Development of deterministic-stochastic model to integrate variable renewable energy-driven electricity and large-scale utility networks: Towards decarbonization petrochemical industry

Development of deterministic-stochastic model to integrate variable renewable energy-driven electricity and large-scale utility networks: Towards decarbonization petrochemical industry

This paper aims to develop the mathematical model of electricity based on renewable energy and large-scale utility (eRELU) networks to achieve a low-carbon economy. Huge petrochemical industries allocated in South Korea are considered to evaluate the proposed model by techno-economic and environment...

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Bibliographic Details
Published in:Energy (Oxford) Vol. 238; p. 122006
Main Authors: Hwangbo, Soonho, Heo, SungKu, Yoo, ChangKyoo
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-01-2022
Elsevier BV
Subjects:
Boilers
Carbon
Carbon sequestration
Clean energy
Climate change
Decarbonization
Economic models
Electricity
Energy
Energy policy
Energy storage
Energy transition
Environmental assessment
Greenhouse gases
Large-scale utility network
Mathematical models
Mathematical programming
Networks
Operating costs
Parameter uncertainty
Petrochemical industry
Petrochemicals industry
Renewable energy
Renewable energy policy
Renewable resources
Stochastic models
Stochasticity
Storage systems
Variable renewable electricity
Petrochemical industry
Climate change
Large-scale utility network
Renewable energy policy
Variable renewable electricity
Mathematical programming
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Summary:This paper aims to develop the mathematical model of electricity based on renewable energy and large-scale utility (eRELU) networks to achieve a low-carbon economy. Huge petrochemical industries allocated in South Korea are considered to evaluate the proposed model by techno-economic and environmental assessment subject to Korean renewable energy policy. The suggested mathematical model consists of two parts: the deterministic model to optimize industrial-scale utility networks and the stochastic model to construct clean electricity networks using variable renewable energy coupled with energy storage systems to provide feasible quantities of renewable electricity required from the optimized utility network. The resulting model is complemented by carbon capture and storage (CCS) systems in doing so the inevitable amount of greenhouse gases from boilers in utility networks can be significantly captured. Diverse scenarios under the uncertain parameters such as facility investment/operating costs and capacity factors of renewable energy are applied to the developed model, and the results show that the best scenario-based eRELU-CCS network reduces 16% of the total costs and capture/mitigate 114 tCO2/d comparing to the base case. It is expected that the proposed model will play an essential role in advancing the country's energy transition. [Display omitted] •Mathematical model developed for renewable energy and large-scale utility network.•CCS technology is combined with the optimized utility network for low-carbon economy.•A case study of huge petrochemical industries in South Korea were applied.•Scenario-based techno-economic and environmental assessment was conducted.•16% of total economic costs and 114 tCO2/d of GHG emissions were reduced.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2021.122006