Abstract
The rapid growth of electric load fuels urbanization but creates unsettling environmental challenges. In that regard, the energy system is a crucial part of consuming water and emitting greenhouse gases. To support reliable and economical energy system operations, with reduced water waste and carbon emissions, we design a viable co-optimization of water-energy-carbon nexus for an integrated energy system by adequately modelling essential interdependencies of power, gas, and water systems. A two-stage distributionally robust optimization method is proposed: the first-stage model minimizes the day-ahead reserve capacity scheduling for the next day, and the second-stage model enables real-time dispatch by considering the variability in renewable power generation. The carbon emissions by power generation and distribution are incorporated in both stages to ensure low-carbon operations. We use a two-stage moment-based distributionally robust approach to capture and represent the uncertainties in renewable generation. Instead of assuming a deterministic distribution, we characterize an ambiguity set with mean vectors and covariance matrices, which produces a family set of distributions. We conduct case studies using a modified IEEE 33-bus power system that includes and links a 20-node gas system and a 10-node water system. The comparative results indicate that the proposed co-optimization of water-energy-carbon nexus is superior than several benchmarks. By considering the close interdependencies of water, energy, and carbon, we create an optimal resource allocation scheme, which is capable of minimizing operation costs, lessening carbon emissions, and reducing water waste. The current research enables effective operation schemes for urban energy systems, illustrates a viable way to curb local environmental emissions, and increases water usage efficiency in the water-energy-carbon nexus.
Original language | English |
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Pages (from-to) | 4432-4446 |
Number of pages | 15 |
Journal | IEEE Transactions on Power Systems |
Volume | 38 |
Issue number | 5 |
Early online date | 13 Oct 2022 |
DOIs | |
Publication status | Published - 30 Sept 2023 |
Funding
This work was supported in part by the National Natural Science Foundation ofChina underGrants 72025404, 71621002, and 71974187, in part by theNewGenerationArtificial Intelligence Development Plan of China (2015-2030) under Grant 2021ZD0111205), in part by Beijing Natural Science Foundation underGrant L192012, and in part by the BeijingNova Program under Grant Z201100006820085. Paper no. TPWRS-00266-2022. The authors are grateful to Paul Jen-HwaHuand Daniel Dajun Zeng (IEEE Fellow) for proofreading this paper
Funders | Funder number |
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Intelligence Development Plan of China | 2015-2030, 2021ZD0111205 |
National Natural Science Foundation of China | 71974187, 71621002, 72025404 |
National Natural Science Foundation of China | |
Natural Science Foundation of Beijing Municipality | L192012 |
Natural Science Foundation of Beijing Municipality | |
Beijing Nova Program | TPWRS-00266-2022, Z201100006820085 |
Beijing Nova Program |
Keywords
- Carbon reduction
- energy management
- renewable energy sources
- water-energy-carbon nexus system
ASJC Scopus subject areas
- Energy Engineering and Power Technology
- Electrical and Electronic Engineering