Smart City Gnosys

Smart city article details

Title Modelling And Optimisation In The Design Of Green Hydrogen Cities - A Case Study Of Shanghai
ID_Doc 37662
Authors Wang H.; Cui G.; Guo Y.; Jiang J.
Year 2024
Published Chemical Engineering Transactions , 113
DOI http://dx.doi.org/10.3303/CET24113002
Abstract Given the urgent necessity of addressing the climate crisis, there is a worldwide tendency to achieve rapid decarbonisation across various sectors of the economy, especially within the urban areas. Recently, hydrogen has been considered as a solid solution of the future urban net-zero energy system. Due to its high energy density, hydrogen has great potential to decarbonise the key urban sectors such as transportation, heating, and electricity. The objective of this study is to not only provide an overview on the concept of Green Hydrogen City but to develop a comprehensive energy planning methodology utilising hydrogen as the main source through a detailed case study of Shanghai. In this context, a hydrogen-based energy system model is presented and applied to Shanghai. This model evaluates the feasibility of utilising renewable energy sources for local hydrogen production, storage, and consumption across Shanghai's electricity, heating, and transportation sectors. It considers operational, technical, and resource constraints to optimise the integration of hydrogen technologies within the urban energy system. It can be concluded that the green hydrogen city concept holds substantial promise for future urban implementation, and this study offers methodological guidance to smart city planners and decision-makers striving for decarbonization solutions and a carbon-free urban economy. Copyright © 2024, AIDIC Servizi S.r.l.
Author Keywords


Similar Articles

Id Similarity Authors Title Published
57039 View0.905Gheorghe L.; Lucian M.; Dorel S.; Florentina-Cătălina N.The Transition To An Eco-Friendly City As A First Step Toward Climate Neutrality With Green HydrogenTechnologies, 13, 3 (2025)
46996 View0.901Wang J.; An Q.; Zhao Y.; Pan G.; Song J.; Hu Q.; Tan C.-W.Role Of Electrolytic Hydrogen In Smart City Decarbonization In ChinaApplied Energy, 336 (2023)
32009 View0.88Suresh A.R.; Venkatasubramanian R.; Hussien Jasim L.; Santhoshkumar M.P.; Aggarwal S.; Kale M.Integrating Hydrogen Energy Storage Into Urban Mobility SolutionsE3S Web of Conferences, 540 (2024)
51332 View0.874Kabir S.; Hoque M.J.-A.-M.; Adnan M.A.; Shufian A.; Rashid Mahin M.S.; Aman A.U.; Raasetti M.Smart Power Systems For Smart Cities: Architectural Development And Economic Performance AssessmentIEEE Region 10 Humanitarian Technology Conference, R10-HTC (2023)
43323 View0.867Canales C.P.; Kristófersson D.M.; Kristjánsdóttir H.; Sigfúsdóttir S.Production, Storage, And Usage Of Green Hydrogen As An Opportunity For The Development Of Smart Cities: The Case Of Reykjavik, IcelandSmart Cities in Europe and Asia: Urban Planning and Management for a Sustainable Future (2023)
38334 View0.863Li J.; Chen J.; Yuan Z.; Xu L.; Zhang Y.; Al-Bahrani M.Multi-Objective Risk-Constrained Optimal Performance Of Hydrogen-Based Multi Energy Systems For Future Sustainable SocietiesSustainable Cities and Society, 87 (2022)
36232 View0.862Calandra D.; Wang T.; Cane M.; Alfiero S.Management Of Hydrogen Mobility Challenges: A Systematic Literature ReviewJournal of Cleaner Production, 410 (2023)
57956 View0.861Sertsöz M.Towards A Synthetic Positive Energy District (Ped) In İstanbul: Balancing Cost, Mobility, And Environmental ImpactBuildings, 14, 10 (2024)
19322 View0.858Akdeniz O.; Olgac E.; Karasan A.Determination Of Cause-Effect Relation Among Success Factors Of Small-Scale Hydrogen Valley Site Selection For Smart City Energy Security2024 International Conference on Innovation and Intelligence for Informatics, Computing, and Technologies, 3ICT 2024 (2024)
59953 View0.852Kumar D.Urban Energy Systems: Modeling And Simulation For Smart CitiesUrban Energy Systems: Modeling and Simulation for Smart Cities (2023)