Robust Planning for Hydrogen‐Based Multienergy System Considering P2HH and Seasonal Hydrogen Storage

Since renewable energy is rapidly growing in the active distribution networks, the integrated energy system coupled with energy storage is a promising way to address the intermittent issues of renewable sources. This paper proposes an optimal planning model for the hydrogen‐based integrated energy s...

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Bibliographic Details
Published in:International transactions on electrical energy systems 2024-01, Vol.2024 (1)
Main Authors: Wang, Shufan, Yang, Dong, Zhang, Linglu, Chenmei, Lingzhi
Format: Article
Language:English
Subjects:
Algorithms
Alternative energy sources
Carbon dioxide
Complex variables
Compressed natural gas
Constraints
Contingency
Electricity
Electricity distribution
Energy distribution
Energy industry
Energy storage
Flexibility
Fossil fuels
Heat
Hydrogen
Hydrogen production
Hydrogen storage
Independent variables
Integrated energy systems
Mathematical programming
Mixed integer
Renewable energy
Renewable resources
Robustness
Stochastic programming
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Summary:Since renewable energy is rapidly growing in the active distribution networks, the integrated energy system coupled with energy storage is a promising way to address the intermittent issues of renewable sources. This paper proposes an optimal planning model for the hydrogen‐based integrated energy system (HIES) considering power to heat and hydrogen (P2HH) and seasonal hydrogen storage (SHS) to take full advantage of multienergy complementarity. To tackle the unstable factors introduced by renewable sources and varying loads, we apply robust optimization and stochastic programming theory to improve the robustness of the planning results. Meanwhile, we also consider the N‐1 contingency constraints to make the technology selection, capacity allocation, and economic operation more reliable. The complex constraints resulting from producing two independent binary variables are converted into mixed integer linear constraints, which can be solved effectively using the nested column‐and‐constraint generation algorithm. Numerical simulation demonstrates the effectiveness of the P2HH and SHS in reducing the total cost of the HIES planning.
ISSN:2050-7038
2050-7038
DOI:10.1155/2024/1156761