting the importance of the concept. Renewables integration is an important driver of ESI highlighted in nearly all the papers. The flexibility benefits of integrated energy systems are highlighted throughout by a set of case studies that range from small district heating systems to national scale systems. Enhanced reliability, economic benefits and reductions in emissions all feature strongly across the seven papers and all stem from the ESI approach.
客座编辑
能源系统集成(ESI)是跨多种途径和/或地理尺度协调能源系统的运行和规划的过程,以提供可靠的、具有成本效益的能源服务,同时对环境的影响最小。能源系统已经从很少或没有依赖关系的单个系统演变为包括客户、城市和地区在内的规模复杂的集成系统集。这种演变是由政治、经济和环境目标驱动的。通过部署大型可再生能源产能,同时保持可靠性和竞争力,我们努力实现全球公认的减少碳排放的当务之急,因此需要灵活的能源系统。这种灵活性可以通过整合各种系统来实现:通过物理连接能量载体,即电、热和燃料;通过在其他基础设施(即水、数据和运输)之间协调这些载体;从制度上协调能源市场;并且,在空间上,通过增加粒度一直到客户级别的市场足迹。智能电网和ESI是相关的,特别是电力、消费者、数据和运输之间的耦合。本专题将重点介绍电与水、热和燃料耦合的ESI方面,以及这种耦合带来的挑战和/或机遇。本专题的七篇论文来自欧洲、亚洲、北美和大洋洲,其中几篇论文的多名作者分布在全球各地,说明了ESI的国际重要性和已经发展起来的合作。这些论文几乎涵盖了ESI的所有子主题,包括电与燃料、热、气之间的耦合;跨尺度的耦合以及与其他基础设施(例如水)的耦合。电力和交通之间的耦合是一个缺失的主题,但考虑到这个主题在过去十年的文献中受到的关注,这并不奇怪。在计划和/或操作时间框架上的优化几乎是所有论文的核心。十多年前,Geidl等人在苏黎世联邦理工学院提出了能源中心的概念,在许多论文的文献调查部分中都有很强的特色,突出了这个概念的重要性。可再生能源整合是ESI的重要驱动因素,几乎所有论文都强调了这一点。从小型区域供热系统到全国范围的系统,通过一系列案例研究,强调了综合能源系统的灵活性优势。提高可靠性、经济效益和减少排放在这七篇论文中都有很强的特点,而且都源于ESI方法。
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
Accounting Research Journal
Accounting Research Journal BUSINESS, FINANCE-
CiteScore
5.00
自引率
0.00%
发文量
13
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