| Title | Development and validation of theoretical-computational model for nuclear powered hydrogen production: A case study for Saudi Arabia |
|---|---|
| ID_Doc | 12726 |
| Authors | Khan, SUD; Al-Hamdan, A; Almutairi, Z |
| Title | Development and validation of theoretical-computational model for nuclear powered hydrogen production: A case study for Saudi Arabia |
| Year | 2022 |
| Published | |
| Abstract | Recently, the Kingdom of Saudi Arabia announced plans to build a green hydrogen power plant that will run on 4 GW of renewable energy, the largest hydrogen production project in the world to date. This is a defining moment for the Kingdom's development and a key element of Saudi Vision 2030, which contributes to the strategy for clean energy and a circular economy, and nuclear cogeneration for hydrogen production can support such a pragmatic move. Therefore, the current study focuses on the production of hydrogen gas in a hightemperature gas-cooled reactor (HTGR) using the thermochemical energy of sodium iodine (SI) for water decomposition. The study investigates the performance of the HTGR cogeneration system for both electricity and hydrogen gas production under different operating scenarios. Based on the developed deterministic mathematical model, which includes 1800 operating scenarios, an energy-related cost analysis is provided. The technoeconomic analysis showed that the maximization of hydrogen production for the HTGR process results in a maximum thermal exergy with an energetic efficiency of 70 % and a production rate of 105,615 m3/h at the lowest production cost of 7.7 cents/m3. The cost of electricity production from cogeneration was calculated as 3.23 cents/kWh, compared to other renewable energy sources (5 cents/kWh). This optimal operating scenario was selected to provide information needed to attract investment in Saudi Arabia for the deployment of this promising cogeneration technology based on deterministic exergy cost analysis approach. |
Similar Articles
| ID | Score | Article |
|---|---|---|
12674
|
Barghash, H; Al Farsi, A; Okedu, KE; Al-Wahaibi, BM Cost benefit analysis for green hydrogen production from treated effluent: The case study of Oman(2022) | |
| 9758
|
Martínez-Rodríguez, A; Abánades, A Comparative Analysis of Energy and Exergy Performance of Hydrogen Production Methods(2020)Entropy, 22.0, 11 | |
| 686
|
Kabir, MM; Akter, MM; Huang, ZG; Tijing, L; Shon, HK Hydrogen production from water industries for a circular economy(2023) | |
| 15144
|
Assunçao, R; Eckl, F; Ramos, CP; Correia, CB; Neto, RC Oxygen liquefaction economical value in the development of the hydrogen economy(2024) | |
| 6226
|
Ayub, Y; Ren, JZ; He, C; Azzaro-Pantel, C Co-gasification of biomass and plastic waste for green and blue hydrogen Production: Novel process development, economic, exergy, advanced exergy, and exergoeconomics analysis(2024) | |
| 32934
|
Nikolaidis, P; Poullikkas, A A comparative overview of hydrogen production processes(2017) | |
| 64565
|
Mokrzycki, E; Gawlik, L The Development of a Green Hydrogen Economy: Review(2024)Energies, 17, 13 | |
| 6549
|
Zelenika, I; Mavar, KN; Medved, I; Pavlovic, D Sustainable Energy Solutions: Utilising UGS for Hydrogen Production by Electrolysis(2024)Applied Sciences-Basel, 14, 15 | |
| 9081
|
Ipsakis, D; Varvoutis, G; Lampropoulos, A; Papaefthimiou, S; Marnellos, GE; Konsolakis, M Techno-economic assessment of industrially-captured CO2 upgrade to synthetic natural gas by means of renewable hydrogen(2021) | |
| 26588
|
Rambhujun, N; Salman, MS; Wang, T; Pratthana, C; Sapkota, P; Costalin, M; Lai, QW; Aguey-Zinsou, KF Renewable hydrogen for the chemical industry(2020) |